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EPM240F100C5N产品简介:
ICGOO电子元器件商城为您提供EPM240F100C5N由altera设计生产,在icgoo商城现货销售,并且可以通过原厂、代理商等渠道进行代购。 EPM240F100C5N价格参考。alteraEPM240F100C5N封装/规格:嵌入式 - CPLD(复杂可编程逻辑器件), 。您可以下载EPM240F100C5N参考资料、Datasheet数据手册功能说明书,资料中有EPM240F100C5N 详细功能的应用电路图电压和使用方法及教程。
参数 | 数值 |
产品目录 | 集成电路 (IC)半导体 |
描述 | IC CPLD 192MC 4.7NS 100FBGACPLD - 复杂可编程逻辑器件 CPLD - MAX II 192 Macro 80 IOs |
产品分类 | |
I/O数 | 80 |
品牌 | Altera Corporation |
产品手册 | |
产品图片 | |
rohs | 符合RoHS无铅 / 符合限制有害物质指令(RoHS)规范要求 |
产品系列 | 嵌入式处理器和控制器,CPLD - 复杂可编程逻辑器件,Altera Corporation EPM240F100C5NMAX® II |
数据手册 | |
产品型号 | EPM240F100C5N |
产品 | MAX II |
产品目录页面 | |
产品种类 | CPLD - 复杂可编程逻辑器件 |
供应商器件封装 | 100-FBGA(11x11) |
其它名称 | 544-1709 |
包装 | 托盘 |
可编程类型 | 系统内可编程 |
商标 | Altera Corporation |
大电池数量 | 192 |
存储类型 | Flash |
安装类型 | 表面贴装 |
安装风格 | SMD/SMT |
宏单元数 | 192 |
封装 | Tray |
封装/外壳 | 100-LBGA |
封装/箱体 | FBGA-100 |
工作温度 | 0°C ~ 85°C |
工作电源电压 | 2.5 V, 3.3 V |
工作电源电流 | 55 mA |
工厂包装数量 | 176 |
延迟时间 | 4.7 ns |
延迟时间tpd(1)最大值 | 4.7ns |
总内存 | 8192 bit |
最大工作温度 | + 70 C |
最大工作频率 | 304 MHz |
最小工作温度 | 0 C |
栅极数 | - |
标准包装 | 176 |
用户闪存-UFM | 8192 bit |
电源电压-内部 | 2.5V,3.3V |
电源电压-最大 | 3.6 V |
电源电压-最小 | 2.375 V |
系列 | MAX II |
输入/输出端数量 | 80 |
逻辑元件/块数 | 240 |
逻辑元件数量 | 240 |
逻辑数组块数量——LAB | 24 |
MAX II Device Handbook 101 Innovation Drive San Jose, CA 95134 www.altera.com MII5V1-3.3
Copyright © 2009 Altera Corporation. All rights reserved. Altera, The Programmable Solutions Company, the stylized Altera logo, specific device designations, and all other words and logos that are identified as trademarks and/or service marks are, unless noted otherwise, the trademarks and service marks of Altera Corporation in the U.S. and other countries. All other product or service names are the property of their respective holders. Altera products are protected under numerous U.S. and foreign patents and pending ap- plications, maskwork rights, and copyrights. Altera warrants performance of its semiconductor products to current specifications in accordance with Altera's standard warranty, but reserves the right to make changes to any products and services at any time without notice. Altera assumes no responsibility or liability arising out of the application or use of any information, product, or service described herein except as expressly agreed to in writing by Altera Corporation. Altera customers are advised to obtain the latest version of device specifications before relying on any published information and before placing orders for products or services.
Contents Chapter Revision Dates . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . xi About this Handbook . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .About–xiii How to Contact Altera . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1–xiii Typographic Conventions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1–xiii Section I. MAX II Device Family Data Sheet Revision History . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . I–1 Chapter1. Introduction Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1–1 Features . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1–1 Referenced Documents . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1–4 Document Revision History . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1–4 Chapter2. MAX II Architecture Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2–1 Functional Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2–1 Logic Array Blocks . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2–4 LAB Interconnects . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2–4 LAB Control Signals . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2–5 Logic Elements . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2–6 LUT Chain and Register Chain . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2–8 addnsub Signal . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2–8 LE Operating Modes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2–8 Normal Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2–9 Dynamic Arithmetic Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2–9 Carry-Select Chain . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2–10 Clear and Preset Logic Control . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2–12 MultiTrack Interconnect . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2–12 Global Signals . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2–16 User Flash Memory Block . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2–18 UFM Storage . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2–19 Internal Oscillator . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2–20 Program, Erase, and Busy Signals . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2–20 Auto-Increment Addressing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2–20 Serial Interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2–20 UFM Block to Logic Array Interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2–20 MultiVolt Core . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2–22 © August 2009 Altera Corporation MAX II Device Handbook
iv I/O Structure . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2–23 Fast I/O Connection . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2–23 I/O Blocks . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2–24 I/O Standards and Banks . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2–26 PCI Compliance . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2–28 Schmitt Trigger . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2–29 Output Enable Signals . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2–29 Programmable Drive Strength . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2–29 Slew-Rate Control . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2–30 Open-Drain Output . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2–30 Programmable Ground Pins . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2–30 Bus Hold . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2–31 Programmable Pull-Up Resistor . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2–31 Programmable Input Delay . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2–31 MultiVolt I/O Interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2–31 Referenced Documents . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2–32 Document Revision History . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2–33 Chapter3. JTAG and In-System Programmability Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3–1 IEEE Std. 1149.1 (JTAG) Boundary-Scan Support . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3–1 JTAG Block . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3–3 Parallel Flash Loader . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3–3 In System Programmability . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3–4 IEEE 1532 Support . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3–5 Jam Standard Test and Programming Language (STAPL) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3–5 Programming Sequence . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3–5 UFM Programming . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3–6 In-System Programming Clamp . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3–6 Real-Time ISP . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3–7 Design Security . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3–7 Programming with External Hardware . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3–7 Referenced Documents . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3–7 Document Revision History . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3–8 Chapter4. Hot Socketing and Power-On Reset in MAX II Devices Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4–1 MAX II Hot-Socketing Specifications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4–1 Devices Can Be Driven before Power-Up . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4–1 I/O Pins Remain Tri-Stated during Power-Up . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4–2 Signal Pins Do Not Drive the V or V Power Supplies . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4–2 CCIO CCINT AC and DC Specifications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4–2 Hot Socketing Feature Implementation in MAX II Devices . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4–2 Power-On Reset Circuitry . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4–5 Power-Up Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4–6 Referenced Documents . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4–8 Document Revision History . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4–8 Chapter5. DC and Switching Characteristics Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5–1 MAX II Device Handbook © August 2009 Altera Corporation
v Operating Conditions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5–1 Absolute Maximum Ratings . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5–1 Recommended Operating Conditions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5–2 Programming/Erasure Specifications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5–3 DC Electrical Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5–3 Output Drive Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5–5 I/O Standard Specifications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5–5 Bus Hold Specifications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5–7 Power-Up Timing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5–8 Power Consumption . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5–8 Timing Model and Specifications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5–8 Preliminary and Final Timing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5–9 Performance . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5–10 Internal Timing Parameters . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5–11 External Timing Parameters . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5–18 External Timing I/O Delay Adders . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5–21 Maximum Input and Output Clock Rates . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5–24 JTAG Timing Specifications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5–25 Referenced Documents . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5–26 Document Revision History . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5–27 Chapter6. Reference and Ordering Information Software . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6–1 Device Pin-Outs . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6–1 Ordering Information . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6–1 Referenced Documents . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6–2 Document Revision History . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6–2 Section II. PCB Layout Guidelines Revision History . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . II–1 Chapter7. Package Information Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7–1 Board Decoupling Guidelines . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7–1 Device and Package Cross Reference . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7–1 Thermal Resistance . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7–2 Package Outlines . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7–3 68-Pin Micro FineLine Ball-Grid Array (MBGA) – Wire Bond . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7–3 100-Pin Plastic Thin Quad Flat Pack (TQFP) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7–5 100-Pin Micro FineLine Ball-Grid Array (MBGA) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7–7 100-Pin FineLine Ball-Grid Array (FBGA) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7–8 144-Pin Plastic Thin Quad Flat Pack (TQFP) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7–10 144-Pin Micro FineLine Ball-Grid Array (MBGA) – Wire Bond . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7–12 256-Pin Micro FineLine Ball-Grid Array (MBGA) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7–13 256-Pin FineLine Ball-Grid Array (FBGA) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7–15 324-Pin FineLine Ball-Grid Array (FBGA) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7–16 Document Revision History . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7–18 Chapter8. Using MAX II Devices in Multi-Voltage Systems Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8–1 I/O Standards . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8–2 MultiVolt Core and I/O Operation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8–3 5.0-V Device Compatibility . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8–3 © August 2009 Altera Corporation MAX II Device Handbook
vi Recommended Operating Condition for 5.0-V Compatibility . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8–7 Hot Socketing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8–8 Power-Up Sequencing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8–8 Power-On Reset . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8–8 Conclusion . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8–8 Referenced Documents . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8–9 Document Revision History . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8–9 Section III. User Flash Memory Revision History . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . III–1 Chapter9. Using User Flash Memory in MAX II Devices Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9–1 UFM Array Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9–1 Memory Organization Map . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9–1 Using and Accessing UFM Storage . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9–2 UFM Functional Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9–3 UFM Address Register . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9–5 UFM Data Register . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9–5 UFM Program/Erase Control Block . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9–6 Oscillator . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9–6 Instantiating the Oscillator without the UFM . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9–7 UFM Operating Modes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9–9 Read/Stream Read . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9–9 Program . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9–10 Erase . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9–11 Programming and Reading the UFM with JTAG . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9–12 Jam Files . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9–12 Jam Players . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9–12 Software Support for UFM Block . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9–13 Inter-Integrated Circuit . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9–14 I2C Protocol . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9–14 Device Addressing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9–16 Byte Write Operation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9–16 Page Write Operation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9–17 Write Protection . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9–17 Erase Operation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9–18 Read Operation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9–20 ALTUFM I2C Interface Timing Specification . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9–22 Instantiating the I2C Interface Using the Quartus II altufm Megafunction . . . . . . . . . . . . . . . . . 9–22 Serial Peripheral Interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9–24 Opcodes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9–25 ALTUFM SPI Timing Specification . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9–34 Instantiating SPI Using Quartus II altufm Megafunction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9–35 Parallel Interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9–36 ALTUFM Parallel Interface Timing Specification . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9–37 Instantiating Parallel Interface Using Quartus II altufm Megafunction . . . . . . . . . . . . . . . . . . . . 9–38 None (Altera Serial Interface) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9–39 Instantiating None Using Quartus II altufm Megafunction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9–39 Creating Memory Content File . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9–40 Memory Initialization for the altufm_parallel Megafunction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9–43 Memory Initialization for the altufm_spi Megafunction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9–43 Memory Initialization for the altufm_i2c Megafunction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9–44 MAX II Device Handbook © August 2009 Altera Corporation
vii Simulation Parameters . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9–46 Conclusion . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9–46 Referenced Documents . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9–47 Document Revision History . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9–47 Chapter10. Replacing Serial EEPROMs with MAX II User Flash Memory Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10–1 Design Considerations . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10–1 List of Vendors and Devices . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10–2 Conclusion . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10–11 Referenced Documents . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10–11 Document Revision History . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10–12 Section IV. In-System Programmability Revision History . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . IV–1 Chapter11. In-System Programmability Guidelines for MAX II Devices Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11–1 General ISP Guidelines . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11–1 Operating Conditions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11–1 ISP Voltage . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11–1 Input Voltages . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11–2 UFM Operations During In-System Programming . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11–2 Interrupting In-System Programming . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11–3 MultiVolt Devices and Power-Up Sequences . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11–3 V Powered before V . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11–3 CCIO CCINT I/O Pins Tri-Stated during In-System Programming . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11–3 Pull-Up and Pull-Down of JTAG Pins During In-System Programming . . . . . . . . . . . . . . . . . . . . . 11–4 IEEE Std. 1149.1 Signals . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11–4 TCK Signal . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11–4 Programming via a Download Cable . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11–5 Disabling IEEE Std. 1149.1 Circuitry . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11–5 Working with Different Voltage Levels . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11–6 Sequential versus Concurrent Programming . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11–6 Sequential Programming . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11–6 Concurrent Programming . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11–6 ISP Troubleshooting Guidelines . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11–7 Invalid ID and Unrecognized Device Messages . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11–7 Download Cable Connected Incorrectly . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11–7 TDO Is Not Connected . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11–8 Incomplete JTAG Chain . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11–8 Noisy TCK Signal . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11–8 Jam Player Ported Incorrectly . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11–8 Troubleshooting Tips . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11–8 Verify the JTAG Chain Continuity . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11–8 Check the V Level of the Board During In-System Programming . . . . . . . . . . . . . . . . . . . . . . . 11–9 CC Power-Up Problems . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11–9 Random Signals on JTAG Pins . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11–9 Software Issues . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11–9 ISP via Embedded Processors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11–9 Processor and Memory Requirements . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11–9 Porting the Jam Player . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11–10 ISP via In-Circuit Testers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11–10 © August 2009 Altera Corporation MAX II Device Handbook
viii Conclusion . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11–10 Referenced Documents . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11–10 Document Revision History . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11–11 Chapter12. Real-Time ISP and ISP Clamp for MAX II Devices Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12–1 Real-Time ISP . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12–1 How Real-Time ISP Works . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12–1 Real-Time ISP with the Quartus II Software . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12–2 Real-Time ISP with Jam and JBC Players . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12–4 ISP Clamp . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12–4 How ISP Clamp Works . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12–5 Using ISP Clamp in the Quartus II Software . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12–5 Using the IPS File . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12–6 Defining the Pin States in Assignment Editor . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12–9 ISP Clamp with Jam/JBC Files . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12–10 Conclusion . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12–10 Referenced Documents . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12–10 Document Revision History . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12–11 Chapter13. IEEE 1149.1 (JTAG) Boundary-Scan Testing for MAXII Devices Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13–1 IEEE Std. 1149.1 BST Architecture . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13–2 IEEE Std. 1149.1 Boundary-Scan Register . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13–3 Boundary-Scan Cells of a MAXII Device I/O Pin . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13–4 JTAG Pins and Power Pins . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13–5 IEEE Std. 1149.1 BST Operation Control . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13–6 SAMPLE/PRELOAD Instruction Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13–9 EXTEST Instruction Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13–11 BYPASS Instruction Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13–13 IDCODE Instruction Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13–14 USERCODE Instruction Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13–14 CLAMP Instruction Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13–14 HIGHZ Instruction Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13–14 I/O Voltage Support in JTAG Chain . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13–15 BST for Programmed Devices . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13–15 Disabling IEEE Std. 1149.1 BST Circuitry . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13–16 Guidelines for IEEE Std. 1149.1 Boundary-Scan Testing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13–16 Boundary-Scan Description Language (BSDL) Support . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13–17 Conclusion . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13–17 Referenced Documents . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13–17 Document Revision History . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13–18 Chapter14. Using Jam STAPL for ISP via an Embedded Processor Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14–1 Embedded Systems . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14–1 Connecting the JTAG Chain to the Embedded Processor . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14–1 Example Interface PLD Design . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14–2 Board Layout . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14–3 TCK Signal Trace Protection and Integrity . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14–4 Pull-Down Resistors on TCK . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14–4 JTAG Signal Traces . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14–4 External Resistors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14–4 MAX II Device Handbook © August 2009 Altera Corporation
ix Software Development . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14–4 Jam Files (.jam and .jbc) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14–5 ASCII Text Files (.jam) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14–5 Jam Byte-Code Files (.jbc) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14–5 Generating Jam Files . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14–5 Using Jam Files with the MAX II User Flash Memory Block . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14–7 Jam Players . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14–7 Jam Player Compatibility . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14–7 The Jam STAPL Byte-Code Player . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14–7 Porting the Jam STAPL Byte-Code Player . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14–8 Jam STAPL Byte-Code Player Memory Usage . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14–11 Updating Devices Using Jam . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14–14 MAX II Jam/JBC Actions and Procedure Commands . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14–15 Running the Jam STAPL Byte-Code Player . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14–17 Conclusion . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14–18 Referenced Documents . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14–18 Document Revision History . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14–19 Chapter15. Using the Agilent 3070 Tester for In-System Programming Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15–1 New PLD Product for Agilent 3070 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15–1 Device Support . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15–1 Agilent 3070 Development Flow without the PLD ISP Software . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15–2 Step 1: Create a PCB and Test Fixture . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15–3 Creating the PCB . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15–3 Creating the Fixture . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15–3 Step 2: Create a Serial Vector Format File . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15–4 Step 3: Convert SVF Files to PCF Files . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15–5 Step 4: Create Executable Tests from Files . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15–5 Create the Library for the Target Device or Scan Chain . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15–5 Run the Test Consultant . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15–6 Create Digital Tests . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15–6 Create the Wirelist Information for the Tests . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15–6 Modify the Test Plan . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15–6 Step 5: Compile the Executable Tests . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15–7 Step 6: Debug the Test . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15–7 Development Flow for Agilent3070 with PLD ISP Software . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15–8 Programming Times . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15–10 Guidelines . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15–10 Conclusion . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15–11 Referenced Documents . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15–11 Document Revision History . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15–11 Section V. Design Considerations Revision History . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . V–1 Chapter16. Understanding Timing in MAX II Devices Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16–1 External Timing Parameters . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16–1 Internal Timing Parameters . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16–2 Internal Timing Parameters for MAX II UFM . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16–3 Timing Models . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16–4 © August 2009 Altera Corporation MAX II Device Handbook
x Calculating Timing Delays . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16–5 Setup and Hold Time from an I/O Data and Clock Input . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16–6 Programmable Input Delay . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16–7 Timing Model versus QuartusII Timing Analyzer . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16–7 Conclusion . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16–8 Referenced Documents . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16–8 Document Revision History . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16–8 Chapter17. Understanding and Evaluating Power in MAXII Devices Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17–1 Power in MAX II Devices . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17–1 MAX II Power Estimation Using the PowerPlay Early Power Estimator . . . . . . . . . . . . . . . . . . . . . . . . 17–3 PowerPlay Early Power Estimator Inputs . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17–3 Input Parameters . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17–4 Clock Section . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17–5 Logic Section . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17–6 UFM Section . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17–8 I/O Section . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17–8 Other Input Information . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17–11 Set Toggle % . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17–11 Reset . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17–12 Importing the Quartus II Early Power Estimator File . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17–12 Power Estimation Summary . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17–13 Power . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17–13 Thermal Analysis . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17–14 Power Supply Current . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17–15 Power Saving Techniques . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17–15 Conclusion . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17–16 Referenced Documents . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17–16 Document Revision History . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17–17 MAX II Device Handbook © August 2009 Altera Corporation
Chapter Revision Dates The chapters in this book, MAX II Device Handbook, were revised on the following dates. Where chapters or groups of chapters are available separately, part numbers are listed. Chapter1 Introduction Revised: August 2009 Part Number: MII51001-1.9 Chapter2 MAX II Architecture Revised: October 2008 Part Number: MII51002-2.2 Chapter3 JTAG and In-System Programmability Revised: October 2008 Part Number: MII51003-1.6 Chapter4 Hot Socketing and Power-On Reset in MAX II Devices Revised: October 2008 Part Number: MII51004-2.1 Chapter5 DC and Switching Characteristics Revised: August 2009 Part Number: MII51005-2.5 Chapter6 Reference and Ordering Information Revised: August 2009 Part Number: MII51006-1.6 Chapter7 Package Information Revised: October 2008 Part Number: MII51007-2.1 Chapter8 Using MAX II Devices in Multi-Voltage Systems Revised: October 2008 Part Number: MII51009-1.7 Chapter9 Using User Flash Memory in MAX II Devices Revised: October 2008 Part Number: MII51010-1.8 Chapter10 Replacing Serial EEPROMs with MAX II User Flash Memory Revised: October 2008 Part Number: MII51012-1.5 Chapter11 In-System Programmability Guidelines for MAX II Devices Revised: October 2008 Part Number: MII51013-1.7 Chapter12 Real-Time ISP and ISP Clamp for MAX II Devices © August 2009 Altera Corporation MAX II Device Handbook
xii Revised: October 2008 Part Number: MII51019-1.6 Chapter13 IEEE 1149.1 (JTAG) Boundary-Scan Testing for MAXII Devices Revised: October 2008 Part Number: MII51014-1.7 Chapter14 Using Jam STAPL for ISP via an Embedded Processor Revised: October 2008 Part Number: MII51015-1.8 Chapter15 Using the Agilent 3070 Tester for In-System Programming Revised: October 2008 Part Number: MII51016-1.5 Chapter16 Understanding Timing in MAX II Devices Revised: October 2008 Part Number: MII51017-2.1 Chapter17 Understanding and Evaluating Power in MAXII Devices Revised: October 2008 Part Number: MII51018-2.1 MAX II Device Handbook © August 2009 Altera Corporation
About this Handbook This handbook provides comprehensive information about the Altera® MAX® II family of devices. How to Contact Altera For the most up-to-date information about Altera products, refer to the following table. Contact Contact (Note1) Method Address Technical support Website www.altera.com/support Technical training Website www.altera.com/training Email custrain@altera.com Altera literature services Email literature@altera.com Non-technical support (General) Email nacomp@altera.com (Software Licensing) Email authorization@altera.com Note: (1) You can also contact your local Altera sales office or sales representative. Typographic Conventions This document uses the typographic conventions shown in the following table. Visual Cue Meaning Bold Type with Initial Capital Command names, dialog box titles, checkbox options, and dialog box options are Letters shown in bold, initial capital letters. Example: Save As dialog box. bold type External timing parameters, directory names, project names, disk drive names, file names, file name extensions, and software utility names are shown in bold type. Examples: f , \qdesigns directory, d: drive, chiptrip.gdf file. MAX Italic Type with Initial Capital Letters Document titles are shown in italic type with initial capital letters. Example: AN 75: High-Speed Board Design. Italic type Internal timing parameters and variables are shown in italic type. Examples: t , n + 1. PIA Variable names are enclosed in angle brackets (< >) and shown in italic type. Example: <file name>, <project name>.pof file. Initial Capital Letters Keyboard keys and menu names are shown with initial capital letters. Examples: Delete key, the Options menu. “Subheading Title” References to sections within a document and titles of on-line help topics are shown in quotation marks. Example: “Typographic Conventions.” © August 2009 Altera Corporation MAX II Device Handbook
xiv Typographic Conventions Visual Cue Meaning Courier type Signal and port names are shown in lowercase Courier type. Examples: data1, tdi, input. Active-low signals are denoted by suffix n, e.g., resetn. Anything that must be typed exactly as it appears is shown in Courier type. For example: c:\qdesigns\tutorial\chiptrip.gdf. Also, sections of an actual file, such as a Report File, references to parts of files (e.g., the AHDL keyword SUBDESIGN), as well as logic function names (e.g., TRI) are shown in Courier. 1., 2., 3., and Numbered steps are used in a list of items when the sequence of the items is a., b., c., etc. important, such as the steps listed in a procedure. ■ ■ Bullets are used in a list of items when the sequence of the items is not important. v The checkmark indicates a procedure that consists of one step only. 1 The hand points to information that requires special attention. A caution calls attention to a condition or possible situation that can damage or c destroy the product or the user’s work. A warning calls attention to a condition or possible situation that can cause injury to w the user. r The angled arrow indicates you should press the Enter key. f The feet direct you to more information on a particular topic. MAX II Device Handbook © August 2009 Altera Corporation
Section I. MAX II Device Family Data Sheet This section provides designers with the data sheet specifications for MAX® II devices. The chapters contain feature definitions of the internal architecture, Joint Test Action Group (JTAG) and in-system programmability (ISP) information, DC operating conditions, AC timing parameters, and ordering information for MAX II devices. This section includes the following chapters: ■ Chapter1, Introduction ■ Chapter2, MAX II Architecture ■ Chapter3, JTAG and In-System Programmability ■ Chapter4, Hot Socketing and Power-On Reset in MAX II Devices ■ Chapter5, DC and Switching Characteristics ■ Chapter6, Reference and Ordering Information Revision History Refer to each chapter for its own specific revision history. For information about when each chapter was updated, refer to the Chapter Revision Dates section, which appears in the complete handbook. © August 2009 Altera Corporation MAX II Device Handbook
I–2 Section I: MAX II Device Family Data Sheet Revision History MAX II Device Handbook © August 2009 Altera Corporation
1. Introduction MII51001-1.9 Introduction The MAX® II family of instant-on, non-volatile CPLDs is based on a 0.18-µm, 6-layer-metal-flash process, with densities from 240 to 2,210 logic elements (LEs) (128 to 2,210 equivalent macrocells) and non-volatile storage of 8Kbits. MAXII devices offer high I/O counts, fast performance, and reliable fitting versus other CPLD architectures. Featuring MultiVolt core, a user flash memory (UFM) block, and enhanced in-system programmability (ISP), MAXII devices are designed to reduce cost and power while providing programmable solutions for applications such as bus bridging, I/O expansion, power-on reset (POR) and sequencing control, and device configuration control. Features The MAXII CPLD has the following features: ■ Low-cost, low-power CPLD ■ Instant-on, non-volatile architecture ■ Standby current as low as 25 µA ■ Provides fast propagation delay and clock-to-output times ■ Provides four global clocks with two clocks available per logic array block (LAB) ■ UFM block up to 8Kbits for non-volatile storage ■ MultiVolt core enabling external supply voltages to the device of either 3.3V/2.5V or 1.8V ■ MultiVolt I/O interface supporting 3.3-V, 2.5-V, 1.8-V, and 1.5-V logic levels ■ Bus-friendly architecture including programmable slew rate, drive strength, bus-hold, and programmable pull-up resistors ■ Schmitt triggers enabling noise tolerant inputs (programmable per pin) ■ I/Os are fully compliant with the Peripheral Component Interconnect Special Interest Group (PCI SIG) PCI Local Bus Specification, Revision 2.2 for 3.3-V operation at 66 MHz ■ Supports hot-socketing ■ Built-in Joint Test Action Group (JTAG) boundary-scan test (BST) circuitry compliant with IEEE Std. 1149.1-1990 ■ ISP circuitry compliant with IEEE Std. 1532 © August 2009 Altera Corporation MAX II Device Handbook
1–2 Chapter 1: Introduction Features Table1–1 shows the MAXII family features. Table1–1. MAXII Family Features EPM240 EPM570 EPM1270 EPM2210 Feature EPM240G EPM570G EPM1270G EPM2210G EPM240Z EPM570Z LEs 240 570 1,270 2,210 240 570 Typical Equivalent Macrocells 192 440 980 1,700 192 440 Equivalent Macrocell Range 128 to 240 240 to 570 570 to 1,270 1,270 to 2,210 128 to 240 240 to 570 UFM Size (bits) 8,192 8,192 8,192 8,192 8,192 8,192 Maximum User I/O pins 80 160 212 272 80 160 t (ns) (1) 4.7 5.4 6.2 7.0 7.5 9.0 PD1 f (MHz) (2) 304 304 304 304 152 152 CNT t (ns) 1.7 1.2 1.2 1.2 2.3 2.2 SU t (ns) 4.3 4.5 4.6 4.6 6.5 6.7 CO Notes to Table1–1: (1) t represents a pin-to-pin delay for the worst case I/O placement with a full diagonal path across the device and combinational logic PD1 implemented in a single LUT and LAB that is adjacent to the output pin. (2) The maximum frequency is limited by the I/O standard on the clock input pin. The 16-bit counter critical delay will run faster than this number. f For more information about equivalent macrocells, refer to the MAXII Logic Element to Macrocell Conversion Methodology white paper. MAXII and MAXIIG devices are available in three speed grades: –3, –4, and –5, with –3 being the fastest. Similarly, MAXIIZ devices are available in three speed grades: –6, –7, and –8, with –6 being the fastest. These speed grades represent the overall relative performance, not any specific timing parameter. For propagation delay timing numbers within each speed grade and density, refer to the DC and Switching Characteristics chapter in the MAXII Device Handbook. Table1–2 shows MAXII device speed-grade offerings. Table1–2. MAXII Speed Grades Speed Grade Device –3 –4 –5 –6 –7 –8 EPM240 v v v— — — EPM240G EPM570 v v v— — — EPM570G EPM1270 v v v— — — EPM1270G EPM2210 v v v— — — EPM2210G EPM240Z — — — v v v EPM570Z — — —v v v MAX II Device Handbook © August 2009 Altera Corporation
Chapter 1: Introduction 1–3 Features MAXII devices are available in space-saving FineLine BGA, Micro FineLine BGA, and thin quad flat pack (TQFP) packages (refer to Table1–3 and Table1–4). MAXII devices support vertical migration within the same package (for example, you can migrate between the EPM570, EPM1270, and EPM2210 devices in the 256-pin FineLine BGA package). Vertical migration means that you can migrate to devices whose dedicated pins and JTAG pins are the same and power pins are subsets or supersets for a given package across device densities. The largest density in any package has the highest number of power pins; you must lay out for the largest planned density in a package to provide the necessary power pins for migration. For I/O pin migration across densities, cross reference the available I/O pins using the device pin-outs for all planned densities of a given package type to identify which I/O pins can be migrated. The Quartus® II software can automatically cross-reference and place all pins for you when given a device migration list. Table1–3. MAXII Packages and User I/O Pins 68-Pin 100-Pin 144-Pin 256-Pin Micro Micro 100-Pin Micro Micro 256-Pin 324-Pin FineLine FineLine FineLine 100-Pin 144-Pin FineLine FineLine FineLine FineLine Device BGA (1) BGA(1) BGA TQFP TQFP BGA (1) BGA(1) BGA BGA EPM240 — 80 80 80 — — — — — EPM240G EPM570 — 76 76 76 116 — 160 160 — EPM570G EPM1270 — — — — 116 — 212 212 — EPM1270G EPM2210 — — — — — — — 204 272 EPM2210G EPM240Z 54 80 — — — — — — — EPM570Z — 76 — — — 116 160 — — Note to Table1–3: (1) Packages available in lead-free versions only. Table1–4. MAXII TQFP, FineLine BGA, and Micro FineLine BGA Package Sizes 68-Pin 100-Pin 144-Pin 256-Pin Micro Micro 100-Pin Micro Micro 256-Pin 324-Pin FineLine FineLine FineLine 100-Pin 144-Pin FineLine FineLine FineLine FineLine Package BGA BGA BGA TQFP TQFP BGA BGA BGA BGA Pitch (mm) 0.5 0.5 1 0.5 0.5 0.5 0.5 1 1 Area (mm2) 25 36 121 256 484 49 121 289 361 Length × width 5 × 5 6 × 6 11 × 11 16 × 16 22 × 22 7 × 7 11 × 11 17 × 17 19 × 19 (mm × mm) © August 2009 Altera Corporation MAX II Device Handbook
1–4 Chapter 1: Introduction Referenced Documents MAXII devices have an internal linear voltage regulator which supports external supply voltages of 3.3 V or 2.5 V, regulating the supply down to the internal operating voltage of 1.8 V. MAXIIG and MAXIIZ devices only accept 1.8V as the external supply voltage. MAXIIZ devices are pin-compatible with MAXIIG devices in the 100-pin Micro FineLine BGA and 256-pin Micro FineLine BGA packages. Except for external supply voltage requirements, MAXII and MAXII G devices have identical pin-outs and timing specifications. Table1–5 shows the external supply voltages supported by the MAXII family. Table1–5. MAXII External Supply Voltages EPM240G EPM570G EPM240 EPM1270G EPM570 EPM2210G EPM1270 EPM240Z Devices EPM2210 EPM570Z (1) MultiVolt core external supply voltage (V ) (2) 3.3 V, 2.5 V 1.8 V CCINT MultiVolt I/O interface voltage levels (V ) 1.5 V, 1.8 V, 2.5 V, 3.3 V 1.5 V, 1.8 V, 2.5 V, 3.3 V CCIO Notes to Table1–5: (1) MAXIIG and MAXIIZ devices only accept 1.8 V on their VCCINT pins. The 1.8-V V external supply powers the device core directly. CCINT (2) MAXII devices operate internally at 1.8 V. Referenced Documents This chapter references the following documents: ■ DC and Switching Characteristics chapter in the MAXII Device Handbook ■ MAXII Logic Element to Macrocell Conversion Methodology white paper Document Revision History Table1–6 shows the revision history for this chapter. Table1–6. Document Revision History Date and Revision Changes Made Summary of Changes August 2009, ■ Updated Table1–2. Added information for speed grade –8 version 1.9 October 2008, ■ Updated “Introduction” section. — version 1.8 ■ Updated new Document Format. December 2007, ■ Updated Table1–1 through Table1–5. Updated document with MAXIIZ information. version1.7 ■ Added “Referenced Documents” section. December 2006, ■ Added document revision history. — version 1.6 August 2006, ■ Minor update to features list. — version 1.5 July 2006, ■ Minor updates to tables. — version 1.4 MAX II Device Handbook © August 2009 Altera Corporation
Chapter 1: Introduction 1–5 Document Revision History Table1–6. Document Revision History Date and Revision Changes Made Summary of Changes June 2005, ■ Updated timing numbers in Table 1-1. — version 1.3 December 2004, ■ Updated timing numbers in Table 1-1. — version 1.2 June 2004, ■ Updated timing numbers in Table 1-1. — version 1.1 © August 2009 Altera Corporation MAX II Device Handbook
1–6 Chapter 1: Introduction Document Revision History MAX II Device Handbook © August 2009 Altera Corporation
2. MAX II Architecture MII51002-2.2 Introduction This chapter describes the architecture of the MAX II device and contains the following sections: ■ “Functional Description” on page2–1 ■ “Logic Array Blocks” on page2–4 ■ “Logic Elements” on page2–6 ■ “MultiTrack Interconnect” on page2–12 ■ “Global Signals” on page2–16 ■ “User Flash Memory Block” on page2–18 ■ “MultiVolt Core” on page2–22 ■ “I/O Structure” on page2–23 Functional Description MAX® II devices contain a two-dimensional row- and column-based architecture to implement custom logic. Row and column interconnects provide signal interconnects between the logic array blocks (LABs). The logic array consists of LABs, with 10 logic elements (LEs) in each LAB. An LE is a small unit of logic providing efficient implementation of user logic functions. LABs are grouped into rows and columns across the device. The MultiTrack interconnect provides fast granular timing delays between LABs. The fast routing between LEs provides minimum timing delay for added levels of logic versus globally routed interconnect structures. The MAX II device I/O pins are fed by I/O elements (IOE) located at the ends of LAB rows and columns around the periphery of the device. Each IOE contains a bidirectional I/O buffer with several advanced features. I/O pins support Schmitt trigger inputs and various single-ended standards, such as 66-MHz, 32-bit PCI, and LVTTL. MAX II devices provide a global clock network. The global clock network consists of four global clock lines that drive throughout the entire device, providing clocks for all resources within the device. The global clock lines can also be used for control signals such as clear, preset, or output enable. © October 2008 Altera Corporation MAX II Device Handbook
2–2 Chapter 2: MAX II Architecture Functional Description Figure2–1 shows a functional block diagram of the MAX II device. Figure2–1. MAX II Device Block Diagram IOE IOE IOE IOE IOE IOE Logic Logic Logic IOE Element Element Element IOE Logic Logic Logic Logic Array Element Element Element BLock (LAB) MultiTrack Interconnect Logic Logic Logic IOE Element Element Element Logic Logic Logic IOE Element Element Element MultiTrack Interconnect Each MAX II device contains a flash memory block within its floorplan. On the EPM240 device, this block is located on the left side of the device. On the EPM570, EPM1270, and EPM2210 devices, the flash memory block is located on the bottom-left area of the device. The majority of this flash memory storage is partitioned as the dedicated configuration flash memory (CFM) block. The CFM block provides the non- volatile storage for all of the SRAM configuration information. The CFM automatically downloads and configures the logic and I/O at power-up, providing instant-on operation. f For more information about configuration upon power-up, refer to the Hot Socketing and Power-On Reset in MAX II Devices chapter in the MAX II Device Handbook. A portion of the flash memory within the MAX II device is partitioned into a small block for user data. This user flash memory (UFM) block provides 8,192 bits of general-purpose user storage. The UFM provides programmable port connections to the logic array for reading and writing. There are three LAB rows adjacent to this block, with column numbers varying by device. Table2–1 shows the number of LAB rows and columns in each device, as well as the number of LAB rows and columns adjacent to the flash memory area in the EPM570, EPM1270, and EPM2210 devices. The long LAB rows are full LAB rows that extend from one side of row I/O blocks to the other. The short LAB rows are adjacent to the UFM block; their length is shown as width in LAB columns. MAX II Device Handbook © October 2008 Altera Corporation
Chapter 2: MAX II Architecture 2–3 Functional Description Table2–1. MAX II Device Resources LAB Rows Short LAB Rows Devices UFM Blocks LAB Columns Long LAB Rows (Width) (1) Total LABs EPM240 1 6 4 — 24 EPM570 1 12 4 3 (3) 57 EPM1270 1 16 7 3 (5) 127 EPM2210 1 20 10 3 (7) 221 Note to Table2–1: (1) The width is the number of LAB columns in length. Figure2–2 shows a floorplan of a MAX II device. Figure2–2. MAX II Device Floorplan (Note1) I/O Blocks I/O Blocks Logic Array Logic Array Blocks Blocks 2 GCLK 2 GCLK Inputs Inputs I/O Blocks UFM Block CFM Block Note to Figure2–2: (1) The device shown is an EPM570 device. EPM1270 and EPM2210 devices have a similar floorplan with more LABs. For EPM240 devices, the CFM and UFM blocks are located on the left side of the device. © October 2008 Altera Corporation MAX II Device Handbook
2–4 Chapter 2: MAX II Architecture Logic Array Blocks Logic Array Blocks Each LAB consists of 10 LEs, LE carry chains, LAB control signals, a local interconnect, a look-up table (LUT) chain, and register chain connection lines. There are 26 possible unique inputs into an LAB, with an additional 10 local feedback input lines fed by LE outputs in the same LAB. The local interconnect transfers signals between LEs in the same LAB. LUT chain connections transfer the output of one LE’s LUT to the adjacent LE for fast sequential LUT connections within the same LAB. Register chain connections transfer the output of one LE’s register to the adjacent LE’s register within an LAB. The Quartus® II software places associated logic within an LAB or adjacent LABs, allowing the use of local, LUT chain, and register chain connections for performance and area efficiency. Figure2–3 shows the MAX II LAB. Figure2–3. MAX II LAB Structure Row Interconnect Column Interconnect LE0 Fast I/O connection Fast I/O connection to IOE (1) LE1 to IOE (1) LE2 DirectLink DirectLink interconnect from interconnect from LE3 adjacent LAB adjacent LAB or IOE or IOE LE4 LE5 LE6 DirectLink DirectLink interconnect to LE7 interconnect to adjacent LAB adjacent LAB or IOE LE8 or IOE LE9 Logic Element LAB Local Interconnect Note to Figure2–3: (1) Only from LABs adjacent to IOEs. LAB Interconnects The LAB local interconnect can drive LEs within the same LAB. The LAB local interconnect is driven by column and row interconnects and LE outputs within the same LAB. Neighboring LABs, from the left and right, can also drive an LAB’s local interconnect through the DirectLink connection. The DirectLink connection feature minimizes the use of row and column interconnects, providing higher performance and flexibility. Each LE can drive 30 other LEs through fast local and DirectLink interconnects. Figure2–4 shows the DirectLink connection. MAX II Device Handbook © October 2008 Altera Corporation
Chapter 2: MAX II Architecture 2–5 Logic Array Blocks Figure2–4. DirectLink Connection DirectLink interconnect from DirectLink interconnect from left LAB or IOE output right LAB or IOE output LE0 LE1 LE2 LE3 LE4 LE5 DirectLink DirectLink interconnect LE6 interconnect to left to right LE7 Local LE8 Interconnect LE9 Logic Element LAB LAB Control Signals Each LAB contains dedicated logic for driving control signals to its LEs. The control signals include two clocks, two clock enables, two asynchronous clears, a synchronous clear, an asynchronous preset/load, a synchronous load, and add/subtract control signals, providing a maximum of 10 control signals at a time. Although synchronous load and clear signals are generally used when implementing counters, they can also be used with other functions. Each LAB can use two clocks and two clock enable signals. Each LAB’s clock and clock enable signals are linked. For example, any LE in a particular LAB using the labclk1 signal also uses labclkena1. If the LAB uses both the rising and falling edges of a clock, it also uses both LAB-wide clock signals. Deasserting the clock enable signal turns off the LAB-wide clock. Each LAB can use two asynchronous clear signals and an asynchronous load/preset signal. By default, the Quartus II software uses a NOT gate push-back technique to achieve preset. If you disable the NOT gate push-back option or assign a given register to power-up high using the Quartus II software, the preset is then achieved using the asynchronous load signal with asynchronous load data input tied high. With the LAB-wide addnsub control signal, a single LE can implement a one-bit adder and subtractor. This saves LE resources and improves performance for logic functions such as correlators and signed multipliers that alternate between addition and subtraction depending on data. The LAB column clocks [3..0], driven by the global clock network, and LAB local interconnect generate the LAB-wide control signals. The MultiTrack interconnect structure drives the LAB local interconnect for non-global control signal generation. The MultiTrack interconnect’s inherent low skew allows clock and control signal distribution in addition to data. Figure2–5 shows the LAB control signal generation circuit. © October 2008 Altera Corporation MAX II Device Handbook
2–6 Chapter 2: MAX II Architecture Logic Elements Figure2–5. LAB-Wide Control Signals Dedicated 4 LAB Column Clocks Local Interconnect Local Interconnect Local Interconnect Local Interconnect Local Interconnect labclkena1 labclkena2 syncload labclr2 addnsub Local labclk1 labclk2 asyncload labclr1 synclr Interconnect or labpre Logic Elements The smallest unit of logic in the MAX II architecture, the LE, is compact and provides advanced features with efficient logic utilization. Each LE contains a four-input LUT, which is a function generator that can implement any function of four variables. In addition, each LE contains a programmable register and carry chain with carry-select capability. A single LE also supports dynamic single-bit addition or subtraction mode selectable by an LAB-wide control signal. Each LE drives all types of interconnects: local, row, column, LUT chain, register chain, and DirectLink interconnects. See Figure2–6. MAX II Device Handbook © October 2008 Altera Corporation
Chapter 2: MAX II Architecture 2–7 Logic Elements Figure2–6. MAX II LE Register chain routing from previous LE LAB-wide Register Bypass Synchronous LAB Carry-In Load Programmable addnsub Carry-In1 SyLnAcBh-rwonidoeus PRaecgkisetder Select Register Carry-In0 Clear LUT chain routing to next LE data1 Row, column, ddaattaa23 LoToakb-leUp CChaarriny SyLnocahdr oannodus DPRN/ALDQ aronudt inDgirectLink (LUT) Clear Logic ADATA data4 ENA CLRN Row, column, and DirectLink routing labclr1 labclr2 Asynchronous labpre/aload Clear/Preset/ Local routing Chip-Wide Load Logic Reset (DEV_CLRn) Register chain Clock and Register output Feedback Clock Enable Select labclk1 labclk2 labclkena1 labclkena2 Carry-Out0 Carry-Out1 LAB Carry-Out Each LE’s programmable register can be configured for D, T, JK, or SR operation. Each register has data, true asynchronous load data, clock, clock enable, clear, and asynchronous load/preset inputs. Global signals, general-purpose I/O pins, or any LE can drive the register’s clock and clear control signals. Either general-purpose I/O pins or LEs can drive the clock enable, preset, asynchronous load, and asynchronous data. The asynchronous load data input comes from the data3 input of the LE. For combinational functions, the LUT output bypasses the register and drives directly to the LE outputs. Each LE has three outputs that drive the local, row, and column routing resources. The LUT or register output can drive these three outputs independently. Two LE outputs drive column or row and DirectLink routing connections and one drives local interconnect resources. This allows the LUT to drive one output while the register drives another output. This register packing feature improves device utilization because the device can use the register and the LUT for unrelated functions. Another special packing mode allows the register output to feed back into the LUT of the same LE so that the register is packed with its own fan-out LUT. This provides another mechanism for improved fitting. The LE can also drive out registered and unregistered versions of the LUT output. © October 2008 Altera Corporation MAX II Device Handbook
2–8 Chapter 2: MAX II Architecture Logic Elements LUT Chain and Register Chain In addition to the three general routing outputs, the LEs within an LAB have LUT chain and register chain outputs. LUT chain connections allow LUTs within the same LAB to cascade together for wide input functions. Register chain outputs allow registers within the same LAB to cascade together. The register chain output allows an LAB to use LUTs for a single combinational function and the registers to be used for an unrelated shift register implementation. These resources speed up connections between LABs while saving local interconnect resources. Refer to “MultiTrack Interconnect” on page2–12 for more information about LUT chain and register chain connections. addnsub Signal The LE’s dynamic adder/subtractor feature saves logic resources by using one set of LEs to implement both an adder and a subtractor. This feature is controlled by the LAB-wide control signal addnsub. The addnsub signal sets the LAB to perform either A + B or A – B. The LUT computes addition; subtraction is computed by adding the two’s complement of the intended subtractor. The LAB-wide signal converts to two’s complement by inverting the B bits within the LAB and setting carry-in to 1, which adds one to the least significant bit (LSB). The LSB of an adder/subtractor must be placed in the first LE of the LAB, where the LAB-wide addnsub signal automatically sets the carry-in to 1. The Quartus II Compiler automatically places and uses the adder/subtractor feature when using adder/subtractor parameterized functions. LE Operating Modes The MAX II LE can operate in one of the following modes: ■ “Normal Mode” ■ “Dynamic Arithmetic Mode” Each mode uses LE resources differently. In each mode, eight available inputs to the LE, the four data inputs from the LAB local interconnect, carry-in0 and carry- in1 from the previous LE, the LAB carry-in from the previous carry-chain LAB, and the register chain connection are directed to different destinations to implement the desired logic function. LAB-wide signals provide clock, asynchronous clear, asynchronous preset/load, synchronous clear, synchronous load, and clock enable control for the register. These LAB-wide signals are available in all LE modes. The addnsub control signal is allowed in arithmetic mode. The Quartus II software, in conjunction with parameterized functions such as library of parameterized modules (LPM) functions, automatically chooses the appropriate mode for common functions such as counters, adders, subtractors, and arithmetic functions. MAX II Device Handbook © October 2008 Altera Corporation
Chapter 2: MAX II Architecture 2–9 Logic Elements Normal Mode The normal mode is suitable for general logic applications and combinational functions. In normal mode, four data inputs from the LAB local interconnect are inputs to a four-input LUT (see Figure2–7). The Quartus II Compiler automatically selects the carry-in or the data3 signal as one of the inputs to the LUT. Each LE can use LUT chain connections to drive its combinational output directly to the next LE in the LAB. Asynchronous load data for the register comes from the data3 input of the LE. LEs in normal mode support packed registers. Figure2–7. LE in Normal Mode sload sclear aload (LAB Wide) (LAB Wide) (LAB Wide) Register chain connection addnsub (LAB Wide) ALD/PRE (1) ADATA Q Row, column, and D DirectLink routing data1 data2 Row, column, and ENA data3 4-Input CLRN DirectLink routing cin (from cout LUT of previous LE) clock (LAB Wide) Local routing data4 ena (LAB Wide) aclr (LAB Wide) LUT chain connection Register Register Feedback chain output Note to Figure2–7: (1) This signal is only allowed in normal mode if the LE is at the end of an adder/subtractor chain. Dynamic Arithmetic Mode The dynamic arithmetic mode is ideal for implementing adders, counters, accumulators, wide parity functions, and comparators. An LE in dynamic arithmetic mode uses four 2-input LUTs configurable as a dynamic adder/subtractor. The first two 2-input LUTs compute two summations based on a possible carry-in of 1 or 0; the other two LUTs generate carry outputs for the two chains of the carry-select circuitry. As shown in Figure2–8, the LAB carry-in signal selects either the carry-in0 or carry-in1 chain. The selected chain’s logic level in turn determines which parallel sum is generated as a combinational or registered output. For example, when implementing an adder, the sum output is the selection of two possible calculated sums: data1 + data2 + carry in0 or data1 + data2 + carry-in1 © October 2008 Altera Corporation MAX II Device Handbook
2–10 Chapter 2: MAX II Architecture Logic Elements The other two LUTs use the data1 and data2 signals to generate two possible carry-out signals: one for a carry of 1 and the other for a carry of 0. The carry-in0 signal acts as the carry-select for the carry-out0 output and carry-in1 acts as the carry- select for the carry-out1 output. LEs in arithmetic mode can drive out registered and unregistered versions of the LUT output. The dynamic arithmetic mode also offers clock enable, counter enable, synchronous up/down control, synchronous clear, synchronous load, and dynamic adder/subtractor options. The LAB local interconnect data inputs generate the counter enable and synchronous up/down control signals. The synchronous clear and synchronous load options are LAB-wide signals that affect all registers in the LAB. The Quartus II software automatically places any registers that are not used by the counter into other LABs. The addnsub LAB-wide signal controls whether the LE acts as an adder or subtractor. Figure2–8. LE in Dynamic Arithmetic Mode LAB Carry-In Carry-In0 sload sclear aload Carry-In1 (LAB Wide) (LAB Wide) (LAB Wide) Register chain addnsub connection (LAB Wide) (1) data1 LUT ALD/PRE data2 ADATA Q Row, column, and data3 D direct link routing LUT Row, column, and ENA CLRN direct link routing clock (LAB Wide) LUT ena (LAB Wide) Local routing aclr (LAB Wide) LUT LUT chain connection Register chain output Register Feedback Carry-Out0 Carry-Out1 Note to Figure2–8: (1) The addnsub signal is tied to the carry input for the first LE of a carry chain only. Carry-Select Chain The carry-select chain provides a very fast carry-select function between LEs in dynamic arithmetic mode. The carry-select chain uses the redundant carry calculation to increase the speed of carry functions. The LE is configured to calculate outputs for a possible carry-in of 0 and carry-in of 1 in parallel. The carry-in0 and carry-in1 signals from a lower-order bit feed forward into the higher-order bit via the parallel carry chain and feed into both the LUT and the next portion of the carry chain. Carry- select chains can begin in any LE within an LAB. MAX II Device Handbook © October 2008 Altera Corporation
Chapter 2: MAX II Architecture 2–11 Logic Elements The speed advantage of the carry-select chain is in the parallel precomputation of carry chains. Since the LAB carry-in selects the precomputed carry chain, not every LE is in the critical path. Only the propagation delays between LAB carry-in generation (LE 5 and LE 10) are now part of the critical path. This feature allows the MAX II architecture to implement high-speed counters, adders, multipliers, parity functions, and comparators of arbitrary width. Figure2–9 shows the carry-select circuitry in an LAB for a 10-bit full adder. One portion of the LUT generates the sum of two bits using the input signals and the appropriate carry-in bit; the sum is routed to the output of the LE. The register can be bypassed for simple adders or used for accumulator functions. Another portion of the LUT generates carry-out bits. An LAB-wide carry-in bit selects which chain is used for the addition of given inputs. The carry-in signal for each chain, carry-in0 or carry-in1, selects the carry-out to carry forward to the carry-in signal of the next- higher-order bit. The final carry-out signal is routed to an LE, where it is fed to local, row, or column interconnects. Figure2–9. Carry-Select Chain LAB Carry-In 0 1 LAB Carry-In AB11 LE0 Sum1 Carry-In0 Carry-In1 A2 Sum2 B2 LE1 LUT data1 Sum data2 A3 LE2 Sum3 LUT B3 A4 LE3 Sum4 LUT B4 A5 LE4 Sum5 LUT B5 0 1 A6 LE5 Sum6 Carry-Out0 Carry-Out1 B6 A7 LE6 Sum7 B7 A8 LE7 Sum8 B8 A9 LE8 Sum9 B9 A10 LE9 Sum10 B10 To top of adjacent LAB LAB Carry-Out © October 2008 Altera Corporation MAX II Device Handbook
2–12 Chapter 2: MAX II Architecture MultiTrack Interconnect The Quartus II software automatically creates carry chain logic during design processing, or you can create it manually during design entry. Parameterized functions such as LPM functions automatically take advantage of carry chains for the appropriate functions. The Quartus II software creates carry chains longer than 10 LEs by linking adjacent LABs within the same row together automatically. A carry chain can extend horizontally up to one full LAB row, but does not extend between LAB rows. Clear and Preset Logic Control LAB-wide signals control the logic for the register’s clear and preset signals. The LE directly supports an asynchronous clear and preset function. The register preset is achieved through the asynchronous load of a logic high. MAX II devices support simultaneous preset/asynchronous load and clear signals. An asynchronous clear signal takes precedence if both signals are asserted simultaneously. Each LAB supports up to two clears and one preset signal. In addition to the clear and preset ports, MAX II devices provide a chip-wide reset pin (DEV_CLRn) that resets all registers in the device. An option set before compilation in the Quartus II software controls this pin. This chip-wide reset overrides all other control signals and uses its own dedicated routing resources (that is, it does not use any of the four global resources). Driving this signal low before or during power-up prevents user mode from releasing clears within the design. This allows you to control when clear is released on a device that has just been powered-up. If not set for its chip- wide reset function, the DEV_CLRn pin is a regular I/O pin. By default, all registers in MAXII devices are set to power-up low. However, this power-up state can be set to high on individual registers during design entry using the QuartusII software. MultiTrack Interconnect In the MAX II architecture, connections between LEs, the UFM, and device I/O pins are provided by the MultiTrack interconnect structure. The MultiTrack interconnect consists of continuous, performance-optimized routing lines used for inter- and intra- design block connectivity. The Quartus II Compiler automatically places critical design paths on faster interconnects to improve design performance. The MultiTrack interconnect consists of row and column interconnects that span fixed distances. A routing structure with fixed length resources for all devices allows predictable and short delays between logic levels instead of large delays associated with global or long routing lines. Dedicated row interconnects route signals to and from LABs within the same row. These row resources include: ■ DirectLink interconnects between LABs ■ R4 interconnects traversing four LABs to the right or left The DirectLink interconnect allows an LAB to drive into the local interconnect of its left and right neighbors. The DirectLink interconnect provides fast communication between adjacent LABs and/or blocks without using row interconnect resources. MAX II Device Handbook © October 2008 Altera Corporation
Chapter 2: MAX II Architecture 2–13 MultiTrack Interconnect The R4 interconnects span four LABs and are used for fast row connections in a four- LAB region. Every LAB has its own set of R4 interconnects to drive either left or right. Figure2–10 shows R4 interconnect connections from an LAB. R4 interconnects can drive and be driven by row IOEs. For LAB interfacing, a primary LAB or horizontal LAB neighbor can drive a given R4 interconnect. For R4 interconnects that drive to the right, the primary LAB and right neighbor can drive on to the interconnect. For R4 interconnects that drive to the left, the primary LAB and its left neighbor can drive on to the interconnect. R4 interconnects can drive other R4 interconnects to extend the range of LABs they can drive. R4 interconnects can also drive C4 interconnects for connections from one row to another. Figure2–10. R4 Interconnect Connections Adjacent LAB can R4 Interconnect drive onto another C4 Column Interconnects (1) Driving Right LAB’s R4 Interconnect R4 Interconnect Driving Left LAB Primary LAB Neighbor LAB (2) Neighbor Notes to Figure2–10: (1) C4 interconnects can drive R4 interconnects. (2) This pattern is repeated for every LAB in the LAB row. The column interconnect operates similarly to the row interconnect. Each column of LABs is served by a dedicated column interconnect, which vertically routes signals to and from LABs and row and column IOEs. These column resources include: ■ LUT chain interconnects within an LAB ■ Register chain interconnects within an LAB ■ C4 interconnects traversing a distance of four LABs in an up and down direction MAX II devices include an enhanced interconnect structure within LABs for routing LE output to LE input connections faster using LUT chain connections and register chain connections. The LUT chain connection allows the combinational output of an LE to directly drive the fast input of the LE right below it, bypassing the local interconnect. These resources can be used as a high-speed connection for wide fan-in © October 2008 Altera Corporation MAX II Device Handbook
2–14 Chapter 2: MAX II Architecture MultiTrack Interconnect functions from LE1 to LE 10 in the same LAB. The register chain connection allows the register output of one LE to connect directly to the register input of the next LE in the LAB for fast shift registers. The Quartus II Compiler automatically takes advantage of these resources to improve utilization and performance. Figure2–11 shows the LUT chain and register chain interconnects. Figure2–11. LUT Chain and Register Chain Interconnects Local Interconnect Routing Among LEs in the LAB LUT Chain LE0 Register Chain Routing to Routing to Adjacent Adjacent LE LE's Register Input LE1 Local LE2 Interconnect LE3 LE4 LE5 LE6 LE7 LE8 LE9 The C4 interconnects span four LABs up or down from a source LAB. Every LAB has its own set of C4 interconnects to drive either up or down. Figure2–12 shows the C4 interconnect connections from an LAB in a column. The C4 interconnects can drive and be driven by column and row IOEs. For LAB interconnection, a primary LAB or its vertical LAB neighbor can drive a given C4 interconnect. C4 interconnects can drive each other to extend their range as well as drive row interconnects for column- to-column connections. MAX II Device Handbook © October 2008 Altera Corporation
Chapter 2: MAX II Architecture 2–15 MultiTrack Interconnect Figure2–12. C4 Interconnect Connections (Note1) C4 Interconnect Drives Local and R4 Interconnects Up to Four Rows C4 Interconnect Driving Up LAB Row Interconnect Adjacent LAB can drive onto neighboring LAB's C4 interconnect Local Interconnect C4 Interconnect Driving Down Note to Figure2–12: (1) Each C4 interconnect can drive either up or down four rows. © October 2008 Altera Corporation MAX II Device Handbook
2–16 Chapter 2: MAX II Architecture Global Signals The UFM block communicates with the logic array similar to LAB-to-LAB interfaces. The UFM block connects to row and column interconnects and has local interconnect regions driven by row and column interconnects. This block also has DirectLink interconnects for fast connections to and from a neighboring LAB. For more information about the UFM interface to the logic array, see “User Flash Memory Block” on page2–18. Table2–2 shows the MAX II device routing scheme. Table2–2. MAX II Device Routing Scheme Destination LUT Register Local DirectLink UFM Column Row Fast I/O Source Chain Chain (1) (1) R4 (1) C4 (1) LE Block IOE IOE (1) LUT Chain — — — — — — v — — — — Register Chain — — — — — — v — — — — Local — — — — — — v v v v — Interconnect DirectLink — — v — — — — — — — — Interconnect R4 Interconnect — — v — v v — — — — — C4 Interconnect — — v — v v — — — — — LE v v v v v v — — v v v UFM Block — — v v v v — — — — — Column IOE — — — — — v — — — — — Row IOE — — — v v v — — — — — Note to Table2–2: (1) These categories are interconnects. Global Signals Each MAX II device has four dual-purpose dedicated clock pins (GCLK[3..0], two pins on the left side and two pins on the right side) that drive the global clock network for clocking, as shown in Figure2–13. These four pins can also be used as general- purpose I/O if they are not used to drive the global clock network. The four global clock lines in the global clock network drive throughout the entire device. The global clock network can provide clocks for all resources within the device including LEs, LAB local interconnect, IOEs, and the UFM block. The global clock lines can also be used for global control signals, such as clock enables, synchronous or asynchronous clears, presets, output enables, or protocol control signals such as TRDY and IRDY for PCI. Internal logic can drive the global clock network for internally-generated global clocks and control signals. Figure2–13 shows the various sources that drive the global clock network. MAX II Device Handbook © October 2008 Altera Corporation
Chapter 2: MAX II Architecture 2–17 Global Signals Figure2–13. Global Clock Generation GCLK0 GCLK1 4 GCLK2 GCLK3 Global Clock 4 Network Logic Array(1) Note to Figure2–13: (1) Any I/O pin can use a MultiTrack interconnect to route as a logic array-generated global clock signal. The global clock network drives to individual LAB column signals, LAB column clocks [3..0], that span an entire LAB column from the top to the bottom of the device. Unused global clocks or control signals in a LAB column are turned off at the LAB column clock buffers shown in Figure2–14. The LAB column clocks [3..0] are multiplexed down to two LAB clock signals and one LAB clear signal. Other control signal types route from the global clock network into the LAB local interconnect. See “LAB Control Signals” on page2–5 for more information. © October 2008 Altera Corporation MAX II Device Handbook
2–18 Chapter 2: MAX II Architecture User Flash Memory Block Figure2–14. Global Clock Network (Note1) LAB Column I/O Block Region clock[3..0] 4 4 4 4 4 4 4 4 LAB Column clock[3..0] I/O Block Region UFM Block (2) I/O Block Region CFM Block Notes to Figure2–14: (1) LAB column clocks in I/O block regions provide high fan-out output enable signals. (2) LAB column clocks drive to the UFM block. User Flash Memory Block MAX II devices feature a single UFM block, which can be used like a serial EEPROM for storing non-volatile information up to 8,192 bits. The UFM block connects to the logic array through the MultiTrack interconnect, allowing any LE to interface to the UFM block. Figure2–15 shows the UFM block and interface signals. The logic array is used to create customer interface or protocol logic to interface the UFM block data outside of the device. The UFM block offers the following features: ■ Non-volatile storage up to 16-bit wide and 8,192 total bits ■ Two sectors for partitioned sector erase ■ Built-in internal oscillator that optionally drives logic array ■ Program, erase, and busy signals MAX II Device Handbook © October 2008 Altera Corporation
Chapter 2: MAX II Architecture 2–19 User Flash Memory Block ■ Auto-increment addressing ■ Serial interface to logic array with programmable interface Figure2–15. UFM Block and Interface Signals UFM Block PROGRAM Program RTP_BUSY ERASE Erase BUSY Control OSC_ENA OSC _:4 OSC 9 UFM Sector 1 ARCLK UFM Sector 0 Address Register 16 16 ARSHFT ARDin DRDin Data Register DRDout DRCLK DRSHFT UFM Storage Each device stores up to 8,192 bits of data in the UFM block. Table2–3 shows the data size, sector, and address sizes for the UFM block. Table2–3. UFM Array Size Device Total Bits Sectors Address Bits Data Width EPM240 8,192 2 9 16 (4,096 bits/sector) EPM570 EPM1270 EPM2210 There are 512 locations with 9-bit addressing ranging from 000h to 1FFh. Sector 0 address space is 000h to 0FFh and Sector 1 address space is from 100h to 1FFh. The data width is up to 16 bits of data. The Quartus II software automatically creates logic to accommodate smaller read or program data widths. Erasure of the UFM involves individual sector erasing (that is, one erase of sector 0 and one erase of sector 1 is required to erase the entire UFM block). Since sector erase is required before a program or write, having two sectors enables a sector size of data to be left untouched while the other sector is erased and programmed with new data. © October 2008 Altera Corporation MAX II Device Handbook
2–20 Chapter 2: MAX II Architecture User Flash Memory Block Internal Oscillator As shown in Figure2–15, the dedicated circuitry within the UFM block contains an oscillator. The dedicated circuitry uses this internally for its read and program operations. This oscillator's divide by 4 output can drive out of the UFM block as a logic interface clock source or for general-purpose logic clocking. The typical OSC output signal frequency ranges from 3.3 to 5.5 MHz, and its exact frequency of operation is not programmable. Program, Erase, and Busy Signals The UFM block’s dedicated circuitry automatically generates the necessary internal program and erase algorithm once the PROGRAM or ERASE input signals have been asserted. The PROGRAM or ERASE signal must be asserted until the busy signal deasserts, indicating the UFM internal program or erase operation has completed. The UFM block also supports JTAG as the interface for programming and/or reading. f For more information about programming and erasing the UFM block, refer to the Using User Flash Memory in MAX II Devices chapter in the MAX II Device Handbook. Auto-Increment Addressing The UFM block supports standard read or stream read operations. The stream read is supported with an auto-increment address feature. Deasserting the ARSHIFT signal while clocking the ARCLK signal increments the address register value to read consecutive locations from the UFM array. Serial Interface The UFM block supports a serial interface with serial address and data signals. The internal shift registers within the UFM block for address and data are 9 bits and 16 bits wide, respectively. The Quartus II software automatically generates interface logic in LEs for a parallel address and data interface to the UFM block. Other standard protocol interfaces such as SPI are also automatically generated in LE logic by the Quartus II software. f For more information about the UFM interface signals and the Quartus II LE-based alternate interfaces, refer to the Using User Flash Memory in MAX II Devices chapter in the MAX II Device Handbook. UFM Block to Logic Array Interface The UFM block is a small partition of the flash memory that contains the CFM block, as shown in Figure2–1 and Figure2–2. The UFM block for the EPM240 device is located on the left side of the device adjacent to the left most LAB column. The UFM block for the EPM570, EPM1270, and EPM2210 devices is located at the bottom left of the device. The UFM input and output signals interface to all types of interconnects (R4 interconnect, C4 interconnect, and DirectLink interconnect to/from adjacent LAB rows). The UFM signals can also be driven from global clocks, GCLK[3..0]. The interface region for the EPM240 device is shown in Figure2–16. The interface regions for EPM570, EPM1270, and EPM2210 devices are shown in Figure2–17. MAX II Device Handbook © October 2008 Altera Corporation
Chapter 2: MAX II Architecture 2–21 User Flash Memory Block Figure2–16. EPM240 UFM Block LAB Row Interface (Note1) CFM Block UFM Block LAB PROGRAM ERASE OSC_ENA LAB RTP_BUSY DRDin DRCLK DRSHFT ARin ARCLK LAB ARSHFT DRDout OSC BUSY Note to Figure2–16: (1) The UFM block inputs and outputs can drive to/from all types of interconnects, not only DirectLink interconnects from adjacent row LABs. © October 2008 Altera Corporation MAX II Device Handbook
2–22 Chapter 2: MAX II Architecture MultiVolt Core Figure2–17. EPM570, EPM1270, and EPM2210 UFM Block LAB Row Interface CFM Block RTP_BUSY BUSY OSC DRDout LAB DRDin DRDCLK DRDSHFT ARDin PROGRAM ERASE OSC_ENA ARCLK LAB ARSHFT UFM Block LAB MultiVolt Core The MAX II architecture supports the MultiVolt core feature, which allows MAX II devices to support multiple V levels on the V supply. An internal linear voltage CC CCINT regulator provides the necessary 1.8-V internal voltage supply to the device. The voltage regulator supports 3.3-V or 2.5-V supplies on its inputs to supply the 1.8-V internal voltage to the device, as shown in Figure2–18. The voltage regulator is not guaranteed for voltages that are between the maximum recommended 2.5-V operating voltage and the minimum recommended 3.3-V operating voltage. The MAX IIG and MAX IIZ devices use external 1.8-V supply. The 1.8-V V external CC supply powers the device core directly. Figure2–18. MultiVolt Core Feature in MAX II Devices Voltage 1.8-V Core 3.3-V or 2.5-V on 1.8-V on Regulator Voltage VCCINT Pins VCCINT Pins 1.8-V Core Voltage MAX II Device MAX IIG or MAX IIZ Device MAX II Device Handbook © October 2008 Altera Corporation
Chapter 2: MAX II Architecture 2–23 I/O Structure I/O Structure IOEs support many features, including: ■ LVTTL and LVCMOS I/O standards ■ 3.3-V, 32-bit, 66-MHz PCI compliance ■ Joint Test Action Group (JTAG) boundary-scan test (BST) support ■ Programmable drive strength control ■ Weak pull-up resistors during power-up and in system programming ■ Slew-rate control ■ Tri-state buffers with individual output enable control ■ Bus-hold circuitry ■ Programmable pull-up resistors in user mode ■ Unique output enable per pin ■ Open-drain outputs ■ Schmitt trigger inputs ■ Fast I/O connection ■ Programmable input delay MAX II device IOEs contain a bidirectional I/O buffer. Figure2–19 shows the MAX II IOE structure. Registers from adjacent LABs can drive to or be driven from the IOE’s bidirectional I/O buffers. The Quartus II software automatically attempts to place registers in the adjacent LAB with fast I/O connection to achieve the fastest possible clock-to-output and registered output enable timing. For input registers, the QuartusII software automatically routes the register to guarantee zero hold time. You can set timing assignments in the QuartusII software to achieve desired I/O timing. Fast I/O Connection A dedicated fast I/O connection from the adjacent LAB to the IOEs within an I/O block provides faster output delays for clock-to-output and t propagation delays. PD This connection exists for data output signals, not output enable signals or input signals. Figure2–20, Figure2–21, and Figure2–22 illustrate the fast I/O connection. © October 2008 Altera Corporation MAX II Device Handbook
2–24 Chapter 2: MAX II Architecture I/O Structure Figure2–19. MAX II IOE Structure Data_in Fast_out Data_out OE DEV_OE Optional PCI Clamp (1) Programmable VCCIO VCCIO Pull-Up I/O Pin Drive Strength Control Optional Bus-Hold Open-Drain Output Circuit Slew Control Optional Schmitt Programmable Trigger Input Input Delay Note to Figure2–19: (1) Available in EPM1270 and EPM2210 devices only. I/O Blocks The IOEs are located in I/O blocks around the periphery of the MAX II device. There are up to seven IOEs per row I/O block (5 maximum in the EPM240 device) and up to four IOEs per column I/O block. Each column or row I/O block interfaces with its adjacent LAB and MultiTrack interconnect to distribute signals throughout the device. The row I/O blocks drive row, column, or DirectLink interconnects. The column I/O blocks drive column interconnects. MAX II Device Handbook © October 2008 Altera Corporation
Chapter 2: MAX II Architecture 2–25 I/O Structure Figure2–20 shows how a row I/O block connects to the logic array. Figure2–20. Row I/O Block Connection to the Interconnect (Note1) R4 Interconnects C4 Interconnects I/O Block Local Interconnect data_out [6..0] 7 OE [6..0] 7 LAB Row fast_out I/O Block [6..0] 7 data_in[6..0] 7 Direct Link Interconnect Direct Link from Adjacent LAB Interconnect to Adjacent LAB Row I/O Block Contains up to LAB Local LAB Column Seven IOEs clock [3..0] Interconnect Note to Figure2–20: (1) Each of the seven IOEs in the row I/O block can have one data_out or fast_out output, one OE output, and one data_in input. © October 2008 Altera Corporation MAX II Device Handbook
2–26 Chapter 2: MAX II Architecture I/O Structure Figure2–21 shows how a column I/O block connects to the logic array. Figure2–21. Column I/O Block Connection to the Interconnect (Note1) Column I/O Column I/O Block Block Contains Up To 4 IOEs data_in data_out OE fast_out [3..0] [3..0] [3..0] [3..0] 4 4 4 4 I/O Block Local Interconnect Fast I/O Interconnect LAB Column Path Clock [3..0] R4 Interconnects LAB LAB LAB LAB Local LAB Local LAB Local Interconnect Interconnect Interconnect C4 Interconnects C4 Interconnects Note to Figure2–21: (1) Each of the four IOEs in the column I/O block can have one data_out or fast_out output, one OE output, and one data_in input. I/O Standards and Banks MAX II device IOEs support the following I/O standards: ■ 3.3-V LVTTL/LVCMOS ■ 2.5-V LVTTL/LVCMOS ■ 1.8-V LVTTL/LVCMOS ■ 1.5-V LVCMOS ■ 3.3-V PCI MAX II Device Handbook © October 2008 Altera Corporation
Chapter 2: MAX II Architecture 2–27 I/O Structure Table2–4 describes the I/O standards supported by MAX II devices. Table2–4. MAX II I/O Standards Output Supply Voltage I/O Standard Type (VCCIO) (V) 3.3-V LVTTL/LVCMOS Single-ended 3.3 2.5-V LVTTL/LVCMOS Single-ended 2.5 1.8-V LVTTL/LVCMOS Single-ended 1.8 1.5-V LVCMOS Single-ended 1.5 3.3-V PCI (1) Single-ended 3.3 Note to Table2–4: (1) The 3.3-V PCI compliant I/O is supported in Bank 3 of the EPM1270 and EPM2210 devices. The EPM240 and EPM570 devices support two I/O banks, as shown in Figure2–22. Each of these banks support all the LVTTL and LVCMOS standards shown in Table2–4. PCI compliant I/O is not supported in these devices and banks. Figure2–22. MAX II I/O Banks for EPM240 and EPM570 (Note1), (2) I/O Bank 1 I/O Bank 2 All I/O Banks Support ■ 3.3-V LVTTL/LVCMOS ■ 2.5-V LVTTL/LVCMOS ■ 1.8-V LVTTL/LVCMOS ■ 1.5-V LVCMOS Notes to Figure2–22: (1) Figure2–22 is a top view of the silicon die. (2) Figure2–22 is a graphical representation only. Refer to the pin list and the Quartus II software for exact pin locations. The EPM1270 and EPM2210 devices support four I/O banks, as shown in Figure2–23. Each of these banks support all of the LVTTL and LVCMOS standards shown in Table2–4. PCI compliant I/O is supported in Bank 3. Bank 3 supports the PCI clamping diode on inputs and PCI drive compliance on outputs. You must use Bank 3 for designs requiring PCI compliant I/O pins. The Quartus II software automatically places I/O pins in this bank if assigned with the PCI I/O standard. © October 2008 Altera Corporation MAX II Device Handbook
2–28 Chapter 2: MAX II Architecture I/O Structure Figure2–23. MAX II I/O Banks for EPM1270 and EPM2210 (Note1), (2) I/O Bank 2 Also Supports All I/O Banks Support the 3.3-V PCI ■ 3.3-V LVTTL/LVCMOS I/O Standard ■ 2.5-V LVTTL/LVCMOS ■ 1.8-V LVTTL/LVCMOS ■ 1.5-V LVCMOS I/O Bank 1 I/O Bank 3 I/O Bank 4 Notes to Figure2–23: (1) Figure2–23 is a top view of the silicon die. (2) Figure2–23 is a graphical representation only. Refer to the pin list and the Quartus II software for exact pin locations. Each I/O bank has dedicated V pins that determine the voltage standard support CCIO in that bank. A single device can support 1.5-V, 1.8-V, 2.5-V, and 3.3-V interfaces; each individual bank can support a different standard. Each I/O bank can support multiple standards with the same V for input and output pins. For example, when CCIO V is 3.3 V, Bank3 can support LVTTL, LVCMOS, and 3.3-V PCI. V powers both CCIO CCIO the input and output buffers in MAX II devices. The JTAG pins for MAX II devices are dedicated pins that cannot be used as regular I/O pins. The pins TMS, TDI, TDO, and TCK support all the I/O standards shown in Table2–4 on page2–27 except for PCI. These pins reside in Bank 1 for all MAX II devices and their I/O standard support is controlled by the V setting for Bank 1. CCIO PCI Compliance The MAX II EPM1270 and EPM2210 devices are compliant with PCI applications as well as all 3.3-V electrical specifications in the PCI Local Bus Specification Revision 2.2. These devices are also large enough to support PCI intellectual property (IP) cores. Table2–5 shows the MAX II device speed grades that meet the PCI timing specifications. MAX II Device Handbook © October 2008 Altera Corporation
Chapter 2: MAX II Architecture 2–29 I/O Structure Table2–5. MAX II Devices and Speed Grades that Support 3.3-V PCI Electrical Specifications and Meet PCI Timing Device 33-MHz PCI 66-MHz PCI EPM1270 All Speed Grades –3 Speed Grade EPM2210 All Speed Grades –3 Speed Grade Schmitt Trigger The input buffer for each MAX II device I/O pin has an optional Schmitt trigger setting for the 3.3-V and 2.5-V standards. The Schmitt trigger allows input buffers to respond to slow input edge rates with a fast output edge rate. Most importantly, Schmitt triggers provide hysteresis on the input buffer, preventing slow-rising noisy input signals from ringing or oscillating on the input signal driven into the logic array. This provides system noise tolerance on MAX II inputs, but adds a small, nominal input delay. The JTAG input pins (TMS, TCK, and TDI) have Schmitt trigger buffers that are always enabled. 1 The TCK input is susceptible to high pulse glitches when the input signal fall time is greater than 200ns for all I/O standards. Output Enable Signals Each MAX II IOE output buffer supports output enable signals for tri-state control. The output enable signal can originate from the GCLK[3..0] global signals or from the MultiTrack interconnect. The MultiTrack interconnect routes output enable signals and allows for a unique output enable for each output or bidirectional pin. MAX II devices also provide a chip-wide output enable pin (DEV_OE) to control the output enable for every output pin in the design. An option set before compilation in the Quartus II software controls this pin. This chip-wide output enable uses its own routing resources and does not use any of the four global resources. If this option is turned on, all outputs on the chip operate normally when DEV_OE is asserted. When the pin is deasserted, all outputs are tri-stated. If this option is turned off, the DEV_OE pin is disabled when the device operates in user mode and is available as a user I/O pin. Programmable Drive Strength The output buffer for each MAX II device I/O pin has two levels of programmable drive strength control for each of the LVTTL and LVCMOS I/O standards. Programmable drive strength provides system noise reduction control for high performance I/O designs. Although a separate slew-rate control feature exists, using the lower drive strength setting provides signal slew-rate control to reduce system noise and signal overshoot without the large delay adder associated with the slew-rate control feature. Table2–6 shows the possible settings for the I/O standards with drive strength control. The Quartus II software uses the maximum current strength as the default setting. The PCI I/O standard is always set at 20 mA with no alternate setting. © October 2008 Altera Corporation MAX II Device Handbook
2–30 Chapter 2: MAX II Architecture I/O Structure Table2–6. Programmable Drive Strength (Note1) I/O Standard IOH/IOL Current Strength Setting (mA) 3.3-V LVTTL 16 8 3.3-V LVCMOS 8 4 2.5-V LVTTL/LVCMOS 14 7 1.8-V LVTTL/LVCMOS 6 3 1.5-V LVCMOS 4 2 Note to Table2–6: (1) The I current strength numbers shown are for a condition of a V = V minimum, where the V minimum OH OUT OH OH is specified by the I/O standard. The I current strength numbers shown are for a condition of a V = V OL OUT OL maximum, where the V maximum is specified by the I/O standard. For 2.5-V LVTTL/LVCMOS, the I OL OH condition is V = 1.7 V and the I condition is V =0.7 V. OUT OL OUT Slew-Rate Control The output buffer for each MAX II device I/O pin has a programmable output slew- rate control that can be configured for low noise or high-speed performance. A faster slew rate provides high-speed transitions for high-performance systems. However, these fast transitions may introduce noise transients into the system. A slow slew rate reduces system noise, but adds a nominal output delay to rising and falling edges. The lower the voltage standard (for example, 1.8-V LVTTL) the larger the output delay when slow slew is enabled. Each I/O pin has an individual slew-rate control, allowing the designer to specify the slew rate on a pin-by-pin basis. The slew-rate control affects both the rising and falling edges. Open-Drain Output MAX II devices provide an optional open-drain (equivalent to open-collector) output for each I/O pin. This open-drain output enables the device to provide system-level control signals (for example, interrupt and write enable signals) that can be asserted by any of several devices. This output can also provide an additional wired-OR plane. Programmable Ground Pins Each unused I/O pin on MAX II devices can be used as an additional ground pin. This programmable ground feature does not require the use of the associated LEs in the device. In the Quartus II software, unused pins can be set as programmable GND on a global default basis or they can be individually assigned. Unused pins also have the option of being set as tri-stated input pins. MAX II Device Handbook © October 2008 Altera Corporation
Chapter 2: MAX II Architecture 2–31 I/O Structure Bus Hold Each MAX II device I/O pin provides an optional bus-hold feature. The bus-hold circuitry can hold the signal on an I/O pin at its last-driven state. Since the bus-hold feature holds the last-driven state of the pin until the next input signal is present, an external pull-up or pull-down resistor is not necessary to hold a signal level when the bus is tri-stated. The bus-hold circuitry also pulls undriven pins away from the input threshold voltage where noise can cause unintended high-frequency switching. The designer can select this feature individually for each I/O pin. The bus-hold output will drive no higher than V to prevent overdriving signals. If the bus-hold feature is enabled, CCIO the device cannot use the programmable pull-up option. The bus-hold circuitry uses a resistor to pull the signal level to the last driven state. The DC and Switching Characteristics chapter in the MAX II Device Handbook gives the specific sustaining current for each V voltage level driven through this resistor and CCIO overdrive current used to identify the next-driven input level. The bus-hold circuitry is only active after the device has fully initialized. The bus-hold circuit captures the value on the pin present at the moment user mode is entered. Programmable Pull-Up Resistor Each MAX II device I/O pin provides an optional programmable pull-up resistor during user mode. If the designer enables this feature for an I/O pin, the pull-up resistor holds the output to the V level of the output pin’s bank. CCIO 1 The programmable pull-up resistor feature should not be used at the same time as the bus-hold feature on a given I/O pin. Programmable Input Delay The MAX II IOE includes a programmable input delay that is activated to ensure zero hold times. A path where a pin directly drives a register, with minimal routing between the two, may require the delay to ensure zero hold time. However, a path where a pin drives a register through long routing or through combinational logic may not require the delay to achieve a zero hold time. The Quartus II software uses this delay to ensure zero hold times when needed. MultiVolt I/O Interface The MAX II architecture supports the MultiVolt I/O interface feature, which allows MAX II devices in all packages to interface with systems of different supply voltages. The devices have one set of VCC pins for internal operation (V ), and up to four CCINT sets for input buffers and I/O output driver buffers (V ), depending on the number CCIO of I/O banks available in the devices where each set of VCC pins powers one I/O bank. The EPM240 and EPM570 devices have two I/O banks respectively while the EPM1270 and EPM2210 devices have four I/O banks respectively. © October 2008 Altera Corporation MAX II Device Handbook
2–32 Chapter 2: MAX II Architecture Referenced Documents Connect VCCIO pins to either a 1.5-V, 1.8 V, 2.5-V, or 3.3-V power supply, depending on the output requirements. The output levels are compatible with systems of the same voltage as the power supply (that is, when VCCIO pins are connected to a 1.5-V power supply, the output levels are compatible with 1.5-V systems). When VCCIO pins are connected to a 3.3-V power supply, the output high is 3.3 V and is compatible with 3.3-V or 5.0-V systems. Table2–7 summarizes MAX II MultiVolt I/O support. Table2–7. MAX II MultiVolt I/O Support (Note1) Input Signal Output Signal VCCIO (V) 1.5 V 1.8 V 2.5 V 3.3 V 5.0 V 1.5 V 1.8 V 2.5 V 3.3 V 5.0 V v v v v— v — — — — 1.5 v v v v— v (2) v — — — 1.8 — — v v — v (3) v (3) v — — 2.5 — — v (4) v v (5) v (6) v (6) v (6) v v (7) 3.3 Notes to Table2–7: (1) To drive inputs higher than V but less than 4.0 V including the overshoot, disable the I/O clamp diode. However, to drive 5.0-V inputs to the CCIO device, enable the I/O clamp diode to prevent V from rising above 4.0 V. I (2) When V = 1.8 V, a MAX II device can drive a 1.5-V device with 1.8-V tolerant inputs. CCIO (3) When V = 2.5 V, a MAX II device can drive a 1.5-V or 1.8-V device with 2.5-V tolerant inputs. CCIO (4) When V = 3.3 V and a 2.5-V input signal feeds an input pin, the VCCIO supply current will be slightly larger than expected. CCIO (5) MAX II devices can be 5.0-V tolerant with the use of an external resistor and the internal I/O clamp diode on the EPM1270 and EPM2210 devices. (6) When V = 3.3 V, a MAX II device can drive a 1.5-V, 1.8-V, or 2.5-V device with 3.3-V tolerant inputs. CCIO (7) When V = 3.3 V, a MAX II device can drive a device with 5.0-V TTL inputs but not 5.0-V CMOS inputs. In the case of 5.0-V CMOS, open- CCIO drain setting with internal I/O clamp diode (available only on EPM1270 and EPM2210 devices) and external resistor is required. f For information about output pin source and sink current guidelines, refer to the AN 428: MAX II CPLD Design Guidelines. Referenced Documents This chapter referenced the following documents: ■ AN 428: MAX II CPLD Design Guidelines ■ DC and Switching Characteristics chapter in the MAX II Device Handbook ■ Hot Socketing and Power-On Reset in MAX II Devices chapter in the MAX II Device Handbook ■ Using User Flash Memory in MAX II Devices chapter in the MAX II Device Handbook MAX II Device Handbook © October 2008 Altera Corporation
Chapter 2: MAX II Architecture 2–33 Document Revision History Document Revision History Table2–8 shows the revision history for this chapter. Table2–8. Document Revision History Date and Revision Changes Made Summary of Changes October 2008, ■ Updated Table2–4 and Table2–6. — version 2.2 ■ Updated “I/O Standards and Banks” section. ■ Updated New Document Format. March 2008, ■ Updated “Schmitt Trigger” section. — version 2.1 December 2007, ■ Updated “Clear and Preset Logic Control” section. Updated document with version 2.0 MAX IIZ information. ■ Updated “MultiVolt Core” section. ■ Updated “MultiVolt I/O Interface” section. ■ Updated Table2–7. ■ Added “Referenced Documents” section. December 2006, ■ Minor update in “Internal Oscillator” section. Added document — version 1.7 revision history. August 2006, ■ Updated functional description and I/O structure sections. — version 1.6 July 2006, ■ Minor content and table updates. — vervion 1.5 February 2006, ■ Updated “LAB Control Signals” section. — version 1.4 ■ Updated “Clear and Preset Logic Control” section. ■ Updated “Internal Oscillator” section. ■ Updated Table2–5. August 2005, ■ Removed Note 2 from Table 2-7. — version 1.3 December 2004, ■ Added a paragraph to page 2-15. — version 1.2 June 2004, ■ Added CFM acronym. Corrected Figure 2-19. — version 1.1 © October 2008 Altera Corporation MAX II Device Handbook
2–34 Chapter 2: MAX II Architecture Document Revision History MAX II Device Handbook © October 2008 Altera Corporation
3. JTAG and In-System Programmability MII51003-1.6 Introduction This chapter discusses how to use the IEEE Standard 1149.1 Boundary-Scan Test (BST) circuitry in MAX II devices and includes the following sections: ■ “IEEE Std. 1149.1 (JTAG) Boundary-Scan Support” on page3–1 ■ “In System Programmability” on page3–4 IEEE Std. 1149.1 (JTAG) Boundary-Scan Support All MAX® II devices provide Joint Test Action Group (JTAG) boundary-scan test (BST) circuitry that complies with the IEEE Std. 1149.1-2001 specification. JTAG boundary- scan testing can only be performed at any time after V and all V banks have CCINT CCIO been fully powered and a t amount of time has passed. MAX II devices can also CONFIG use the JTAG port for in-system programming together with either the Quartus®II software or hardware using Programming Object Files (.pof), JamTM Standard Test and Programming Language (STAPL) Files (.jam), or Jam Byte-Code Files (.jbc). The JTAG pins support 1.5-V, 1.8-V, 2.5-V, or 3.3-V I/O standards. The supported voltage level and standard are determined by the V of the bank where it resides. CCIO The dedicated JTAG pins reside in Bank 1 of all MAX II devices. MAX II devices support the JTAG instructions shown in Table3–1. Table3–1. MAX II JTAG Instructions (Part 1 of 2) JTAG Instruction Instruction Code Description SAMPLE/PRELOAD 00 0000 0101 Allows a snapshot of signals at the device pins to be captured and examined during normal device operation, and permits an initial data pattern to be output at the device pins. EXTEST (1) 00 0000 1111 Allows the external circuitry and board-level interconnects to be tested by forcing a test pattern at the output pins and capturing test results at the input pins. BYPASS 11 1111 1111 Places the 1-bit bypass register between the TDI and TDO pins, which allows the BST data to pass synchronously through selected devices to adjacent devices during normal device operation. USERCODE 00 0000 0111 Selects the 32-bit USERCODE register and places it between the TDI and TDO pins, allowing the USERCODE to be serially shifted out of TDO. This register defaults to all 1’s if not specified in the Quartus II software. IDCODE 00 0000 0110 Selects the IDCODE register and places it between TDI and TDO, allowing the IDCODE to be serially shifted out of TDO. HIGHZ (1) 00 0000 1011 Places the 1-bit bypass register between the TDI and TDO pins, which allows the boundary scan test data to pass synchronously through selected devices to adjacent devices during normal device operation, while tri-stating all of the I/O pins. © October 2008 Altera Corporation MAX II Device Handbook
3–2 Chapter 3: JTAG and In-System Programmability IEEE Std. 1149.1 (JTAG) Boundary-Scan Support Table3–1. MAX II JTAG Instructions (Part 2 of 2) JTAG Instruction Instruction Code Description CLAMP (1) 00 0000 1010 Places the 1-bit bypass register between the TDI and TDO pins, which allows the boundary scan test data to pass synchronously through selected devices to adjacent devices during normal device operation, while holding I/O pins to a state defined by the data in the boundary-scan register. USER0 00 0000 1100 This instruction allows you to define the scan chain between TDI and TDO in the MAX II logic array. This instruction is also used for custom logic and JTAG interfaces. USER1 00 0000 1110 This instruction allows you to define the scan chain between TDI and TDO in the MAX II logic array. This instruction is also used for custom logic and JTAG interfaces. IEEE 1532 (2) IEEE 1532 ISC instructions used when programming a MAX II device instructions via the JTAG port. Notes to Table3–1: (1) HIGHZ, CLAMP, and EXTEST instructions do not disable weak pull-up resistors or bus hold features. (2) These instructions are shown in the 1532 BSDL files, which will be posted on the Altera® website at www.altera.com when they are available. w Unsupported JTAG instructions should not be issued to the MAXII device as this may put the device into an unknown state, requiring a power cycle to recover device operation. The MAX II device instruction register length is 10 bits and the USERCODE register length is 32 bits. Table3–2 and Table3–3 show the boundary-scan register length and device IDCODE information for MAXII devices. Table3–2. MAX II Boundary-Scan Register Length Device Boundary-Scan Register Length EPM240 240 EPM570 480 EPM1270 636 EPM2210 816 Table3–3. 32-Bit MAX II Device IDCODE (Part 1 of 2) Binary IDCODE (32 Bits) (1) Version Manufacturer LSB Device (4 Bits) Part Number Identity (11 Bits) (1 Bit) (2) HEX IDCODE EPM240 0000 0010 0000 1010 0001 000 0110 1110 1 0x020A10DD EPM240G EPM570 0000 0010 0000 1010 0010 000 0110 1110 1 0x020A20DD EPM570G EPM1270 0000 0010 0000 1010 0011 000 0110 1110 1 0x020A30DD EPM1270G EPM2210 0000 0010 0000 1010 0100 000 0110 1110 1 0x020A40DD EPM2210G MAX II Device Handbook © October 2008 Altera Corporation
Chapter 3: JTAG and In-System Programmability 3–3 IEEE Std. 1149.1 (JTAG) Boundary-Scan Support Table3–3. 32-Bit MAX II Device IDCODE (Part 2 of 2) Binary IDCODE (32 Bits) (1) Version Manufacturer LSB Device (4 Bits) Part Number Identity (11 Bits) (1 Bit) (2) HEX IDCODE EPM240Z 0000 0010 0000 1010 0101 000 0110 1110 1 0x020A50DD EPM570Z 0000 0010 0000 1010 0110 000 0110 1110 1 0x020A60DD Notes to Table3–2: (1) The most significant bit (MSB) is on the left. (2) The IDCODE’s least significant bit (LSB) is always 1. f For JTAG AC characteristics, refer to the DC and Switching Characteristics chapter in the MAX II Device Handbook. f For more information about JTAG BST, refer to the IEEE 1149.1 (JTAG) Boundary-Scan Testing for MAXII Devices chapter in the MAX II Device Handbook. JTAG Block The MAX II JTAG block feature allows you to access the JTAG TAP and state signals when either the USER0 or USER1 instruction is issued to the JTAG TAP. The USER0 and USER1 instructions bring the JTAG boundary-scan chain (TDI) through the user logic instead of the MAX II device’s boundary-scan cells. Each USER instruction allows for one unique user-defined JTAG chain into the logic array. Parallel Flash Loader The JTAG block ability to interface JTAG to non-JTAG devices is ideal for general- purpose flash memory devices (such as Intel- or Fujitsu-based devices) that require programming during in-circuit test. The flash memory devices can be used for FPGA configuration or be part of system memory. In many cases, the MAX II device is already connected to these devices as the configuration control logic between the FPGA and the flash device. Unlike ISP-capable CPLD devices, bulk flash devices do not have JTAG TAP pins or connections. For small flash devices, it is common to use the serial JTAG scan chain of a connected device to program the non-JTAG flash device. This is slow and inefficient in most cases and impractical for large parallel flash devices. Using the MAX II device’s JTAG block as a parallel flash loader, with the Quartus II software, to program and verify flash contents provides a fast and cost- effective means of in-circuit programming during test. Figure3–1 shows MAX II being used as a parallel flash loader. © October 2008 Altera Corporation MAX II Device Handbook
3–4 Chapter 3: JTAG and In-System Programmability In System Programmability Figure3–1. MAX II Parallel Flash Loader MAX II Device Flash Memory Device Altera FPGA DQ[7..0] DQ[7..0] CONF_DONE nSTATUS A[20..0] A[20..0] nCE OE OE WE WE CE CE RY/BY RY/BY DATA0 TDO_U nCONFIG Parallel TDI TDI_U DCLK Flash Loader TMS TMS_U Configuration TCK TCK_U Logic SHIFT_U CLKDR_U TDO (1),(2) UPDATE_U RUNIDLE_U USER1_U Notes to Figure3–1: (1) This block is implemented in LEs. (2) This function is supported in the Quartus II software. In System Programmability MAX II devices can be programmed in-system via the industry standard 4-pin IEEE Std. 1149.1 (JTAG) interface. In-system programmability (ISP) offers quick, efficient iterations during design development and debugging cycles. The logic, circuitry, and interconnects in the MAX II architecture are configured with flash-based SRAM configuration elements. These SRAM elements require configuration data to be loaded each time the device is powered. The process of loading the SRAM data is called configuration. The on-chip configuration flash memory (CFM) block stores the SRAM element’s configuration data. The CFM block stores the design’s configuration pattern in a reprogrammable flash array. During ISP, the MAX II JTAG and ISP circuitry programs the design pattern into the CFM block’s non-volatile flash array. The MAX II JTAG and ISP controller internally generate the high programming voltages required to program the CFM cells, allowing in-system programming with any of the recommended operating external voltage supplies (that is, 3.3 V/2.5 V or 1.8V for the MAX IIG and MAX IIZ devices). ISP can be performed anytime after V and all V banks have been fully powered and the device has completed the CCINT CCIO configuration power-up time. By default, during in-system programming, the I/O pins are tri-stated and weakly pulled-up to V to eliminate board conflicts. The in- CCIO system programming clamp and real-time ISP feature allow user control of I/O state or behavior during ISP. For more information, refer to “In-System Programming Clamp” on page3–6 and “Real-Time ISP” on page3–7. These devices also offer an ISP_DONE bit that provides safe operation when in- system programming is interrupted. This ISP_DONE bit, which is the last bit programmed, prevents all I/O pins from driving until the bit is programmed. MAX II Device Handbook © October 2008 Altera Corporation
Chapter 3: JTAG and In-System Programmability 3–5 In System Programmability IEEE 1532 Support The JTAG circuitry and ISP instruction set in MAX II devices is compliant to the IEEE 1532-2002 programming specification. This provides industry-standard hardware and software for in-system programming among multiple vendor programmable logic devices (PLDs) in a JTAG chain. The MAX II 1532 BSDL files will be released on the Altera website when available. Jam Standard Test and Programming Language (STAPL) The Jam STAPL JEDEC standard, JESD71, can be used to program MAXII devices with in-circuit testers, PCs, or embedded processors. The Jam byte code is also supported for MAX II devices. These software programming protocols provide a compact embedded solution for programming MAX II devices. f For more information, refer to the Using Jam STAPL for ISP via an Embedded Processor chapter in the MAX II Device Handbook. Programming Sequence During in-system programming, 1532 instructions, addresses, and data are shifted into the MAX II device through the TDI input pin. Data is shifted out through the TDO output pin and compared against the expected data. Programming a pattern into the device requires the following six ISP steps. A stand-alone verification of a programmed pattern involves only stages 1, 2, 5, and 6. These steps are automatically executed by third-party programmers, the Quartus II software, or the Jam STAPL and Jam Byte-Code Players. 1. Enter ISP—The enter ISP stage ensures that the I/O pins transition smoothly from user mode to ISP mode. 2. Check ID—Before any program or verify process, the silicon ID is checked. The time required to read this silicon ID is relatively small compared to the overall programming time. 3. Sector Erase—Erasing the device in-system involves shifting in the instruction to erase the device and applying an erase pulse(s). The erase pulse is automatically generated internally by waiting in the run/test/idle state for the specified erase pulse time of 500 ms for the CFM block and 500 ms for each sector of the UFM block. 4. Program—Programming the device in-system involves shifting in the address, data, and program instruction and generating the program pulse to program the flash cells. The program pulse is automatically generated internally by waiting in the run/test/idle state for the specified program pulse time of 75 µs. This process is repeated for each address in the CFM and UFM blocks. 5. Verify—Verifying a MAX II device in-system involves shifting in addresses, applying the verify instruction to generate the read pulse, and shifting out the data for comparison. This process is repeated for each CFM and UFM address. 6. Exit ISP—An exit ISP stage ensures that the I/O pins transition smoothly from ISP mode to user mode. © October 2008 Altera Corporation MAX II Device Handbook
3–6 Chapter 3: JTAG and In-System Programmability In System Programmability Table3–4 shows the programming times for MAX II devices using in-circuit testers to execute the algorithm vectors in hardware. Software-based programming tools used with download cables are slightly slower because of data processing and transfer limitations. Table3–4. MAX II Device Family Programming Times EPM240 EPM570 EPM240G EPM570G EPM1270 EPM2210 Description EPM240Z EPM570Z EPM1270G EPM2210G Unit Erase + Program (1 MHz) 1.72 2.16 2.90 3.92 sec Erase + Program (10 MHz) 1.65 1.99 2.58 3.40 sec Verify (1 MHz) 0.09 0.17 0.30 0.49 sec Verify (10 MHz) 0.01 0.02 0.03 0.05 sec Complete Program Cycle (1 MHz) 1.81 2.33 3.20 4.41 sec Complete Program Cycle (10 MHz) 1.66 2.01 2.61 3.45 sec UFM Programming The Quartus II software, with the use of POF, Jam, or JBC files, supports programming of the user flash memory (UFM) block independent of the logic array design pattern stored in the CFM block. This allows updating or reading UFM contents through ISP without altering the current logic array design, or vice versa. By default, these programming files and methods will program the entire flash memory contents, which includes the CFM block and UFM contents. The stand-alone embedded Jam STAPL player and Jam Byte-Code Player provides action commands for programming or reading the entire flash memory (UFM and CFM together) or each independently. f For more information, refer to the Using Jam STAPL for ISP via an Embedded Processor chapter in the MAX II Device Handbook. In-System Programming Clamp By default, the IEEE 1532 instruction used for entering ISP automatically tri-states all I/O pins with weak pull-up resistors for the duration of the ISP sequence. However, some systems may require certain pins on MAXII devices to maintain a specific DC logic level during an in-field update. For these systems, an optional in-system programming clamp instruction exists in MAX II circuitry to control I/O behavior during the ISP sequence. The in-system programming clamp instruction enables the device to sample and sustain the value on an output pin (an input pin would remain tri-stated if sampled) or to explicitly set a logic high, logic low, or tri-state value on any pin. Setting these options is controlled on an individual pin basis using the Quartus II software. f For more information, refer to the Real-Time ISP and ISP Clamp for MAXII Devices chapter in the MAX II Device Handbook. MAX II Device Handbook © October 2008 Altera Corporation
Chapter 3: JTAG and In-System Programmability 3–7 Referenced Documents Real-Time ISP For systems that require more than DC logic level control of I/O pins, the real-time ISP feature allows you to update the CFM block with a new design image while the current design continues to operate in the SRAM logic array and I/O pins. A new programming file is updated into the MAX II device without halting the original design’s operation, saving down-time costs for remote or field upgrades. The updated CFM block configures the new design into the SRAM upon the next power cycle. It is also possible to execute an immediate configuration of the SRAM without a power cycle by using a specific sequence of ISP commands. The configuration of SRAM without a power cycle takes a specific amount of time (t ). During this time, the CONFIG I/O pins are tri-stated and weakly pulled-up to V . CCIO Design Security All MAX II devices contain a programmable security bit that controls access to the data programmed into the CFM block. When this bit is programmed, design programming information, stored in the CFM block, cannot be copied or retrieved. This feature provides a high level of design security because programmed data within flash memory cells is invisible. The security bit that controls this function, as well as all other programmed data, is reset only when the device is erased. The SRAM is also invisible and cannot be accessed regardless of the security bit setting. The UFM block data is not protected by the security bit and is accessible through JTAG or logic array connections. Programming with External Hardware MAX II devices can be programmed by downloading the information via in-circuit testers, embedded processors, the Altera® ByteblasterMV™, MasterBlaster™, ByteBlaster™ II, and USB-Blaster cables. BP Microsystems, System General, and other programming hardware manufacturers provide programming support for Altera devices. Check their websites for device support information. Referenced Documents This chapter references the following documents: ■ DC and Switching Characteristics chapter in the MAX II Device Handbook ■ IEEE 1149.1 (JTAG) Boundary-Scan Testing for MAX II Devices chapter in the MAX II Device Handbook ■ Real-Time ISP and ISP Clamp for MAXII Devices chapter in the MAX II Device Handbook ■ Using Jam STAPL for ISP via an Embedded Processor chapter in the MAXII Device Handbook © October 2008 Altera Corporation MAX II Device Handbook
3–8 Chapter 3: JTAG and In-System Programmability Document Revision History Document Revision History Table3–5 shows the revision history for this chapter. Table3–5. Document Revision History Date and Revision Changes Made Summary of Changes October 2008, ■ Updated New Document Format. — version 1.6 December 2007, ■ Added warning note after Table3–1. — version 1.5 ■ Updated Table3–3 and Table3–4. ■ Added “Referenced Documents” section. December 2006, ■ Added document revision history. — version 1.4 June 2005, ■ Added text and Table 3-4. — version 1.3 June 2005, ■ Updated text on pages 3-5 to 3-8. — version 1.3 June 2004, ■ Corrected Figure 3-1. Added CFM acronym. — version 1.1 MAX II Device Handbook © October 2008 Altera Corporation
4. Hot Socketing and Power-On Reset in MAX II Devices MII51004-2.1 Introduction MAX® II devices offer hot socketing, also known as hot plug-in or hot swap, and power sequencing support. Designers can insert or remove a MAX II board in a system during operation without undesirable effects to the system bus. The hot socketing feature removes some of the difficulties designers face when using components on printed circuit boards (PCBs) that contain a mixture of 3.3-, 2.5-, 1.8-, and 1.5-V devices. The MAX II device hot socketing feature provides: ■ Board or device insertion and removal ■ Support for any power-up sequence ■ Non-intrusive I/O buffers to system buses during hot insertion This chapter contains the following sections: ■ “MAX II Hot-Socketing Specifications” on page4–1 ■ “Power-On Reset Circuitry” on page4–5 MAX II Hot-Socketing Specifications MAX II devices offer all three of the features required for the hot-socketing capability listed above without any external components or special design requirements. The following are hot-socketing specifications: ■ The device can be driven before and during power-up or power-down without any damage to the device itself. ■ I/O pins remain tri-stated during power-up. The device does not drive out before or during power-up, thereby affecting other buses in operation. ■ Signal pins do not drive the V or V power supplies. External input signals CCIO CCINT to device I/O pins do not power the device V or V power supplies via CCIO CCINT internal paths. This is true if the V and the V supplies are held at GND. CCINT CCIO 1 Altera uses GND as reference for the hot-socketing and I/O buffers circuitry designs. You must connect the GND between boards before connecting the V and the V CCINT CCIO power supplies to ensure device reliability and compliance to the hot-socketing specifications. Devices Can Be Driven before Power-Up Signals can be driven into the MAX II device I/O pins and GCLK[3..0] pins before or during power-up or power-down without damaging the device. MAX II devices support any power-up or power-down sequence (V , V , V , V , V ), CCIO1 CCIO2 CCIO3 CCIO4 CCINT simplifying the system-level design. © October 2008 Altera Corporation MAX II Device Handbook
4–2 Chapter 4: Hot Socketing and Power-On Reset in MAX II Devices Hot Socketing Feature Implementation in MAX II Devices I/O Pins Remain Tri-Stated during Power-Up A device that does not support hot-socketing may interrupt system operation or cause contention by driving out before or during power-up. In a hot socketing situation, the MAX II device’s output buffers are turned off during system power-up. MAX II devices do not drive out until the device attains proper operating conditions and is fully configured. Refer to “Power-On Reset Circuitry” on page4–5 for information about turn-on voltages. Signal Pins Do Not Drive the V or V Power Supplies CCIO CCINT MAXII devices do not have a current path from I/O pins or GCLK[3..0] pins to the V or V pins before or during power-up. A MAX II device may be inserted into CCIO CCINT (or removed from) a system board that was powered up without damaging or interfering with system-board operation. When hot socketing, MAX II devices may have a minimal effect on the signal integrity of the backplane. AC and DC Specifications You can power up or power down the V and V pins in any sequence. During CCIO CCINT hot socketing, the I/O pin capacitance is less than 8pF. MAXII devices meet the following hot socketing specifications: ■ The hot socketing DC specification is: | I | < 300 A. IOPIN ■ The hot socketing AC specification is: | I | < 8mA for 10ns or less. IOPIN 1 MAX II devices are immune to latch-up when hot socketing. If the TCK JTAG input pin is driven high during hot socketing, the current on that pin might exceed the specifications above. I is the current at any user I/O pin on the device. The AC specification applies IOPIN when the device is being powered up or powered down. This specification takes into account the pin capacitance but not board trace and external loading capacitance. Additional capacitance for trace, connector, and loading must be taken into consideration separately. The peak current duration due to power-up transients is 10ns or less. The DC specification applies when all V supplies to the device are stable in the CC powered-up or powered-down conditions. Hot Socketing Feature Implementation in MAX II Devices The hot socketing feature turns off (tri-states) the output buffer during the power-up event (either V or V supplies) or power-down event. The hot-socket circuit CCINT CCIO generates an internal HOTSCKT signal when either V or V is below the CCINT CCIO threshold voltage during power-up or power-down. The HOTSCKT signal cuts off the output buffer to make sure that no DC current (except for weak pull-up leaking) leaks through the pin. When V ramps up very slowly during power-up, V may still be CC CC relatively low even after the power-on reset (POR) signal is released and device configuration is complete. MAX II Device Handbook © October 2008 Altera Corporation
Chapter 4: Hot Socketing and Power-On Reset in MAX II Devices 4–3 Hot Socketing Feature Implementation in MAX II Devices 1 Make sure that the V is within the recommended operating range even though CCINT SRAM download has completed. Each I/O and clock pin has the circuitry shown in Figure4–1. Figure4–1. Hot Socketing Circuit Block Diagram for MAX II Devices Power On Reset V Monitor CCIO Weak Pull-Up Resistor Output Enable PAD Voltage Hot Socket Tolerance Control Input Buffer to Logic Array The POR circuit monitors V and V voltage levels and keeps I/O pins tri-stated CCINT CCIO until the device has completed its flash memory configuration of the SRAM logic. The weak pull-up resistor (R) from the I/O pin to V is enabled during download to CCIO keep the I/O pins from floating. The 3.3-V tolerance control circuit permits the I/O pins to be driven by 3.3 V before V and/or V are powered, and it prevents the CCIO CCINT I/O pins from driving out when the device is not fully powered or operational. The hot socket circuit prevents I/O pins from internally powering V and V when CCIO CCINT driven by external signals before the device is powered. f For information about 5.0-V tolerance, refer to the Using MAX II Devices in Multi- Voltage Systems chapter in the MAX II Device Handbook. Figure4–2 shows a transistor-level cross section of the MAX II device I/O buffers. This design ensures that the output buffers do not drive when V is powered before CCIO V or if the I/O pad voltage is higher than V . This also applies for sudden CCINT CCIO voltage spikes during hot insertion. The V leakage current charges the 3.3-V PAD tolerant circuit capacitance. © October 2008 Altera Corporation MAX II Device Handbook
4–4 Chapter 4: Hot Socketing and Power-On Reset in MAX II Devices Hot Socketing Feature Implementation in MAX II Devices Figure4–2. Transistor-Level Diagram of MAX II Device I/O Buffers VPAD Ensures 3.3-V Tolerance and IOE Signal or the The Larger of Hot-Socket IOE Signal Larger of VCCIO or VPAD VCCIO or VPAD Protection VCCIO n+ n+ p+ p+ n+ p-well n-well p-substrate The CMOS output drivers in the I/O pins intrinsically provide electrostatic discharge (ESD) protection. There are two cases to consider for ESD voltage strikes: positive voltage zap and negative voltage zap. A positive ESD voltage zap occurs when a positive voltage is present on an I/O pin due to an ESD charge event. This can cause the N+ (Drain)/ P-Substrate junction of the N-channel drain to break down and the N+ (Drain)/P-Substrate/N+ (Source) intrinsic bipolar transistor turn on to discharge ESD current from I/O pin to GND. The dashed line (see Figure4–3) shows the ESD current discharge path during a positive ESD zap. Figure4–3. ESD Protection During Positive Voltage Zap I/O Source Gate D PMOS N+ Drain I/O P-Substrate G Drain NMOS Gate N+ S Source GND GND MAX II Device Handbook © October 2008 Altera Corporation
Chapter 4: Hot Socketing and Power-On Reset in MAX II Devices 4–5 Power-On Reset Circuitry When the I/O pin receives a negative ESD zap at the pin that is less than –0.7 V (0.7 V is the voltage drop across a diode), the intrinsic P-Substrate/N+ drain diode is forward biased. Therefore, the discharge ESD current path is from GND to the I/O pin, as shown in Figure4–4. Figure4–4. ESD Protection During Negative Voltage Zap I/O Source Gate D PMOS N+ Drain I/O P-Substrate G Drain NMOS Gate N+ S Source GND GND Power-On Reset Circuitry MAX II devices have POR circuits to monitor V and V voltage levels during CCINT CCIO power-up. The POR circuit monitors these voltages, triggering download from the non-volatile configuration flash memory (CFM) block to the SRAM logic, maintaining tri-state of the I/O pins (with weak pull-up resistors enabled) before and during this process. When the MAX II device enters user mode, the POR circuit releases the I/O pins to user functionality. The POR circuit of the MAX II (except MAXIIZ) device continues to monitor the V voltage level to detect a brown-out condition. The CCINT POR circuit of the MAXIIZ device does not monitor the V voltage level after the CCINT device enters into user mode. More details are provided in the following sub-sections. © October 2008 Altera Corporation MAX II Device Handbook
4–6 Chapter 4: Hot Socketing and Power-On Reset in MAX II Devices Power-On Reset Circuitry Power-Up Characteristics When power is applied to a MAX II device, the POR circuit monitors V and CCINT begins SRAM download at an approximate voltage of 1.7 V or 1.55 V for MAX IIG and MAX IIZ devices. From this voltage reference, SRAM download and entry into user mode takes 200 to 450 µs maximum, depending on device density. This period of time is specified as t in the power-up timing section of the DC and Switching CONFIG Characteristics chapter in the MAX II Device Handbook. Entry into user mode is gated by whether all V banks are powered with sufficient CCIO operating voltage. If V T and V are powered simultaneously, the device enters CCIN CCIO user mode within the t specifications. If V is powered more than t after CONFIG CCIO CONFIG V , the device does not enter user mode until 2 µs after all V banks are powered. CCINT CCIO For MAX II and MAX IIG devices, when in user mode, the POR circuitry continues to monitor the V (but not V ) voltage level to detect a brown-out condition. If CCINT CCIO there is a V voltage sag at or below 1.4 V during user mode, the POR circuit resets CCINT the SRAM and tri-states the I/O pins. Once V rises back to approximately 1.7 V CCINT (or 1.55V for MAXIIG devices), the SRAM download restarts and the device begins to operate after t time has passed. CONFIG For MAX IIZ devices, the POR circuitry does not monitor the V and V voltage CCINT CCIO levels after the device enters user mode. If there is a V voltage sag below 1.4 V CCINT during user mode, the functionality of the device will not be guaranteed and you must power down the V to 0V for a minimum of 10µs before powering the V CCINT CCINT and V up again. Once V rises from 0V back to approximately 1.55V, the CCIO CCINT SRAM download restarts and the device begins to operate after t time has CONFIG passed. Figure4–5 shows the voltages for POR of MAXII, MAXIIG, and MAXIIZ devices during power-up into user mode and from user mode to power-down or brown-out. 1 All V and V pins of all banks must be powered on MAX II devices before CCINT CCIO entering user mode. MAX II Device Handbook © October 2008 Altera Corporation
Chapter 4: Hot Socketing and Power-On Reset in MAX II Devices 4–7 Power-On Reset Circuitry Figure4–5. Power-Up Characteristics for MAX II, MAX IIG, and MAX IIZ Devices (Note1), (2) VCCINT MAX II Device Approximate Voltage 3.3 V for SRAM Download Start 2.5 V Device Resets the SRAM and 1.7 V Tri-States I/O Pins 1.4 V tCONFIG 0 V User Mode Tri-State Tri-State Operation VCCINT MAX IIG Device 3.3 V Approximate Voltage for SRAM Download Start Device Resets 1.8 V the SRAM and Tri-States I/O Pins 1.55 V 1.4 V tCONFIG 0 V User Mode Tri-State Tri-State Operation VCCINT MAX IIZ Device 3.3 V Approximate Voltage VCCINT must be powered down for SRAM Download Start to 0 V if the VCCINT dips below this level 1.8 V 1.55 V 1.4 V tCONFIG minimum 10 µs tCONFIG 0 V User Mode User Mode Tri-State Tri-State Operation Operation Notes to Figure4–5: (1) Time scale is relative. (2) Figure4–5 assumes all V banks power up simultaneously with the V profile shown. If not, t stretches out until all V banks are powered. CCIO CCINT CONFIG CCIO 1 After SRAM configuration, all registers in the device are cleared and released into user function before I/O tri-states are released. To release clears after tri-states are released, use the DEV_CLRn pin option. To hold the tri-states beyond the power-up configuration time, use the DEV_OE pin option. © October 2008 Altera Corporation MAX II Device Handbook
4–8 Chapter 4: Hot Socketing and Power-On Reset in MAX II Devices Referenced Documents Referenced Documents This chapter refereces the following documents: ■ DC and Switching Characteristics chapter in the MAX II Device Handbook ■ Using MAX II Devices in Multi-Voltage Systems chapter in the MAXII Device Handbook Document Revision History Table4–1 shows the revision history for this chapter. Table4–1. Document Revision History Date and Revision Changes Made Summary of Changes October 2008, ■ Updated “MAX II Hot-Socketing Specifications” and “Power-On — Reset Circuitry” sections. version2.1 ■ Updated New Document Format. December 2007, ■ Updated “Hot Socketing Feature Implementation in MAX II Updated document with version 2.0 Devices” section. MAX IIZ information. ■ Updated “Power-On Reset Circuitry” section. ■ Updated Figure4–5. ■ Added “Referenced Documents” section. December 2006, ■ Added document revision history. — version 1.5 February 2006, ■ Updated “MAX II Hot-Socketing Specifications” section. — version 1.4 ■ Updated “AC and DC Specifications” section. ■ Updated “Power-On Reset Circuitry” section. June 2005, ■ Updated AC and DC specifications on page 4-2. — version 1.3 December 2004, ■ Added content to Power-Up Characteristics section. — version 1.2 ■ Updated Figure 4-5. June 2004, ■ Corrected Figure 4-2. — version 1.1 MAX II Device Handbook © October 2008 Altera Corporation
5. DC and Switching Characteristics MII51005-2.5 Introduction System designers must consider the recommended DC and switching conditions discussed in this chapter to maintain the highest possible performance and reliability of the MAX®II devices. This chapter contains the following sections: ■ “Operating Conditions” on page5–1 ■ “Power Consumption” on page5–8 ■ “Timing Model and Specifications” on page5–8 Operating Conditions Table5–1 through Table5–12 provide information about absolute maximum ratings, recommended operating conditions, DC electrical characteristics, and other specifications for MAXII devices. Absolute Maximum Ratings Table5–1 shows the absolute maximum ratings for the MAXII device family. Table5–1. MAXII Device Absolute Maximum Ratings (Note1), (2) Symbol Parameter Conditions Minimum Maximum Unit V Internal supply voltage (3) With respect to ground –0.5 4.6 V CCINT V I/O supply voltage — –0.5 4.6 V CCIO V DC input voltage — –0.5 4.6 V I I DC output current, per pin (4) — –25 25 mA OUT T Storage temperature No bias –65 150 °C STG T Ambient temperature Under bias (5) –65 135 °C AMB T Junction temperature TQFP and BGA packages — 135 °C J under bias Notes to Table5–1: (1) Refer to the Operating Requirements for Altera Devices Data Sheet. (2) Conditions beyond those listed in Table5–1 may cause permanent damage to a device. Additionally, device operation at the absolute maximum ratings for extended periods of time may have adverse affects on the device. (3) Maximum V for MAXII devices is 4.6 V. For MAXIIG and MAXIIZ devices, it is 2.4 V. CCINT (4) Refer to AN 286: Implementing LED Drivers in MAX & MAX II Devices for more information about the maximum source and sink current for MAXII devices. (5) Refer to Table5–2 for information about “under bias” conditions. © August 2009 Altera Corporation MAX II Device Handbook
5–2 Chapter 5: DC and Switching Characteristics Operating Conditions Recommended Operating Conditions Table5–2 shows the MAXII device family recommended operating conditions. Table5–2. MAXII Device Recommended Operating Conditions Symbol Parameter Conditions Minimum Maximum Unit V (1) 3.3-V supply voltage for internal logic and MAXII devices 3.00 3.60 V CCINT ISP 2.5-V supply voltage for internal logic and MAXII devices 2.375 2.625 V ISP 1.8-V supply voltage for internal logic and MAXIIG and MAXIIZ 1.71 1.89 V ISP devices V (1) Supply voltage for I/O buffers, 3.3-V — 3.00 3.60 V CCIO operation Supply voltage for I/O buffers, 2.5-V — 2.375 2.625 V operation Supply voltage for I/O buffers, 1.8-V — 1.71 1.89 V operation Supply voltage for I/O buffers, 1.5-V — 1.425 1.575 V operation V Input voltage (2), (3), (4) –0.5 4.0 V I V Output voltage — 0 V V O CCIO T Operating junction temperature Commercial range 0 85 °C J Industrial range –40 100 °C Extended range (5) –40 125 °C Notes to Table5–2: (1) MAXII device in-system programming and/or user flash memory (UFM) programming via JTAG or logic array is not guaranteed outside the recommended operating conditions (for example, if brown-out occurs in the system during a potential write/program sequence to the UFM, users are recommended to read back UFM contents and verify against the intended write data). (2) Minimum DC input is –0.5 V. During transitions, the inputs may undershoot to –2.0 V for input currents less than 100 mA and periods shorter than 20 ns. (3) During transitions, the inputs may overshoot to the voltages shown in the following table based upon input duty cycle. The DC case is equivalent to 100% duty cycle. For more information about 5.0-V tolerance, refer to the Using MAX II Devices in Multi-Voltage Systems chapter in the MAXII Device Handbook. V Max. Duty Cycle IN 4.0 V 100% (DC) 4.1 90% 4.2 50% 4.3 30% 4.4 17% 4.5 10% (4) All pins, including clock, I/O, and JTAG pins, may be driven before V and V are powered. CCINT CCIO (5) For the extended temperature range of 100 to 125º C, MAXII UFM programming (erase/write) is only supported via the JTAG interface. UFM programming via the logic array interface is not guaranteed in this range. MAX II Device Handbook © August 2009 Altera Corporation
Chapter 5: DC and Switching Characteristics 5–3 Operating Conditions Programming/Erasure Specifications Table5–3 shows the MAXII device family programming/erasure specifications. Table5–3. MAXII Device Programming/Erasure Specifications Parameter Minimum Typical Maximum Unit Erase and reprogram cycles — — 100 (1) Cycles Note to Table5–3: (1) This specification applies to the UFM and configuration flash memory (CFM) blocks. DC Electrical Characteristics Table5–4 shows the MAXII device family DC electrical characteristics. Table5–4. MAXII Device DC Electrical Characteristics (Note1) (Part 1 of 2) Symbol Parameter Conditions Minimum Typical Maximum Unit I Input pin leakage V = V max to 0 V (2) –10 — 10 µA I I CCIO current I Tri-stated I/O pin V = V max to 0 V (2) –10 — 10 µA OZ O CCIO leakage current I V supply current MAXII devices — 12 — mA CCSTANDBY CCINT (standby) (3) MAXIIG devices — 2 — mA EPM240Z (Commercial — 25 90 µA grade) (4) EPM240Z (Industrial — 25 139 µA grade) (5) EPM570Z (Commercial — 27 96 µA grade) (4) EPM570Z (Industrial — 27 152 µA grade) (5) V (6) Hysteresis for Schmitt V = 3.3 V — 400 — mV SCHMITT CCIO trigger input (7) V = 2.5 V — 190 — mV CCIO I V supply current MAXII devices — 55 — mA CCPOWERUP CCINT during power-up (8) MAXIIG and MAXIIZ — 40 — mA devices R Value of I/O pin pull-up V = 3.3 V (9) 5 — 25 k PULLUP CCIO resistor during user V = 2.5 V (9) 10 — 40 k mode and in-system CCIO V = 1.8 V (9) 25 — 60 k programming CCIO V = 1.5 V (9) 45 — 95 k CCIO © August 2009 Altera Corporation MAX II Device Handbook
5–4 Chapter 5: DC and Switching Characteristics Operating Conditions Table5–4. MAXII Device DC Electrical Characteristics (Note1) (Part 2 of 2) Symbol Parameter Conditions Minimum Typical Maximum Unit I I/O pin pull-up resistor — — — 300 µA PULLUP current when I/O is unprogrammed C Input capacitance for — — — 8 pF IO user I/O pin C Input capacitance for — — — 8 pF GCLK dual-purpose GCLK/user I/O pin Notes to Table5–4: (1) Typical values are for T = 25°C, V = 3.3 or 2.5 V, and V = 1.5 V, 1.8 V, 2.5 V, or 3.3 V. A CCINT CCIO (2) This value is specified for normal device operation. The value may vary during power-up. This applies for all V settings (3.3, 2.5, CCIO 1.8, and 1.5 V). (3) V= ground, no load, no toggling inputs. I (4) Commercial temperature ranges from 0°C to 85°C with maximum current at 85°C. (5) Industrial temperature ranges from –40°C to 100°C with maximum current at 100°C. (6) This value applies to commercial and industrial range devices. For extended temperature range devices, the V typical value is SCHMITT 300 mV for V = 3.3 V and 120 mV for V = 2.5 V. CCIO CCIO (7) The TCK input is susceptible to high pulse glitches when the input signal fall time is greater than 200 ns for all I/O standards. (8) This is a peak current value with a maximum duration of t time. CONFIG (9) Pin pull-up resistance values will lower if an external source drives the pin higher than V . CCIO MAX II Device Handbook © August 2009 Altera Corporation
Chapter 5: DC and Switching Characteristics 5–5 Operating Conditions Output Drive Characteristics Figure5–1 shows the typical drive strength characteristics of MAXII devices. Figure5–1. Output Drive Characteristics of MAXII Devices MAX II Output Drive IOH Characteristics MAX II Output Drive IOL Characteristics (Maximum Drive Strength) (Maximum Drive Strength) 70 60 3.3-V VCCIO 3.3-V VCCIO mA)60 mA)50 Typical I Output Current (O1234500000 211...585---VVV VVVCCCCCCIIIOOO Typical I Output Current (O12340000 1.5-V 1V.C8-CVI OVCCIO2.5-V VCCIO 0 0 0.0 0.5 1.0 1.5 2.0 2.5 3.0 3.5 0.0 0.5 1.0 1.5 2.0 2.5 3.0 3.5 Voltage (V) Voltage (V) MAX II Output Drive IOH Characteristics MAX II Output Drive IOL Characteristics (Minimum Drive Strength) (Minimum Drive Strength) 35 30 3.3-V VCCIO 3.3-V VCCIO Typical I Output Current (mA)O11223505050 211...585---VVV VVVCCCCCCIIIOOO Typical I Output Current (mA)O112250505 1.5-V 1V.C8-CVI OVCCIO2.5-V VCCIO 0 0 0.0 0.5 1.0 1.5 2.0 2.5 3.0 3.5 0.0 0.5 1.0 1.5 2.0 2.5 3.0 3.5 Voltage (V) Voltage (V) Note to Figure5–1: (1) The DC output current per pin is subject to the absolute maximum rating of Table5–1. I/O Standard Specifications Table5–5 through Table5–10 show the MAXII device family I/O standard specifications. Table5–5. 3.3-V LVTTL Specifications Symbol Parameter Conditions Minimum Maximum Unit V I/O supply voltage — 3.0 3.6 V CCIO V High-level input voltage — 1.7 4.0 V IH V Low-level input voltage — –0.5 0.8 V IL V High-level output voltage IOH = –4 mA (1) 2.4 — V OH V Low-level output voltage IOL = 4 mA (1) — 0.45 V OL Table5–6. 3.3-V LVCMOS Specifications (Part 1 of 2) Symbol Parameter Conditions Minimum Maximum Unit V I/O supply voltage — 3.0 3.6 V CCIO V High-level input voltage — 1.7 4.0 V IH V Low-level input voltage — –0.5 0.8 V IL © August 2009 Altera Corporation MAX II Device Handbook
5–6 Chapter 5: DC and Switching Characteristics Operating Conditions Table5–6. 3.3-V LVCMOS Specifications (Part 2 of 2) Symbol Parameter Conditions Minimum Maximum Unit V High-level output voltage V = 3.0, V – 0.2 — V OH CCIO CCIO IOH = –0.1 mA (1) V Low-level output voltage V = 3.0, — 0.2 V OL CCIO IOL = 0.1 mA (1) Table5–7. 2.5-V I/O Specifications Symbol Parameter Conditions Minimum Maximum Unit V I/O supply voltage — 2.375 2.625 V CCIO V High-level input voltage — 1.7 4.0 V IH V Low-level input voltage — –0.5 0.7 V IL V High-level output voltage IOH = –0.1 mA (1) 2.1 — V OH IOH = –1 mA (1) 2.0 — V IOH = –2 mA (1) 1.7 — V V Low-level output voltage IOL = 0.1 mA (1) — 0.2 V OL IOL = 1 mA (1) — 0.4 V IOL = 2 mA (1) — 0.7 V Table5–8. 1.8-V I/O Specifications Symbol Parameter Conditions Minimum Maximum Unit V I/O supply voltage — 1.71 1.89 V CCIO V High-level input voltage — 0.65 × V 2.25 (2) V IH CCIO V Low-level input voltage — –0.3 0.35 × V V IL CCIO V High-level output voltage IOH = –2 mA (1) V – 0.45 — V OH CCIO V Low-level output voltage IOL = 2 mA (1) — 0.45 V OL Table5–9. 1.5-V I/O Specifications Symbol Parameter Conditions Minimum Maximum Unit V I/O supply voltage — 1.425 1.575 V CCIO V High-level input voltage — 0.65 × V V + 0.3 (2) V IH CCIO CCIO V Low-level input voltage — –0.3 0.35 × V V IL CCIO V High-level output voltage IOH = –2 mA (1) 0.75 × V — V OH CCIO V Low-level output voltage IOL = 2 mA (1) — 0.25 × V V OL CCIO Notes to Table5–5 through Table5–9: (1) This specification is supported across all the programmable drive strength settings available for this I/O standard, as shown in the MAX II Architecture chapter (I/O Structure section) in the MAXII Device Handbook. (2) This maximum V reflects the JEDEC specification. The MAXII input buffer can tolerate a V maximum of 4.0, as specified IH IH by the V parameter in Table5–2. I MAX II Device Handbook © August 2009 Altera Corporation
Chapter 5: DC and Switching Characteristics 5–7 Operating Conditions Table5–10. 3.3-V PCI Specifications (Note1) Symbol Parameter Conditions Minimum Typical Maximum Unit V I/O supply — 3.0 3.3 3.6 V CCIO voltage V High-level input — 0.5 × V — V + 0.5 V IH CCIO CCIO voltage V Low-level input — –0.5 — 0.3 × V V IL CCIO voltage V High-level IOH = –500 µA 0.9 × V — — V OH CCIO output voltage V Low-level IOL = 1.5 mA — — 0.1 × V V OL CCIO output voltage Note to Table5–10: (1) 3.3-V PCI I/O standard is only supported in Bank 3 of the EPM1270 and EPM2210 devices. Bus Hold Specifications Table5–11 shows the MAXII device family bus hold specifications. Table5–11. Bus Hold Specifications V Level CCIO 1.5 V 1.8 V 2.5 V 3.3 V Parameter Conditions Min Max Min Max Min Max Min Max Unit Low sustaining V > V (maximum) 20 — 30 — 50 — 70 — µA IN IL current High sustaining V < V (minimum) –20 — –30 — –50 — –70 — µA IN IH current Low overdrive 0 V < V < V — 160 — 200 — 300 — 500 µA IN CCIO current High overdrive 0 V < V < V — –160 — –200 — –300 — –500 µA IN CCIO current © August 2009 Altera Corporation MAX II Device Handbook
5–8 Chapter 5: DC and Switching Characteristics Power Consumption Power-Up Timing Table5–12 shows the power-up timing characteristics for MAXII devices. Table5–12. MAXII Power-Up Timing Symbol Parameter Device Min Typ Max Unit t (1) The amount of time from when EPM240 — — 200 µs CONFIG minimum V is reached until CCINT EPM570 — — 300 µs the device enters user mode (2) EPM1270 — — 300 µs EPM2210 — — 450 µs Notes to Table5–12: (1) Table5–12 values apply to commercial and industrial range devices. For extended temperature range devices, the t maximum values are CONFIG as follows: Device Maximum EPM240 300 µs EPM570 400 µs EPM1270 400 µs EPM2210 500 µs (2) For more information about POR trigger voltage, refer to the Hot Socketing and Power-On Reset in MAX II Devices chapter in the MAXII Device Handbook. Power Consumption Designers can use the Altera® PowerPlay Early Power Estimator and PowerPlay Power Analyzer to estimate the device power. f For more information about these power analysis tools, refer to the Understanding and Evaluating Power in MAX II Devices chapter in the MAXII Device Handbook and the PowerPlay Power Analysis chapter in volume 3 of the Quartus II Handbook. Timing Model and Specifications MAXII devices timing can be analyzed with the Altera Quartus® II software, a variety of popular industry-standard EDA simulators and timing analyzers, or with the timing model shown in Figure5–2. MAXII devices have predictable internal delays that enable the designer to determine the worst-case timing of any design. The software provides timing simulation, point-to-point delay prediction, and detailed timing analysis for device-wide performance evaluation. MAX II Device Handbook © August 2009 Altera Corporation
Chapter 5: DC and Switching Characteristics 5–9 Timing Model and Specifications Figure5–2. MAXII Device Timing Model Output and Output Enable Data Delay t R4 t IODR Data-In/LUT Chain tIOE User Logic Element Output Routing Output Flash LUT Delay tC4 Delay Delay I/O InptuINt Delay InpMuDte etRDmlaoLoyurtying tLOCAL Regis tDtLetUeCr lTaCyontrol tCtttPOtCSRHOUMEB tFASTIO tttOXZDZX I/O Pin tCLR From Adjacent LE t I/O Pin INPUT GLOB Combinational Path Delay Global Input Delay To Adjacent LE Register Delays Data-Out The timing characteristics of any signal path can be derived from the timing model and parameters of a particular device. External timing parameters, which represent pin-to-pin timing delays, can be calculated as the sum of internal parameters. f Refer to the Understanding Timing in MAX II Devices chapter in the MAXII Device Handbook for more information. This section describes and specifies the performance, internal, external, and UFM timing specifications. All specifications are representative of the worst-case supply voltage and junction temperature conditions. Preliminary and Final Timing Timing models can have either preliminary or final status. The QuartusII software issues an informational message during the design compilation if the timing models are preliminary. Table5–13 shows the status of the MAXII device timing models. Preliminary status means the timing model is subject to change. Initially, timing numbers are created using simulation results, process data, and other known parameters. These tests are used to make the preliminary numbers as close to the actual timing parameters as possible. Final timing numbers are based on actual device operation and testing. These numbers reflect the actual performance of the device under the worst-case voltage and junction temperature conditions. Table5–13. MAXII Device Timing Model Status (Part 1 of 2) Device Preliminary Final EPM240 — v EPM240Z (1) — v EPM570 — v EPM570Z (1) — v © August 2009 Altera Corporation MAX II Device Handbook
5–10 Chapter 5: DC and Switching Characteristics Timing Model and Specifications Table5–13. MAXII Device Timing Model Status (Part 2 of 2) Device Preliminary Final EPM1270 — v EPM2210 — v Note to Table5–13: (1) The MAXIIZ device timing models are only available in the Quartus II software version 8.0 and later. Performance Table5–14 shows the MAXII device performance for some common designs. All performance values were obtained with the Quartus II software compilation of megafunctions. Performance values for –3, –4, and –5 speed grades are based on an EPM1270 device target, while –6, –7, and –8 speed grades are based on an EPM570Z device target. Table5–14. MAXII Device Performance Performance Resources Used MAX II / MAX IIG MAX IIZ –3 –4 –5 –6 –7 –8 Resource Design Size and UFM Speed Speed Speed Speed Speed Speed Used Function Mode LEs Blocks Grade Grade Grade Grade Grade Grade Unit LE 16-bit counter (1) — 16 0 304.0 247.5 201.1 184.1 123.5 118.3 MHz 64-bit counter (1) — 64 0 201.5 154.8 125.8 83.2 83.2 80.5 MHz 16-to-1 multiplexer — 11 0 6.0 8.0 9.3 17.4 17.3 20.4 ns 32-to-1 multiplexer — 24 0 7.1 9.0 11.4 12.5 22.8 25.3 ns 16-bit XOR function — 5 0 5.1 6.6 8.2 9.0 15.0 16.1 ns 16-bit decoder with — 5 0 5.2 6.6 8.2 9.2 15.0 16.1 ns single address line UFM 512 × 16 None 3 1 10.0 10.0 10.0 10.0 10.0 10.0 MHz 512 × 16 SPI (2) 37 1 8.0 8.0 8.0 9.7 9.7 9.7 MHz 512 × 8 Parallel 73 1 (4) (4) (4) (4) (4) (4) MHz (3) 512 × 16 I2C (3) 142 1 100 100 100 100 100 100 kHz (5) (5) (5) (5) (5) (5) Notes to Table5–14: (1) This design is a binary loadable up counter. (2) This design is configured for read-only operation in Extended mode. Read and write ability increases the number of LEs used. (3) This design is configured for read-only operation. Read and write ability increases the number of LEs used. (4) This design is asynchronous. (5) The I2C megafunction is verified in hardware up to 100-kHz serial clock line (SCL) rate. MAX II Device Handbook © August 2009 Altera Corporation
Chapter 5: DC and Switching Characteristics 5–11 Timing Model and Specifications Internal Timing Parameters Internal timing parameters are specified on a speed grade basis independent of device density. Table5–15 through Table5–22 describe the MAXII device internal timing microparameters for logic elements (LEs), input/output elements (IOEs), UFM blocks, and MultiTrack interconnects. The timing values for –3, –4, and –5 speed grades shown in Table5–15 through Table5–22 are based on an EPM1270 device target, while –6, –7, and –8 speed grade values are based on an EPM570Z device target. f For more explanations and descriptions about each internal timing microparameters symbol, refer to the Understanding Timing in MAX II Devices chapter in the MAXII Device Handbook. Table5–15. LE Internal Timing Microparameters MAX II / MAX IIG MAX IIZ –3 Speed –4 Speed –5 Speed –6 Speed –7 Speed –8 Speed Grade Grade Grade Grade Grade Grade Symbol Parameter Min Max Min Max Min Max Min Max Min Max Min Max Unit t LE combinational — 571 — 742 — 914 — 1,215 — 2,247 — 2,247 ps LUT LUT delay t Combinational — 147 — 192 — 236 — 243 — 305 — 309 ps COMB path delay t LE register clear 238 — 309 — 381 — 401 — 541 — 545 — ps CLR delay t LE register preset 238 — 309 — 381 — 401 — 541 — 545 — ps PRE delay t LE register setup 208 — 271 — 333 — 260 — 319 — 321 — ps SU time before clock t LE register hold 0 — 0 — 0 — 0 — 0 — 0 — ps H time after clock t LE register clock- — 235 — 305 — 376 — 380 — 489 — 494 ps CO to-output delay t Minimum clock 166 — 216 — 266 — 253 — 335 — 339 — ps CLKHL high or low time t Register control — 857 — 1,114 — 1,372 — 1,356 — 1,722 — 1,741 ps C delay © August 2009 Altera Corporation MAX II Device Handbook
5–12 Chapter 5: DC and Switching Characteristics Timing Model and Specifications Table5–16. IOE Internal Timing Microparameters MAX II / MAX IIG MAX IIZ –3 Speed –4 Speed –5 Speed –6 Speed –7 Speed –8 Speed Grade Grade Grade Grade Grade Grade Symbol Parameter Min Max Min Max Min Max Min Max Min Max Min Max Unit t Data output delay — 159 — 207 — 254 — 170 — 348 — 428 ps FASTIO from adjacent LE to I/O block t I/O input pad and — 708 — 920 — 1,132 — 907 — 970 — 986 ps IN buffer delay t (1) I/O input pad and — 1,519 — 1,974 — 2,430 — 2,261 — 2,670 — 3,322 ps GLOB buffer delay used as global signal pin t Internally — 354 — 374 — 460 — 530 — 966 — 1,410 ps IOE generated output enable delay t Input routing delay — 224 — 291 — 358 — 318 — 410 — 509 ps DL t (2) Output delay buffer — 1,064 — 1,383 — 1,702 — 1,319 — 1,526 — 1,543 ps OD and pad delay t (3) Output buffer — 756 — 982 — 1,209 — 1,045 — 1,264 — 1,276 ps XZ disable delay t (4) Output buffer — 1,003 — 1,303 — 1,604 — 1,160 — 1,325 — 1,353 ps ZX enable delay Notes to Table5–16: (1) Delay numbers for t differ for each device density and speed grade. The delay numbers for t , shown in Table5–16, are based on an EPM240 GLOB GLOB device target. (2) Refer to Table5–32 and 5–24 for delay adders associated with different I/O standards, drive strengths, and slew rates. (3) Refer to Table5–19 and 5–14 for t delay adders associated with different I/O standards, drive strengths, and slew rates. XZ (4) Refer to Table5–17 and 5–13 for t delay adders associated with different I/O standards, drive strengths, and slew rates. ZX Table5–17 through Table5–20 show the adder delays for t and t microparameters ZX XZ when using an I/O standard other than 3.3-V LVTTL with 16 mA drive strength. Table5–17. t IOE Microparameter Adders for Fast Slew Rate (Part 1 of 2) ZX MAX II / MAX IIG MAX IIZ –3 Speed –4 Speed –5 Speed –6 Speed –7 Speed –8 Speed Grade Grade Grade Grade Grade Grade Standard Min Max Min Max Min Max Min Max Min Max Min Max Unit 3.3-V LVTTL 16 mA — 0 — 0 — 0 — 0 — 0 — 0 ps 8 mA — 28 — 37 — 45 — 72 — 71 — 74 ps 3.3-V LVCMOS 8 mA — 0 — 0 — 0 — 0 — 0 — 0 ps 4 mA — 28 — 37 — 45 — 72 — 71 — 74 ps 2.5-V LVTTL / 14 mA — 14 — 19 — 23 — 75 — 87 — 90 ps LVCMOS 7 mA — 314 — 409 — 503 — 162 — 174 — 177 ps 1.8-V LVTTL / 6 mA — 450 — 585 — 720 — 279 — 289 — 291 ps LVCMOS 3 mA — 1,443 — 1,876 — 2,309 — 499 — 508 — 512 ps MAX II Device Handbook © August 2009 Altera Corporation
Chapter 5: DC and Switching Characteristics 5–13 Timing Model and Specifications Table5–17. t IOE Microparameter Adders for Fast Slew Rate (Part 2 of 2) ZX MAX II / MAX IIG MAX IIZ –3 Speed –4 Speed –5 Speed –6 Speed –7 Speed –8 Speed Grade Grade Grade Grade Grade Grade Standard Min Max Min Max Min Max Min Max Min Max Min Max Unit 1.5-V LVCMOS 4 mA — 1,118 — 1,454 — 1,789 — 580 — 588 — 588 ps 2 mA — 2,410 — 3,133 — 3,856 — 915 — 923 — 923 ps 3.3-V PCI 20 mA — 19 — 25 — 31 — 72 — 71 — 74 ps Table5–18. t IOE Microparameter Adders for Slow Slew Rate ZX MAX II / MAX IIG MAX IIZ –3 Speed –4 Speed –5 Speed –6 Speed –7 Speed –8 Speed Grade Grade Grade Grade Grade Grade Standard Min Max Min Max Min Max Min Max Min Max Min Max Unit 3.3-V LVTTL 16 mA — 6,350 — 6,050 — 5,749 — 5,951 — 5,952 — 6,063 ps 8 mA — 9,383 — 9,083 — 8,782 — 6,534 — 6,533 — 6,662 ps 3.3-V LVCMOS 8 mA — 6,350 — 6,050 — 5,749 — 5,951 — 5,952 — 6,063 ps 4 mA — 9,383 — 9,083 — 8,782 — 6,534 — 6,533 — 6,662 ps 2.5-V LVTTL / 14 mA — 10,412 — 10,112 — 9,811 — 9,110 — 9,105 — 9,237 ps LVCMOS 7 mA — 13,613 — 13,313 — 13,012 — 9,830 — 9,835 — 9,977 ps 3.3-V PCI 20 mA — –75 — –97 — –120 — 6,534 — 6,533 — 6,662 ps Table5–19. t IOE Microparameter Adders for Fast Slew Rate XZ MAX II / MAX IIG MAX IIZ –3 Speed –4 Speed –5 Speed –6 Speed –7 Speed –8 Speed Grade Grade Grade Grade Grade Grade Standard Min Max Min Max Min Max Min Max Min Max Min Max Unit 3.3-V LVTTL 16 mA — 0 — 0 — 0 — 0 — 0 — 0 ps 8 mA — –56 — –72 — –89 — –69 — –69 — –69 ps 3.3-V LVCMOS 8 mA — 0 — 0 — 0 — 0 — 0 — 0 ps 4 mA — –56 — –72 — –89 — –69 — –69 — –69 ps 2.5-V LVTTL / 14 mA — –3 — –4 — –5 — –7 — –11 — –11 ps LVCMOS 7 mA — –47 — –61 — –75 — –66 — –70 — –70 ps 1.8-V LVTTL / 6 mA — 119 — 155 — 191 — 45 — 34 — 37 ps LVCMOS 3 mA — 207 — 269 — 331 — 34 — 22 — 25 ps 1.5-V LVCMOS 4 mA — 606 — 788 — 970 — 166 — 154 — 155 ps 2 mA — 673 — 875 — 1,077 — 190 — 177 — 179 ps 3.3-V PCI 20 mA — 71 — 93 — 114 — –69 — –69 — –69 ps © August 2009 Altera Corporation MAX II Device Handbook
5–14 Chapter 5: DC and Switching Characteristics Timing Model and Specifications Table5–20. t IOE Microparameter Adders for Slow Slew Rate XZ MAX II / MAX IIG MAX IIZ –3 Speed –4 Speed –5 Speed –6 Speed –7 Speed –8 Speed Grade Grade Grade Grade Grade Grade Standard Min Max Min Max Min Max Min Max Min Max Min Max Unit 3.3-V LVTTL 16 mA — 206 — –20 — –247 — 1,433 — 1,446 — 1,454 ps 8 mA — 891 — 665 — 438 — 1,332 — 1,345 — 1,348 ps 3.3-V LVCMOS 8 mA — 206 — –20 — –247 — 1,433 — 1,446 — 1,454 ps 4 mA — 891 — 665 — 438 — 1,332 — 1,345 — 1,348 ps 2.5-V LVTTL / 14 mA — 222 — –4 — –231 — 213 — 208 — 213 ps LVCMOS 7 mA — 943 — 717 — 490 — 166 — 161 — 166 ps 3.3-V PCI 20 mA — 161 — 210 — 258 — 1,332 — 1,345 — 1,348 ps 1 The default slew rate setting for MAXII devices in the QuartusII design software is “fast”. Table5–21. UFM Block Internal Timing Microparameters (Part 1 of 3) MAX II / MAX IIG MAX IIZ –3 Speed –4 Speed –5 Speed –6 Speed –7 Speed –8 Speed Grade Grade Grade Grade Grade Grade Symbol Parameter Min Max Min Max Min Max Min Max Min Max Min Max Unit t Address register clock 100 — 100 — 100 — 100 — 100 — 100 — ns ACLK period t Address register shift 20 — 20 — 20 — 20 — 20 — 20 — ns ASU signal setup to address register clock t Address register shift 20 — 20 — 20 — 20 — 20 — 20 — ns AH signal hold to address register clock t Address register data 20 — 20 — 20 — 20 — 20 — 20 — ns ADS in setup to address register clock t Address register data 20 — 20 — 20 — 20 — 20 — 20 — ns ADH in hold from address register clock t Data register clock 100 — 100 — 100 — 100 — 100 — 100 — ns DCLK period t Data register shift 60 — 60 — 60 — 60 — 60 — 60 — ns DSS signal setup to data register clock t Data register shift 20 — 20 — 20 — 20 — 20 — 20 — ns DSH signal hold from data register clock MAX II Device Handbook © August 2009 Altera Corporation
Chapter 5: DC and Switching Characteristics 5–15 Timing Model and Specifications Table5–21. UFM Block Internal Timing Microparameters (Part 2 of 3) MAX II / MAX IIG MAX IIZ –3 Speed –4 Speed –5 Speed –6 Speed –7 Speed –8 Speed Grade Grade Grade Grade Grade Grade Symbol Parameter Min Max Min Max Min Max Min Max Min Max Min Max Unit t Data register data in 20 — 20 — 20 — 20 — 20 — 20 — ns DDS setup to data register clock t Data register data in 20 — 20 — 20 — 20 — 20 — 20 — ns DDH hold from data register clock t Program signal to 0 — 0 — 0 — 0 — 0 — 0 — ns DP data clock hold time t Maximum delay — 960 — 960 — 960 — 960 — 960 — 960 ns PB between program rising edge to UFM busy signal rising edge t Minimum delay 20 — 20 — 20 — 20 — 20 — 20 — ns BP allowed from UFM busy signal going low to program signal going low t Maximum length of — 100 — 100 — 100 — 100 — 100 — 100 µs PPMX busy pulse during a program t Minimum erase signal 0 — 0 — 0 — 0 — 0 — 0 — ns AE to address clock hold time t Maximum delay — 960 — 960 — 960 — 960 — 960 — 960 ns EB between the erase rising edge to the UFM busy signal rising edge t Minimum delay 20 — 20 — 20 — 20 — 20 — 20 — ns BE allowed from the UFM busy signal going low to erase signal going low t Maximum length of — 500 — 500 — 500 — 500 — 500 — 500 ms EPMX busy pulse during an erase t Delay from data — 5 — 5 — 5 — 5 — 5 — 5 ns DCO register clock to data register output © August 2009 Altera Corporation MAX II Device Handbook
5–16 Chapter 5: DC and Switching Characteristics Timing Model and Specifications Table5–21. UFM Block Internal Timing Microparameters (Part 3 of 3) MAX II / MAX IIG MAX IIZ –3 Speed –4 Speed –5 Speed –6 Speed –7 Speed –8 Speed Grade Grade Grade Grade Grade Grade Symbol Parameter Min Max Min Max Min Max Min Max Min Max Min Max Unit t Delay from data 180 — 180 — 180 — 180 — 180 — 180 — ns OE register clock to data register output t Maximum read — 65 — 65 — 65 — 65 — 65 — 65 ns RA access time t Maximum delay 250 — 250 — 250 — 250 — 250 — 250 — ns OSCS between the OSC_ENA rising edge to the erase/program signal rising edge t Minimum delay 250 — 250 — 250 — 250 — 250 — 250 — ns OSCH allowed from the erase/program signal going low to OSC_ENA signal going low Figure5–3 through Figure5–5 show the read, program, and erase waveforms for UFM block timing parameters shown in Table5–21. Figure5–3. UFM Read Waveforms ARShft t 9 Address Bits t t ACLK AH ASU ARClk t ADH ARDin DRShft tADS t tDCLK 16 Data Bits tDSH DRClk DSS DRDin tDCO DRDout OSC_ENA Program Erase Busy MAX II Device Handbook © August 2009 Altera Corporation
Chapter 5: DC and Switching Characteristics 5–17 Timing Model and Specifications Figure5–4. UFM Program Waveforms ARShft tASU tAC9LK Address Bits tAH ARClk t ADH ARDin t DRShft ADS 16 Data Bits tDSS tDCLK tDSH DRClk DRDin t DDH t DRDout DDS t t OSCS OSCH OSC_ENA Program Erase tPB tBP Busy t PPMX Figure5–5. UFM Erase Waveform ARShft tASU tACLK 9 Address Bits tAH ARClk t ADH ARDin DRShft tADS DRClk DRDin DRDout OSC_ENA t OSCS t Program OSCH Erase Busy tEB tBE t EPMX Table5–22. Routing Delay Internal Timing Microparameters MAX II / MAX IIG MAX IIZ –3 Speed –4 Speed –5 Speed –6 Speed –7 Speed –8 Speed Grade Grade Grade Grade Grade Grade Routing Min Max Min Max Min Max Min Max Min Max Min Max Unit t — 429 — 556 — 687 — (1) — (1) — (1) ps C4 t — 326 — 423 — 521 — (1) — (1) — (1) ps R4 t — 330 — 429 — 529 — (1) — (1) — (1) ps LOCAL Note to Table5–22: (1) The numbers will only be available in a later revision. © August 2009 Altera Corporation MAX II Device Handbook
5–18 Chapter 5: DC and Switching Characteristics Timing Model and Specifications External Timing Parameters External timing parameters are specified by device density and speed grade. All external I/O timing parameters shown are for the 3.3-V LVTTL I/O standard with the maximum drive strength and fast slew rate. For external I/O timing using standards other than LVTTL or for different drive strengths, use the I/O standard input and output delay adders in Table5–27 through Table5–31. f For more information about each external timing parameters symbol, refer to the Understanding Timing in MAX II Devices chapter in the MAXII Device Handbook. Table5–23 shows the external I/O timing parameters for EPM240 devices. Table5–23. EPM240 Global Clock External I/O Timing Parameters (Part 1 of 2) MAX II / MAX IIG MAX IIZ –3 Speed –4 Speed –5 Speed –6 Speed –7 Speed –8 Speed Grade Grade Grade Grade Grade Grade Symbol Parameter Condition Min Max Min Max Min Max Min Max Min Max Min Max Unit t Worst case 10 pF — 4.7 — 6.1 — 7.5 — 7.9 — 12.0 — 14.0 ns PD1 pin-to-pin delay through 1 look-up table (LUT) t Best case 10 pF — 3.7 — 4.8 — 5.9 — 5.8 — 7.8 — 8.5 ns PD2 pin-to-pin delay through 1LUT t Global clock — 1.7 — 2.2 — 2.7 — 2.4 — 4.1 — 4.6 — ns SU setup time t Global clock — 0 — 0 — 0 — 0 — 0 — 0 — ns H hold time t Global clock 10 pF 2.0 4.3 2.0 5.6 2.0 6.9 2.0 6.6 2.0 8.1 2.0 8.6 ns CO to output delay t Global clock — 166 — 216 — 266 — 253 — 335 — 339 — ps CH high time t Global clock — 166 — 216 — 266 — 253 — 335 — 339 — ps CL low time t Minimum — 3.3 — 4.0 — 5.0 — 5.4 — 8.1 — 8.4 — ns CNT global clock period for 16-bit counter MAX II Device Handbook © August 2009 Altera Corporation
Chapter 5: DC and Switching Characteristics 5–19 Timing Model and Specifications Table5–23. EPM240 Global Clock External I/O Timing Parameters (Part 2 of 2) MAX II / MAX IIG MAX IIZ –3 Speed –4 Speed –5 Speed –6 Speed –7 Speed –8 Speed Grade Grade Grade Grade Grade Grade Symbol Parameter Condition Min Max Min Max Min Max Min Max Min Max Min Max Unit f Maximum — — 304.0 — 247.5 — 201.1 — 184.1 — 123.5 — 118.3 MHz CNT global clock (1) frequency for 16-bit counter Note to Table5–23: (1) The maximum frequency is limited by the I/O standard on the clock input pin. The 16-bit counter critical delay performs faster than this global clock input pin maximum frequency. Table5–24 shows the external I/O timing parameters for EPM570 devices. Table5–24. EPM570 Global Clock External I/O Timing Parameters (Part 1 of 2) MAX II / MAX IIG MAX IIZ –3 Speed –4 Speed –5 Speed –6 Speed –7 Speed –8 Speed Grade Grade Grade Grade Grade Grade Symbol Parameter Condition Min Max Min Max Min Max Min Max Min Max Min Max Unit t Worst case pin- 10 pF — 5.4 — 7.0 — 8.7 — 9.5 — 15.1 — 17.7 ns PD1 to-pin delay through 1 look- up table (LUT) t Best case pin- 10 pF — 3.7 — 4.8 — 5.9 — 5.7 — 7.7 — 8.5 ns PD2 to-pin delay through 1 LUT t Global clock — 1.2 — 1.5 — 1.9 — 2.2 — 3.9 — 4.4 — ns SU setup time t Global clock — 0 — 0 — 0 — 0 — 0 — 0 — ns H hold time t Global clock to 10 pF 2.0 4.5 2.0 5.8 2.0 7.1 2.0 6.7 2.0 8.2 2.0 8.7 ns CO output delay t Global clock — 166 — 216 — 266 — 253 — 335 — 339 — ps CH high time t Global clock — 166 — 216 — 266 — 253 — 335 — 339 — ps CL low time t Minimum — 3.3 — 4.0 — 5.0 — 5.4 — 8.1 — 8.4 — ns CNT global clock period for 16-bit counter © August 2009 Altera Corporation MAX II Device Handbook
5–20 Chapter 5: DC and Switching Characteristics Timing Model and Specifications Table5–24. EPM570 Global Clock External I/O Timing Parameters (Part 2 of 2) MAX II / MAX IIG MAX IIZ –3 Speed –4 Speed –5 Speed –6 Speed –7 Speed –8 Speed Grade Grade Grade Grade Grade Grade Symbol Parameter Condition Min Max Min Max Min Max Min Max Min Max Min Max Unit f Maximum — — 304.0 — 247.5 — 201.1 — 184.1 — 123.5 — 118.3 MHz CNT global clock (1) frequency for 16-bit counter Note to Table5–24: (1) The maximum frequency is limited by the I/O standard on the clock input pin. The 16-bit counter critical delay performs faster than this global clock input pin maximum frequency. Table5–25 shows the external I/O timing parameters for EPM1270 devices. Table5–25. EPM1270 Global Clock External I/O Timing Parameters MAX II / MAX IIG –3 Speed Grade –4 Speed Grade –5 Speed Grade Symbol Parameter Condition Min Max Min Max Min Max Unit t Worst case pin-to-pin 10 pF — 6.2 — 8.1 — 10.0 ns PD1 delay through 1 look-up table (LUT) t Best case pin-to-pin 10 pF — 3.7 — 4.8 — 5.9 ns PD2 delay through 1 LUT t Global clock setup time — 1.2 — 1.5 — 1.9 — ns SU t Global clock hold time — 0 — 0 — 0 — ns H t Global clock to output 10 pF 2.0 4.6 2.0 5.9 2.0 7.3 ns CO delay t Global clock high time — 166 — 216 — 266 — ps CH t Global clock low time — 166 — 216 — 266 — ps CL t Minimum global clock — 3.3 — 4.0 — 5.0 — ns CNT period for 16-bit counter f Maximum global clock — — 304.0 (1) — 247.5 — 201.1 MHz CNT frequency for 16-bit counter Note to Table5–25: (1) The maximum frequency is limited by the I/O standard on the clock input pin. The 16-bit counter critical delay performs faster than this global clock input pin maximum frequency. MAX II Device Handbook © August 2009 Altera Corporation
Chapter 5: DC and Switching Characteristics 5–21 Timing Model and Specifications Table5–26 shows the external I/O timing parameters for EPM2210 devices. Table5–26. EPM2210 Global Clock External I/O Timing Parameters MAX II / MAX IIG –3 Speed Grade –4 Speed Grade –5 Speed Grade Symbol Parameter Condition Min Max Min Max Min Max Unit t Worst case pin-to-pin delay 10 pF — 7.0 — 9.1 — 11.2 ns PD1 through 1 look-up table (LUT) t Best case pin-to-pin delay 10 pF — 3.7 — 4.8 — 5.9 ns PD2 through 1 LUT t Global clock setup time — 1.2 — 1.5 — 1.9 — ns SU t Global clock hold time — 0 — 0 — 0 — ns H t Global clock to output delay 10 pF 2.0 4.6 2.0 6.0 2.0 7.4 ns CO t Global clock high time — 166 — 216 — 266 — ps CH t Global clock low time — 166 — 216 — 266 — ps CL t Minimum global clock — 3.3 — 4.0 — 5.0 — ns CNT period for 16-bit counter f Maximum global clock — — 304.0 — 247.5 — 201.1 MHz CNT frequency for 16-bit counter (1) Note to Table5–26: (1) The maximum frequency is limited by the I/O standard on the clock input pin. The 16-bit counter critical delay performs faster than this global clock input pin maximum frequency. External Timing I/O Delay Adders The I/O delay timing parameters for I/O standard input and output adders, and input delays are specified by speed grade independent of device density. Table5–27 through Table5–31 show the adder delays associated with I/O pins for all packages. The delay numbers for –3, –4, and –5 speed grades shown in Table5–27 through Table5–33 are based on an EPM1270 device target, while –6, –7, and –8 speed grade values are based on an EPM570Z device target. If an I/O standard other than 3.3-V LVTTL is selected, add the input delay adder to the external t timing SU parameters shown in Table5–23 through Table5–26. If an I/O standard other than 3.3-V LVTTL with 16mA drive strength and fast slew rate is selected, add the output delay adder to the external t and t shown in Table5–23 through Table5–26. CO PD Table5–27. External Timing Input Delay Adders (Part 1 of 2) MAX II / MAX IIG MAX IIZ –3 Speed –4 Speed –5 Speed –6 Speed –7 Speed –8 Speed Grade Grade Grade Grade Grade Grade I/O Standard Min Max Min Max Min Max Min Max Min Max Min Max Unit 3.3-V LVTTL Without Schmitt — 0 — 0 — 0 — 0 — 0 — 0 ps Trigger With Schmitt — 334 — 434 — 535 — 387 — 434 — 442 ps Trigger © August 2009 Altera Corporation MAX II Device Handbook
5–22 Chapter 5: DC and Switching Characteristics Timing Model and Specifications Table5–27. External Timing Input Delay Adders (Part 2 of 2) MAX II / MAX IIG MAX IIZ –3 Speed –4 Speed –5 Speed –6 Speed –7 Speed –8 Speed Grade Grade Grade Grade Grade Grade I/O Standard Min Max Min Max Min Max Min Max Min Max Min Max Unit 3.3-V LVCMOS Without Schmitt — 0 — 0 — 0 — 0 — 0 — 0 ps Trigger With Schmitt — 334 — 434 — 535 — 387 — 434 — 442 ps Trigger 2.5-V LVTTL / Without Schmitt — 23 — 30 — 37 — 42 — 43 — 43 ps LVCMOS Trigger With Schmitt — 339 — 441 — 543 — 429 — 476 — 483 ps Trigger 1.8-V LVTTL / Without Schmitt — 291 — 378 — 466 — 378 — 373 — 373 ps LVCMOS Trigger 1.5-V LVCMOS Without Schmitt — 681 — 885 — 1,090 — 681 — 622 — 658 ps Trigger 3.3-V PCI Without Schmitt — 0 — 0 — 0 — 0 — 0 — 0 ps Trigger Table5–28. External Timing Input Delay t Adders for GCLK Pins GLOB MAX II / MAX IIG MAX IIZ –3 Speed –4 Speed –5 Speed –6 Speed –7 Speed –8 Speed Grade Grade Grade Grade Grade Grade I/O Standard Min Max Min Max Min Max Min Max Min Max Min Max Unit 3.3-V LVTTL Without Schmitt — 0 — 0 — 0 — 0 — 0 — 0 ps Trigger With Schmitt — 308 — 400 — 493 — 387 — 434 — 442 ps Trigger 3.3-V LVCMOS Without Schmitt — 0 — 0 — 0 — 0 — 0 — 0 ps Trigger With Schmitt — 308 — 400 — 493 — 387 — 434 — 442 ps Trigger 2.5-V LVTTL / Without Schmitt — 21 — 27 — 33 — 42 — 43 — 43 ps LVCMOS Trigger With Schmitt — 423 — 550 — 677 — 429 — 476 — 483 ps Trigger 1.8-V LVTTL / Without Schmitt — 353 — 459 — 565 — 378 — 373 — 373 ps LVCMOS Trigger 1.5-V LVCMOS Without Schmitt — 855 — 1,111 — 1,368 — 681 — 622 — 658 ps Trigger 3.3-V PCI Without Schmitt — 6 — 7 — 9 — 0 — 0 — 0 ps Trigger MAX II Device Handbook © August 2009 Altera Corporation
Chapter 5: DC and Switching Characteristics 5–23 Timing Model and Specifications Table5–29. External Timing Output Delay and t Adders for Fast Slew Rate OD MAX II / MAX IIG MAX IIZ –3 Speed –4 Speed –5 Speed –6 Speed –7 Speed –8 Speed Grade Grade Grade Grade Grade Grade I/O Standard Min Max Min Max Min Max Min Max Min Max Min Max Unit 3.3-V LVTTL 16 mA — 0 — 0 — 0 — 0 — 0 — 0 ps 8 mA — 65 — 84 — 104 — –6 — –2 — –3 ps 3.3-V LVCMOS 8 mA — 0 — 0 — 0 — 0 — 0 — 0 ps 4 mA — 65 — 84 — 104 — –6 — –2 — –3 ps 2.5-V LVTTL / 14 mA — 122 — 158 — 195 — –63 — –71 — –88 ps LVCMOS 7 mA — 193 — 251 — 309 — 10 — –1 — 1 ps 1.8-V LVTTL / 6 mA — 568 — 738 — 909 — 128 — 118 — 118 ps LVCMOS 3 mA — 654 — 850 — 1,046 — 352 — 327 — 332 ps 1.5-V LVCMOS 4 mA — 1,059 — 1,376 — 1,694 — 421 — 400 — 400 ps 2 mA — 1,167 — 1,517 — 1,867 — 757 — 743 — 743 ps 3.3-V PCI 20 mA — 3 — 4 — 5 — –6 — –2 — –3 ps Table5–30. External Timing Output Delay and t Adders for Slow Slew Rate OD MAX II / MAX IIG MAX IIZ –3 Speed –4 Speed –5 Speed –6 Speed –7 Speed –8 Speed Grade Grade Grade Grade Grade Grade I/O Standard Min Max Min Max Min Max Min Max Min Max Min Max Unit 3.3-V LVTTL 16 mA — 7,064 — 6,745 — 6,426 — 5,966 — 5,992 — 6,118 ps 8 mA — 7,946 — 7,627 — 7,308 — 6,541 — 6,570 — 6,720 ps 3.3-V LVCMOS 8 mA — 7,064 — 6,745 — 6,426 — 5,966 — 5,992 — 6,118 ps 4 mA — 7,946 — 7,627 — 7,308 — 6,541 — 6,570 — 6,720 ps 2.5-V LVTTL / 14 mA — 10,434 — 10,115 — 9,796 — 9,141 — 9,154 — 9,297 ps LVCMOS 7 mA — 11,548 — 11,229 — 10,910 — 9,861 — 9,874 — 10,037 ps 1.8-V LVTTL / 6 mA — 22,927 — 22,608 — 22,289 — 21,811 — 21,854 — 21,857 ps LVCMOS 3 mA — 24,731 — 24,412 — 24,093 — 23,081 — 23,034 — 23,107 ps 1.5-V LVCMOS 4 mA — 38,723 — 38,404 — 38,085 — 39,121 — 39,124 — 39,124 ps 2 mA — 41,330 — 41,011 — 40,692 — 40,631 — 40,634 — 40,634 ps 3.3-V PCI 20 mA — 261 — 339 — 418 — 6,644 — 6,627 — 6,914 ps © August 2009 Altera Corporation MAX II Device Handbook
5–24 Chapter 5: DC and Switching Characteristics Timing Model and Specifications Table5–31. MAXII IOE Programmable Delays MAX II / MAX IIG MAX IIZ –3 Speed –4 Speed –5 Speed –6 Speed –7 Speed –8 Speed Grade Grade Grade Grade Grade Grade Parameter Min Max Min Max Min Max Min Max Min Max Min Max Unit Input Delay from Pin to — 1,225 — 1,592 — 1,960 — 1,858 — 2,171 — 2,214 ps Internal Cells = 1 Input Delay from Pin to — 89 — 115 — 142 — 569 — 609 — 616 ps Internal Cells = 0 Maximum Input and Output Clock Rates Table5–32 and Table5–33 show the maximum input and output clock rates for standard I/O pins in MAXII devices. Table5–32. MAXII Maximum Input Clock Rate for I/O MAX II / MAX IIG MAX IIZ –3 Speed –4 Speed –5 Speed –6 Speed –7 Speed –8 Speed I/O Standard Grade Grade Grade Grade Grade Grade Unit 3.3-V LVTTL Without Schmitt 304 304 304 304 304 304 MHz Trigger With Schmitt 250 250 250 250 250 250 MHz Trigger 3.3-V LVCMOS Without Schmitt 304 304 304 304 304 304 MHz Trigger With Schmitt 250 250 250 250 250 250 MHz Trigger 2.5-V LVTTL Without Schmitt 220 220 220 220 220 220 MHz Trigger With Schmitt 188 188 188 188 188 188 MHz Trigger 2.5-V LVCMOS Without Schmitt 220 220 220 220 220 220 MHz Trigger With Schmitt 188 188 188 188 188 188 MHz Trigger 1.8-V LVTTL Without Schmitt 200 200 200 200 200 200 MHz Trigger 1.8-V LVCMOS Without Schmitt 200 200 200 200 200 200 MHz Trigger 1.5-V LVCMOS Without Schmitt 150 150 150 150 150 150 MHz Trigger 3.3-V PCI Without Schmitt 304 304 304 304 304 304 MHz Trigger MAX II Device Handbook © August 2009 Altera Corporation
Chapter 5: DC and Switching Characteristics 5–25 Timing Model and Specifications Table5–33. MAXII Maximum Output Clock Rate for I/O MAX II / MAX IIG MAX IIZ –3 Speed –4 Speed –5 Speed –6 Speed –7 Speed –8 Speed I/O Standard Grade Grade Grade Grade Grade Grade 3.3-V LVTTL 304 304 304 304 304 304 MHz 3.3-V LVCMOS 304 304 304 304 304 304 MHz 2.5-V LVTTL 220 220 220 220 220 220 MHz 2.5-V LVCMOS 220 220 220 220 220 220 MHz 1.8-V LVTTL 200 200 200 200 200 200 MHz 1.8-V LVCMOS 200 200 200 200 200 200 MHz 1.5-V LVCMOS 150 150 150 150 150 150 MHz 3.3-V PCI 304 304 304 304 304 304 MHz JTAG Timing Specifications Figure5–6 shows the timing waveforms for the JTAG signals. Figure5–6. MAXII JTAG Timing Waveforms TMS TDI tJCP tJPSU tJPH tJCH tJCL TCK tJPZX tJPCO tJPXZ TDO tJSSU tJSH Signal to be Captured tJSZX tJSCO tJSXZ Signal to be Driven Table5–34 shows the JTAG Timing parameters and values for MAXII devices. Table5–34. MAXII JTAG Timing Parameters (Part 1 of 2) Symbol Parameter Min Max Unit t (1) TCK clock period for V =3.3 V 55.5 — ns JCP CCIO1 TCK clock period for V =2.5 V 62.5 — ns CCIO1 TCK clock period for V =1.8 V 100 — ns CCIO1 TCK clock period for V =1.5 V 143 — ns CCIO1 t TCK clock high time 20 — ns JCH t TCK clock low time 20 — ns JCL © August 2009 Altera Corporation MAX II Device Handbook
5–26 Chapter 5: DC and Switching Characteristics Referenced Documents Table5–34. MAXII JTAG Timing Parameters (Part 2 of 2) Symbol Parameter Min Max Unit t JTAG port setup time (2) 8 — ns JPSU t JTAG port hold time 10 — ns JPH t JTAG port clock to output (2) — 15 ns JPCO t JTAG port high impedance to valid output (2) — 15 ns JPZX t JTAG port valid output to high impedance (2) — 15 ns JPXZ t Capture register setup time 8 — ns JSSU t Capture register hold time 10 — ns JSH t Update register clock to output — 25 ns JSCO t Update register high impedance to valid output — 25 ns JSZX t Update register valid output to high impedance — 25 ns JSXZ Notes to Table5–34: (1) Minimum clock period specified for 10 pF load on the TDO pin. Larger loads on TDO will degrade the maximum TCK frequency. (2) This specification is shown for 3.3-V LVTTL/LVCMOS and 2.5-V LVTTL/LVCMOS operation of the JTAG pins. For 1.8-V LVTTL/LVCMOS and 1.5-V LVCMOS, the t minimum is 6 ns and t , t , and t are maximum values at 35 ns. JPSU JPCO JPZX JPXZ Referenced Documents This chapter references the following documents: ■ I/O Structure section in the MAX II Architecture chapter in the MAXII Device Handbook ■ Hot Socketing and Power-On Reset in MAX II Devices chapter in the MAXII Device Handbook ■ Operating Requirements for Altera Devices Data Sheet ■ PowerPlay Power Analysis chapter in volume 3 of the QuartusII Handbook ■ Understanding and Evaluating Power in MAX II Devices chapter in the MAXII Device Handbook ■ Understanding Timing in MAX II Devices chapter in the MAXII Device Handbook ■ Using MAX II Devices in Multi-Voltage Systems chapter in the MAXII Device Handbook MAX II Device Handbook © August 2009 Altera Corporation
Chapter 5: DC and Switching Characteristics 5–27 Document Revision History Document Revision History Table5–35 shows the revision history for this chapter. Table5–35. Document Revision History (Part 1 of 2) Date and Revision Changes Made Summary of Changes August 2009, ■ Added Table5–28, Table5–29, and Table5–30. Added information for version 2.5 speed grade –8 ■ Updated Table5–2, Table5–4, Table5–14, Table5–15, Table5–16, Table5–17, Table5–18, Table5–19, Table5–20, Table5–21, Table5–22, Table5–23, Table5–24, Table5–27, Table5–31, Table5–32, and Table5–33. November 2008, ■ Updated Table5–2. — version 2.4 ■ Updated “Internal Timing Parameters” section. October 2008, ■ Updated New Document Format. — version 2.3 ■ Updated Figure5–1. July 2008, ■ Updated Table5–14 , Table5–23 , and Table5–24. — version 2.2 March 2008, ■ Added (Note5) to Table5–4. — version 2.1 December 2007, ■ Updated (Note3) and (4) to Table5–1. Updated document with version 2.0 MAXIIZ information. ■ Updated Table5–2 and added (Note5). ■ Updated ICCSTANDBY and ICCPOWERUP information and added IPULLUP information in Table5–4. ■ Added (Note1) to Table5–10. ■ Updated Figure5–2. ■ Added (Note1) to Table5–13. ■ Updated Table5–13 through Table5–24, and Table5–27 through Table5–30. ■ Added tCOMB information to Table5–15. ■ Updated Figure5–6. ■ Added “Referenced Documents” section. December 2006, ■ Added note to Table5–1. — version 1.8 ■ Added document revision history. July 2006, ■ Minor content and table updates. — version 1.7 February 2006, ■ Updated “External Timing I/O Delay Adders” section. — version 1.6 ■ Updated Table5–29. ■ Updated Table5–30. November 2005, ■ Updated Tables 5-2, 5-4, and 5-12. — version 1.5 August 2005, ■ Updated Figure 5-1. — version 1.4 ■ Updated Tables 5-13, 5-16, and 5-26. ■ Removed Note 1 from Table 5-12. © August 2009 Altera Corporation MAX II Device Handbook
5–28 Chapter 5: DC and Switching Characteristics Document Revision History Table5–35. Document Revision History (Part 2 of 2) Date and Revision Changes Made Summary of Changes June 2005, ■ Updated the R parameter in Table 5-4. — PULLUP version 1.3 ■ Added Note 2 to Tables 5-8 and 5-9. ■ Updated Table 5-13. ■ Added “Output Drive Characteristics” section. ■ Added I2C mode and Notes 5 and 6 to Table5-14. ■ Updated timing values to Tables 5-14 through 5-33. December 2004, ■ Updated timing Tables 5-2, 5-4, 5-12, and Tables 15-14 through 5-34. — version 1.2 ■ Table 5-31 is new. June 2004, ■ Updated timing Tables 5-15 through 5-32. — version 1.1 MAX II Device Handbook © August 2009 Altera Corporation
6. Reference and Ordering Information MII51006-1.6 Software MAX® II devices are supported by the Altera® Quartus® II design software with new, optional MAX+PLUS® II look and feel, which provides HDL and schematic design entry, compilation and logic synthesis, full simulation and advanced timing analysis, and device programming. Refer to the Design Software Selector Guide for more details about the Quartus II software features. The Quartus II software supports the Windows XP/2000/NT, Sun Solaris, Linux Red Hat v8.0, and HP-UX operating systems. It also supports seamless integration with industry-leading EDA tools through the NativeLink interface. Device Pin-Outs Printed device pin-outs for MAXII devices are available on the Altera website (www.altera.com). Ordering Information Figure6–1 describes the ordering codes for MAXII devices. For more information about a specific package, refer to the Package Information chapter in the MAXII Device Handbook. Figure6–1. MAXII Device Packaging Ordering Information EPM 240 G T 100 C 3 ES Family Signature Optional Suffix EPM: MAX II Indicates specific device options or shipment method ES: Engineering sample Device Type N: Lead-free packaging 240: 240 Logic Elements Speed Grade 570: 570 Logic Elements 1270: 1,270 Logic Elements 2210: 2,210 Logic Elements 3, 4, 5, 6, 7, or 8, with 3 being the fastest Product-Line Suffix Operating Temperature Indicates device type Blank (no identifieGrZ)::: 121...588---VVV VVorCC CC3II.NN3TT- Vzloe VwroC-p-CpoINowTw edere rd vdeicevevicicee CAI::: CIAnuodtmuosmmtroeiatriclv iteae lmt etepmmeprpeaertuarartuetur (erTe (J T( =TJ J-= 4= -0 40°0° C °C Ct ot o t1o 80 1502°° 5 CC°) )C) Package Type T: Thin quad flat pack (TQFP) F: FineLine BGA M: Micro FineLine BGA Pin Count Number of pins for a particular package © August 2009 Altera Corporation MAX II Device Handbook
6–2 Chapter 6: Reference and Ordering Information Referenced Documents Referenced Documents This chapter references the following document: ■ Package Information chapter in the MAXII Device Handbook Document Revision History Table6–1 shows the revision history for this chapter. Table6–1. Document Revision History Date and Revision Changes Made Summary of Changes August 2009, ■ Updated Figure6–1. Added information for speed version 1.6 grade –8 October 2008, ■ Updated New Document Format. — version 1.5 December 2007, ■ Added “Referenced Documents” section. Updated document with version 1.4 MAXIIZ information. ■ Updated Figure6–1. December 2006, ■ Added document revision history. — version 1.3 October 2006, ■ Updated Figure 6-1. — version 1.2 June 2005, ■ Removed Dual Marking section. — version 1.1 MAX II Device Handbook © August 2009 Altera Corporation
Section II. PCB Layout Guidelines This section provides information for board layout designers to successfully layout their boards for MAX® II devices. It contains the required printed circuit board (PCB) layout guidelines, device pin tables, and package specifications. This section includes the following chapters: ■ Chapter7, Package Information ■ Chapter8, Using MAX II Devices in Multi-Voltage Systems Revision History Refer to each chapter for its own specific revision history. For information about when each chapter was updated, refer to the Chapter Revision Dates section, which appears in the complete handbook. © October 2008 Altera Corporation MAX II Device Handbook
II–2 Section II: PCB Layout Guidelines Revision History MAX II Device Handbook © October 2008 Altera Corporation
7. Package Information MII51007-2.1 Introduction This chapter provides package information for Altera’s MAX® II devices, and includes these sections: ■ “Board Decoupling Guidelines” on page7–1 ■ “Device and Package Cross Reference” on page7–1 ■ “Thermal Resistance” on page7–2 ■ “Package Outlines” on page7–3 In this chapter, packages are listed in order of ascending pin count. See Figure7–1 through 7–17. Board Decoupling Guidelines Decoupling requirements are based on the amount of logic used in the device and the output switching requirements. As the number of I/O pins and the capacitive load on the pins increase, more decoupling capacitance is required. As many as possible 0.1- mF power-supply decoupling capacitors should be connected to the VCC and GND pins or the VCC and GND planes. These capacitors should be located as close as possible to the MAX II device. Each VCCINT/GNDINT and VCCIO/GNDIO pair should be decoupled with a 0.1-mF capacitor. When using high-density packages, such as ball-grid array (BGA) packages, it may not be possible to use one decoupling capacitor per VCC/GND pair. In this case, you should use as many decoupling capacitors as possible. For less dense designs, a reduction in the number of capacitors may be acceptable. Decoupling capacitors should have a good frequency response, such as monolithic-ceramic capacitors. Device and Package Cross Reference Table7–1 shows which Altera® MAX II devices are available in thin quad flat pack (TQFP), FineLine BGA (FBGA), and Micro Fineline BGA (MBGA) packages. Table7–1. MAX II Devices in TQFP, FineLine BGA, and Micro FineLine BGA Packages (Part 1 of 2) Device Package Pin EPM240Z MBGA (1) 68 EPM240 FBGA(1) 100 EPM240G EPM240 MBGA(1) 100 EPM240G EPM240Z EPM240 TQFP 100 EPM240G © October 2008 Altera Corporation MAX II Device Handbook
7–2 Chapter 7: Package Information Thermal Resistance Table7–1. MAX II Devices in TQFP, FineLine BGA, and Micro FineLine BGA Packages (Part 2 of 2) Device Package Pin EPM570 FBGA(1) 100 EPM570G EPM570 MBGA(1) 100 EPM570G EPM570Z EPM570 TQFP 100 EPM570G EPM570Z MBGA (1) 144 EPM570 TQFP 144 EPM570G EPM570 FBGA 256 EPM570G EPM570 MBGA(1) 256 EPM570G EPM570Z EPM1270 TQFP 144 EPM1270G FBGA 256 MBGA(1) 256 EPM2210 FBGA 256 EPM2210G FBGA 324 Note to Table7–1: (1) Packages available in lead-free versions only. Thermal Resistance Table7–2 provides (junction-to-ambient thermal resistance) and (junction-to- JA JC case thermal resistance) values for Altera MAX II devices. Table7–2. Thermal Resistance of MAX II Devices (Part 1 of 2) (°C/W) (°C/W) (°C/W) (°C/W) JA JA JA JA Device Pin Count Package (°C/W) Still Air 100 ft./min. 200 ft./min. 400 ft./min. JC EPM240Z 68 MBGA 35.5 68.7 63.0 60.9 59.2 EPM240 100 FBGA 20.8 51.2 45.2 43.2 41.5 EPM240G EPM240 100 MBGA 32.1 53.8 47.7 45.7 44.0 EPM240G EPM240Z EPM240 100 TQFP 12.0 39.5 37.5 35.5 31.6 EPM240G EPM570 100 FBGA 14.8 42.8 36.8 34.9 33.3 EPM570G MAX II Device Handbook © October 2008 Altera Corporation
Chapter 7: Package Information 7–3 Package Outlines Table7–2. Thermal Resistance of MAX II Devices (Part 2 of 2) (°C/W) (°C/W) (°C/W) (°C/W) JA JA JA JA Device Pin Count Package (°C/W) Still Air 100 ft./min. 200 ft./min. 400 ft./min. JC EPM570 100 MBGA 25.0 46.5 40.4 38.4 36.8 EPM570G EPM570Z EPM570 100 TQFP 11.2 38.7 36.6 34.6 30.8 EPM570G EPM570Z 144 MBGA 20.2 51.8 45.1 43.2 41.5 EPM570 144 TQFP 10.5 32.1 30.3 28.7 26.1 EPM570G EPM570 256 FBGA 13.0 37.4 33.1 30.5 28.4 EPM570G EPM570 256 MBGA 12.9 39.5 33.6 31.6 30.1 EPM570G EPM570Z EPM1270 144 TQFP 10.5 31.4 29.7 28.2 25.8 EPM1270G 256 FBGA 10.4 33.5 29.3 26.8 24.7 256 MBGA 10.6 36.1 30.2 28.3 26.8 EPM2210 256 FBGA 8.7 30.2 26.1 23.6 21.7 EPM2210G 324 FBGA 8.2 29.8 25.7 23.3 21.3 Package Outlines The package outlines on the following pages are listed in order of ascending pin count. Altera package outlines meet the requirements of JEDEC Publication No. 95. 68-Pin Micro FineLine Ball-Grid Array (MBGA) – Wire Bond ■ All dimensions and tolerances conform to ASME Y14.5M – 1994 ■ Controlling dimension is in millimeters ■ Pin A1 may be indicated by an ID dot, or a special feature, in its proximity on package surface Package Information (Part 1 of 2) Package Outline Dimension Table (Part 1 of 2) Description Specification Millimeters Symbol Ordering Code Reference M Min. Nom. Max. Package Acronym MBGA A — — 1.20 Substrate Material BT A1 0.15 — — Solder Ball Composition Pb-free: Sn:3Ag:0.5Cu (Typ.) A2 — — 1.00 JEDEC Outline Reference MO-195 Variation: AB A3 0.60 REF © October 2008 Altera Corporation MAX II Device Handbook
7–4 Chapter 7: Package Information Package Outlines Package Information (Part 2 of 2) Package Outline Dimension Table (Part 2 of 2) Maximum Lead D 5.00 BSC 0.003 inches (0.08mm) Coplanarity Weight 0.1g E 5.00 BSC Printed on moisture barrier b 0.25 0.30 0.35 Moisture Sensitivity Level bag e 0.50 BSC Figure7–1. 68-Pin Micro FineLine BGA Package Outline TOP VIEW BOTTOM VIEW D Pin A1 Corner 9 8 7 6 5 4 3 2 1 A B Pin A1 ID C D E e E F G H J b e A3 A2 A A 1 MAX II Device Handbook © October 2008 Altera Corporation
Chapter 7: Package Information 7–5 Package Outlines 100-Pin Plastic Thin Quad Flat Pack (TQFP) ■ All dimensions and tolerances conform to ANSI Y14.5M – 1994 ■ Controlling dimension is in millimeters ■ Pin 1 may be indicated by an ID dot, or a special feature, in its proximity on package surface Package Information Package Outline Dimension Table Description Specification Millimeters Symbol Ordering Code Reference T Min. Nom. Max. Package Acronym TQFP A — — 1.20 Leadframe Material Copper A1 0.05 — 0.15 A2 0.95 1.00 1.05 Regular: 85Sn:15Pb (Typ.) Lead Finish (Plating) Pb-free: Matte Sn D 16.00 BSC JEDEC Outline Reference MS-026 Variation: AED D1 14.00 BSC Maximum Lead E 16.00 BSC 0.003 inches (0.08mm) Coplanarity Weight 0.6 g E1 14.00 BSC Printed on moisture barrier L 0.45 0.60 0.75 Moisture Sensitivity Level bag L1 1.00 REF S 0.20 — — b 0.17 0.22 0.27 c 0.09 — 0.20 e 0.50 BSC 0 3.5 7 © October 2008 Altera Corporation MAX II Device Handbook
7–6 Chapter 7: Package Information Package Outlines Figure7–2. 100-Pin TQFP Package Outline D D1 Pin 100 Pin 1 Pin 1 ID E1 E Pin 25 A2 A See Detail A A1 DETAIL A e C Gage Plane b S 0.25mm L L1 MAX II Device Handbook © October 2008 Altera Corporation
Chapter 7: Package Information 7–7 Package Outlines 100-Pin Micro FineLine Ball-Grid Array (MBGA) ■ All dimensions and tolerances conform to ASME Y14.5 – 1994. ■ Controlling dimension is in millimeters. ■ Pin A1 may be indicated by an ID dot, or a special feature, in its proximity on package surface Package Information Package Outline Dimension Table Description Specification Millimeters Symbol Ordering Code Reference M Min. Nom. Max. Package Acronym MBGA A — — 1.20 Substrate Material BT A1 0.15 — — Solder Ball Composition Pb-free: Sn:3Ag:0.5Cu (Typ.) A2 — — 1.00 JEDEC Outline Reference MO-195 Variation: AC A3 0.60 REF Maximum Lead D 6.00 BSC 0.003 inches (0.08mm) Coplanarity Weight 0.1g E 6.00 BSC Printed on moisture barrier b 0.25 0.30 0.35 Moisture Sensitivity Level bag e 0.50 BSC © October 2008 Altera Corporation MAX II Device Handbook
7–8 Chapter 7: Package Information Package Outlines Figure7–3. 100-Pin Micro FineLine BGA Package Outline TOP VIEW BOTTOM VIEW D Pin A1 Corner 11 10 9 8 7 6 5 4 3 2 1 A B Pin A1 ID C D e E F E G H J K L b e A3 A2 A A 1 100-Pin FineLine Ball-Grid Array (FBGA) ■ All dimensions and tolerances conform to ASME Y14.5 – 1994 ■ Controlling dimension is in millimeters ■ Pin A1 may be indicated by an ID dot, or a special feature, in its proximity on package surface Package Information Package Outline Dimension Table Description Specification Millimeters Symbol Ordering Code Reference F Min. Nom. Max. Package Acronym FBGA A — — 1.55 Substrate Material BT A1 0.25 — — MAX II Device Handbook © October 2008 Altera Corporation
Chapter 7: Package Information 7–9 Package Outlines Package Information Package Outline Dimension Table A2 1.05 REF Regular: 63Sn:37Pb (Typ.) Solder Ball Composition Pb-free: Sn:3Ag:0.5Cu (Typ.) A3 — — 0.80 JEDEC Outline Reference MO-192 Variation: DAC-1 D 11.00 BSC Maximum Lead E 11.00 BSC 0.008 inches (0.20mm) Coplanarity Weight 0.6 g b 0.45 0.50 0.55 Printed on moisture barrier e 1.00 BSC Moisture Sensitivity Level bag Figure7–4. 100-Pin FineLine BGA Package Outline TOP VIEW BOTTOM VIEW D Pin A1 Corner 10 9 8 7 6 5 4 3 2 1 A B Pin A1 ID C D e E E F G H J K b e A3 A2 A A 1 © October 2008 Altera Corporation MAX II Device Handbook
7–10 Chapter 7: Package Information Package Outlines 144-Pin Plastic Thin Quad Flat Pack (TQFP) ■ All dimensions and tolerances conform to ANSI Y14.5M – 1994 ■ Controlling dimension is in millimeters ■ Pin 1 may be indicated by an ID dot, or a special feature, in its proximity on package surface Package Information Package Outline Figure Reference Description Specification Millimeters Symbol Ordering Code Reference T Min. Nom. Max. Package Acronym TQFP A — — 1.60 Leadframe Material Copper A1 0.05 — 0.15 A2 1.35 1.40 1.45 Regular: 85Sn:15Pb (Typ.) Lead Finish (Plating) Pb-free: Matte Sn D 22.00 BSC JEDEC Outline Reference MS-026 Variation: BFB D1 20.00 BSC Maximum Lead E 22.00 BSC 0.003 inches (0.08mm) Coplanarity Weight 1.1 g E1 20.00 BSC Printed on moisture barrier L 0.45 0.60 0.75 Moisture Sensitivity Level bag L1 1.00 REF S 0.20 — — b 0.17 0.22 0.27 c 0.09 — 0.20 e 0.50 BSC 0 3.5 7 MAX II Device Handbook © October 2008 Altera Corporation
Chapter 7: Package Information 7–11 Package Outlines Figure7–5. 144-Pin TQFP Package Outline D D1 Pin 144 Pin 1 Pin 1 ID E1 E Pin 36 A2 A A1 See Detail A DETAIL A e C Gage Plane b S 0.25mm L L1 © October 2008 Altera Corporation MAX II Device Handbook
7–12 Chapter 7: Package Information Package Outlines 144-Pin Micro FineLine Ball-Grid Array (MBGA) – Wire Bond ■ All dimensions and tolerances conform to ASME Y14.5M – 1994. ■ Controlling dimension is in millimeters. ■ Pin A1 may be indicated by an ID dot, or a special feature, in its proximity on package surface Package Information Package Outline Dimension Table Description Specification Millimeters Symbol Ordering Code Reference M Min. Nom. Max. Package Acronym MBGA A — — 1.20 Substrate Material BT A1 0.15 — — Solder Ball Composition Pb-free: Sn:3Ag:0.5Cu (Typ.) A2 — — 1.00 JEDEC Outline Reference MO-195 Variation: AD A3 0.60 REF Maximum Lead D 7.00 BSC 0.003 inches (0.08mm) Coplanarity Weight 0.1 g E 7.00 BSC Printed on moisture barrier b 0.25 0.30 0.35 Moisture Sensitivity Level bag e 0.50 BSC MAX II Device Handbook © October 2008 Altera Corporation
Chapter 7: Package Information 7–13 Package Outlines Figure7–6. 144-Pin Micro FineLine BGA Package Outline TOP VIEW BOTTOM VIEW D Pin A1 Corner 13 12 11 10 9 8 7 6 5 4 3 2 1 A B Pin A1 ID C D e E F E G H J K L M N A3 A2 A b e A 1 256-Pin Micro FineLine Ball-Grid Array (MBGA) ■ All dimensions and tolerances conform to ASME Y14.5 – 1994 ■ Controlling dimension is in millimeters ■ Pin A1 may be indicated by an ID dot, or a special feature, in its proximity on package surface Package Information (Part 1 of 2) Package Outline Dimension Table (Part 1 of 2) Description Specification Millimeters Symbol Ordering Code Reference M Min. Nom. Max. Package Acronym MBGA A — — 1.20 Substrate Material BT A1 0.15 — — Solder Ball Composition Pb-free: Sn:3Ag:0.5Cu (Typ.) A2 — — 1.00 JEDEC Outline Reference MO-192 Variation: BH A3 0.60 REF Maximum Lead D 11.00 BSC 0.003 inches (0.08mm) Coplanarity Weight 0.3 g E 11.00 BSC © October 2008 Altera Corporation MAX II Device Handbook
7–14 Chapter 7: Package Information Package Outlines Package Information (Part 2 of 2) Package Outline Dimension Table (Part 2 of 2) Printed on moisture barrier b 0.25 0.30 0.35 Moisture Sensitivity Level bag e 0.50 BSC Figure7–7. 256-Pin Micro FineLine BGA Package Outline TOP VIEW BOTTOM VIEW D Pin A1 Corner Pin A1 ID e E e b AA 32 A A 1 MAX II Device Handbook © October 2008 Altera Corporation
Chapter 7: Package Information 7–15 Package Outlines 256-Pin FineLine Ball-Grid Array (FBGA) ■ All dimensions and tolerances conform to ANSI Y14.5M – 1994 ■ Controlling dimension is in millimeters ■ Pin A1 may be indicated by an ID dot, or a special feature, in its proximity on package surface Package Information Package Outline Dimension Table Description Specification Millimeters Ordering Code Reference F Min. Nom. Max. Package Acronym FBGA A — — 2.20 Substrate Material BT A1 0.30 — — A2 — — 1.80 Regular: 63Sn:37Pb (Typ.) Solder Ball Composition Pb-free: Sn:3Ag:0.5Cu (Typ.) A3 0.70 REF JEDEC Outline Reference MS-034 Variation: AAF-1 D 17.00 BSC Maximum Lead E 17.00 BSC 0.008 inches (0.20 mm) Coplanarity Weight 1.5 g b 0.50 0.60 0.70 Printed on moisture barrier e 1.00 BSC Moisture Sensitivity Level bag © October 2008 Altera Corporation MAX II Device Handbook
7–16 Chapter 7: Package Information Package Outlines Figure7–8. 256-Pin FineLine BGA Package Outline TOP VIEW BOTTOM VIEW D Pin A1 Corner Pin A1 ID e E b e A3 A2 A A 1 324-Pin FineLine Ball-Grid Array (FBGA) ■ All dimensions and tolerances conform to ANSI Y14.5M – 1994 ■ Controlling dimension is in millimeters ■ Pin A1 may be indicated by an ID dot, or a special feature, in its proximity on package surface Package Information (Part 1 of 2) Package Outline Dimension Table (Part 1 of 2) Description Specification Millimeters Symbol Ordering Code Reference F Min. Nom. Max. Package Acronym FBGA A — — 2.20 Substrate Material BT A1 0.30 — — A2 — — 1.80 Regular: 63Sn:37Pb (Typ.) Solder Ball Composition Pb-free: Sn:3Ag:0.5Cu (Typ.) A3 0.70 REF JEDEC Outline Reference MS-034 Variation: AAG-1 D 19.00 BSC Maximum Lead E 19.00 BSC 0.008 inches (0.20 mm) Coplanarity Weight 1.6 g b 0.50 0.60 0.70 MAX II Device Handbook © October 2008 Altera Corporation
Chapter 7: Package Information 7–17 Package Outlines Package Information (Part 2 of 2) Package Outline Dimension Table (Part 2 of 2) Printed on moisture barrier e 1.00 BSC Moisture Sensitivity Level bag Figure7–9. 324-Pin FineLine BGA Package Outline TOP VIEW BOTTOM VIEW D Pin A1 Corner Pin A1 ID e E b e A3 A2 A A1 © October 2008 Altera Corporation MAX II Device Handbook
7–18 Chapter 7: Package Information Document Revision History Document Revision History Table7–3 shows the revision history for this chapter. Table7–3. Document Revision History Date and Revision Changes Made Summary of Changes October 2008, ■ Updated New Document Format. — version 2.1 December 2007, ■ Updated Table7–1 and Table7–2. ■ Updated document with version 2.0 MAXIIZ information. ■ Added “68-Pin Micro FineLine Ball-Grid Array (MBGA) – Wire Bond” and “144-Pin Micro FineLine Ball-Grid Array ■ Added information about (MBGA) – Wire Bond” sections. 68-Pin Micro FineLine Ball-Grid Array and 144- ■ Replaced Figure7–9 with correct diagram. Pin Micro FineLine Ball-Grid Array. December 2006, ■ Added document revision history. — version 1.4 July 2006, ■ Updated packaging information. — version 1.3 August 2005, ■ Updated the 100-pin plastic thin quad flat pack (TQFP) — version 1.2 information. December 2004, ■ Updated Board Decoupling Guidelines section (changed — version 1.1 the 0.2 value to 0.1.) MAX II Device Handbook © October 2008 Altera Corporation
8. Using MAX II Devices in Multi-Voltage Systems MII51009-1.7 Introduction Technological advancements in deep submicron processes have lowered the supply voltage levels of semiconductor devices, creating a design environment where devices on a system board may potentially use many different supply voltages such as 5.0, 3.3, 2.5, 1.8, and 1.5 V, which can ultimately lead to voltage conflicts. To accommodate interfacing with a variety of devices on system boards, MAX® II devices have MultiVolt I/O interfaces that allow devices in a mixed-voltage design environment to communicate directly with MAX II devices. The MultiVolt interface separates the power supply voltage (V ) from the output voltage (V ), enabling CCINT CCIO MAX II devices to interface with other devices using a different voltage level on the same printed circuit board (PCB). Additionally, the MAX II device family supports the MultiVolt core feature. For 1.8-V operation, use the MAX IIG or MAX IIZ devices. The 1.8-V input directly powers the core of the devices. For 2.5-V or 3.3-V operation, use the MAX II devices. MAX II devices that support 2.5-V and 3.3-V operation have an internal voltage regulator that regulates at 1.8 V. This chapter discusses several features that allow you to implement Altera® devices in multiple-voltage systems without damaging the device or the system, including: ■ Hot Socketing—Insert or remove MAX II devices to and from a powered-up system without affecting the device or system operation ■ Power-Up Sequence Flexibility—MAX II devices can accommodate any possible power-up sequence ■ Power-On Reset—MAX II devices maintain a reset state until voltage is within operating range This chapter contains the following sections: ■ “I/O Standards” on page8–2 ■ “MultiVolt Core and I/O Operation” on page8–3 ■ “5.0-V Device Compatibility” on page8–3 ■ “Recommended Operating Condition for 5.0-V Compatibility” on page8–7 ■ “Hot Socketing” on page8–8 ■ “Power-Up Sequencing” on page8–8 ■ “Power-On Reset” on page8–8 © October 2008 Altera Corporation MAX II Device Handbook
8–2 Chapter 8: Using MAX II Devices in Multi-Voltage Systems I/O Standards I/O Standards The I/O buffer of MAX II devices is programmable and supports a wide range of I/O voltage standards. Each I/O bank in a MAX II device can be programmed to comply with a different I/O standard. All I/O banks can be configured with the following standards: ■ 3.3-V LVTTL/LVCMOS ■ 2.5-V LVTTL/LVCMOS ■ 1.8-V LVTTL/LVCMOS ■ 1.5-V LVCMOS The Schmitt trigger input option is supported by the 3.3-V and 2.5-V I/O standards. The I/O Bank 3 also includes 3.3-V PCI I/O standard interface capability on the EPM1270 and EPM2210 devices. See Figure8–1. Figure8–1. I/O Standards Supported by MAX II Device (Note1), (2), (3), (4), (5) I/O Bank 2 I/O Bank 3 also supports the 3.3-V PCI I/O Standard All I/O Banks support ■ 3.3-V LVTTL/LVCMOS ■ 2.5-V LVTTL/LVCMOS I/O Bank 1 ■ 1.8-V LVTTL/LVCMOS I/O Bank 3 ■ 1.5-V LVCMOS Individual Power Bus I/O Bank 4 Notes to Figure8–1: (1) Figure8–1 is a top view of the silicon die. (2) Figure8–1 is a graphical representation only. Refer to the pin list and the Quartus® II software for exact pin locations. (3) EPM240 and EPM570 devices only have two I/O banks. (4) The 3.3-V PCI I/O standard is only supported in EPM1270 and EPM2210 devices. (5) The Schmitt trigger input option for 3.3-V and 2.5-V I/O standards is supported for all I/O pins. MAX II Device Handbook © October 2008 Altera Corporation
Chapter 8: Using MAX II Devices in Multi-Voltage Systems 8–3 MultiVolt Core and I/O Operation MultiVolt Core and I/O Operation MAX II devices include MultiVolt core I/O operation capability, allowing the core and I/O blocks of the device to be powered-up with separate supply voltages. The VCCINT pins supply power to the device core and the VCCIO pins supply power to the device I/O buffers. The VCCINT pins can be powered-up with 1.8V for MAX IIG and MAX IIZ devices or 2.5/3.3V for MAX II devices. All the VCCIO pins for a given I/O bank that have MultiVolt capability should be supplied from the same voltage level (for example, 5.0, 3.3, 2.5, 1.8, or 1.5 V). See Figure8–2. Figure8–2. Implementing a Multiple-Voltage System with a MAX II Device (Note1), (2), (3), (4) 1.8 V/2.5 V/3.3 V Power Supply VCCINT 5.0-V VCCIO MAX II VCCIO 3.3-V Device Device Device VCCIO 2.5-V Device Notes to Figure8–2: (1) For MAX IIG and MAX IIZ devices, VCCINT pins will only accept a 1.8-V power supply. (2) For MAX II devices, VCCINT pins will only accept a 2.5-V or 3.3-V power supply. (3) MAX II devices can drive a 5.0-V TTL input when V = 3.3 V. To drive a 5.0-V CMOS, an open-drain setting with CCIO internal I/O clamp diode and external resistor are required. (4) MAX II devices can be 5.0-V tolerant with the use of an external resistor and the internal I/O clamp diode on EPM1270 and EPM2210 devices. 5.0-V Device Compatibility A MAX II device can drive a 5.0-V TTL device by connecting the V pins of the CCIO MAX II device to 3.3 V. This is possible because the output high voltage (V ) of a 3.3- OH V interface meets the minimum high-level voltage of 2.4 V of a 5.0-V TTL device. A MAX II device may not correctly interoperate with a 5.0-V CMOS device if the output of the MAX II device is connected directly to the input of the 5.0-V CMOS device. If the MAX II device‘s V is greater than V , the PMOS pull-up transistor OUT CCIO still conducts if the pin is driving high, preventing an external pull-up resistor from pulling the signal to 5.0V. To make MAX II device outputs compatible with 5.0-V CMOS devices, configure the output pins as open-drain pins with the I/O clamp diode enabled, and use an external pull-up resistor. See Figure8–3. © October 2008 Altera Corporation MAX II Device Handbook
8–4 Chapter 8: Using MAX II Devices in Multi-Voltage Systems 5.0-V Device Compatibility Figure8–3. MAX II Device Compatibility with 5.0-V CMOS Devices 5.0 V ± 0.5 V 3.3 V V V CCIO CCIO V CCIO (1) R EXT Open Drain Model as R INT V OUT 5.0-V CMOS Device A V IN VSS Note to Figure8–3: (1) This diode is only active after power-up. MAX II devices require an external diode if driven by 5.0 V before power-up. The open-drain pin never drives high, only low or tri-state. When the open-drain pin is active, it drives low. When the open-drain pin is inactive, the pin is tri-stated and the trace pulls up to 5.0 V by the external resistor. The purpose of enabling the I/O clamp diode is to protect the MAX II device’s I/O pins. The 3.3-V V supplied to the CCIO I/O clamp diodes causes the voltage at point A to clamp at 4.0 V, which meets the MAXII device’s reliability limits when the trace voltage exceeds 4.0 V. The device operates successfully because a 5.0-V input is within its input specification. 1 The I/O clamp diode is only supported in the EPM1270 and EPM2210 devices’ I/O Bank 3. An external protection diode is needed for other I/O banks in EPM1270 and EPM2210 devices and all I/O pins in EPM240 and EPM570 devices. The pull-up resistor value should be small enough for sufficient signal rise time, but large enough so that it does not violate the I (output low) specification of MAX II OL devices. The maximum MAX II device I depends on the programmable drive strength of the OL I/O output. Table8–1 shows the programmable drive strength settings that are available for the 3.3-V LVTTL/LVCMOS I/O standard for MAX II devices. The Quartus II software uses the maximum current strength as the default setting. The PCI I/O standard is always set at 20 mA with no alternate setting. Table8–1. 3.3-V LVTTL/LVCMOS Programmable Drive Strength I/O Standard I /I Current Strength Setting (mA) OH OL 3.3-V LVTTL 16 8 3.3-V LVCMOS 8 4 MAX II Device Handbook © October 2008 Altera Corporation
Chapter 8: Using MAX II Devices in Multi-Voltage Systems 8–5 5.0-V Device Compatibility To compute the required value of R , first calculate the model of the open-drain EXT transistors on the MAX II device. This output resistor (R ) can be modeled by EXT dividing V by I (R = V /I ). Table8–2 shows the maximum V for the 3.3-V OL OL EXT OL OL OL LVTTL/LVCMOS I/O standard for MAXII devices. f For more information about I/O standard specifications, refer to the DC and Switching Characteristics chapter in the MAX II Device Handbook. Table8–2. 3.3-V LVTTL/LVCMOS Maximum V OL I/O Standard Voltage (V) 3.3-V LVTTL 0.45 3.3-V LVCMOS 0.20 Select R so that the MAX II device’s I specification is not violated. You can EXT OL compute the required pull-up resistor value of R by using the equation: R = EXT EXT (V /I ) – R . For example, if an I/O pin is configured as a 3.3-V LVTTL with a 16 CC OL INT mA drive strength, given that the maximum power supply (V ) is 5.5 V, the value of CC R can be calculated as follows: EXT Equation8–1. 5.5 V–0.45 V R = --------------------------------------- = 315.6 EXT 16mA This resistor value computation assumes worst-case conditions. You can adjust the R value according to the device configuration drive strength. Additionally, if your EXT system does not see a wide variation in voltage-supply levels, you can adjust these calculations accordingly. Because MAX II devices are 3.3-V, 32-bit, 66-MHz PCI compliant, the input circuitry accepts a maximum high-level input voltage (V ) of 4.0V. To drive a MAX II device IH with a 5.0-V device, you must connect a resistor (R ) between the MAX II device and 2 the 5.0-V device. See Figure8–4. © October 2008 Altera Corporation MAX II Device Handbook
8–6 Chapter 8: Using MAX II Devices in Multi-Voltage Systems 5.0-V Device Compatibility Figure8–4. Driving a MAX II PCI-Compliant Device with a 5.0-V Device MAX II Device 5.0-V Device 3.3 V 5.0 V ± 0.5 V V CCIO VCC VCCIO PCI Clamp (1) I R I 2 Model as R 1 B Note to Figure8–4: (1) This diode is only active after power-up. MAX II devices require an external diode if driven by 5.0 V before power-up. If V for MAX II devices is 3.3 V and the I/O clamp diode is enabled, the voltage at point B in CCIO Figure8–4 is 4.0 V, which meets the MAX II devices reliability limits when the trace voltage exceeds 4.0 V. To limit large current draw from the 5.0-V device, R should be small enough for 2 a fast signal rise time and large enough so that it does not violate the high-level output current (I ) specifications of the devices driving the trace. OH To compute the required value of R , first calculate the model of the pull-up transistors on the 2 5.0-V device. This output resistor (R ) can be modeled by dividing the 5.0-V device supply 1 voltage (V ) by the I : R = V /I CC OH 1 CC OH Figure8–5 shows an example of typical output drive characteristics of a 5.0-V device. Figure8–5. Output Drive Characteristics of a 5.0-v Device 150 I OL 135 120 VCCINT = 5.0 V VCCIO = 5.0 V Typical I 90 O Output Current (mA) 60 I OH 30 1 2 3 4 5 V Output Voltage (V) O MAX II Device Handbook © October 2008 Altera Corporation
Chapter 8: Using MAX II Devices in Multi-Voltage Systems 8–7 Recommended Operating Condition for 5.0-V Compatibility As shown above, R = 5.0 V/135 mA. 1 The values usually shown in data sheets reflect typical operating conditions. Subtract 20% from the data sheet value for guard band. This subtraction applied to the above example gives R a value of 30. 1 Select R so that the MAX II device’s I specification is not violated. For example, if 2 OH the above device has a maximum I of 8 mA, given the I/O clamp diode, V = V OH IN CCIO + 0.7 V = 3.7 V. Given that the maximum supply load of a 5.0-V device (V ) is 5.5 V, CC the value of R can be calculated as follows: 2 Equation8–2. 5.5 V–3.7 V–8 mA30 R = -------------------------------------------------------------------------------- = 194 2 8mA This analysis assumes worst-case conditions. If your system does not see a wide variation in voltage-supply levels, you can adjust these calculations accordingly. Because 5.0-V device tolerance in MAX II devices requires use of the I/O clamp, and this clamp is activated only after power-up, 5.0-V signals may not be driven into the device until it is configured. The I/O clamp diode is only supported in the EPM1270 and EPM2210 devices’ I/O Bank3. An external protection diode is needed for other I/O banks for EPM1270 and EPM2210 devices and all I/O pins in EPM240 and EPM570 devices. Recommended Operating Condition for 5.0-V Compatibility As mentioned earlier, a 5.0-V tolerance can be supported with the I/O clamp diode enabled with external series/pull-up resistance. To guarantee long term reliability of the device’s I/O buffer, there are restrictions on the signal duty cycle that drive the MAX II I/O, which is based on the maximum clamp current. Table8–3 shows the maximum signal duty cycle for 3.3-V V given a PCI clamp current-handling CCIO capability. Table8–3. Maximum Signal Duty Cycle V (V) (1) I (mA) (2) Max Duty Cycle (%) IN CH 4.0 5.00 100 4.1 11.67 90 4.2 18.33 50 4.3 25.00 30 4.4 31.67 17 4.5 38.33 10 4.6 45.00 5 Notes to Table8–3: (1) V is the voltage at the package pin. IN (2) The I is calculated with a 3.3-V V . A higher V value will have a lower I value CH CCIO CCIO CH with the same V . IN © October 2008 Altera Corporation MAX II Device Handbook
8–8 Chapter 8: Using MAX II Devices in Multi-Voltage Systems Hot Socketing For signals with duty cycle greater than 30% on MAX II input pins, Altera recommends a V voltage of 3.0 V to guarantee long-term I/O reliability. For signals CCIO with duty cycle less than 30%, the V voltage can be 3.3 V. CCIO Hot Socketing For information about hot socketing, refer to the Hot Socketing and Power-On Reset in MAX II Devices chapter in the MAX II Device Handbook. Power-Up Sequencing MAX II devices are designed to operate in multiple-voltage environments where it may be difficult to control power sequencing. Therefore, MAX II devices are designed to tolerate any possible power-up sequence. Either V or V can initially supply CCINT CCIO power to the device, and 3.3-V, 2.5-V, 1.8-V, or 1.5-V input signals can drive the devices without special precautions before V or V is applied. MAX II devices CCINT CCIO can operate with a V voltage level that is higher than the V level. CCIO CCINT When V and V are supplied from different power sources to a MAX II device, a CCIO CCINT delay between V and V may occur. Normal operation does not occur until both CCIO CCINT power supplies are in their recommended operating range. When V is powered- CCINT up, the IEEE Std. 1149.1 Joint Test Action Group (JTAG) circuitry is active. If the TMS and TCK are connected to V and V is not powered-up, the JTAG signals are left CCIO CCIO floating. Thus, any transition on TCK can cause the state machine to transition to an unknown JTAG state, leading to incorrect operation when V is finally powered-up. CCIO To disable the JTAG state during the power-up sequence, TCK should be pulled low to ensure that an inadvertent rising edge does not occur on TCK. Power-On Reset For information about Power-On Reset (POR), refer to the Hot Socketing and Power-On Reset in MAX II Devices chapter in the MAX II Device Handbook. Conclusion MAX II devices have MultiVolt I/O support, allowing 1.5-V, 1.8-V, 2.5-V, and 3.3-V devices to interface directly with MAX II devices without causing voltage conflicts. In addition, MAX II devices can interface with 5.0-V devices by slightly modifying the external hardware interface and enabling I/O clamp diodes via the Quartus II software. This MultiVolt capability also enables the device core to run at its core voltage, V , while maintaining I/O pin compatibility with other devices. Altera has CCINT taken further steps to make system design easier by designing devices that allow V and V to power-up in any sequence and by incorporating support for hot CCINT CCIO socketing. MAX II Device Handbook © October 2008 Altera Corporation
Chapter 8: Using MAX II Devices in Multi-Voltage Systems 8–9 Referenced Documents Referenced Documents This chapter references the following documents: ■ DC and Switching Characteristics chapter in the MAX II Device Handbook ■ Hot Socketing and Power-On Reset in MAX II Devices chapter in the MAX II Device Handbook Document Revision History Table8–4 shows the revision history for this chapter. Table8–4. Document Revision History Date and Revision Changes Made Summary of Changes October 2008, ■ Updated Figure8–2. — version 1.7 ■ Updated “5.0-V Device Compatibility” and “Conclusion”sections. ■ Updated New Document Format. December 2007, ■ Updated “Introduction” section. Updated document with version 1.6 MAX IIZ information. ■ “MultiVolt Core and I/O Operation” section. ■ Updated (Note1) to Figure8–2. ■ Added “Referenced Documents” section. December 2006, ■ Added document revision history. — version 1.5 August 2006, ■ Updated “5.0-V Device Compatibility” section. — version 1.4 February 2006, ■ Updated Figure8–3. — version 1.3 January 2005, ■ Previously published as Chapter 9. No changes to content. — version 1.2 December 2004, ■ Corrected typographical errors in Note 3 of Figure8–2. — version 1.1 © October 2008 Altera Corporation MAX II Device Handbook
8–10 Chapter 8: Using MAX II Devices in Multi-Voltage Systems Document Revision History MAX II Device Handbook © October 2008 Altera Corporation
Section III. User Flash Memory This section provides information on the user flash memory (UFM) block in MAX® II devices. This section includes the following chapters: ■ Chapter9, Using User Flash Memory in MAX II Devices ■ Chapter10, Replacing Serial EEPROMs with MAX II User Flash Memory Revision History Refer to each chapter for its own specific revision history. For information on when each chapter was updated, refer to the Chapter Revision Dates section, which appears in the complete handbook. © October 2008 Altera Corporation MAX II Device Handbook
III–2 Section III: User Flash Memory Revision History MAX II Device Handbook © October 2008 Altera Corporation
9. Using User Flash Memory in MAX II Devices MII51010-1.8 Introduction MAX® II devices feature a user flash memory (UFM) block that can be used similar to a serial EEPROM for storing non-volatile information up to 8 Kbits. The UFM provides an ideal storage solution supporting any possible protocol for interfacing (SPI, parallel, and other protocols) through bridging logic designed into the MAX II logic array. This chapter provides guidelines for UFM applications by describing the features and functionality of the MAX II UFM block and the Quartus® II altufm megafunction. This chapter contains the following sections: ■ “UFM Array Description” on page9–1 ■ “UFM Functional Description” on page9–3 ■ “UFM Operating Modes” on page9–9 ■ “Programming and Reading the UFM with JTAG” on page9–12 ■ “Software Support for UFM Block” on page9–13 ■ “Creating Memory Content File” on page9–40 ■ “Simulation Parameters” on page9–46 UFM Array Description Each UFM array is organized as two separate sectors with 4,096 bits per sector. Each sector can be erased independently. Table9–1 shows the dimension of the UFM array. Table9–1. UFM Array Size Device Total Bits Sectors Address Bits Data Width EPM240 8,192 2 (4,096 bits per sector) 9 16 EPM570 EPM1270 EPM2210 Memory Organization Map Table9–2 shows the memory organization for the MAX II UFM block. There are 512 locations with 9 bits addressing a range of 000h to 1FFh. Each location stores 16-bit wide data. The most significant bit (MSB) of the address register indicates the sector in operation. © October 2008 Altera Corporation MAX II Device Handbook
9–2 Chapter 9: Using User Flash Memory in MAX II Devices UFM Array Description Table9–2. Memory Organization Sector Address Range 1 100h 1FFh 0 000h 0FFh Using and Accessing UFM Storage You can use the UFM to store data of different memory sizes and data widths. Even though the UFM storage width is 16 bits, you can implement different data widths or a serial interface with the altufm megafunction. Table9–3 shows the different data widths available for the three types of interfaces supported in the Quartus II software. Table9–3. Data Widths for Logic Array Interfaces Logic Array Interface Data Width (Bits) Interface Type I2C 8 Serial SPI 8 or 16 Serial Parallel Options of 3 to 16 Parallel None 16 Serial For more details about the logic array interface options in the altufm megafunction, refer to “Software Support for UFM Block” on page9–13. 1 The UFM block is accessible through the logic array interface as well as the JTAG interface. However, the UFM logic array interface does not have access to the CFM block. MAX II Device Handbook © October 2008 Altera Corporation
Chapter 9: Using User Flash Memory in MAX II Devices 9–3 UFM Functional Description UFM Functional Description Figure9–1 is the block diagram of the MAX II UFM block and the interface signals. Figure9–1. UFM Block and Interface Signals UFM Block PROGRAM Program RTP_BUSY ERASE Erase BUSY Control OSC_ENA OSC _:4 OSC 9 UFM Sector 1 ARCLK UFM Sector 0 Address Register 16 16 ARSHFT ARDin DRDin Data Register DRDout DRCLK DRSHFT Table9–4 summarizes the MAX II UFM block input and output interface signals. Table9–4. UFM Interface Signals (Part 1 of 2) Port Name Port Type Description DRDin Input Serial input to the data register. It is used to enter a data word when writing to the UFM. The data register is 16 bits wide and data is shifted serially from the least significant bit (LSB) to the MSB with each DRCLK. This port is required for writing, but unused if the UFM is in read-only mode. DRCLK Input Clock input that controls the data register. It is required and takes control when data is shifted from DRDin to DRDout or loaded in parallel from the flash memory. The maximum frequency for DRCLK is 10 MHz. DRSHFT Input Signal that determines whether to shift the data register or load it on a DRCLK edge. A high value shifts the data from DRDin into the LSB of the data register and from the MSB of the data register out to DRDout. A low value loads the value of the current address in the flash memory to the data register. ARDin Input Serial input to the address register. It is used to enter the address of a memory location to read, program, or erase. The address register is 9bits wide for the UFM size (8,192 bits). © October 2008 Altera Corporation MAX II Device Handbook
9–4 Chapter 9: Using User Flash Memory in MAX II Devices UFM Functional Description Table9–4. UFM Interface Signals (Part 2 of 2) Port Name Port Type Description ARCLK Input Clock input that controls the address register. It is required when shifting the address data from ARDin into the address register or during the increment stage. The maximum frequency for ARCLK is 10 MHz. ARSHFT Input Signal that determines whether to shift the address register or increment it on an ARCLK edge. A high value shifts the data from ARDin serially into the address register. A low value increments the current address by 1. The address register rolls over to 0 when the address space is at the maximum. PROGRAM Input Signal that initiates a program sequence. On the rising edge, the data in the data register is written to the address pointed to by the address register. The BUSY signal asserts until the program sequence is completed. ERASE Input Signal that initiates an erase sequence. On a rising edge, the memory sector indicated by the MSB of the address register will be erased. The BUSY signal asserts until the erase sequence is completed. OSC_ENA Input This signal turns on the internal oscillator in the UFM block, and is optional but required when the OSC output is used. If OSC_ENA is driven high, the internal oscillator is enabled and the OSC output will toggle. If OSC_ENA is driven low, the internal oscillator is disabled and the OSC output drives constant low. DRDout Output Serial output of the data register. Each time the DRCLK signal is applied, a new value is available. The DRDout data depends on the DRSHFT signal. When the DRSHFT signal is high, DRDout value is the new value that is shifted into the MSB of the data register. If the DRSHFT is low, DRDout would contain the MSB of the memory location read into the data register. BUSY Output Signal that indicates when the memory is BUSY performing a PROGRAM or ERASE instruction. When it is high, the address and data register should not be clocked. The new PROGRAM or ERASE instruction will not be executed until the BUSY signal is deasserted. OSC Output Output of the internal oscillator. It can be used to generate a clock to control user logic with the UFM. It requires an OSC enable input to produce an output. RTP_BUSY Output This output signal is optional and only needed if the real-time ISP feature is used. The signal is asserted high during real-time ISP and stays in the RUN_STATE for 500ms before initiating real-time ISP to allow for the final read/erase/write operation. No read, write, erase, or address and data shift operations are allowed to be issued once the RTP_BUSY signal goes high. The data and address registers do not retain the contents of the last read or write operation for the UFM block during real-time ISP. f To see the interaction between the UFM block and the logic array of MAX II devices, refer to the MAX II Architecture chapter in the MAX II Device Handbook (Figure2–16 for EPM240 devices and Figure2–17 for EPM570, EPM1270, and EPM2210 devices). MAX II Device Handbook © October 2008 Altera Corporation
Chapter 9: Using User Flash Memory in MAX II Devices 9–5 UFM Functional Description UFM Address Register The MAX II UFM block is organized as a 512 × 16 memory. Since the UFM block is organized into two separate sectors, the MSB of the address indicates the sector that will be in action; 0 is for sector 0 (UFM0) while 1 is for sector 1 (UFM1). An ERASE instruction erases the content of the specific sector that is indicated by the MSB of the address register. Figure9–2 shows the selection of the UFM sector in action using the MSB of the address register. Refer to “Erase” on page9–11 for more information about ERASE mode. Figure9–2. Selection of the UFM Sector Using the MSB of the Address Register Sector 0 Address Register UFM Block 0 ARDin A0 A1 A2 A3 A4 A5 A6 A7 A8 1 LSB MSB UFM Block ARClk Sector 1 Three control signals exist for the address register: ARSHFT, ARCLK, and ARDin. ARSHFT is used as both a shift-enable control signal and an auto-increment signal. If the ARSHFT signal is high, a rising edge on ARCLK will load address data serially from the ARDin port and move data serially through the register. A clock edge with the ARSHFT signal low increments the address register by 1. This implements an auto- increment of the address to allow data streaming. When a program, read, or an erase sequence is executing, the address that is in the address register becomes the active UFM location. UFM Data Register The UFM data register is 16 bits wide with four control signals: DRSHFT, DRCLK, DRDin, and DRDout. DRSHFT distinguishes between clock edges that move data serially from DRDin or to DRDout and clock edges that latch parallel data from the UFM sectors. If the DRSHFT signal is high, a clock edge moves data serially through the registers from DRDin to DRDout. If the DRSHFT signal is low, a clock edge captures data from the UFM sector pointed by the address register in parallel. The MSB is the first bit that will be seen at DRDout. The data register DRSHFT signal will also be used to enable the UFM for reading data. When the DRSHFT signal is low, the UFM latches data into the data register. Figure9–3 shows the UFM data register. © October 2008 Altera Corporation MAX II Device Handbook
9–6 Chapter 9: Using User Flash Memory in MAX II Devices UFM Functional Description Figure9–3. UFM Data Register MAX II UFM Block 16 16 Data Register DRDin DRDout D0 D1 D2 D3 D4 D5 D6 D7 D8 D9 D10 D11 D12 D13 D14 D15 DRCLK LSB MSB UFM Program/Erase Control Block The UFM program/erase control block is used to generate all the control signals necessary to program and erase the UFM block independently. This reduces the number of LEs necessary to implement a UFM controller in the logic array. It also guarantees correct timing of the control signals to the UFM. A rising edge on either PROGRAM or ERASE causes this control signal block to activate and begin sequencing through the program or erase cycle. At this point, for a program instruction, whatever data is in the data register will be written to the address pointed to by the address register. Only sector erase is supported by the UFM. Once an ERASE command is executed, this control block will erase the sector whose address is stored in the address register. When the PROGRAM or ERASE command first activates the program/erase control block, the BUSY signal will be driven high to indicate an operation in progress in the UFM. Once the program or erase algorithm is completed, the BUSY signal will be forced low. Oscillator OSC_ENA, one of the input signals in the UFM block, is used to enable the oscillator signal to output through the OSC output port. You can use this OSC output port to connect with the interface logic in the logic array. It can be routed through the logic array and fed back as an input clock for the address register (ARCLK) and the data register (DRCLK). The output frequency of the OSC port is one-fourth that of the oscillator frequency. As a result, the frequency range of the OSC port is 3.3 to 5.5MHz. The maximum clock frequency accepted by ARCLK and DRCLK is 10 MHz and the duty cycle accepted by the DRCLK and ARCLK input ports is approximately 45% to 50%. When the OSC_ENA input signal is asserted, the oscillator is enabled and the output is routed to the logic array through the OSC output. When the OSC_ENA is set low, the OSC output drives constant low. The routing delay from the OSC port of the UFM block to OSC output pin depends on placement. You can analyze this delay using the Quartus II timing analyzer. MAX II Device Handbook © October 2008 Altera Corporation
Chapter 9: Using User Flash Memory in MAX II Devices 9–7 UFM Functional Description The undivided internal oscillator, which is not accessible, operates in a frequency range from 13.33 to 22.22 MHz. The internal oscillator is enabled during power-up, in- system programming, and real-time ISP. At all other times, the oscillator is not running unless the UFM is instantiated in the design and the OSC_ENA port is asserted. To see how specific operating modes of ALTUFM handle OSC_ENA and the oscillator, refer to “Software Support for UFM Block” on page9–13. For user generated logic interfacing to the UFM, the oscillator must be enabled during PROGRAM or ERASE operations, but not during READ operations. OSC_ENA can be tied low if you are not issuing any PROGRAM or ERASE commands. 1 During real-time ISP operation, the internal oscillator automatically enables and outputs through the OSC output port (if this port is instantiated) even though the OSC_ENA signal is tied low. You can use the RTP_BUSY signal to detect the beginning and ending of the real-time ISP operation for gated control of this self-enabled OSC output condition. 1 The internal oscillator is not enabled all the time. The internal oscillator for the program/erase operation is only activated when the flash memory block is being programmed or erased. During the READ operation, the internal oscillator is activated whenever the flash memory block is reading data. Instantiating the Oscillator without the UFM You can use the IO/MAX II oscillator megafunction selection in the MegaWizard® Plug-In Manager to instantiate the UFM oscillator if you intend to use this signal without using the UFM memory block. Figure9–4 shows the altufm_osc megafunction instantiation in the Quartus II software. Figure9–4. The Quartus II altufm_osc Megafunction This megafunction is in the I/O folder on page 2a of the MegaWizard® Plug-In Manager, as shown in Figure9–5. You can start the MegaWizard Plug-In Manager on the Tools menu. © October 2008 Altera Corporation MAX II Device Handbook
9–8 Chapter 9: Using User Flash Memory in MAX II Devices UFM Functional Description Figure9–5. Selecting the altufm_osc Megafunction in the MegaWizard Plug-In Manager Figure9–6 shows page 3 of the IO/MAX II oscillator megafunction. You have an option to choose to simulate the OSC output port at its maximum or minimum frequency during the design simulation. The frequency chosen is only used as a timing parameter simulation and does not affect the real MAX II device OSC output frequency. Figure9–6. Page 3 of the OSC Megafunction MegaWizard Plug-In Manager MAX II Device Handbook © October 2008 Altera Corporation
Chapter 9: Using User Flash Memory in MAX II Devices 9–9 UFM Operating Modes UFM Operating Modes There are three different modes for the UFM block: ■ Read/Stream Read ■ Program (Write) ■ Erase During program, address and data can be loaded concurrently. You can manipulate the UFM interface controls as necessary to implement the specific protocol provided the UFM timing specifications are met. Figure9–7 through Figure9–10 show the control waveforms for accessing UFM in three different modes. For PROGRAM mode (Figure9–9) and ERASE mode (Figure9–10), the PROGRAM and ERASE signals are not obligated to assert immediately after loading the address and data. They can be asserted anytime after the address register and data register have been loaded. Do not assert the READ, PROGRAM, and ERASE signals or shift data and address into the UFM after entering the real-time ISP mode. You can use the RTP_BUSY signal to detect the beginning and end of real-time ISP operation and generate control logic to stop all UFM port operations. This user-generated control logic is only necessary for the altufm_none megafunction, which provides no auto-generated logic. The other interfaces for the altufm megafunction (altufm_parallel, altufm_spi, altufm_i2c) contain control logic to automatically monitor the RTP_BUSY signal and will cease operations to the UFM when a real-time ISP operation is in progress. 1 You can program the UFM and CFM blocks independently without overwriting the other block which is not programmed. The Quartus II programmer provides the options to program the UFM and CFM blocks individually or together (the entire MAX II Device). f Refer to the In-System Programmability Guidelines for MAX II Devices chapter in the MAX II Device Handbook for guidelines about using ISP and real-time ISP while utilizing the UFM block within your design. f Refer to the MAX II Architecture chapter in the MAX II Device Handbook for a complete description of the device architecture, and for the specific values of the timing parameters listed in this chapter. Read/Stream Read The three control signals, PROGRAM, ERASE, and BUSY are not required during read or stream read operation. To perform a read operation, the address register has to be loaded with the reference address where the data is or is going to be located in the UFM. The address register can be stopped from incrementing or shifting addresses from ARDin by stopping the ARCLK clock pulse. DRSHFT must be asserted low at the next rising edge of DRCLK to load the data from the UFM to the data register. To shift the bits from the register, 16 clock pulses have to be provided to read 16-bit wide data. You can use DRCLK to control the read time or disable the data register by discontinuing the DRCLK clock pulse. Figure9–7 shows the UFM control waveforms during read mode. © October 2008 Altera Corporation MAX II Device Handbook
9–10 Chapter 9: Using User Flash Memory in MAX II Devices UFM Operating Modes The UFM block can also perform stream read operation, reading continuously from the UFM using the address increment feature. Stream read mode is started by loading the base address into the address register. DRSHFT must then be asserted low at the first rising edge of DRCLK to load data into the data register from the address pointed to by the address register. DRSHFT will then assert high to shift out the 16-bit wide data with the MSB out first. Figure9–8 shows the UFM control waveforms during stream read mode. Figure9–7. UFM Read Waveforms ARShft t 9 Address Bits t t ACLK AH ASU ARClk t ADH ARDin DRShft tADS t tDCLK 16 Data Bits tDSH DRClk DSS DRDin tDCO DRDout OSC_ENA Program Erase Busy Figure9–8. UFM Stream Read Waveforms Increment Increment Address Address ARShft 9 Address Bits ARClk ARDin DRShft 16 Data Bits DRClk DRDin DRDout OSC_ENA Program Erase Busy Program To program or write to the UFM, you must first perform a sequence to load the reference address into the address register. DRSHFT must then be asserted high to load the data serially into the data register starting with the MSB. Loading an address into the address register and loading data into the data register can be done concurrently. After the 16 bits of data have been successfully shifted into the data register, the PROGRAM signal must be asserted high to start writing to the UFM. On the rising edge, the data currently in the data register is written to the location currently in the address register. The BUSY signal is asserted until the program sequence is completed. The MAX II Device Handbook © October 2008 Altera Corporation
Chapter 9: Using User Flash Memory in MAX II Devices 9–11 UFM Operating Modes data and address register should not be modified until the BUSY signal is de-asserted, or the flash content will be corrupted. The PROGRAM signal is ignored if the BUSY signal is asserted. When the PROGRAM signal is applied at exactly the same time as the ERASE signal, the behavior is undefined and the contents of flash is corrupted. Figure9–9 shows the UFM waveforms during program mode. Figure9–9. UFM Program Waveforms ARShft tASU tAC9LK Address Bits tAH ARClk t ADH ARDin t DRShft ADS 16 Data Bits tDSS tDCLK tDSH DRClk DRDin t DDH t DRDout DDS t t OSCS OSCH OSC_ENA Program Erase tPB tBP Busy t PPMX Erase The ERASE signal initiates an erase sequence to erase one sector of the UFM. The data register is not needed to perform an erase sequence. To indicate the sector of the UFM to be erased, the MSB of the address register should be loaded with 0 to erase the UFM sector 0, or 1 to erase the UFM sector 1 (Figure9–2 on page9–5). On a rising edge of the ERASE signal, the memory sector indicated by the MSB of the address register will be erased. The BUSY signal is asserted until the erase sequence is completed. The address register should not be modified until the BUSY signal is de- asserted to prevent the content of the flash from being corrupted. This ERASE signal will be ignored when the BUSY signal is asserted. Figure9–10 illustrates the UFM waveforms during erase mode. 1 When the UFM sector is erased, it has 16-bit locations all filled with FFFF. Each UFM storage bit can be programmed no more than once between erase sequences. You can write to any word up to two times as long as the second programming attempt at that location only adds 0s. 1s are mask bits for your input word that cannot overwrite 0s in the flash array. New 1s in the location can only be achieved by an erase. Therefore, it is possible for you to perform byte writes since the UFM array is 16 bits for each location. © October 2008 Altera Corporation MAX II Device Handbook
9–12 Chapter 9: Using User Flash Memory in MAX II Devices Programming and Reading the UFM with JTAG Figure9–10. UFM Erase Waveforms ARShft tASU tACLK 9 Address Bits tAH ARClk t ADH ARDin DRShft tADS DRClk DRDin DRDout OSC_ENA t OSCS t Program OSCH Erase Busy tEB tBE t EPMX Programming and Reading the UFM with JTAG In Altera MAX II devices, you can write or read data to/from the UFM using the IEEE Std. 1149.1 JTAG interface. You can use a PC or UNIX workstation, the Quartus II Programmer, and the ByteBlasterTM MV or ByteBlasterTM II parallel port download cable to download Programmer Object File (.pof), JamTM Standard Test and Programming Language (STAPL) Files (.jam), or Jam Byte-Code Files (.jbc) from the Quartus II software targeting the MAX II device UFM block. 1 The POF, Jam File, or JBC File can be generated using the Quartus II software. Jam Files Both Jam STAPL and JBC files support programming for the UFM block. Jam Players Jam Players read the descriptive information in Jam files and translate them into data that programs the target device. Jam Players do not program a particular device architecture or vendor; they only read and understand the syntax defined by the Jam file specification. In-field changes are confined to the Jam file, not the Jam Player. As a result, you do not need to modify the Jam Player source code for each in-field upgrade. There are two types of Jam Players to accommodate the two types of Jam files: an ASCII Jam STAPL Player and a Jam STAPL Byte-Code Player. Both ASCII Jam STAPL Player and Jam STAPL Byte-Code Player are coded in the C programming language for 16-bit and 32-bit processors. f For guidelines on UFM operation during ISP, refer to the In-System Programmability Guidelines for MAX II Devices chapter in the MAX II Device Handbook. MAX II Device Handbook © October 2008 Altera Corporation
Chapter 9: Using User Flash Memory in MAX II Devices 9–13 Software Support for UFM Block Software Support for UFM Block The Altera Quartus II software includes sophisticated tools that fully utilize the advantages of UFM block in MAX II device, while maintaining simple, easy-to-use procedures that accelerate the design process. The following section describes how the altufm megafunction supports a simple design methodology for instantiating standard interface protocols for the UFM block, such as: ■ I2C ■ SPI ■ Parallel ■ None (Altera Serial Interface) This section includes the megafunction symbol, the input and output ports, a description of the MegaWizard Plug-In Manager options, and example MegaWizard screen shots. Refer to Quartus II Help for the altufm megafunction AHDL functional prototypes (applicable to Verilog HDL), VHDL component declaration, and parameter descriptions. Figure9–11 shows altufm megafunction selection (Flash Memory) in the MegaWizard Plug-In Manager. This megafunction is in the memory compiler directory on page 2a of the MegaWizard Plug-In Manager. You can start the MegaWizard Plug-In Manager on the Tools menu. Figure9–11. altufm Megafunction Selection in the MegaWizard Plug-In Manager The altufm MegaWizard Plug-In Manager has separate pages that apply to the MAX II UFM block. During compilation, the Quartus II Compiler verifies the altufm parameters selected against the available logic array interface options, and any specific assignments. © October 2008 Altera Corporation MAX II Device Handbook
9–14 Chapter 9: Using User Flash Memory in MAX II Devices Software Support for UFM Block Inter-Integrated Circuit Inter-Integrated Circuit (I2C) is a bidirectional two-wire interface protocol, requiring only two bus lines; a serial data/address line (SDA), and a serial clock line (SCL). Each device connected to the I2C bus is software addressable by a unique address. The I2C bus is a multi-master bus where more than one integrated circuit (IC) capable of initiating a data transfer can be connected to it, which allows masters to function as transmitters or receivers. The altufm_i2c megafunction features a serial, 8-bit bidirectional data transfer up to 100 Kbits per second. With the altufm_i2c megafunction, the MAX II UFM and logic can be configured as a slave device for the I2C bus. The altufm megafunction’s I2C interface is designed to function similar to I2C serial EEPROMs. The Quartus II software supports three different memory sizes: ■ (128 × 8) 1 Kbits ■ (256 × 8) 2 Kbits ■ (512 × 8) 4 Kbits ■ (1,024 × 8) 8 Kbits I2C Protocol The following defines the characteristics of the I2C bus protocol: ■ Only two bus lines are required: SDA and SCL. Both SDA and SCL are bidirectional lines which remain high when the bus is free. ■ Data transfer can be initiated only when the bus is free. ■ The data on the SDA line must be stable during the high period of the clock. The high or low state of the data line can only change when the clock signal on the SCL line is low. ■ Any transition on the SDA line while the SCL is high is one such unique case which indicates a start or stop condition. Table9–5 summarizes the altufm_i2c megafunction input and output interface signals. Table9–5. altufm_i2c Interface Signals Pin Description Function SDA Serial Data/Address Line The bidirectional SDA port is used to transmit and receive serial data from the UFM. The output stage of the SDA port is configured as an open drain pin to perform the wired-AND function. SCL Serial Clock Line The bidirectional SCL port is used to synchronize the serial data transfer to and from the UFM. The output stage of the SCL port is configured as an open drain pin to perform a wired-AND function. WP Write Protect Optional active high signal that disables the erase and write function for read/write mode. The altufm_i2c megafunction gives you an option to protect the entire UFM memory or only the upper half of memory. A, A, A Slave Address Input These inputs set the UFM slave address. The A, A, A, A slave address bits 2 1 0 6 5 4 3 are programmable, set internally to 1010 by default. MAX II Device Handbook © October 2008 Altera Corporation
Chapter 9: Using User Flash Memory in MAX II Devices 9–15 Software Support for UFM Block START and STOP Condition The master always generates start (S) and stop (P) conditions. After the start condition, the bus is considered busy. Only a stop (P) condition frees the bus. The bus stays busy if the repeated start (Sr) condition is executed instead of a stop condition. In this occurrence, the start (S) and repeated start (Sr) conditions are functionally identical. A high-to-low transition on the SDA line while the SCL is high indicates a start condition. A low-to-high transition on the SDA line while the SCL is high indicates a stop condition. Figure9–12 shows the start and stop conditions. Figure9–12. Start and Stop Conditions SDA SDA SCL SCL S P Start Condition Stop Condition Acknowledge Acknowledged data transfer is a requirement of I2C. The master must generate a clock pulse to signify the acknowledge bit. The transmitter releases the SDA line (high) during the acknowledge clock pulse. The receiver (slave) must pull the SDA line low during the acknowledge clock pulse so that SDA remains a stable low during the clock high period, indicating positive acknowledgement from the receiver. If the receiver pulls the SDA line high during the acknowledge clock pulse, the receiver sends a not-acknowledge condition indicating that it is unable to process the last byte of data. If the receiver is busy (for example, executing an internally-timed erase or write operation), it will not acknowledge any new data transfer. Figure9–13 shows the acknowledge condition on the I2C bus. Figure9–13. Acknowledge on the I2C Bus Data Output By Transmitter Not Acknowledge Data Output By Receiver Acknowledge SCL From Master S Clock Pulse For Start Condition Acknowledgement © October 2008 Altera Corporation MAX II Device Handbook
9–16 Chapter 9: Using User Flash Memory in MAX II Devices Software Support for UFM Block Device Addressing After the start condition, the master sends the address of the particular slave device it is requesting. The four most significant bits (MSBs) of the 8-bit slave address are usually fixed while the next three significant bits (A, A, A) are device address bits 2 1 0 and define which device the master is accessing. The last bit of the slave address specifies whether a read or write operation is to be performed. When this bit is set to 1, a read operation is selected. When this bit is set to 0, a write operation is selected. The four MSBs of the slave address (A , A, A, A) are programmable and can be 6 5 4 3 defined on page 3 of the altufm MegaWizard Plug-In Manager. The default value for these four MSBs is 1010. The next three significant bits are defined using the three A, 2 A, A input ports of the altufm_i2c megafunction. You can connect these ports to 1 0 input pins in the design file and connect them to switches on the board. The other option is to connect them to V and GND primitives in the design file, which CC conserves pins. Figure9–14 shows the slave address bits. Figure9–14. Slave Address Bits MSB LSB 1- or 2-Kbit Memory Size 1 0 1 0 A2 A1 A0 R/W MSB LSB 4-Kbit Memory Size (1) 1 0 1 0 A2 A1 a8 R/W MSB LSB 8-Kbit Memory Size (2) 1 0 1 0 A2 a9 a8 R/W Notes to Figure9–14: (1) For the 4-Kbit memory size, the A location in the slave address becomes the MSB (a8) of the memory byte address. 0 (2) For the 8-Kbit memory size, the A location in the slave address becomes a8 of the memory byte address, while the 0 A location in the slave address becomes the MSB (a9) of the memory byte address. 1 After the master sends a start condition and the slave address byte, the altufm_i2c logic monitors the bus and responds with an acknowledge (on the SDA line) when its address matches the transmitted slave address. The altufm_i2c megafunction then performs a read or write operation to/from the UFM, depending on the state of the bit. Byte Write Operation The master initiates a transfer by generating a start condition, then sending the correct slave address (with the R/W bit set to 0) to the slave. If the slave address matches, the altufm_i2c slave acknowledges on the ninth clock pulse. The master then transfers an 8-bit byte address to the UFM, which acknowledges the reception of the address. The master transfers the 8-bit data to be written to the UFM. Once the altufm_i2c logic acknowledges the reception of the 8-bit data, the master generates a stop condition. The internal write from the MAX II logic array to the UFM begins only after the master generates a stop condition. While the UFM internal write cycle is in progress, the altufm_i2c logic ignores any attempt made by the master to initiate a new transfer. Figure9–15 shows the Byte Write sequence. MAX II Device Handbook © October 2008 Altera Corporation
Chapter 9: Using User Flash Memory in MAX II Devices 9–17 Software Support for UFM Block Figure9–15. Byte Write Sequence S Slave Address R/W A Byte Address A Data A P S – Start Condition "0" (write) From Master to Slave P – Stop Condition A – Acknowledge From Slave to Master Page Write Operation Page write operation has a similar sequence as the byte write operation, except that a number of bytes of data are transmitted in sequence before the master issues a stop condition. The internal write from the MAX II logic array to the UFM begins only after the master generates a stop condition. While the UFM internal write cycle is in progress, the altufm_i2c logic ignores any attempt made by the master to initiate a new transfer. The altufm_i2c megafunction allows you to choose the page size of 8 bytes, 16 bytes, or 32 bytes for the page write operation, as shown in Figure9–24 on page9–24. A write operation is only possible on an erased UFM block or word location. The UFM block differs from serial EEPROMs, requiring an erase operation prior to writing new data in the UFM block. A special erase sequence is required, as discussed in “Erase Operation” on page9–18. Acknowledge Polling The master can detect whether the internal write cycle is completed by polling for an acknowledgement from the slave. The master can resend the start condition together with the slave address as soon as the byte write sequence is finished. The slave does not acknowledge if the internal write cycle is still in progress. The master can repeat the acknowledge polling and can proceed with the next instruction after the slave acknowledges. Write Protection The altufm_i2c megafunction includes an optional Write Protection (WP) port available on page 4 of the altufm MegaWizard Plug-In Manager (see Figure9–24 on page9–24). In the MegaWizard Plug-In Manager, you can choose the WP port to protect either the full or upper half memory. When WP is set to 1, the upper half or the entire memory array (depending on the write protection level selected) is protected, and the write and erase operation is not allowed. In this case the altufm_i2c megafunction acknowledges the slave address and memory address. After the master transfers the first data byte, the altufm_i2c megafunction sends a not-acknowledge condition to the master to indicate that the instruction will not execute. When WP is set to 0, the write and erase operations are allowed. © October 2008 Altera Corporation MAX II Device Handbook
9–18 Chapter 9: Using User Flash Memory in MAX II Devices Software Support for UFM Block Erase Operation Commercial serial EEPROMs automatically erase each byte of memory before writing into that particular memory location during a write operation. However, the MAX II UFM block is flash based and only supports sector erase operations and not byte erase operations. When using read/write mode, a sector or full memory erase operation is required before writing new data into any location that previously contained data. The block cannot be erased when the altufm_i2c megafunction is in read-only mode. Data can be initialized into memory for read/write and read-only modes by including a memory initialization file (.mif) or hexidecimal file (.hex) in the altufm MegaWizard Plug-In Manager. This data is automatically written into the UFM during device programming by the Quartus II software or third-party programming tool. The altufm_i2c megafunction supports four different erase operation methods shown on page 4 of the altufm MegaWizard Plug-In Manager: ■ Full Erase (Device Slave Address Triggered) ■ Sector Erase (Byte Address Triggered) ■ Sector Erase (A Triggered) 2 ■ No Erase These erase options only work as described if that particular option is selected in the MegaWizard Plug-In Manager before compiling the design files and programming the device. Only one option is possible for the altufm_i2c megafunction. Erase options are discussed in more detail in the following sections. Full Erase (Device Slave Address Erase) The full erase option uses the A , A, A bits of the slave address to distinguish 2 1 0 between an erase or read/write operation. This slave operation decoding occurs when the master transfers the slave address to the slave after generating the start condition. If the A , A, and A slave address bits transmitted to the UFM slave equals 111 and the 2 1 0 four remaining MSBs match the rest of the slave addresses, then the Full Erase operation is selected. If the A, A, A , A A, A, and A slave address bits transmitted 6 5 4 3 2 1 0 to the UFM match its unique slave address setting, the read/write operation is selected and functions as expected. As a result, this erase option utilizes two slave addresses on the bus reserving A, A , A, A , 1, 1, 1 as the erase trigger. Both sectors of 6 5 4 3 the UFM block will be erased when the Full Erase operation is executed. This operation requires acknowledge polling. The internal UFM erase function only begins after the master generates a stop condition. Figure9–16 shows the full erase sequence triggered by using the slave address. If the memory is write-protected (WP = 1), the slave does not acknowledge the erase trigger slave address (A , A, A, A , 1, 1, 1) sent by the master. The master should then 6 5 4 3 send a stop condition to terminate the transfer. The full erase operation will not be executed. MAX II Device Handbook © October 2008 Altera Corporation
Chapter 9: Using User Flash Memory in MAX II Devices 9–19 Software Support for UFM Block Figure9–16. Full Erase Sequence Triggered Using the Slave Address Slave Address S R/W A P A6A5A4A3111 S – Start Condition '0' (write) From Master to Slave P – Stop Condition A – Acknowledge From Slave to Master Sector Erase (Byte Address Triggered) This sector erase operation is triggered by defining a 7- to 10-bit byte address for each sector depending on the memory size. The trigger address for each sector is entered on page 4 of the altufm MegaWizard Plug-In Manager, as shown in Figure9–24 on page9–24. When a write operation is executed targeting this special byte address location, the UFM sector that contains that byte address location is erased. This sector erase operation is automatically followed by a write of the intended write byte to that address. The default byte address location for UFM Sector 0 erase is address 0x00. The default byte address location for UFM Sector 1 erase is [(selected memory size)/2]. You can specify another byte location as the trigger-erase addresses for each sector. This sector erase operation supports up to eight UFM blocks or serial EEPROMs on the I2C bus. This sector erase operation requires acknowledge polling. Sector Erase (A Triggered) 2 This sector erase operation uses the received A slave address bit to distinguish 2 between an erase or read/write operation. This slave operation decoding occurs when the master transmits the slave address after generating the start condition. If the A bit 2 received by the UFM slave is 1, the sector erase operation is selected. If the A bit 2 received is 0, the read/write operation is selected. While this reserves the A bit as an 2 erase or read/write operation bit, the A and A bits still act as slave address bits to 0 1 address the UFM. With this erase option, there can be up to four UFM slaves cascaded on the bus for 1-Kbit and 2-Kbit memory sizes. Only two UFM slaves can be cascaded on the bus for 4-Kbit memory size, since A of the slave address becomes the ninth bit 0 (MSB) of the byte address. After the slave acknowledges the slave address and its erase or read/write operation bit, the master can transfer any byte address within the sector that must be erased. The internal UFM sector erase operation only begins after the master generates a stop condition. Figure9–17 shows the sector erase sequence using the A bit of the slave address. 2 Figure9–17. Sector Erase Sequence Indicated Using the A Bit of the Slave Address 2 Slave Address S R/W A Byte Address A P A2 = '1' S – Start Condition '0' (write)(1) From Master to Slave P – Stop Condition A – Acknowledge From Slave to Master Note to Figure9–17: (1) A = 0 indicates a read/write operation is executed in place of an erase. In this case, the R/W bit determines whether 2 it is a read or write operation. © October 2008 Altera Corporation MAX II Device Handbook
9–20 Chapter 9: Using User Flash Memory in MAX II Devices Software Support for UFM Block If the altufm_i2c megafunction is write-protected (WP=1), the slave does not acknowledge the byte address (which indicates the UFM sector to be erased) sent in by the master. The master should then send a stop condition to terminate the transfer and the sector erase operation will not be executed. No Erase The no erase operation never erases the UFM contents. This method is recommended when UFM does not require constant re-writing after its initial write of data. For example, if the UFM data is to be initialized with data during manufacturing using I2C, you may not require writing to the UFM again. In that case, you should use the no erase option and save logic element (LE) resources from being used to create erase logic. Read Operation The read operation is initiated in the same manner as the write operation except that the R/W bit must be set to 1. Three different read operations are supported: ■ Current Address Read (Single Byte) ■ Random Address Read (Single byte) ■ Sequential Read (Multi-Byte) After each UFM data has been read and transferred to the master, the UFM address register is incremented for all single and multi-byte read operations. Current Address Read This read operation targets the current byte location pointed to by the UFM address register. Figure9–18 shows the current address read sequence. Figure9–18. Current Address Read Sequence S Slave Address R/W A Data P ‘1’ (read) S – Start Condition From Master to Slave P – Stop Condition A – Acknowledge From Slave to Master Random Address Read Random address read operation allows the master to select any byte location for a read operation. The master first performs a “dummy” write operation by sending the start condition, slave address, and byte address of the location it wishes to read. After the altufm_i2c megafunction acknowledges the slave and byte address, the master generates a repeated start condition, the slave address, and the R/W bit is set to 1. The altufm_i2c megafunction then responds with acknowledge and sends the 8-bit data requested. The master then generates a stop condition. Figure9–19 shows the random address read sequence. MAX II Device Handbook © October 2008 Altera Corporation
Chapter 9: Using User Flash Memory in MAX II Devices 9–21 Software Support for UFM Block Figure9–19. Random Address Read Sequence Slave Byte Slave S Address R/W A Address A Sr Address R/W A Data P ‘0’ (write) ‘1’ (read) S – Start Condition From Master to Slave Sr – Repeated Start P – Stop Condition From Slave to Master A – Acknowledge Sequential Read Sequential read operation can be initiated by either the current address read operation or the random address read operation. Instead of sending a stop condition after the Slave has transmitted one byte of data to the master, the master acknowledges that byte and sends additional clock pulses (on SCL line) for the slave to transmit data bytes from consecutive byte addresses. The operation is terminated when the master generates a stop condition instead of responding with an acknowledge. Figure9–20 shows the sequential read sequence. Figure9–20. Sequential Read Sequence Slave Byte Slave S Address R/W A Address A Sr Address R/W A Data A … Data P ‘0’ (write) ‘1’ (read) Data (n - bytes) + Acknowledgment (n - 1 bytes) S – Start Condition From Master to Slave Sr – Repeated Start P – Stop Condition From Slave to Master A – Acknowledge © October 2008 Altera Corporation MAX II Device Handbook
9–22 Chapter 9: Using User Flash Memory in MAX II Devices Software Support for UFM Block ALTUFM I2C Interface Timing Specification Figure9–21 shows the timing waveform for the altufm_i2c megafunction read/write mode. Figure9–21. Timing Waveform for the altufm_i2c Megafunction SDA tSU:STA tHD:STA tHD:DAT tSU:DAT tSU:STO tBUF tSCLSDA SCL tHIGH tLOW Table9–6 through Table9–8 list the timing specification needed for the altufm_i2c megafunction read/write mode. Table9–6. I2C Interface Timing Specification Symbol Parameter Min Max Unit F SCL clock frequency — 100 kHz SCL t SCL going low to SDA data out — 15 ns SCL:SDA t Bus free time between a stop and start condition 4.7 — µs BUF t (Repeated) start condition hold time 4 — µs HD:STA t (Repeated) start condition setup time 4.7 — µs SU:STA t SCL clock low period 4.7 — µs LOW t SCL clock high period 4 — µs HIGH t SDA data in hold time 0 — ns HD:DAT t SDA data in setup time 20 — ns SU:DAT t STOP condition setup time 4 — ns SU:STO Table9–7. UFM Write Cycle Time Parameter Min Max Unit Write Cycle Time — 110 µs Table9–8. UFM Erase Cycle Time Parameter Min Max Unit Sector Erase — 501 ms Cycle Time Full Erase Cycle — 1,002 ms Time Instantiating the I2C Interface Using the Quartus II altufm Megafunction Figure9–22 shows the altufm megafunction symbol for a I2C interface instantiation in the Quartus II software. MAX II Device Handbook © October 2008 Altera Corporation
Chapter 9: Using User Flash Memory in MAX II Devices 9–23 Software Support for UFM Block Figure9–22. altufm Megafunction Symbol For the I2C Interface Instantiation in the Quartus II Software Figure9–23 shows page 3 of the altufm MegaWizard Plug-In Manager when selecting I2C as the interface. On this page, you can choose whether to implement the read/write mode or read-only mode for the UFM. You also have an option to choose the memory size for the altufm_i2c megafunction as well as defining the four MSBs of the slave address (default 1010). Figure9–23. Page 3 of the altufm MegaWizard Plug-In Manager (I2C) 1 The UFM block’s internal oscillator is always running when the altufm_i2c megafunction is instantiated for both read-only and read/write interfaces. Figure9–24 shows page 4 of the altufm MegaWizard Plug-In Manager. You can select the optional write protection and erase operation methods on this page. © October 2008 Altera Corporation MAX II Device Handbook
9–24 Chapter 9: Using User Flash Memory in MAX II Devices Software Support for UFM Block Figure9–24. Page 4 of the altufm MegaWizard Plug-In Manager (I2C) Serial Peripheral Interface Serial peripheral interface (SPI) is a four-pin serial communication subsystem included on the Motorola 6805 and 68HC11 series microcontrollers. It allows the microcontroller unit to communicate with peripheral devices, and is also capable of inter-processor communications in a multiple-master system. The SPI bus consists of masters and slaves. The master device initiates and controls the data transfers and provides the clock signal for synchronization. The slave device responds to the data transfer request from the master device. The master device in an SPI bus initiates a service request with the slave devices responding to the service request. With the altufm megafunction, the UFM and MAX II logic can be configured as a slave device for the SPI bus. The OSC_ENA is always asserted to enable the internal oscillator when the SPI megafunction is instantiated for both read only and read/write interfaces. The Quartus II software supports both the Base mode (which uses 8-bit address and data) and the Extended mode (which uses 16-bit address and data). Base mode uses only UFM sector 0 (2,048 bits), whereas Extended mode uses both UFM sector 0 and sector 1 (8,192 bits). There are only four pins in SPI: SI, SO, SCK, and nCS. Table9–9 describes the SPI pins and functions. MAX II Device Handbook © October 2008 Altera Corporation
Chapter 9: Using User Flash Memory in MAX II Devices 9–25 Software Support for UFM Block Table9–9. SPI Interface Signals Pin Description Function SI Serial Data Input Receive data serially. SO Serial Data Output Transmit data serially. SCK Serial Data Clock The clock signal produced from the master device to synchronize the data transfer. nCS Chip Select Active low signal that enables the slave device to receive or transfer data from the master device. Data transmitted to the SI port of the slave device is sampled by the slave device at the positive SCK clock. Data transmits from the slave device through SO at the negative SCK clock edge. When nCS is asserted, it means the current device is being selected by the master device from the other end of the SPI bus for service. When nCS is not asserted, the SI and SCK ports should be blocked from receiving signals from the master device, and SO should be in High Impedance state to avoid causing contention on the shared SPI bus. All instructions, addresses, and data are transferred with the MSB first and start with high-to-low nCS transition. The circuit diagram is shown in Figure9–25. Figure9–25. Circuit Diagram for SPI Interface Read or Write Operations SI SO SCK nCS Op-Code Decoder Read, Write, and Erase State Machine SPI Interface UFM Block Control Logic Address and Data Hub Eight-Bit Status Shift Register Opcodes The 8-bit instruction opcode is shown in Table9–10. After nCS is pulled low, the indicated opcode must be provided. Otherwise, the interface assumes that the master device has internal logic errors and ignores the rest of the incoming signals. Once nCS is pulled back to high, the interface is back to normal. nCS should be pulled low again for a new service request. © October 2008 Altera Corporation MAX II Device Handbook
9–26 Chapter 9: Using User Flash Memory in MAX II Devices Software Support for UFM Block Table9–10. Instruction Set for SPI Name Opcode Operation WREN 00000110 Enable Write to UFM WRDI 00000100 Disable Write to UFM RDSR 00000101 Read Status Register WRSR 00000001 Write Status Register READ 00000011 Read data from UFM WRITE 00000010 Write data to UFM SECTOR-ERASE 00100000 Sector erase UFM-ERASE 01100000 Erase the entire UFM block (both sectors) The READ and WRITE opcodes are instructions for transmission, which means the data will be read from or written to the UFM. WREN, WRDI, RDSR, and WRSR are instructions for the status register, where they do not have any direct interaction with UFM, but read or set the status register within the interface logic. The status register provides status on whether the UFM block is available for any READ or WRITE operation, whether the interface is WRITE enabled, and the state of the UFM WRITE protection. The status register format is shown in Table9–11. For the read only implementation of ALTUFM SPI (Base or Extended mode), the status register does not exist, saving LE resources. Table9–11. Status Register Format Position Status Default at Power-Up Description Bit 7 X 0 — Bit 6 X 0 — Bit 5 X 0 — Bit 4 X 0 — Bit 3 BP1 0 Indicate the current level of block write protection (1) Bit 2 BP0 0 Indicate the current level of block write protection (1) Bit 1 WEN 0 1= SPI WRITE enabled state 0= SPI WRITE disabled state Bit 0 nRDY 0 1 = Busy, UFM WRITE or ERASE cycle in progress 0 = No UFM WRITE or ERASE cycle in progress Note to Table9–11: (1) Refer to Table9–12 and Table9–13 for more information about status register bits BPI and BPO. The following paragraphs describe the instructions for SPI. READ READ is the instruction for data transmission, where the data is read from the UFM block. When data transfer is taking place, the MSB is always the first bit to be transmitted or received. The data output stream is continuous through all addresses until it is terminated by a low-to-high transition at the nCS port. The READ operation is always performed through the following sequence in SPI, as shown in Figure9–26: MAX II Device Handbook © October 2008 Altera Corporation
Chapter 9: Using User Flash Memory in MAX II Devices 9–27 Software Support for UFM Block 1. nCS is pulled low to indicate the start of transmission. 2. An 8-bit READ opcode (00000011) is received from the master device. (If internal programming is in progress, READ is ignored and not accepted). 3. A 16-bit address is received from the master device. The LSB of the address is received last. As the UFM block can take only nine bits of address maximum, the first seven address bits received are discarded. 4. Data is transmitted for as many words as needed by the slave device through SO for READ operation. When the end of the UFM storage array is reached, the address counter rolls over to the start of the UFM to continue the READ operation. 5. nCS is pulled back to high to indicate the end of transmission. For SPI Base mode, the READ operation is always performed through the following sequence in SPI: 1. nCS is pulled low to indicate the start of transmission. 2. An 8-bit READ opcode (00000011) is received from the master device, followed by an 8-bit address. If internal programming is in progress, the READ operation is ignored and not accepted. 3. Data is transmitted for as many words as needed by the slave device through SO for READ operation. The internal address pointer automatically increments until the highest memory address is reached (address 255 only since the UFM sector 0 is used). The address counter will not roll over once address 255 is reached. The SO output is set to high-impedance (Z) once all the eight data bits from address 255 has been shifted out through the SO port. 4. nCS is pulled back to high to indicate the end of transmission. Figure9–26. READ Operation Sequence for Extended Mode nCS 0 1 2 3 4 5 6 78 9 10 11 20 2122 23 24 2526 27 36 3738 39 SCK 8-bit 16-bit Instruction Address SI 03 H MSB MSB High Impendance SO 16-bit Data Out 1 16-bit Data Out 2 MSB MSB © October 2008 Altera Corporation MAX II Device Handbook
9–28 Chapter 9: Using User Flash Memory in MAX II Devices Software Support for UFM Block Figure9–27 shows the READ operation sequence for Base mode. Figure9–27. READ Operation for Base Mode nCS 1 2 3 4 5 6 7 8 9 10 111213 1415 16 171819 20 21222323 SCK 8-bit 8-bit Instruction Instruction SI 03 H MSB MSB High Impendance SO 8-bit Data Out 1 8-bit Data Out 2 MSB MSB WRITE WRITE is the instruction for data transmission, where the data is written to the UFM block. The targeted location in the UFM block that will be written must be in the erased state (FFFF ) before initiating a WRITE operation. When data transfer is taking H place, the MSB is always the first bit to be transmitted or received. nCS must be driven high before the instruction is executed internally. You may poll the nRDY bit in the software status register for the completion of the internal self-timed WRITE cycle. For SPI Extended mode, the WRITE operation is always done through the following sequence, as shown in Figure9–28: 1. nCS is pulled low to indicate the start of transmission. 2. An 8-bit WRITE opcode (00000010) is received from the master device. If internal programming is in progress, the WRITE operation is ignored and not accepted. 3. A 16-bit address is received from the master device. The LSB of the address will be received last. As the UFM block can take only nine bits of address maximum, the first seven address bits received are discarded. 4. A check is carried out on the status register (see Table9–11) to determine if the WRITE operation has been enabled, and the address is outside of the protected region; otherwise, Step 5 is bypassed. 5. One word (16 bits) of data is transmitted to the slave device through SI. 6. nCS is pulled back to high to indicate the end of transmission. For SPI Base mode, the WRITE operation is always performed through the following sequence in SPI: 1. nCS is pulled low to indicate the start of transmission. 2. An 8-bit WRITE opcode (00000010) is received. If the internal programming is in progress, the WRITE operation is ignored and not accepted. 3. An 8-bit address is received. A check is carried out on the status register (see Table9–11) to determine if the WRITE operation has been enabled, and the address is outside of the protected region; otherwise, Step 4 is skipped. MAX II Device Handbook © October 2008 Altera Corporation
Chapter 9: Using User Flash Memory in MAX II Devices 9–29 Software Support for UFM Block 4. An 8-bit data is transmitted through SI. 5. nCS is pulled back to high to indicate the end of transmission. Figure9–28. WRITE Operation Sequence for Extended Mode nCS 1 2 3 4 5 6 7 8 9 10 111213 1415 16 171819 20 21222323 SCK 8-bit 8-bit Instruction Instruction SI 03 H MSB MSB High Impendance SO 8-bit Data Out 1 8-bit Data Out 2 MSB MSB Figure9–29 shows the WRITE operation sequence for Base mode. Figure9–29. WRITE Operation Sequence for Base Mode nCS 0 1 2 3 4 5 6 78 9 10 1112 1314 15 16 1718 19 20 2122 23 SCK 8-bit 8-bit Instruction Address SI 02H 8-bit Data In MSB MSB High Impendance SO SECTOR-ERASE SECTOR-ERASE is the instruction of erasing one sector of the UFM block. Each sector contains 256 words. WEN bit and the sector must not be protected for SE operation to be successful. nCS must be driven high before the instruction is executed internally. You may poll the nRDY bit in the software status register for the completion of the internal self-timed SECTOR-ERASE cycle. For SPI Extended mode, the SE operation is performed in the following sequence, as shown in Figure9–30: 1. nCS is pulled low. 2. Opcode 00100000 is transmitted into the interface. 3. The 16-bit address is sent. The eighth bit (the first seven bits will be discarded) of the address indicates which sector is erased; a 0 means sector 0 (UFM0) is erased, and a 1 means sector 1 (UFM1) is erased. © October 2008 Altera Corporation MAX II Device Handbook
9–30 Chapter 9: Using User Flash Memory in MAX II Devices Software Support for UFM Block 4. nCS is pulled back to high. For SPI Base mode, the SE instruction erases UFM sector 0. As there are no choices of UFM sectors to be erased, there is no address component to this instruction. The SE operation is always done through the following sequence in SPI Base mode: 1. nCS is pulled low. 2. Opcode 00100000 is transmitted into the interface. 3. nCS is pulled back to high. Figure9–30. SECTOR-ERASE Operation Sequence for Extended Mode nCS 0 1 2 3 4 5 6 78 9 10 11 20 2122 23 SCK 8-bit 16-bit Instruction Address SI 20H MSB MSB High Impendance SO Figure9–31 shows the SECTOR-ERASE operation sequence for Base mode. Figure9–31. Sector_ERASE Operation Sequence for Base Mode nCS 0 1 2 3 4 5 6 7 SCK 8-bit Instruction SI 20 H MSB High Impendance SO MAX II Device Handbook © October 2008 Altera Corporation
Chapter 9: Using User Flash Memory in MAX II Devices 9–31 Software Support for UFM Block UFM-ERASE The UFM-ERASE (CE) instruction erases both UFM sector 0 and sector 1 for SPI Extended Mode. While for SPI Base mode, the CE instruction has the same functionality as the SECTOR-ERASE (SE) instruction, which erases UFM sector 0 only. WEN bit and the UFM sectors must not be protected for CE operation to be successful. nCS must be driven high before the instruction is executed internally. You may poll the nRDY bit in the software status register for the completion of the internal self- timed CE cycle. For both SPI Extended mode and Base mode, the UFM-ERASE operation is performed in the following sequence as shown in Figure9–32: 1. nCS is pulled low. 2. Opcode 01100000 is transmitted into the interface. 3. nCS is pulled back to high. Figure9–32 shows the UFM-ERASE operation sequence. Figure9–32. UFM-ERASE Operation Sequence nCS 0 1 2 3 4 5 6 7 SCK 8-bit Instruction SI 60 H MSB High Impendance SO WREN (Write Enable) The interface is powered-up in the write disable state. Therefore, WEN in the status register (see Table9–11) is 0 at power-up. Before any write is allowed to take place, WREN must be issued to set WEN in the status register to 1. If the interface is in read- only mode, WREN does not have any effect on WEN, since the status register does not exist. Once the WEN is set to 1, it can be reset by the WRDI instruction; the WRITE and SECTOR-ERASE instruction will not reset the WEN bit. WREN is issued through the following sequence, as shown in Figure9–33: 1. nCS is pulled low. 2. Opcode 00000110 is transmitted into the interface to set WEN to 1 in the status register. 3. After the transmission of the eighth bit of WREN, the interface is in wait state (waiting for nCS to be pulled back to high). Any transmission after this is ignored. 4. nCS is pulled back to high. © October 2008 Altera Corporation MAX II Device Handbook
9–32 Chapter 9: Using User Flash Memory in MAX II Devices Software Support for UFM Block Figure9–33. WREN Operation Sequence nCS 0 1 2 3 4 5 6 7 SCK 8-bit Instruction SI 06H MSB High Impendance SO WRDI (Write Disable) After the UFM is programmed, WRDI can be issued to set WEN back to 0, disabling WRITE and preventing inadvertent writing to the UFM. WRDI is issued through the following sequence, as shown in Figure9–34: 1. nCS is pulled low. 2. Opcode 00000100 is transmitted to set WEN to 0 in the status register. 3. After the transmission of the eighth bit of WRDI, the interface is in wait state (waiting for nCS to be pulled back to high). Any transmission after this is ignored. 4. nCS is pulled back to high. Figure9–34. WRDI Operation Sequence nCS 0 1 2 3 4 5 6 7 SCK 8-bit Instruction SI 04H MSB High Impendance SO RDSR (Read Status Register) The content of the status register can be read by issuing RDSR. Once RDSR is received, the interface outputs the content of the status register through the SO port. Although the most significant four bits (Bit 7 to Bit 4) do not hold valuable information, all eight bits in the status register will output through the SO port. This allows future compatibility when Bit 7 to Bit 4 have new meaning in the status register. During the MAX II Device Handbook © October 2008 Altera Corporation
Chapter 9: Using User Flash Memory in MAX II Devices 9–33 Software Support for UFM Block internal program cycle in the UFM, RDSR is the only valid opcode recognized by the interface (therefore, the status register can be read at any time), and nRDY is the only valid status bit. Other status bits are frozen and remain unchanged until the internal program cycle is ended. RDSR is issued through the following sequence, as shown in Figure9–35: 1. nCS is pulled low. 2. Opcode 00000101 is transmitted into the interface. 3. SI ignores incoming signals; SO output the content of the status register, Bit 7 first and Bit 0 last. 4. If nCS is kept low, repeat step 3. 5. nCS is pulled back to high to terminate the transmission. Figure9–35. RDSR Operation Sequence nCS 0 1 2 3 4 5 6 78 9 10 11 12 1314 15 16 17 18 19 20 2122 23 SCK 8-bit Instruction SI 05 H MSB MSB High Impendance SO Status Register Out MSB MSB WRSR (Write Status Register) The block protection bits(BP1 and BP0) are the status bits used to protect certain sections of the UFM from inadvertent write. The BP1 and BP0 status are updated by WRSR. During WRSR, only BP1 and BP0 in the status register can be written with valid information. The rest of the bits in the status register are ignored and not updated. When both BP1 and BP0 are 0, there is no protection for the UFM. When both BP1 and BP0 are 1, there is full protection for the UFM. BP0 and BP1 are set to 0 upon power-up. Table9–12 describe more on the Block Write Protect Bits for Extended mode, while Table9–13 describes more on the Block Write Protect Bits for Base mode. WRSR is issued through the following sequence, as shown in Figure9–36: 1. nCS is pulled low. 2. Opcode 00000001 is transmitted into the interface. 3. An 8-bit status is transmitted into the interface to update BP1 and BP0 of the status register. 4. If nCS is pulled high too early (before all the eight bits in Step 2 or Step 3 are transmitted) or too late (the ninth bit or more is transmitted), WRSR is not executed. © October 2008 Altera Corporation MAX II Device Handbook
9–34 Chapter 9: Using User Flash Memory in MAX II Devices Software Support for UFM Block 5. nCS is pulled back to high to terminate the transmission. Figure9–36. WRSR Operation Sequence nCS 0 1 2 3 4 5 6 78 9 10 11 12 1314 15 SCK 8-bit Instruction SI 01H Status Register In MSB MSB High Impendance SO Table9–12. Block Write Protect Bits for Extended Mode Status Register Bits UFM Array Address Level BP1 BP0 Protected 0 (No protection) 0 0 None 3 (Full protection) 1 1 000 to 1FF Table9–13. Block Write Protect Bits for Base Mode Status Register Bits UFM Array Address Level BP1 BP0 Protected 0 (No protection) 0 0 None 3 (Full protection) 1 1 000 to 0FF ALTUFM SPI Timing Specification Figure9–37 shows the timing specification needed for the SPI Extended mode (read/write). These nCS timing specifications do not apply to the SPI Extended read- only mode nor any of the SPI Base modes. However, for the SPI Extended mode (read only) and the SPI Base mode (both read only and read/write), the nCS signal and SCK are not allowed to toggle at the same time. Table9–14 shows the timing parameters which only apply to the SPI Extended mode (read/write). Figure9–37. SPI Timing Waveform t HNCSHIGH nCS tSCK2NCS tNCS2SCK SCK MAX II Device Handbook © October 2008 Altera Corporation
Chapter 9: Using User Flash Memory in MAX II Devices 9–35 Software Support for UFM Block Table9–14. SPI Timing Parameters for Extended Mode Symbol Description Minimum (ns) Maximum (ns) t The time required for the SCK signal falling 50 — SCK2NCS edge to nCS signal rising edge t The time that the nCS signal must be held 600 — HNCSHIGH high t The time required for the nCS signal falling 750 — NCS2SCK edge to SCK signal rising edge Instantiating SPI Using Quartus II altufm Megafunction Figure9–38 shows the altufm megafunction symbol for SPI instantiation in the Quartus II software. Figure9–38. altufm Megafunction Symbol for SPI Instantiation You can select the desired logic array interface on page 3 of the altufm MegaWizard® Plug-In Manager. Figure9–39 shows page 3 of the altufm MegaWizard Plug-In Manager, selecting SPI as the interface protocol. On this page, you can choose whether to implement the Read/Write or Read Only mode as the access mode for the UFM. You can also select the configuration mode (Base or Extended) for SPI on this page. You can specify the initial content of the UFM block in page 4 of the altufm MegaWizard Plug-In Manager as discussed in “Creating Memory Content File” on page9–40. © October 2008 Altera Corporation MAX II Device Handbook
9–36 Chapter 9: Using User Flash Memory in MAX II Devices Software Support for UFM Block Figure9–39. Page 3 altufm MegaWizard Plug-In Manager (SPI) 1 The UFM block’s internal oscillator is always running when the altufm_spi megafunction is instantiated for read/write interface. The UFM block’s internal oscillator is disabled when the altufm_spi megafunction is instantiated for read only interface. Parallel Interface This interface allows for parallel communication between the UFM block and outside logic. Once the READ request, WRITE request, or ERASE request is asserted (active low assertion), the outside logic or device (such as a microcontroller) are free to continue their operation while the data in the UFM is retrieved, written, or erased. During this time, the nBUSY signal is driven “low” to indicate that it is not available to respond to any further request. After the operation is complete, the nBUSY signal is brought back to “high” to indicate that it is now available to service a new request. If it was the Read request, the DATA_VALID is driven “high” to indicate that the data at the DO port is the valid data from the last read address. Asserting READ, WRITE, and ERASE at the same time is not allowed. Multiple requests are ignored and nothing is read from, written to, or erased in the UFM block. There is no support for sequential read and page write in the parallel interface. For both the read only and the read/write modes of the parallel interface, OSC_ENA is always asserted, enabling the internal oscillator. Table9–15 summarizes the parallel interface pins and functions. MAX II Device Handbook © October 2008 Altera Corporation
Chapter 9: Using User Flash Memory in MAX II Devices 9–37 Software Support for UFM Block Table9–15. Parallel Interface Signals Pin Description Function DI[15:0] 16-bit data Input Receive 16-bit data in parallel. You can select an optional width of 3 to 16 bits using the altufm megafunction. DO[15:0] 16-bit data Output Transmit 16-bit data in parallel. You can select an optional width of 3 to 16 bits using the altufm megafunction. ADDR[8:0] Address Register Operation sequence refers to the data that is pointed to by the address register. You can determine the address bus width using the altufm megafunction. nREAD READ Instruction Signal Initiates a read sequence. nWRITE WRITE Instruction Signal Initiates a write sequence. nERASE ERASE Instruction Signal Initiates a SECTOR-ERASE sequence indicated by the MSB of the ADDR[] port. nBUSY BUSY Signal Driven low to notify that it is not available to respond to any further request. DATA_VALID Data Valid Driven high to indicate that the data at the DO port is the valid data from the last read address for read request. Even though the altufm megafunction allows you to select the address widths range from 3 bits to 9 bits, the UFM block always expects full 9 bits width for the address register. Therefore, the altufm megafunction will always pad the remaining LSB of the address register with '0's if the register width selected is less than 9 bits. The address register will point to sector 0 if the address received at the address register starts with a '0'. The address register will point to sector 1 if the address received starts with a '1'. Even though you can select an optional data register width of 3 to 16 bits using the altufm megafunction, the UFM block always expects full 16 bits width for the data register. Reading from the data register always proceeds from MSB to LSB. The altufm megafunction always pads the remaining LSB of the data register with 1s if the user selects a data width of less than 16-bits. ALTUFM Parallel Interface Timing Specification Figure9–40 shows the timing specifications for the parallel interface. Table9–16 parallel interface instruction signals. The nREAD, nWRITE, and nERASE signals are active low signals. © October 2008 Altera Corporation MAX II Device Handbook
9–38 Chapter 9: Using User Flash Memory in MAX II Devices Software Support for UFM Block Figure9–40. Parallel Interface Timing Waveform tCOMMAND Command tHNBUSY nBusy tHBUS Data or Address Bus Table9–16. Parallel Interface Timing Parameters Symbol Description Minimum (ns) Maximum (ns) t The time required for the command signal 600 3,000 COMMAND (nREAD/nWRITE/nERASE) to be asserted and held low to initiate a read/write/erase sequence t Maximum delay between command signal’s falling edge to the — 300 HNBUSY nBUSY signal’s falling edge t The time that data and/or address bus must be present at the data 600 — HBUS input and/or address register port after the command signal has been asserted low Instantiating Parallel Interface Using Quartus II altufm Megafunction Figure9–41 shows the altufm megafunction symbol for a parallel interface instantiation in the Quartus II software. Figure9–41. altufm Megafunction Symbol for Parallel Interface Instantiation Figure9–42 shows page 3 of the altufm MegaWizard Plug-In Manager, selecting the Parallel Interface as the interface. On this page, you can choose whether to implement the Read/Write mode or Read Only mode for the UFM. You also have an option to choose the width for address bus (up to 9 bits) and for the data bus (up to 16 bits). You can specify the initial content of the UFM block on page 4 of the altufm MegaWizard Plug-In Manager as discussed in “Creating Memory Content File” on page9–40. MAX II Device Handbook © October 2008 Altera Corporation
Chapter 9: Using User Flash Memory in MAX II Devices 9–39 Software Support for UFM Block Figure9–42. Page 3 altufm MegaWizard Plug-In Manager (Parallel) 1 The UFM block’s internal oscillator is always running when the altufm_parallel magafunction is instantiated for read/write interface. The UFM block’s internal oscillator is disabled when the altufm_parallel megafunction is instantiated for read only interface. None (Altera Serial Interface) None means using the dedicated UFM serial interface. The built-in UFM interface uses 13 pins for the communication. The functional description of the 13 pins are described in Table9–4 on page9–3. You can produce your own interface design to communicate to/from the dedicated UFM interface and implement it in the logic array. Instantiating None Using Quartus II altufm Megafunction Figure9–43 shows the altufm megafunction symbol for None instantiation in the Quartus II software. Figure9–43. altufm Megafunction Symbol for None Instantiation © October 2008 Altera Corporation MAX II Device Handbook
9–40 Chapter 9: Using User Flash Memory in MAX II Devices Creating Memory Content File Figure9–44 shows page 3 of the altufm MegaWizard Plug-In Manager, selecting none for the interface protocol. By selecting none, all the other options are grayed out or unavailable to you. However, you still can specify the initial content of the UFM block on page 4 of the altufm MegaWizard Plug-In Manager as discussed in “Creating Memory Content File” on page9–40. Figure9–44. Page 3 altufm MegaWizard Plug-In Manager (None) Creating Memory Content File You can initialize the content of the UFM through a memory content file. Quartus II software supports two types of initial memory content file format: Memory Initialization File (.mif) and Hexadecimal File (.hex). A new memory content file for the UFM block can be created by clicking New on the File menu. Select the HEX file or MIF in the Other Files tab (Figure9–45). MAX II Device Handbook © October 2008 Altera Corporation
Chapter 9: Using User Flash Memory in MAX II Devices 9–41 Creating Memory Content File Figure9–45. Create New File Dialog Box Immediately after clicking OK, a dialog box appears. In this dialog box, the Number of words represents the numbers of address lines while the Word size represents the data width. To create a memory content file for the altufm megafunction, enter 512 for the number of words and 16 for the word size, as shown in Figure9–46. Figure9–46. Number of Words and Word Size Dialog Box © October 2008 Altera Corporation MAX II Device Handbook
9–42 Chapter 9: Using User Flash Memory in MAX II Devices Creating Memory Content File Figure9–47 shows the memory content being written into a HEX file. Figure9–47. Hexadecimal (Intel-Format) File This memory content file is then included using the altufm megafunction. On the Tools menu, click MegaWizard Plug-In Manager. The memory content file (data.hex) is included on page 5 of the altufm megafunction (Figure9–48). Click Yes, and use this file for the memory content file. Click Browse to include the memory content file. MAX II Device Handbook © October 2008 Altera Corporation
Chapter 9: Using User Flash Memory in MAX II Devices 9–43 Creating Memory Content File Figure9–48. Page 4 of the altufm Megafunction Memory Initialization for the altufm_parallel Megafunction For the parallel interface, if a HEX file is used to initialize the memory content for the altufm megafunction, you have to fully specify all 16 bits in each memory address, regardless of the data width selected. If your data width is less than 16 bits wide, your data must be placed in the MSBs of the data word and the remaining LSBs must be padded with 1’s. For an example, if address_width = 3 and data_width = 8 are selected for the altufm_parallel megafunction, the HEX file should contain eight addresses of data (23 addresses), each word containing 16bits. If the initial content at the location 000 is intended to be 10101010, you should specify 1010101011111111 for address 000 in the HEX file. 1 This specification applies only to HEX files used with the parallel interface. MIFs do not require you to fully specify 16 bits for each data word. However, both MIF and HEX files require you to specify all addresses of data according to the address_width selected in the megafunction. Memory Initialization for the altufm_spi Megafunction The same 16-bit data padding mentioned for altufm_parallel is required for HEX files used with the SPI Base (8 bits) and Extended (16 bits) mode interface. In addition, for SPI Base and Extended mode, you must fully specify memory content for all 512addresses (both sector 0 and sector 1) in the HEX file and MIF, even if sector 1 is not used. You can put valid data for SPI Base mode addresses 0to255 (sector 0), and initialize sector 1 to all ones. © October 2008 Altera Corporation MAX II Device Handbook
9–44 Chapter 9: Using User Flash Memory in MAX II Devices Creating Memory Content File Memory Initialization for the altufm_i2c Megafunction The MAX II UFM physical memory block contains a 16-bit wide and 512deep (9-bit address) array. The altufm_i2c megafunction uses the following smaller array sizes: ■ An 8-bit wide and 128 deep (7-bit address) mapping for 1 Kbit memory size ■ An 8-bit wide and 256 deep (8-bit address) mapping for 2 Kbits memory size ■ An 8-bit wide and 512 deep (9-bit address) mapping for 4 Kbits memory size ■ An 8-bit wide and 1,024 deep (10-bit address) mapping for 8 Kbits memory size Altera recommends that you pad the MIF or HEX file for both address and data width to fill the physical memory map for the UFM block and ensure the MIF/HEX file represents a full 16-bit word size and a 9-bit address space. Memory Map for 1-Kbit Memory Initialization Figure9–49 shows the memory map initialization for the altufm_i2c megafunction of 1-Kbit memory size. The altufm_i2c megafunction byte address location of 00h to 3Fh is mapped to the UFM block address location of 000h to 03Fh. The altufm_i2c megafunction byte address location of 40h to 7Fh is mapped to the UFM block address location of 1C0h to 1FFh. Altera recommends that you pad the unused address locations of the UFM block with all ones. Figure9–49. Memory Map for 1-Kbit Memory Initialization MIF or HEX File Contents – to represent the actual data and address size for the UFM block 1-Kbit altufm_i2c Megafunction 1FFh Address 40h in logical memory maps to Logical Memory Contents 1C0h in the MIF/HEX file. Address 7Fh in logical memory maps to 1FFh in the MIF/HEX file, and all 7Fh data in between follows the order in the 1C0h logical memory Upper Half – Addresses 40h to 7Fh 1BFh 40h This section of the UFM is unused – the MIF/HEX file contents should be set to all '1' for addresses 040h to 1BFh 3Fh Lower Half – Addresses 00h to 3Fh 040h 03Fh Address 00h in logical memory maps to address 000h in the MIF/HEX file. Address 3Fh in 00h logical memory maps to 03Fh in the MIF/HEX file, and all data in between follows the order in the logical memory 000h Memory Map for 2-Kbit Memory Initialization Figure9–50 shows the memory map initialization for the altufm_i2c megafunction of 2 Kbits of memory. The altufm_i2c megafunction byte address location of 00h to 7Fh is mapped to the UFM block address location of 000h to 07Fh. The altufm_i2c megafunction byte address location of 80h to FFh is mapped to the UFM block address location of 180h to 1FFh. Altera recommends that you pad the unused address location of the UFM block with all ones. MAX II Device Handbook © October 2008 Altera Corporation
Chapter 9: Using User Flash Memory in MAX II Devices 9–45 Creating Memory Content File Figure9–50. Memory Map for 2-Kbit Memory Initialization MIF or HEX File Contents – to represent the actual data and address size for the UFM block 2-Kbit altufm_i2c Megafunction 1FFh Logical Memory Contents Address 80h in logical memory maps to address 180h in the MIF/HEX file. FFh in logical FFh memory maps to 1FFh in the MIF/HEX file, and all data in between follows the order in the logical memory Upper Half – Addresses 180h 80h to FFh 17Fh This section of the UFM is unused – 80h the MIF/HEX file contents should be set to all '1' for addresses 080h to 17Fh 7Fh 080h Lower Half – Addresses 00h to 7Fh 07Fh Address 00h in logical memory maps to address 000h in the MIF/HEX file. Address 7Fh in logical memory maps to 07Fh in the MIF/HEX file, 00h and all data in between follows the order in the logical memory 000h Memory Map for 4-Kbit Memory Initialization Figure9–49 shows the memory map initialization for the altufm_i2c megafunction of 4-Kbit memory. The altufm_i2c megafunction byte address location of 00h to FFh is mapped to the UFM block address location of 000h to 0FFh. The altufm_i2c megafunction byte address location of 100h to 1FFh is mapped to the UFM block address location of 100h to 1FFh. Figure9–51. Memory Map for 4-Kbit Memory Initialization 4-Kbit altufm_i2c Megafunction MIF or HEX File Contents – to represent Logical Memory Contents the data and address size for the UFM block 1FFh 1FFh Address 100h in logical memory maps to 100h in the MIF/HEX file. Address 1FFh in logical Upper Half – Addresses memory maps to 1FFh in the MIF/HEX file, and all 100h to 1FFh data in between follows the order in the logical memory 100h 100h FFh 0FFh Address 00h in logical memory maps to Lower Half – Addresses 000h in the MIF/HEX file. Address FFh in logical 00h to FFh memory maps to 0FFh in the MIF/HEX file, and all data in between follows the order in the logical memory 00h 000h Memory Map for 8-Kbit Memory Initialization Figure9–52 shows the memory map initialization for the altufm_i2c megafunction of 8-Kbit memory. The altufm_i2c megafunction of 8-Kbit memory fully utilizes all the memory locations in the UFM block. © October 2008 Altera Corporation MAX II Device Handbook
9–46 Chapter 9: Using User Flash Memory in MAX II Devices Simulation Parameters Figure9–52. Memory Map for 8-Kbit Memory Initialization MIF or HEX File Contents - to represent the actual data and address size for the UFM Block 1FFh 8-Kbit altufm_i2c Megafunction The upper quarter of The mid-upper quarter of Logical Memory Contents logical memory maps logical memory maps to the upper byte of to the lower byte of 3FFh sector 1. Address 300h sector 1. Address 200h Upper Quarter Addresses in logical memory in logical memory 300h to 3FFh maps to address 100h maps to address 100h 300h in physical memory in physical memory and all addresses and all addresses 2FFh follow the order in follow the order in Mid-Upper Quarter Addresses logical memory. logical memory. 200h to 2FFh 100h 200h 1FFh 0FFh The mid-lower quarter of The lower quarter of Mid-Lower Quarter Addresses logical memory maps logical memory maps 100h to 1FFh to the lower byte of to the lower byte of 100h sector 0. Address 100h sector 0. Address 000h 0FFh in logical memory in logical memory maps to address 000h maps to address 000h Lower Quarter Addresses in physical memory in physical memory 100h to 1FFh and all addresses and all addresses 000h follow the order in follow the order in logical memory. logical memory. 000h Upper 8-bit (byte) Lower 8-bit (byte) 16-bit data in UFM Padding Data into Memory Map The altufm_i2c megafunction uses the upper 8 bits of the UFM 16-bit word; therefore, the 8 least significant bit (LSB) should be padded with 1, as shown in Figure9–53. Figure9–53. Padding Data into Memory Map 1 0 1 0 1 0 1 0 1 1 1 1 1 1 1 1 8-bit valid data to be placed Pad the lower byte with eight '1's in the upper byte Simulation Parameters Figure9–48 on page9–43 shows page 4 of the altufm megafunction where you can have an option to choose to simulate the OSC output port at the maximum or the minimum frequency during the design simulation. The frequency chosen is only used as the timing parameter for the Quartus II simulator and does not affect the real MAX II device OSC output frequency. Conclusion The MAX II UFM block is a user-accessible, programmable non-volatile flash memory block that provides significant flexibility in its interfacing. MAX II devices fill the need for on-board non-volatile storage in any application, minimizing board space and reducing total system cost. MAX II Device Handbook © October 2008 Altera Corporation
Chapter 9: Using User Flash Memory in MAX II Devices 9–47 Referenced Documents Referenced Documents This chapter references the following documents: ■ In-System Programmability Guidelines for MAX II Devices chapter in the MAX II Device Handbook ■ MAX II Architecture chapter in the MAX II Device Handbook Document Revision History Table9–17 shows the revision history for this chapter. Table9–17. Document Revision History Date and Revision Changes Made Summary of Changes October 2008, ■ Updated “Using and Accessing UFM Storage”, “Oscillator”, “UFM — Operating Modes”, “ALTUFM SPI Timing Specification”, and “ALTUFM version 1.8 Parallel Interface Timing Specification” sections. ■ Updated New Document Format. December 2007, ■ Corrected Figure9–3. — version 1.7 ■ Added “Referenced Documents”. December 2006, ■ Changed signal format in Table9–4. Added Revision History section. — version 1.6 August 2005, ■ Added I2C row to Table 9-3. — version 1.5 ■ Added a new Inter-Integrated Circuit section. ■ Added a new Memory Initialization for the altufm_i2c Megafunction section ■ Updated Figure 9-39. June 2005, ■ Added the Instantiating the Oscillator without the UFM section. — version 1.4 ■ Updated Figure 9-14. January 2005, ■ Previously published as Chapter 10. No changes to content. — version 1.3 © October 2008 Altera Corporation MAX II Device Handbook
9–48 Chapter 9: Using User Flash Memory in MAX II Devices Document Revision History Table9–17. Document Revision History Date and Revision Changes Made Summary of Changes December 2004 ■ Updated text to RTP_BUSY in Table 9-4. — v1.2 ■ Updated text in the Oscillator section. ■ Updated text in the UFM Operating Modes section. ■ Updated text in the Serial Peripheral Interface section. ■ Added a row to Table 9-6. ■ Updated Table 9-7. ■ Updated text to the READ section. ■ Updated text to the WRITE section. ■ Updated text to the SECTOR-ERASE section. ■ Added a new UFM-ERASE section. ■ Updated text to the WRSR section. ■ Updated Table 9-8. ■ Added Table 9-9. ■ Added section ALTUFM SPI Timing Specification. ■ Added Figures 9-13, 9-15, 9-16, 9-21, and 9-24. ■ Added Table 9-10. ■ Added section ALTUFM Parallel Interface Timing Specification. ■ Added section Simulation Parameters. ■ Added Table 9-12 June 2004 ■ Updated Figures 9-4 through 9-7. — v1.1 MAX II Device Handbook © October 2008 Altera Corporation
10. Replacing Serial EEPROMs with MAX II User Flash Memory MII51012-1.5 Introduction Each MAX® II device has a user flash memory (UFM) block to store up to 8 Kbits of user data. You can use the UFM block to replace on-board flash and EEPROM memory devices which are used to store ASSP or processor configuration bits, or electronic ID information for a board during manufacturing. MAX II device logic capacity allows integration of system power-on reset (POR), interface bridging, and I/O expansion designs in addition to these serial flash capabilities. This chapter provides a comprehensive listing of 2-Kbit, 4-Kbit, and 8-Kbit, non- volatile memory devices that could be potentially replaced by MAX II UFM devices. Table10–1 shows the capacity for the UFM block for all MAX II devices. Table10–1. MAX II UFM Array Size Device Total Bits Sectors Address Bits Data Width EPM240 8,192 2 (4096 bits per sector) 9 16 EPM570 EPM1270 EPM2210 This chapter contains the following sections: ■ “Design Considerations” on page10–1 ■ “List of Vendors and Devices” on page10–2 Design Considerations The MAX II UFM can be programmed, erased, and verified through the Joint Test Action Group (JTAG) port or through connections to/from the logic array in accordance with IEEE Std. 1532-2002. There are 13 interface signals to and from the UFM block and logic array which allow the logic array to read or write to the UFM during device user mode. A reference design or user logic can be used to interface the UFM to many standard interface protocols such as Serial Communication Interface (SCI), Serial Peripheral Interface (SPI), Inter-Integrated Circuit (I2C), Microwire, or other proprietary protocols. Altera's Quartus® II altufm megafunction provides interface logic for a subset of these interfaces (parallel and SPI). Any interfaces not provided by the megafunction or design examples, require you to create user logic to bridge the UFM block to your desired interface protocol. f For more information about programming and erasing the UFM block and/or the altufm megafunction, refer to the Using User Flash Memory in MAX II Devices chapter in the MAX II Device Handbook. © October 2008 Altera Corporation MAX II Device Handbook
10–2 Chapter 10: Replacing Serial EEPROMs with MAX II User Flash Memory List of Vendors and Devices The differences between the UFM block and serial EEPROMs that you should consider in your integration of serial EEPROM applications are the sector-based erase and erase/reprogram cycles. Serial EEPROMs support byte wide erase, which is automatically implemented during a byte write sequence. The UFM block supports byte writes, but does not support byte erase requiring a sector-based erase sequence prior to any programming or writing. If the data content of a specific byte location needs to be overwritten in the UFM, the entire sector that byte resides in must be erased unless that byte location was already erased (all 1s). For programming endurance, the UFM erase/reprogram cycles do not meet the 107 and greater cycles seen in serial EEPROMs. f Refer to the DC and Switching Characteristics chapter in the MAX II Device Handbook for the MAX II UFM block erase/programming endurance specification. List of Vendors and Devices Table10–2 through Table10–10 list the vendors and their devices which can be replaced by the MAX II UFM block. The operating condition range for the UFM block and MAX II devices are within the range of the devices listed. Table10–2. Asahi Kasei Microsystems Co. Device Characteristics Interface Operating Size 1- 2- 3- f Voltage (V) MAX Type Device (Bits) SCI Wire Wire Wire I2C Microwire (MHz) (1) EEPROM AK93C75AV 8,192 — — — — — v — 1.8 to 5.5 EEPROM AK93C75BH 8,192 — — — — — v — 1.8 to 5.5 EEPROM AK6480AF/M 8,192 v — — — — — 1 1.8 to 5.5 EEPROM AK6480BH/L 8,192 v — — — — — 1 1.8 to 5.5 EEPROM AK93C65AF/V 4,096 — — — — — v — 1.8 to 5.5 EEPROM AK93C65BH 4,096 — — — — — v — 1.8 to 5.5 EEPROM AK93C61AV 4,096 — — — — — v — 0.9 to 3.6 EEPROM AK6440AF/M 4,096 v — — — — — 1 1.8 to 5.5 EEPROM AK6440BH/L 4,096 v — — — — — 1 1.8 to 5.5 EEPROM AK6004AF 4,096 — — — — v — — 1.8 to 5.5 EEPROM AK93C55AF/V 2,048 — — — — — v — 1.8 to 5.5 EEPROM AK93C55BH 2,048 — — — — — v — 1.8 to 5.5 EEPROM AK93C51AV 2,048 — — — — — v — 0.9 to 3.6 EEPROM AK6420AF/M 2,048 v — — — — — 1 1.8 to 5.5 EEPROM AK6420BH 2,048 v — — — — — 1 1.8 to 5.5 EEPROM AK6003AV 2,048 — — — — v — — 1.8 to 5.5 Note to Table10–2: (1) The MAX II device supports two different V of operating voltage ranges, which are 2.375 to 2.625 V, and CCINT 3.0 to 3.6 V; the MAX IIG device supports the 1.71 to 1.89 V operating voltage range. MAX II Device Handbook © October 2008 Altera Corporation
Chapter 10: Replacing Serial EEPROMs with MAX II User Flash Memory 10–3 List of Vendors and Devices Table10–3. Atmel Corporation Device Characteristics Interface Size Operating Type Device (Bits) SCI SPI 2-Wire 3-Wire I2C Microwire f Voltage (V) (1) MAX EEPROM AT25020 2,048 — v — — — — 3 MHz 2.7 (2.7 ~ 5.5) EEPROM AT25040 4,096 — v — — — — 3 MHz 2.7 (2.7 ~ 5.5) EEPROM AT25020A 2,048 — v — — — — 20 MHz 2.7 (2.7 ~ 5.5) 1.8 (1.8 ~ 5.5) EEPROM AT25040A 4,096 — v — — — — 20 MHz 2.7 (2.7 ~ 5.5) 1.8 (1.8 ~ 5.5) EEPROM AT25080 8,192 — v — — — — 3 MHz 2.7 (2.7 ~ 5.5) 1.8 (1.8 ~ 5.5) EEPROM AT25080A 8,192 — v — — — — 20 MHz 2.7 (2.7 ~ 5.5) 1.8 (1.8 ~ 5.5) EEPROM AT24C02 2,048 — — v — — — 400 kHz 2.7 (2.7 ~ 5.5) 1.8 (1.8 ~ 5.5) EEPROM AT24C04 4,096 — — v — — — 400 kHz 2.7 (2.7 ~ 5.5) 1.8 (1.8 ~ 5.5) EEPROM AT24C08 8,192 — — v — — — 400 kHz 2.7 (2.7 ~ 5.5) 1.8 (1.8 ~ 5.5) EEPROM AT24C02A 2,048 — — v — — — 400 kHz 2.7 (2.7 ~ 5.5) 1.8 (1.8 ~ 5.5) EEPROM AT24C04A 4,096 — — v — — — 400 kHz 2.7 (2.7 ~ 5.5) 1.8 (1.8 ~ 5.5) EEPROM AT24C08A 8,192 — — v — — — 400 kHz 2.7 (2.7 ~ 5.5) 1.8 (1.8 ~ 5.5) EEPROM AT34C02 2,048 — — v — — — 400 kHz 2.7 (2.7 ~ 5.5) 1.8 (1.8 ~ 5.5) EEPROM AT93C56 2,048 — — — v — — 2 MHz 2.7 (2.7 ~5.5) 2.5 (2.5 ~ 5.5) 1.8 (1.8 ~5.5) EEPROM AT93C66 4,096 — — — v — — 2 MHz 2.7 (2.7 ~5.5) 2.5 (2.5 ~ 5.5) 1.8 (1.8 ~5.5) Note to Table10–3: (1) The MAX II device supports two different V of operating voltage ranges, which are 2.375 to 2.625 V, and 3.0 to 3.6 V; the MAX IIG device CCINT supports the 1.71 to 1.89 V operating voltage range. Table10–4. Catalyst Semiconductor, Inc. Device Characteristics (Part 1 of 2) Interface Operating Size Voltage (V) Type Device (Bits) SCI SPI 2-Wire 3-Wire I2C Microwire f (1) MAX EEPROM CAT93C56 2,048 — — — — — v 1 MHz 1.8 to 6.0 EEPROM CAT93C57 2,048 — — — — — v 1 MHz 1.8 to 6.0 EEPROM CAT93C66 4,096 — — — — — v 1 MHz 1.8 to 6.0 EEPROM CAT34WC02 2,048 — — — — v — 400 kHz 1.8 to 6.0 EEPROM CAT24WC03 2,048 — — — — v — 400 kHz 1.8 to 6.0 © October 2008 Altera Corporation MAX II Device Handbook
10–4 Chapter 10: Replacing Serial EEPROMs with MAX II User Flash Memory List of Vendors and Devices Table10–4. Catalyst Semiconductor, Inc. Device Characteristics (Part 2 of 2) Interface Operating Size Voltage (V) Type Device (Bits) SCI SPI 2-Wire 3-Wire I2C Microwire f (1) MAX EEPROM CAT24WC05 4,096 — — — — v — 400 kHz 1.8 to 6.0 EEPROM CAT24WC02 2,048 — — — — v — 400 kHz 1.8 to 6.0 EEPROM CAT24WC04 4,096 — — — — v — 400 kHz 1.8 to 6.0 EEPROM CAT24WC08 8,192 — — — — v — 400 kHz 1.8 to 6.0 EEPROM CAT64LC20 2,048 — v — — — — 1 MHz 2.5 to 6.0 EEPROM CAT64LC40 4,096 — v — — — — 1 MHz 2.5 to 6.0 EEPROM CAT25C02 2,048 — v — — — — 10 MHz 1.8 to 6.0 EEPROM CAT25C03 2,048 — v — — — — 10 MHz 1.8 to 6.0 EEPROM CAT25C04 4,096 — v — — — — 10 MHz 1.8 to 6.0 EEPROM CAT25C05 4,096 — v — — — — 10 MHz 1.8 to 6.0 EEPROM CAT25C08 8,192 — v — — — — 10 MHz 1.8 to 6.0 EEPROM CAT25C09 8,192 — v — — — — 10 MHz 1.8 to 6.0 EEPROM CAT25020 2,048 — v — — — — 10 MHz 1.8 to 6.0 EEPROM CAT25040 4,096 — v — — — — 10 MHz 1.8 to 6.0 Note to Table10–4: (1) The MAX II device supports two different V of operating voltage ranges, which are 2.375 to 2.625 V, and 3.0 to 3.6 V; the MAX IIG device CCINT supports the 1.71 to 1.89 V operating voltage range. Table10–5. Dallas Semiconductor – Maxim Integrated Products, Inc. Device Characteristics Interface Operating Size Voltage (V) Type Device (Bits) SCI 1-Wire 2-Wire 3-Wire I2C Microwire f (MHz) (1) MAX EEPRO DS2433 4,096 — v — — — — — 2.8 to 6.0 M Note to Table10–5: (1) The MAX II device supports two different V of operating voltage ranges, which are 2.375 to 2.625 V, and 3.0 to 3.6 V; the MAX IIG device CCINT supports the 1.71 to 1.89 V operating voltage range. Table10–6. Fairchild Semiconductor Device Characteristics (Part 1 of 2) Interface Operating Size Voltage (V) Type Device (Bits) SCI SPI 2-Wire 3-Wire I2C Microwire f (1) MAX EEPROM FM34W02UL 2,048 — — — — v — 400 kHz 2.7 to 5.5 EEPROM FM93C56L 2,048 — — — — — v 1 MHz 2.7 to 5.5 EEPROM FM93C66L 4,096 — — — — — v 1 MHz 2.7 to 5.5 EEPROM FM93CS56L 2,048 — — — — — v 1 MHz 2.7 to 5.5 EEPROM FM93CS66L 4,096 — — — — — v 1 MHz 2.7 to 5.5 EEPROM FM24C08UL 8,192 — — v — — — 400 kHz 2.7 to 5.5 EEPROM FM24C09UL 8,192 — — v — — — 400 kHz 2.7 to 5.5 MAX II Device Handbook © October 2008 Altera Corporation
Chapter 10: Replacing Serial EEPROMs with MAX II User Flash Memory 10–5 List of Vendors and Devices Table10–6. Fairchild Semiconductor Device Characteristics (Part 2 of 2) Interface Operating Size Voltage (V) Type Device (Bits) SCI SPI 2-Wire 3-Wire I2C Microwire f (1) MAX EEPROM NM24C02L 2,048 — — v — — — 400 kHz 2.7 to 5.5 EEPROM NM25C020L 2,048 — v — — — — 2.1 MHz 2.7 to 5.5 EEPROM NM25C040L 4,096 — v — — — — 2.1 MHz 2.7 to 5.5 Note to Table10–6: (1) The MAX II device supports two different V of operating voltage ranges, which are 2.375 to 2.625 V, and 3.0 to 3.6 V; the MAX IIG device CCINT supports the 1.71 to 1.89 V operating voltage range. Table10–7. Holtek Semiconductor Inc. Device Characteristics Interface Clock Rate Operating Size (MHz) Voltage Type Device (Bits) SCI 1-Wire 2-Wire 3-Wire I2C Microwire (V = 5.0 V) (V) (1) CC EEPROM HT24LC02 2,048 — — v — — — 0.4 2.2 to 5.5 EEPROM HT24LC04 4,096 — — v — — — 0.4 2.4 to 5.5 EEPROM HT24LC08 8,192 — — v — — — 0.4 2.4 to 5.5 EEPROM HT93LC56 2,048 — — — v — — 1 Read: 2.0 ~ 5.5 Write: 2.4 ~ 5.5 EEPROM HT93LC66 4,096 — — — v — — 1 Read: 2.0 ~ 5.5 Write: 2.4 ~ 5.5 Note to Table10–7: (1) The MAX II device supports two different V of operating voltage ranges, which are 2.375 to 2.625 V, and 3.0 to 3.6 V; the MAX IIG device CCINT supports the 1.71 to 1.89 V operating voltage range. Table10–8. Microchip Technology Inc. Device Characteristics (Part 1 of 2) Interface Operating Size Voltage (V) Type Device (Bits) SCI SPI 2-Wire 3-Wire I2C Microwire f (1) MAX EEPROM 24LCS62 2,048 — — — — v — 400 kHz 2.5 to 5.5 EEPROM 24LCS52 2,048 — — — — v — 400 kHz 2.5 to 5.5 EEPROM 24LC22A 2,048 — — — — v — 400 kHz 2.5 to 5.5 EEPROM 24LC02B 2,048 — — — — v — 400 kHz 2.5 to 5.5 EEPROM 24LC025 2,048 — — — — v — 400 kHz 2.5 to 5.5 EEPROM 24LC024 2,048 — — — — v — 400 kHz 2.5 to 5.5 EEPROM 24C02SC 2,048 — — — — v — 400 kHz 2.5 to 5.5 EEPROM 24LCS22A 2,048 — — — — v — 400 kHz 1.8 to 5.5 EEPROM 24AA52 2,048 — — — — v — 100 kHz 1.8 to 5.5 EEPROM 24AA02 2,048 — — — — v — 100 kHz 1.8 to 5.5 EEPROM 24AA04 4,096 — — — — v — 400 kHz (2) 1.8 to 5.5 EEPROM 24AA08 8,192 — — — — v — 400 kHz (2) 1.8 to 5.5 © October 2008 Altera Corporation MAX II Device Handbook
10–6 Chapter 10: Replacing Serial EEPROMs with MAX II User Flash Memory List of Vendors and Devices Table10–8. Microchip Technology Inc. Device Characteristics (Part 2 of 2) Interface Operating Size Voltage (V) Type Device (Bits) SCI SPI 2-Wire 3-Wire I2C Microwire f (1) MAX EEPROM 24LC04B 4,096 — — — — v — 400 kHz 1.8 to 5.5 EEPROM 24LC08B 8,192 — — — — v — 400 kHz 1.8 to 5.5 EEPROM 24LC09 (3) 8,192 — — Advanced — — — 400 kHz 2.5 to 5.5 Communic ation Riser (4) EEPROM 93LC66A 4,096 — — — — — v 2 MHz 2.5 to 6.0 EEPROM 93AA66 4,096 — — — — — v 2 MHz 1.8 to 5.5 EEPROM 93LC66B 4,096 — — — — — v 2 MHz 2.5 to 6.0 EEPROM 93LC56A 2,048 — — — — — v 2 MHz 2.5 to 6.0 EEPROM 93AA56 2,048 — — — — — v 2 MHz 1.8 to 5.5 EEPROM 93LC56B 2,048 — — — — — v 2 MHz 2.5 to 6.0 EEPROM 25LC080 8,192 — v — — — — 2 MHz 2.5 to 5.5 EEPROM 25LC040 4,096 — v — — — — 2 MHz 2.5 to 5.5 EEPROM 25AA080 8,192 — v — — — — 1 MHz 1.8 to 5.5 EEPROM 25AA040 4,096 — v — — — — 1 MHz 1.8 to 5.5 Notes to Table10–8: (1) The MAX II device supports two different V of operating voltage ranges, which are 2.375 to 2.625 V, and 3.0 to 3.6 V; the MAX IIG device CCINT supports the 1.71 to 1.89 V operating voltage range. (2) 100 kHz for V < 2.5 V. CC (3) This device is designed to meet the proprietary protocol. (4) Proprietary protocol by Microchip Technology Inc. Table10–9. Philips Semiconductors Device Characteristics Interface Operating Size Voltage (V) Type Device (bits) SCI SPI 2-Wire 3-Wire I2C Microwire f (1) MAX EEPROM PCF8582C-2 2,048 — — — — v — 100 kHz 2.5 to 6.0 EEPROM PCF8594C-2 4,096 — — — — v — 100 kHz 2.5 to 6.0 EEPROM PCF8598C-2 8,192 — — — — v — 100 kHz 2.5 to 6.0 EEPROM PCF85102C-2 2,048 — — — — v — 100 kHz 2.5 to 6.0 EEPROM PCF85103C-2 2,048 — — — — v — 100 kHz 2.5 to 6.0 Note to Table10–9: (1) The MAX II device supports two different V of operating voltage ranges, which are 2.375 to 2.625 V, and 3.0 to 3.6 V; the MAX IIG device CCINT supports the 1.71 to 1.89 V operating voltage range. MAX II Device Handbook © October 2008 Altera Corporation
Chapter 10: Replacing Serial EEPROMs with MAX II User Flash Memory 10–7 List of Vendors and Devices Table10–10. Rohm Co., Ltd. Device Characteristics (Part 1 of 2) Interface Operating Size 2- 3- Voltage (V) Type Device (Bits) SCI SPI Wire Wire I2C Microwire f (1) MAX EEPROM BR24L02-W 2,048 — — — — v — 400 kHz 1.8 to 5.5 EEPROM BR24L04-W 4,096 — — — — v — 400 kHz 1.8 to 5.5 EEPROM BR24L08-W 8,192 — — — — v — 400 kHz 1.8 to 5.5 EEPROM BR24L02F-W 2,048 — — — — v — 400 kHz 1.8 to 5.5 EEPROM BR24L04F-W 4,096 — — — — v — 400 kHz 1.8 to 5.5 EEPROM BR24L08F-W 8,192 — — — — v — 400 kHz 1.8 to 5.5 EEPROM BR24L02FJ-W 2,048 — — — — v — 400 kHz 1.8 to 5.5 EEPROM BR24L04FJ-W 4,096 — — — — v — 400 kHz 1.8 to 5.5 EEPROM BR24L08FJ-W 8,192 — — — — v — 400 kHz 1.8 to 5.5 EEPROM BR24L02FV-W 2,048 — — — — v — 400 kHz 1.8 to 5.5 EEPROM BR24L04FV-W 4,096 — — — — v — 400 kHz 1.8 to 5.5 EEPROM BR24L08FV-W 8,192 — — — — v — 400 kHz 1.8 to 5.5 EEPROM BR24L02FVM-W 2,048 — — — — v — 400 kHz 1.8 to 5.5 EEPROM BR24L04FVM-W 4,096 — — — — v — 400 kHz 1.8 to 5.5 EEPROM BR24L08FVM-W 8,192 — — — — v — 400 kHz 1.8 to 5.5 EEPROM BR93L56-W 2,048 — — — v — — 2 MHz 1.8 to 5.5 EEPROM BR93L66-W 4,096 — — — v — — 2 MHz 1.8 to 5.5 EEPROM BR93L56F-W 2,048 — — — v — — 2 MHz 1.8 to 5.5 EEPROM BR93L66F-W 4,096 — — — v — — 2 MHz 1.8 to 5.5 EEPROM BR93L56RF-W 2,048 — — — v — — 2 MHz 1.8 to 5.5 EEPROM BR93L66RF-W 4,096 — — — v — — 2 MHz 1.8 to 5.5 EEPROM BR93L56FJ-W 2,048 — — — v — — 2 MHz 1.8 to 5.5 EEPROM BR93L66FJ-W 4,096 — — — v — — 2 MHz 1.8 to 5.5 EEPROM BR93L56RFJ-W 2,048 — — — v — — 2 MHz 1.8 to 5.5 EEPROM BR93L66RFJ-W 4,096 — — — v — — 2 MHz 1.8 to 5.5 EEPROM BR93L56FV-W 2,048 — — — v — — 2 MHz 1.8 to 5.5 EEPROM BR93L66FV-W 4,096 — — — v — — 2 MHz 1.8 to 5.5 EEPROM BR93L56RFV-W 2,048 — — — v — — 2 MHz 1.8 to 5.5 EEPROM BR93L66RFV-W 4,096 — — — v — — 2 MHz 1.8 to 5.5 EEPROM BR93L56RFVM-W 2,048 — — — v — — 2 MHz 1.8 to 5.5 EEPROM BR93L66RFVM-W 4,096 — — — v — — 2 MHz 1.8 to 5.5 EEPROM BR9020-W 2,048 — — — v — — 2 MHz 2.7 to 5.5 EEPROM BR9040-W 4,096 — — — v — — 2 MHz 2.7 to 5.5 EEPROM BR9080AF-W 8,192 — — — v — — 2 MHz 2.7 to 5.5 EEPROM BR9020F-W 2,048 — — — v — — 2 MHz 2.7 to 5.5 EEPROM BR9040F-W 4,096 — — — v — — 2 MHz 2.7 to 5.5 EEPROM BR9080ARFV-W 8,192 — — — v — — 2 MHz 2.7 to 5.5 © October 2008 Altera Corporation MAX II Device Handbook
10–8 Chapter 10: Replacing Serial EEPROMs with MAX II User Flash Memory List of Vendors and Devices Table10–10. Rohm Co., Ltd. Device Characteristics (Part 2 of 2) Interface Operating Size 2- 3- Voltage (V) Type Device (Bits) SCI SPI Wire Wire I2C Microwire f (1) MAX EEPROM BR9020FV-W 2,048 — — — v — — 2 MHz 2.7 to 5.5 EEPROM BR9040FV-W 4,096 — — — v — — 2 MHz 2.7 to 5.5 EEPROM BR9080ARFVM-W 8,192 — — — v — — 2 MHz 2.7 to 5.5 EEPROM BR9020RFV-W 2,048 — — — v — — 2 MHz 2.7 to 5.5 EEPROM BR9040RFV-W 4,096 — — — v — — 2 MHz 2.7 to 5.5 EEPROM BR9020RFVM-W 2,048 — — — v — — 2 MHz 2.7 to 5.5 EEPROM BR9040RFVM-W 4,096 — — — v — — 2 MHz 2.7 to 5.5 Note to Table10–10: (1) The MAX II device supports two different V of operating voltage ranges, which are 2.375 to 2.625 V, and 3.0 to 3.6 V; the MAX IIG device CCINT supports the 1.71 to 1.89 V operating voltage range. Table10–11. Seiko Instruments Inc. Device Characteristics (Part 1 of 3) Interface Size Operating Voltage Type Device (Bits) SCI 1-Wire 2-Wire 3-Wire I2C Microwire f (V) (1) MAX EEPROM S-93C66B 4,096 — — — v — — 2.0 MHz Read: 1.8 ~ 5.5 Write: 2.7 ~ 5.5 EEPROM S-93C56B 2,048 — — — v — — 2.0 MHz Read: 2.0 ~ 5.5 Write: 2.4 ~5.5 EEPROM S-93C76A 8,192 — — — v — — 2.0 MHz Read: 1.8 ~ 5.5 Write: 2.7 ~ 5.5 EEPROM S-93C66A 4,096 — — — v — — 2.0 MHz 1.8 to 5.5 EEPROM S-93C56A 2,048 — — — v — — 2.0 MHz 1.8 to 5.5 EEPROM S-29430A 8,192 — — — v — — 2.0 MHz Read: 1.8 ~ 5.5 Write: 2.5 ~ 5.5 EEPROM S-29453A 8,192 — — — v — — 2.0 MHz Read: 1.8 ~ 5.5 Write: 2.5 ~ 5.5 EEPROM S-29330A 4,096 — — — v — — 2.0 MHz Read: 1.8 ~ 6.5 Write: 2.5 ~ 6.5 EEPROM S-29230A 2,048 — — — v — — 2.0 MHz Read: 1.8 ~ 6.5 Write: 2.5 ~ 6.5 EEPROM S-29220A 2,048 — — — v — — 2.0 MHz Read: 1.8 ~ 6.5 Write: 2.5 ~ 6.5 EEPROM S-29331A 4,096 — — — v — — 2.0 MHz Read: 1.8 ~ 6.5 Write: 2.5 ~ 6.5 EEPROM S-29231A 2,048 — — — v — — 2.0 MHz Read: 1.8 ~ 6.5 Write: 2.5 ~ 6.5 EEPROM S-29221A 2,048 — — — v — — 2.0 MHz Read: 1.8 ~ 6.5 Write: 2.5 ~ 6.5 EEPROM S-29390A 4,096 — — — v — — 2.0 MHz Read: 1.8 ~ 6.5 Write: 2.5 ~ 6.5 MAX II Device Handbook © October 2008 Altera Corporation
Chapter 10: Replacing Serial EEPROMs with MAX II User Flash Memory 10–9 List of Vendors and Devices Table10–11. Seiko Instruments Inc. Device Characteristics (Part 2 of 3) Interface Size Operating Voltage Type Device (Bits) SCI 1-Wire 2-Wire 3-Wire I2C Microwire f (V) (1) MAX EEPROM S-29290A 2,048 — — — v — — 2.0 MHz Read: 1.8 ~ 6.5 Write: 2.5 ~ 6.5 EEPROM S-29391A 4,096 — — — v — — 2.0 MHz Read: 1.8 ~ 6.5 Write: 2.5 ~ 6.5 EEPROM S-29291A 2,048 — — — v — — 2.0 MHz Read: 1.8 ~ 6.5 Write: 2.5 ~ 6.5 EEPROM S-29394A 4,096 — — — v — — 2.0 MHz Read: 1.8 ~ 6.5 Write: 2.5 ~ 6.5 EEPROM S-29294A 2,048 — — — v — — 2.0 MHz Read: 1.8 ~ 6.5 Write: 2.5 ~ 6.5 EEPROM S-29355A 4,096 — — — v — — 2.0 MHz Read: 1.8 V ~ 6.5 V Write: 2.7 V ~ 6.5 V EEPROM S-29255A 2,048 — — — v — — 2.0 MHz Read: 1.8 ~ 6.5 Write: 2.7 ~ 6.5 EEPROM S-29L330A 4,096 — — — v — — 2.0 MHz 1.8 to 5.5 EEPROM S-29L220A 2,048 — — — v — — 2.0 MHz 1.8 to 5.5 EEPROM S-29L331A 4,096 — — — v — — 2.0 MHz 1.8 to 5.5 EEPROM S-29L221A 2,048 — — — v — — 2.0 MHz 1.8 to 5.5 EEPROM S-29L394A 4,096 — — — v — — 2.0 MHz 1.8 to 5.5 EEPROM S-29L294A 2,048 — — — v — — 2.0 MHz 1.8 to 5.5 EEPROM S-29U330A 4,096 — — — v — — 500 kHz Read: 0.9 ~ 3.6 Write:1.8 ~3.6 EEPROM S-29U220A 2,048 — — — v — — 500 kHz Read: 0.9 ~ 3.6 Write:1.8 ~3.6 EEPROM S-29U331A 4,096 — — — v — — 500 kHz Read: 0.9 ~ 3.6 Write:1.8 ~3.6 EEPROM S-29U221A 2,048 — — — v — — 500 kHz Read: 0.9 ~ 3.6 Write:1.8 ~3.6 EEPROM S-29U394A 4,096 — — — v — — 500 kHz Read: 0.9 ~ 3.6 Write:1.8 ~3.6 EEPROM S-29U294A 2,048 — — — v — — 500 kHz Read: 0.9 ~ 3.6 Write:1.8 ~3.6 EEPROM S-29Z330A 4,096 — — — v — — 500 kHz 0.9 to 3.6 EEPROM S-29ZX30A 8,192 — — — v — — 500 kHz 0.9 to 3.6 EEPROM S-24CS08A 8,192 — — v — — — 400 kHz Read: 1.8 to 5.5 Write: 2.7 to 5.5 EEPROM S-24CS04A 4,096 — — v — — — 400 kHz Read: 1.8 ~ 5.5 Write: 2.7 ~ 5.5 EEPROM S-24CS02A 2,048 — — v — — — 400 kHz Read: 1.8 ~ 5.5 Write: 2.7 ~ 5.5 EEPROM S-24C08A 8,192 — — v — — — 400 kHz Read: 1.8 ~ 5.5 Write: 2.7 ~ 5.5 © October 2008 Altera Corporation MAX II Device Handbook
10–10 Chapter 10: Replacing Serial EEPROMs with MAX II User Flash Memory List of Vendors and Devices Table10–11. Seiko Instruments Inc. Device Characteristics (Part 3 of 3) Interface Size Operating Voltage Type Device (Bits) SCI 1-Wire 2-Wire 3-Wire I2C Microwire f (V) (1) MAX EEPROM S-24C04A 4,096 — — v — — — 100 kHz Read: 1.8 ~ 5.5 Write: 2.5 ~ 5.5 EEPROM S-24C02A 2,048 — — v — — — 100 kHz Read: 1.8 ~ 5.5 Write: 2.5 ~ 5.5 EEPROM S-24C04B 4,096 — — v — — — 400 KHz 2.0 to 5.5 EEPROM S-24C02B 2,048 — — v — — — 400 KHz 2.0 to 5.5 Note to Table10–11: (1) The MAX II device supports two different V of operating voltage ranges, which are 2.375 to 2.625 V, and 3.0 to 3.6 V; the MAX IIG device CCINT supports the 1.71 to 1.89 V operating voltage range. Table10–12. STMicroelectronics Device Characteristics (Part 1 of 2) Interface Operating Size Voltage (V) Type Device (Bits) SCI SPI 2-Wire 3-Wire I2C Microwire f (1) MAX EEPROM M24C04-W 4,096 — — — — v — 400 kHz 2.5 to 5.5 EEPROM M24C02-W 2,048 — — — — v — 400 kHz 2.5 to 5.5 EEPROM M24C08-W 8,192 — — — — v — 400 kHz 2.5 to 5.5 EEPROM M24C04-L 4,096 — — — — v — 400 kHz 2.2 to 5.5 EEPROM M24C02-L 2,048 — — — — v — 400 kHz 2.2 to 5.5 EEPROM M24C08-L 8,192 — — — — v — 400 kHz 2.2 to 5.5 EEPROM M24C04-R 4,096 — — — — v — 400 kHz 1.8 to 5.5 EEPROM M24C02-R 2,048 — — — — v — 400 kHz 1.8 to 5.5 EEPROM M24C08-R 8,192 — — — — v — 400 kHz 1.8 to 5.5 EEPROM ST24W04 4,096 — — — — v — 100 kHz 3.0 to 5.5 EEPROM ST25W04 4,096 — — — — v — 100 kHz 2.5 to 5.5 EEPROM ST24C04 4,096 — — — — v — 100 kHz 3.0 to 5.5 EEPROM ST25C04 4,096 — — — — v — 100 kHz 2.5 to 5.5 EEPROM M93C76-W 8192 — — — — — v 2 MHz 2.5 to 5.5 EEPROM M93C66-W 4,096 — — — — — v 2 MHz 2.5 to 5.5 EEPROM M93C56-W 2,048 — — — — — v 2 MHz 2.5 to 5.5 EEPROM M93C76-R 8,192 — — — — — v 2 MHz 1.8 to 5.5 EEPROM M93C66-R 4,096 — — — — — v 2 MHz 1.8 to 5.5 EEPROM M93C56-R 2,048 — — — — — v 2 MHz 1.8 to 5.5 EEPROM M93S66-W 4,096 — — — — — v 2 MHz 2.5 to 5.5 EEPROM M93S56-W 2,048 — — — — — v 2 MHz 2.5 to 5.5 EEPROM M93S66-R 4,096 — — — — — v 2 MHz 1.8 to 5.5 EEPROM M93S56-R 2,048 — — — — — v 2 MHz 1.8 to 5.5 EEPROM M95080-W 8,192 — v — — — — 10 MHz 2.5 to 5.5 EEPROM M95040-W 4,096 — v — — — — 5 MHz 2.5 to 5.5 EEPROM M95020-W 2,048 — v — — — — 5 MHz 2.5 to 5.5 MAX II Device Handbook © October 2008 Altera Corporation
Chapter 10: Replacing Serial EEPROMs with MAX II User Flash Memory 10–11 Conclusion Table10–12. STMicroelectronics Device Characteristics (Part 2 of 2) Interface Operating Size Voltage (V) Type Device (Bits) SCI SPI 2-Wire 3-Wire I2C Microwire f (1) MAX EEPROM M95080-R 8,192 — v — — — — 10 MHz 1.8 to 5.5 EEPROM M95040-S 4,096 — v — — — — 5 MHz 1.8 to 3.6 EEPROM M95020-S 2,048 — v — — — — 5 MHz 1.8 to 3,6 Note to Table10–12: (1) The MAX II device supports two different V of operating voltage ranges, which are 2.375 to 2.625 V, and 3.0 to 3.6 V; the MAX IIG device CCINT supports the 1.71 to 1.89 V operating voltage range. Table10–13. Toshiba Corporation Device Characteristics Interface Size Operating Type Device (Bits) SCI 4-Wire 2-Wire 3-Wire I2C Microwire f Voltage (V) (1) MAX EEPROM TC9WMA2FK 2,048 — v — v — — 1 MHz Read: 1.8 ~ 5.5 Write: 2.3 ~ 5.5 EEPROM TC9WMB2FK 2,048 — — — — v — 400 kHz Read: 1.8 ~ 5.5 Write: 2.3 ~ 5.5 Note to Table10–13: (1) The MAX II device supports two different V of operating voltage ranges, which are 2.375 to 2.625 V, and 3.0 to 3.6 V; the MAX IIG device CCINT supports the 1.71 to 1.89 V operating voltage range. Conclusion MAX II devices can be used to incorporate logic and memory devices on a design board, eliminating chip-to-chip delays, minimizing board space, and reducing total system cost. Since you can program the UFM block to suit your needs, MAX II devices offer more interface flexibility than an off-the-shelf EEPROM device. Referenced Documents This chapter references the following documents: ■ DC and Switching Characteristics chapter in the MAX II Device Handbook ■ Using User Flash Memory in MAX II Devices chapter in the MAX II Device Handbook © October 2008 Altera Corporation MAX II Device Handbook
10–12 Chapter 10: Replacing Serial EEPROMs with MAX II User Flash Memory Document Revision History Document Revision History Table10–14 shows the revision history for this chapter. Table10–14. Document Revision History Date and Revision Changes Made Summary of Changes October 2008, ■ Updated New Document Format. — version 1.5 December 2007, ■ Added “Referenced Documents” section. — version 1.4 December 2006, ■ Added document revision history. — version 1.3 January 2005, ■ Previously published as Chapter 11. No changes to — version 1.2 content. December 2004, ■ Updated text to Design Considerations section. — version 1.1 MAX II Device Handbook © October 2008 Altera Corporation
Section IV. In-System Programmability This section provides information and guidelines for in-system programmability (ISP) and Joint Test Action Group (JTAG) boundary scan testing (BST). This section includes the following chapters: ■ Chapter11, In-System Programmability Guidelines for MAX II Devices ■ Chapter12, Real-Time ISP and ISP Clamp for MAX II Devices ■ Chapter13, IEEE 1149.1 (JTAG) Boundary-Scan Testing for MAXII Devices ■ Chapter14, Using Jam STAPL for ISP via an Embedded Processor ■ Chapter15, Using the Agilent 3070 Tester for In-System Programming Revision History Refer to each chapter for its own specific revision history. For information about when each chapter was updated, refer to the Chapter Revision Dates section, which appears in the complete handbook. © October 2008 Altera Corporation MAX II Device Handbook
IV–2 Section IV: In-System Programmability Revision History MAX II Device Handbook © October 2008 Altera Corporation
11. In-System Programmability Guidelines for MAX II Devices MII51013-1.7 Introduction As time-to-market pressure increases, design engineers require advanced system- level products to ensure problem-free development and manufacturing. Programmable logic devices (PLDs) with in-system programmability (ISP) can help accelerate development time, facilitate in-field upgrades, simplify the manufacturing flow, lower inventory costs, and improve printed circuit board (PCB) testing capabilities. Altera® ISP-capable MAX® II devices can be programmed and reprogrammed in-system via the IEEE Std. 1149.1 Joint Test Action Group (JTAG) interface. This interface allows MAX II devices to be programmed and the PCB to be functionally tested in a single manufacturing step, saving testing time and assembly costs. This chapter describes guidelines you should follow to design successfully with ISP, including: ■ “General ISP Guidelines” on page11–1 ■ “IEEE Std. 1149.1 Signals” on page11–4 ■ “Sequential versus Concurrent Programming” on page11–6 ■ “ISP Troubleshooting Guidelines” on page11–7 ■ “ISP via Embedded Processors” on page11–9 ■ “ISP via In-Circuit Testers” on page11–10 General ISP Guidelines This section provides guidelines that help you design successfully for ISP-capable MAX II devices. These guidelines should be used regardless of your specific design implementation. Operating Conditions Each MAX II device has several parametric ratings, or operating conditions, that are required for proper operation. Although MAX II devices can exceed these conditions when in user mode and still operate correctly, these conditions should not be exceeded during in-system programming. Violating any of the operating conditions during in-system programming can result in programming failures or incorrectly programmed devices. V of all I/O banks and V of the device must be fully CCIO CCINT powered up for ISP to function. ISP Voltage The V and V level specified in the device operating conditions table must be CCINT CCIO maintained on the V and V pins during in-system programming to ensure that CCINT CCIO the device’s flash cells are programmed correctly. The V and V specification CCINT CCIO applies for both commercial- and industrial-temperature-grade devices. © October 2008 Altera Corporation MAX II Device Handbook
11–2 Chapter 11: In-System Programmability Guidelines for MAX II Devices General ISP Guidelines Input Voltages The MAX II Device Family Data Sheet lists the MAX II device input voltage specification in the absolute maximum ratings and the recommended operating conditions tables. The input voltages in the absolute maximum rating table refers to the maximum voltage which the device can tolerate before risking permanent damage. The recommended operating conditions table specify the voltage range for safe device operation. Make sure all pins that transition during in-system programming do not have a ground or V overshoot. Overshoot problems typically occur on free-running CC clocks or data buses that can toggle during in-system programming. All pins that have an overshoot greater than 1.0 V must have series termination. f For more information about the recommended operating conditions and the absolute maximum ratings for MAX II devices and termination, refer to the DC and Switching Characteristics chapter in the MAX II Device Handbook and AN 75: High-Speed Board Designs, respectively. UFM Operations During In-System Programming If your design allows you to access the MAX II UFM (write or erase), you must ensure that all the erase or write operations of the UFM are completed before starting any ISP session (including stand-alone verify, examine, setting security bit, and reading the contents of the UFM). You should never start an ISP session when any erase or write operation of the UFM is on going, as this may put the device in an unrecoverable state. However, this restriction does not apply to the read operation of the UFM. If you cannot ensure that any erase or write operation of the UFM is complete before attempting an ISP operation to the MAX II device, then you should enable the real- time ISP feature. When used properly, this feature can help guard against any UFM/ISP operation contention. When real-time ISP is enabled, the programming algorithm used by the Quartus® II software or the Jam™ (.jam)/Jam Byte-Code (.jbc) files will wait 500 ms before it begins any operation. This is the same amount of time it takes for one UFM sector to be erased (that is, the real-time ISP programming algorithm waits for what may have been a previously started UFM erase sequence to complete). However, if you are using a real-time ISP feature, no other UFM operations are allowed after that time (no address shifting, no data shifting, and no read, write, or erase operations). This can be controlled by monitoring the RTP_BUSY signal on the altufm_none megafunction. When real-time ISP is under way, the RTP_BUSY output signal on the UFM block goes high. You can monitor this signal and ensure that all UFM operations from the logic array cease until real-time ISP is complete. This user- generated control logic is only necessary for the altufm_none megafunction, which provides no auto-generated logic. The other interfaces for the altufm megafunction (altufm_parallel, altufm_spi, altufm_i2c) contain control logic that automatically monitors the RTP_BUSY signal and ceases operations to the UFM when a real-time ISP operation is under way. MAX II Device Handbook © October 2008 Altera Corporation
Chapter 11: In-System Programmability Guidelines for MAX II Devices 11–3 General ISP Guidelines Interrupting In-System Programming Altera does not recommend interrupting the programming process. However, the MAX II device has an ISP_DONE bit that will only be set at the very end of a successful program sequence. The I/O pins will only drive out if this bit is set. This prevents a partially programmed device from driving out and operating unpredictably. MultiVolt Devices and Power-Up Sequences For the JTAG circuitry to operate correctly during in-system programming or boundary-scan testing, all devices in a JTAG chain must be in the same state. Therefore, in systems with multiple power supply voltages, the JTAG pins must be held in the test-logic-reset state until all devices in the chain are completely powered up. This procedure is particularly important because systems with multiple power supplies cannot power all voltage levels simultaneously. MAX II devices have the MultiVolt feature and can use more than one power supply voltage: V and V for each I/O bank. V provides power to the JTAG CCINT CCIO CCINT circuitry; V provides power to input pins and output drivers for output pins, CCIO including TDO. Therefore, when using two power supply voltages, the JTAG circuitry must be held in the test-logic-reset state until both power supplies are turned on. If the JTAG pins are not held in the test-logic-reset state, in-system programming errors can occur. V Powered before V CCIO CCINT If V is powered up before V , the JTAG circuitry is not active but TDO is tri- CCIO CCINT stated. Even though the JTAG circuitry is not active, if the next device in the JTAG chain is powered up with the same trace as V , its JTAG circuitry must stay in the CCIO test-logic-reset state. Because all TMS and TCK signals are common, they must be disabled for all devices in the chain. Therefore, the JTAG pins must be disabled by pulling TCK low and TMS high. I/O Pins Tri-Stated during In-System Programming By default, all device I/O pins are tri-stated during in-system programming. In addition, the MAX II device provides a weak pull-up resistor during ISP. The purpose of this weak pull-up resistor is to eliminate the need for external pull-up resistors on tri-stated I/O pins. For pins that are used to drive signals and require a particular value during in-system programming (for example, output enable or chip enable signals), you can use the in- system programming clamp feature or the real-time ISP feature available for MAX II devices. These two features ensure that each I/O pin is clamped to a specific state during in-system programming. f For more information, refer to the In-System Programming Clamp and Real-Time ISP sections in the JTAG and In-System Programmability chapter in the MAX II Device Handbook. © October 2008 Altera Corporation MAX II Device Handbook
11–4 Chapter 11: In-System Programmability Guidelines for MAX II Devices IEEE Std. 1149.1 Signals Pull-Up and Pull-Down of JTAG Pins During In-System Programming A MAX II device operating in in-system programming mode requires four pins: TDI, TDO, TMS, and TCK. The detailed description and function of each pin can be found in the IEEE 1149.1 (JTAG) Boundary-Scan Testing for MAXII Devices chapter in the MAX II Device Handbook. Three of the four JTAG pins have internal weak pull-up or pull-down resistors. The TDI and TMS pins have internal weak pull-up resistors while the TCK pin has an internal weak pull-down resistor. However, for device programming in a JTAG chain, there might be devices that do not have internal pull-up or pull-down resistors. Altera recommends to externally pull TMS high through 10-k and TCK low through 1-k resistors. Pulling-up the TDI signal externally for the MAX II device is optional. Figure11–1 shows the external pull-up and pull-down for TMS and TCK of the JTAG chain. The TDO pin does not have internal pull-up or pull-down resistors, and does not require external pull-up or pull-down resistors. Figure11–1. External Pull-Up and Pull-Down Resistors for TMS and TCK of a JTAG Chain 10-Pin Male Header (Top View) VCC VCC Other ISP-Capable Other ISP-Capable MAX II Device Device Device 10 kΩ TDI TDO TDI TDO TDI TDO TMS TCK TMS TCK TMS TCK GND 1kΩ The TMS pin is pulled high so that the TAP controller will remain in the TEST_LOGIC/RESET state even if there is input from TCK. To prevent TCK from pulsing high, the TCK pin is pulled low during power-up. Pulling TCK high is not recommended because an increase in the power supply to the pull-up resistor causes the TCK to pulse high; thus, it is possible for the TAP controller to reach an unintended state. IEEE Std. 1149.1 Signals This section provides guidelines for programming with the IEEE Std. 1149.1 (JTAG) interface. TCK Signal Most in-system programming failures are caused by a noisy TCK signal. Noisy transitions on rising or falling edges can cause incorrect clocking of the IEEE Std. 1149.1 Test Access Port (TAP) controller. Incorrect clocking can cause the state machine to transition to an unknown state, leading to in-system programming failures. MAX II Device Handbook © October 2008 Altera Corporation
Chapter 11: In-System Programmability Guidelines for MAX II Devices 11–5 IEEE Std. 1149.1 Signals Further, because the TCK signal must drive all IEEE Std. 1149.1 devices in the chain in parallel, the signal may have a high fan-out. Like any other high fan-out user-mode clock, you must manage a clock tree to maintain signal integrity. Typical errors that result from clock integrity problems are invalid ID messages, blank-check errors, or verification errors. Altera recommends pulling the TCK signal low through the internal weak pull-down resistor or an external 1-k resistor. Fast TCK edges combined with board inductance can cause overshoot problems. When this combination occurs, you must either reduce inductance on the trace or reduce the switching rate by selecting a transistor-to-transistor logic (TTL) driver chip with a slower slew rate. Altera does not recommend using resistor and capacitor (RC) networks to slow down edge rates, because they can violate the device’s input specifications. In most cases, using a driver chip prevents the edge rate from being too slow. Altera recommends using driver chips that do not glitch upon power-up. Programming via a Download Cable You can program MAX II devices using a MasterBlasterTM, ByteBlasterMVTM, ByteBlasterTM II, or USB Blaster download cable. Using a PC or UNIX workstation with the Quartus II software programmer, Programmer Object File (.pof), JamTM Files (.jam), or Jam Byte-Code Files (.jbc) can be downloaded to the MAX II devices via the download cable. If you are using the download cables and your JTAG chain contains three or more devices, Altera recommends adding a buffer to the chain. You should select a buffer with slow transitions to minimize noise, but be sure that the transition rates can still meet TCK performance requirements of your chain. If you must extend the download cable, you can attach a standard PC parallel or USB port cable to the download cable. Do not extend the 10-pin header portion of the download cable; extending this portion of the cable can cause noise and in-system programming problems. f Different download cables will have different programming times. For more information about the MasterBlaster, ByteBlasterMV, ByteBlaster II, or USB Blaster download cable, refer to the MasterBlaster Serial/USB Communications Cable User Guide, ByteBlasterMV Download Cable User Guide, ByteBlaster II Download Cable User Guide, or USB-Blaster Download Cable User Guide. Disabling IEEE Std. 1149.1 Circuitry By default, the JTAG circuitry in MAX II devices is always enabled because they have dedicated JTAG pins and circuitry. The JTAG circuitry must be enabled during ISP and boundary-scan testing, but disabled at all other times. If your design does not use ISP or boundary-scan test (BST) circuitry, Altera recommends disabling the IEEE Std. 1149.1 circuitry. To disable the JTAG circuitry, Altera recommends pulling TMS high and TCK low. Pulling TCK low ensures that a rising edge does not occur on TCK during the power- up sequence. You can pull TCK high, but you must first pull TMS high. Pulling TMS high first ensures that the rising edge or edges on TCK do not cause the JTAG state machine to leave the test-logic-reset state. © October 2008 Altera Corporation MAX II Device Handbook
11–6 Chapter 11: In-System Programmability Guidelines for MAX II Devices Sequential versus Concurrent Programming f For more information about disabling the IEEE 1149.1 circuitry, refer to the Disabling IEEE Std. 1149.1 BST Circuitry section of the IEEE 1149.1 (JTAG) Boundary-Scan Testing chapter in the MAX II Device Handbook. Working with Different Voltage Levels When devices in a JTAG chain operate at different voltage levels, a device’s output voltage specification must meet the subsequent device’s input voltage specification. If the devices do not meet this criteria, you must add additional circuitry, such as a level- shifter, to adjust the voltage levels. For example, when a 5.0-V device drives a 2.5-V device, you must adjust the 5.0-V device’s output voltage to meet the 2.5-V device’s input voltage specification. Because all devices in a JTAG chain are tied together, you must also ensure that the first device’s TDO output meets the subsequent device’s TDI input voltage specification to program a chain of devices successfully. All MAX II devices include a MultiVolt I/O feature, which allows these devices to interface with systems that have different supply voltages. All MAX II devices can be set for 3.3-V, 2.5-V, 1.8-V, or 1.5-V I/O operation. The JTAG pins of MAX II devices support these voltage levels. Refer to the MAX II Architecture chapter in the MAX II Device Handbook for I/O standard compatibility for each V voltage. For example, CCIO V at 3.3 V does not allow JTAG input pins to accept 1.8- or 1.5-V signals. CCIO1 Sequential versus Concurrent Programming This section describes how to program multiple devices using sequential and concurrent programming. The JTAG chain setup for sequential and concurrent programming is similar, only the programming algorithms are different. Sequential Programming Sequential programming is the process of programming multiple devices in a chain, one device at a time. After the first device in the chain is finished being programmed, the next device is programmed. This sequence continues until all specified devices in the JTAG chain are programmed. After a device is programmed, it will be in bypass mode to allow data to be passed to the subsequent devices in the chain. The devices in the chain do not go into user mode until all the devices are programmed. Concurrent Programming Concurrent programming is used to program devices from the same family (for example, the MAX II family) in parallel. The programming time is slightly longer than the time needed to program the largest device in the chain, resulting in considerably faster programming times than sequential programming (where programming time is equal to the sum of individual programming times for all devices). Higher clock rates for shifting data result in even greater time savings. Concurrent programming of devices can be done using Serial Vector Format files (.svf), Jam files, or JBC files created from the Quartus II software. See Figure 11–2. 1. On the Tools menu, click Programmer. 2. Click Add File and select programming files for the respective devices. MAX II Device Handbook © October 2008 Altera Corporation
Chapter 11: In-System Programmability Guidelines for MAX II Devices 11–7 ISP Troubleshooting Guidelines 3. On the File menu, point to Create/Update and click Create JAM, SVF, or ISC File. 4. Specify a file in the File format list. 5. Click OK. Figure 11–2. Create JAM, SVF, or ISC File ISP Troubleshooting Guidelines This section provides tips for troubleshooting ISP-related problems. Invalid ID and Unrecognized Device Messages The first step during in-system programming is to check the device’s silicon ID. If the silicon ID does not match, an Invalid ID or Unrecognized Device error is generated. Typical causes for this error are shown below: ■ Download cable connected incorrectly ■ TDO is not connected ■ Incomplete JTAG chain ■ Noisy TCK signal ■ Jam Player ported incorrectly Download Cable Connected Incorrectly You will receive an error if the download cable is connected incorrectly to the parallel or USB port or if it is not receiving power from your board. f For more information about installing the MasterBlaster, ByteBlasterMV, ByteBlaster, or USB Blaster download cable, refer to the MasterBlaster Serial/USB Communications Cable User Guide, ByteBlasterMV Download Cable User Guide, ByteBlaster II Download Cable User Guide, or USB-Blaster Download Cable User Guide. © October 2008 Altera Corporation MAX II Device Handbook
11–8 Chapter 11: In-System Programmability Guidelines for MAX II Devices ISP Troubleshooting Guidelines TDO Is Not Connected You will receive an error if the TDO port of one device in the chain is not connected. During in-system programming, data must be shifted in and out of each device in the JTAG chain through the JTAG pins. Therefore, each device’s TDO port must be connected to the subsequent device’s TDI port, and the last device’s TDO port must be connected to the download cable’s TDO port. Incomplete JTAG Chain You will receive an error if the JTAG chain is not complete. To check if an incomplete JTAG chain is causing the error, use an oscilloscope to monitor vectors coming out of each device in the chain. If each device’s TDO port does not toggle during in-system programming, your JTAG chain is not complete. Noisy TCK Signal Noise on the TCK signal is the most common reason for in-system programming errors. Noisy transitions on rising or falling edges can cause incorrect clocking of the IEEE Std. 1149.1 TAP controller, causing the state machine to be lost and in-system programming to fail. For more information about dealing with noisy TCK signals, refer to “TCK Signal” on page11–4. Jam Player Ported Incorrectly You will receive an error if the Jam Player was not ported correctly for your platform. To check if the Jam Player is causing the error, apply the IDCODE instruction to the target device using a Jam file. You can use a Jam file to load an IDCODE instruction and then shift out the IDCODE value. This test determines if the JTAG chain is set up correctly and if you can read and write to the JTAG chain properly. You can download the idcode.zip file from the Altera website to obtain the idcode.jam file. Troubleshooting Tips This section discusses some additional suggestions for troubleshooting ISP issues. Verify the JTAG Chain Continuity For in-system programming to occur successfully, the number of devices physically in the JTAG chain must match the number reported in the Quartus II software. The following steps show one simple way to verify that the JTAG chain is connected properly. 1. Open the Programmer in the Quartus II software. 2. Click Auto Detect in the Programmer. The Quartus II software reports the number of devices found on the JTAG chain. If this fails, check the JTAG chain to make sure it is not broken. MAX II Device Handbook © October 2008 Altera Corporation
Chapter 11: In-System Programmability Guidelines for MAX II Devices 11–9 ISP via Embedded Processors Check the V Level of the Board During In-System Programming CC Using an oscilloscope, monitor the V signal on your JTAG chain and set the CCINT trigger to the minimum V level listed in the recommended operating conditions CC table of the appropriate device family data sheet. If a trigger occurs during in-system programming, the devices may need more current than is being supplied by the existing power supply. Try replacing the existing power supply with one that provides more current. Power-Up Problems Excessive voltage or current on I/O pins during power-up can cause one of the devices in the JTAG chain to experience latch-up. Check if any of the devices are hot to the touch; hot devices have probably experienced latch-up and may have been damaged. In this situation, check all voltage sources to make sure that excessive voltage or current is not being fed into the device. Then, replace the affected device and try programming again. Random Signals on JTAG Pins During normal operation, each device’s TAP controller must be in the test-logic-reset state. To force the device back into this state, try pulling the TMS signal high and pulsing the TCK clock signal six times. If the device then powers-up successfully, you must add a higher pull-down resistor on the TCK signal. Software Issues Failures during in-system programming may occasionally be related to the Quartus II software. Software-related issues are documented in the Find Answers section under the Support Center on the Altera website at www.altera.com. Search the database for information relating to software issues that interfere with in-system programming. ISP via Embedded Processors This section provides guidelines for programming ISP-capable devices using the Jam Standard Test and Programming Language (STAPL) and an embedded processor. Processor and Memory Requirements The Jam Byte-Code Player supports 8-bit and higher processors; the ASCII Jam Player supports 16-bit and higher processors. The Jam Player uses memory in a predictable manner, which simplifies in-field upgrades by confining updates to the Jam File. The Jam Player memory uses both ROM and dynamic memory (RAM). ROM is used to store the Jam Player binary and the Jam File; dynamic memory is used when the Jam Player is called. f For information about how to estimate the maximum amount of RAM and ROM required by the Jam Player, refer to the Using Jam STAPL for ISP via an Embedded Processor chapter in the MAX II Device Handbook. © October 2008 Altera Corporation MAX II Device Handbook
11–10 Chapter 11: In-System Programmability Guidelines for MAX II Devices ISP via In-Circuit Testers Porting the Jam Player The Altera Jam Player (both Byte-Code and ASCII versions) works with a PC parallel port. To port the Jam Player to your processor, you only need to modify the jamstub.c or jbistub.c file (for the ASCII Jam Player or Jam Byte-Code Player, respectively). All other files should remain the same. If the Jam Player is ported incorrectly, an Unrecognized Device error is generated. The most common causes for this error are listed below: ■ After porting the Jam Player, the TDO value may be read in reversed polarity. This problem may occur because the default I/O code in the Jam Player assumes the use of the PC parallel port. ■ Although the TMS and TDI signals are clocked in on the rising edge of TCK, outputs do not change until the falling edge of TCK. This situation causes a half TCK clock cycle lag in reading out the values. If the TDO transition is expected on the rising edge, the data appears to be offset by one clock. ■ Altera recommends using registers to synchronize the output transitions. In addition, some processor data ports use a register to synchronize the output signals. For example, reading and writing to the PC’s parallel port is accomplished by reading and writing to registers. The use of these registers must be taken into consideration when reading and writing to the JTAG chain. Incorrect accounting of these registers can cause the values to either lead or lag the expected value. ISP via In-Circuit Testers MAX II devices can also be in-system programmed via in-circuit testers. For more information about using Agilent’s 3070 in-circuit tester to in-system program MAX II devices, refer to the Using Jam STAPL for ISP via an Embedded Processor chapter in the MAX II Device Handbook. Conclusion The information provided in this document is based on development experiences and customer issues resolved by Altera. For more information about resolving in-system programming problems, contact Altera Applications. Referenced Documents This chapter references the following documents: ■ AN 75: High-Speed Board Designs ■ ByteBlasterMV Download Cable User Guide ■ ByteBlaster II Download Cable User Guide ■ DC and Switching Characteristics chapter in the MAX II Device Handbook ■ IEEE 1149.1 (JTAG) Boundary-Scan Testing for MAX II Devices chapter in the MAX II Device Handbook ■ JTAG and In-System Programmability chapter in the MAX II Device Handbook ■ MasterBlaster Serial/USB Communications Cable User Guide MAX II Device Handbook © October 2008 Altera Corporation
Chapter 11: In-System Programmability Guidelines for MAX II Devices 11–11 Document Revision History ■ USB-Blaster Download Cable User Guide ■ Using Jam STAPL for ISP via an Embedded Processor chapter in the MAXII Device Handbook Document Revision History Table11–1 shows the revision history for this chapter. Table11–1. Document Revision History Date and Revision Changes Made Summary of Changes October 2008, ■ Updated New Document Format. — version 1.7 December 2007, ■ Updated “Pull-Up and Pull-Down of JTAG Pins During In-System External pull-up for TDI is version 1.6 Programming” section. optional. ■ Added “Referenced Documents” section. December 2006, ■ Added document revision history. — version 1.5 August 2006, ■ Corrected Figure11–1. — version 1.4 January 2005, ■ Previously published as Chapter 12. No changes to content. — version 1.3 December 2004, ■ Added section User Flash Memory Operations During In-System — version 1.2 Programming. June 2004, ■ Pull-up resistor values. Textual updates. — version 1.1 © October 2008 Altera Corporation MAX II Device Handbook
11–12 Chapter 11: In-System Programmability Guidelines for MAX II Devices Document Revision History MAX II Device Handbook © October 2008 Altera Corporation
12. Real-Time ISP and ISP Clamp for MAX II Devices MII51019-1.6 Introduction During in-system programming, most CPLDs automatically tri-state their input/output (I/O) pins to prevent contention issues on a board. After successful programming, the device enters user mode and the new design begins to function. Apart from this normal programming mode, MAX® II devices also support real-time in-system programmability (ISP) and ISP Clamp programming modes, which allow control of I/O and device behavior during ISP. This chapter describes the following two features and how to use them in the Quartus® II software, as well as the Jam™ Standard Test and Programming Language (STAPL) and Jam STAPL Byte-Code Players: ■ “Real-Time ISP” on page12–1 ■ “ISP Clamp” on page12–4 Real-Time ISP Real-time ISP allows you to program a MAX II device while the device is still in operation. The new design only replaces the existing design when there is a power cycle to the device (i.e., powering down and powering up again). This feature enables you to perform in-field updates to the MAX II device at any time without affecting the operation of the whole system. How Real-Time ISP Works For normal ISP operation, downloading the new design data from the configuration flash memory (CFM) to the SRAM begins after the completion of CFM programming. During the process of CFM programming and subsequent downloading of CFM data to SRAM, I/O pins will remain tri-stated. After the CFM download to the SRAM, the device resets and enters user mode operation. Figure12–1 shows the flow of normal programming. Figure12–1. MAX II Device with Normal ISP Operation 1 1 Programming JTAG CFM Data 2 SRAM (Logic Array) © October 2008 Altera Corporation MAX II Device Handbook
12–2 Chapter 12: Real-Time ISP and ISP Clamp for MAX II Devices Real-Time ISP In real-time ISP mode, the user flash memory (UFM), programmable logic, and I/O pins remain operational while programming of the CFM is in progress. The contents of the CFM will not download into the SRAM after the successful programming of the CFM. Instead, the device waits for a power cycle to occur. The normal power-up sequence occurs (CFM downloads to SRAM at power-up) and the device enters user mode after t time. Figure12–2 shows the flow of real-time ISP. CONFIG Figure12–2. Real-Time ISP Operation Programming JTAG CFM JTAG CFM Data Power Cycle SRAM SRAM (Logic Array) (Logic Array) Programming of CFM CFM Contents Download (Device Remains Operational) (Device I/Os Tri-Stated) f For the t value for a specific MAX II device, refer to the DC and Switching CONFIG Characteristics chapter in the MAX II Device Handbook. Real-Time ISP with the Quartus II Software The programming file formats generated by the Quartus II software that support these two features are the Programmer Object File (.pof) that is used with the Quartus II programmer, and the Jam File (.jam) and Jam Byte-Code File (.jbc) that are used with either the Quartus II programmer or other programming tools. Ensure that you enable this feature before programming a MAX II device through the QuartusII programmer. You can enable the real-time ISP feature by selecting the Enable real-time ISP to allow background programming (for MAX II devices) option from the Quartus II programmer window. See Figure12–3. MAX II Device Handbook © October 2008 Altera Corporation
Chapter 12: Real-Time ISP and ISP Clamp for MAX II Devices 12–3 Real-Time ISP Figure12–3. Real-Time ISP Option in the Quartus II Programmer Window You can also enable the real-time ISP feature in the QuartusII software through the following steps: 1. On the Tools menu, click Options. 2. Under Category, select Programmer. 3. Turn on Enable real-time ISP to allow background programming (for MAX II devices) and click OK. The MAX II device will go into real-time ISP mode when the Quartus II programmer starts programming it with any one of the three types of programming files. © October 2008 Altera Corporation MAX II Device Handbook
12–4 Chapter 12: Real-Time ISP and ISP Clamp for MAX II Devices ISP Clamp Figure12–4 shows the Programmer options in the Options menu. Figure12–4. Programmer Options in the Options Menu Real-Time ISP with Jam and JBC Players You can use the Jam or JBC file created from the POF to program a MAXII device in real-time ISP mode with the Jam or JBC Player. For real-time ISP with the Jam File and Jam Player, type the following at the command-line prompt: jp_23 -aprogram -ddo_real_time_isp=1 <file_name.jam> For Real-Time ISP with the JBC File and JBC Player, type the following at the command-line prompt: jbi_22 -aprogram -ddo_real_time_isp=1 <file_name.jbc> The names of the executable files for the players are different, depending on the version of the players. Download the latest version of the Jam and JBC Player from the Altera® web site at www.altera.com. ISP Clamp When a MAX II device enters normal ISP operation, all the I/O pins tri-state and are weakly pulled up to V with internal pull-up resistors. However, there are CCIO situations when the I/O pins of the device should not be tri-stated when the device is in ISP operation. For instance, in a running system, some signals (e.g., output enable or chip enable signals) might use some of the I/O pins and require those I/O pins to assume a high or low logic level, or even maintain their current state when the device is in ISP mode. MAX II Device Handbook © October 2008 Altera Corporation
Chapter 12: Real-Time ISP and ISP Clamp for MAX II Devices 12–5 ISP Clamp With the ISP clamp feature in MAX II devices, you can hold each I/O pin of a device to a specified static state when programming the device. You can set the state in the Quartus II software. After successfully programming the device in ISP clamp mode, those I/O pins will be released and function according to the new design. This feature can be used to indicate when the device is being programmed and when the programming is done by setting a particular pin to a specific state (different from the state when the device is in user mode) when the device enters ISP clamp mode. How ISP Clamp Works When the ISP clamp feature is used, you can set the I/O pins to tri-state (default), high, low, or even sample the existing state of a pin and hold the pin to that state when the device is in ISP clamp operation. The software determines the values to be scanned into the boundary-scan registers of each I/O pin, based on your settings. This will determine the state of the pins to be clamped to when the device programming is in progress. The weak I/O pull-up resistors are disabled during programming when the ISP clamp feature is used, even if the I/O is clamped to a tri-state value. Before clamping the I/O pins, the SAMPLE/PRELOAD JTAG instruction is first executed to load the appropriate values to the boundary-scan registers. After loading the boundary-scan registers with the appropriate values, the EXTEST instruction is executed to clamp the I/O pins to the specific values loaded into the boundary-scan registers during SAMPLE/PRELOAD. If you choose to sample the existing state of a pin and hold the pin to that state when the device enters ISP clamp mode, you must make sure that the signal is in steady state. You need a steady state signal because you cannot control the sample set-up time as it depends on the TCK frequency as well as the download cable and software. You might not capture the correct value when sampling a signal that toggles or is not static for long periods of time. Figure12–5 shows the ISP clamp operation. Figure12–5. ISP Clamp Operation 1 Before Programming 2 During Programming 3 After Programming (User Mode) (ISP Clamp Mode) (User Mode) JTAG CFM Programming JTAG CFM JTAG CFM Data SRAM SRAM SRAM (Core Logic) (Core Logic) (Core Logic) I/Os Drive Out I/Os Clamped to I/Os Drive Out According to Design Specified States According to New Design Using ISP Clamp in the Quartus II Software You have to define the states of the I/O pins to use the ISP clamp feature. There are two ways to define the pin states in the Quartus II software. You can either: ■ Use an I/O Pin State file (.ips), or ■ Use the Assignment Editor to set the clamp states of the pins © October 2008 Altera Corporation MAX II Device Handbook
12–6 Chapter 12: Real-Time ISP and ISP Clamp for MAX II Devices ISP Clamp Using the IPS File Creating an IPS File You can specify the clamp states of the pins when the device is in ISP clamp operation without configuring the settings in the Assignment Editor and recompiling the design. You must first create a new I/O pin state file (.ips) file and define the states of the pins in the file, or use an existing IPS file. The IPS file defines the states for all the pins of the device when the device is in ISP clamp operation. The file created is usable for programming the device with any designs, as long as it targets the same device and package. An IPS file must be used together with a POF file, which contains the programming data to program the device. To create an IPS file, perform the following: 1. Click Programmer on the toolbar, or on the Tools menu, click Programmer to open the Quartus II Programmer window. 2. Click Add File in the programmer to add the programming file (POF, Jam, or JBC) into the programmer window. 3. Click on the programming file in the programmer (the entire row will be highlighted) and on the Edit menu, click ISP CLAMP State Editor. See Figure12–6. Figure12–6. Edit Menu 4. Specify the states of the pins in your design in the ISP Clamp State Editor. There are four clamp state choices: tri-state, high, low, and sample and sustain. By default, all pins are set to tri-state. 5. Save the IPS file after making the modifications. Figure12–7 shows the ISP Clamp State Editor. On the File menu, you can also click Create/Update > Create/Update IPS File to open the ISP Clamp State Editor and create a new IPS file. MAX II Device Handbook © October 2008 Altera Corporation
Chapter 12: Real-Time ISP and ISP Clamp for MAX II Devices 12–7 ISP Clamp Figure12–7. ISP Clamp State Editor Using the IPS File In the Quartus II Programmer, you must specify the IPS file you want to use by performing the following steps: 1. Double-click on the cell under the IPS File column. The Select I/O Pin State File menu appears. 2. Choose the IPS file for your project and click Open. You can also left-click on the programming file (this will highlight the entire row) and on the Edit menu, click Add IPS File to open the Select I/O Pin State File dialog box as shown in Figure12–8. Figure12–8. Select I/O Pin State File Menu 1. The IPS file you have selected will be listed in the Quartus II Programmer window, as shown in Figure12–9. 1 Make sure the ISP CLAMP check box is checked before you start programming your device. © October 2008 Altera Corporation MAX II Device Handbook
12–8 Chapter 12: Real-Time ISP and ISP Clamp for MAX II Devices ISP Clamp Figure12–9. The Quartus II Programmer Window with the Specific IPS File Saving the IPS File Information to the Programming File The pin state information in the IPS file can be saved into the POF to avoid requiring two files. You will only need the programming file to program a device in ISP clamp mode. This programming file is also used for creating the Jam and JBC files for the ISP clamp so that the Jam or JBC files will contain the pin state information. The following are the steps to save the pin state information from the IPS file to the programming files. 1. Add in the programming file in the programmer window. 2. Add in the IPS file to the programmer. 3. Click Save File in the programmer window or on the Edit menu, and the Save Data To File As dialog box will appear. See Figure12–10. 4. Enter the file name, check the Include IPS file information box, and click Save. The POF with saved IPS information only supports ISP clamp operation in the Quartus II software and not with third-party programming tools. For third-party tools, Jam or JBC files should be used if ISP clamp is required. Figure12–10. Save Data To File as Menu When programming a device with the ISP Clamp box checked, the Quartus II Programmer will first look for the IPS file. If the IPS file is not found, only then it will look into the POF for the pin state information. MAX II Device Handbook © October 2008 Altera Corporation
Chapter 12: Real-Time ISP and ISP Clamp for MAX II Devices 12–9 ISP Clamp Defining the Pin States in Assignment Editor Another way to define the pin states is through the Assignment Editor. After you have defined the pin states in the Assignment Editor and compile the design, the programming file generated will have all the pin state information in it. The following are the assignment editor states: 1. Click Start Analysis and Synthesis on the toolbar. 2. On the Assignments menu, click Assignment Editor. 3. In the Assignment Editor, under Category, select I/O Features. 4. List down all the pins you wish to clamp when the device is in ISP clamp mode under the To column. You can use the Node Finder to help you select the pins. 5. Select In-System Programming Clamp State for all the pins under Assignment Name after you have listed down the pins you wish to set state values. 6. Define the states for each of the pins under Value. You can also choose to clamp the pins to high, low, tri-state, or sample and sustain the pin state. By default, the pins are tri-stated when the device enters ISP clamp mode. Figure12–11 shows how to define the states of the pins in the Assignment Editor. Figure12–11. Assignment Editor 1. Save the assignments and recompile your design. After you have recompiled the design, the ISP clamp state information will be stored in the POF. You can also view the settings in the Quartus II Settings File (.qsf). Running ISP Clamp in the Quartus II Programmer In the Quartus II Programmer window, make sure that the ISP Clamp check box is checked before programming the device. Do not add any IPS file in the programmer as the programmer will use the values specified in the IPS file instead of the values you set in the Assignment Editor (which is stored in the POF). Figure12–12 shows the Quartus II Programmer window with ISP Clamp checkbox. Jam and JBC files created using the POF will have the pin state information in them. © October 2008 Altera Corporation MAX II Device Handbook
12–10 Chapter 12: Real-Time ISP and ISP Clamp for MAX II Devices Conclusion Figure12–12. Quartus II Programmer Window with ISP Clamp Checkbox ISP Clamp with Jam/JBC Files The Jam or JBC files used for ISP clamp should contain all the pin state information and do not need any IPS file. Always use the POF file with pin state information to create the Jam or JBC files. The pin state information can be stored into the POF through the Assignment Editor or saving the pin state information to the POF as mentions earlier. The Jam or JBC files can be used with the Quartus II programmer, or with the Jam or JBC player, respectively. Conclusion With the real-time ISP and ISP clamp features in MAX II devices, you can set the I/O pins of a device to certain states while programming the device. Through real-time ISP, you can program a MAX II device at any time without affecting the functionality of your system. The ISP clamp feature allows you to hold the I/O pins of a device to specific states when programming the device. Referenced Documents This chapter references the following document: ■ DC and Switching Characteristics chapter in the MAX II Device Handbook MAX II Device Handbook © October 2008 Altera Corporation
Chapter 12: Real-Time ISP and ISP Clamp for MAX II Devices 12–11 Document Revision History Document Revision History Table12–1 shows the revision history for this chapter. Table12–1. Document Revision History Date and Revision Changes Made Summary of Changes October 2008, ■ Updated New Document Format. — version 1.6 December 2007, ■ Added “Referenced Documents” section. — version 1.5 December 2006, ■ Added document revision history. — version 1.4 February 2006, ■ Updated the “Real-Time ISP with the Quartus II Software” section. — version 1.3 ■ Added Figure12–3. ■ Updated Figure12–9 and 12–10. June 2005, ■ Updated the first paragraph of the How ISP Clamp Works section. — version 1.2 January 2005, ■ Previously published as Chapter 13. No changes to content. — version 1.1 © October 2008 Altera Corporation MAX II Device Handbook
12–12 Chapter 12: Real-Time ISP and ISP Clamp for MAX II Devices Document Revision History MAX II Device Handbook © October 2008 Altera Corporation
13. IEEE 1149.1 (JTAG) Boundary-Scan Testing for MAX II Devices MII51014-1.7 Introduction As printed circuit boards (PCBs) become more complex, the need for thorough testing becomes increasingly important. Advances in surface-mount packaging and PCB manufacturing have resulted in smaller boards, making traditional test methods (for example, external test probes and “bed-of-nails” test fixtures) harder to implement. As a result, cost savings from PCB space reductions are sometimes offset by cost increases in traditional testing methods. In the 1980s, the Joint Test Action Group (JTAG) developed a specification for boundary-scan testing that was later standardized as the IEEE Std. 1149.1 specification. This boundary-scan test (BST) architecture offers the capability to efficiently test components on PCBs with tight lead spacing. This BST architecture can test pin connections without using physical test probes and capture functional data while a device is operating normally. Boundary-scan cells in a device can force signals onto pins, or capture data from pin or core logic signals. Forced test data is serially shifted into the boundary-scan cells. Captured data is serially shifted out and externally compared to expected results. Figure13–1 shows the concept of boundary-scan testing. Figure13–1. IEEE Std. 1149.1 Boundary-Scan Testing Boundary-Scan Cell Serial Serial Data In IC Pin Signal Data Out Core Core Logic Logic Interconnection to Be Tested JTAG Device 1 JTAG Device 2 This chapter discusses how to use the IEEE Std. 1149.1 BST circuitry in MAX®II devices. The topics are as follows: ■ “IEEE Std. 1149.1 BST Architecture” on page13–2 ■ “IEEE Std. 1149.1 Boundary-Scan Register” on page13–3 ■ “IEEE Std. 1149.1 BST Operation Control” on page13–6 ■ “I/O Voltage Support in JTAG Chain” on page13–15 ■ “BST for Programmed Devices” on page13–15 ■ “Disabling IEEE Std. 1149.1 BST Circuitry” on page13–16 ■ “Guidelines for IEEE Std. 1149.1 Boundary-Scan Testing” on page13–16 ■ “Boundary-Scan Description Language (BSDL) Support” on page13–17 © October 2008 Altera Corporation MAX II Device Handbook
13–2 Chapter 13: IEEE 1149.1 (JTAG) Boundary-Scan Testing for MAXII Devices IEEE Std. 1149.1 BST Architecture In addition to BST, you can use the IEEE Std. 1149.1 controller for in-system programming for MAXII devices. MAXII devices support IEEE1532 programming, which utilizes the IEEE Std. 1149.1 Test Access Port (TAP) interface. However, this chapter only discusses the BST feature of the IEEE Std. 1149.1 circuitry. IEEE Std. 1149.1 BST Architecture A MAXII device operating in IEEE Std. 1149.1 BST mode uses four required pins, TDI, TDO, TMS, and TCK. Table13–1 summarizes the functions of each of these pins. MAXII devices do not have a TRST pin. Table13–1. EEE Std. 1149.1 Pin Descriptions Pin Description Function TDI (1) Test data input Serial input pin for instructions as well as test and programming data. Data is shifted in on the rising edge of TCK. TDO Test data output Serial data output pin for instructions as well as test and programming data. Data is shifted out on the falling edge of TCK. The pin is tri-stated if data is not being shifted out of the device. TMS (1) Test mode select Input pin that provides the control signal to determine the transitions of the TAP controller state machine. Transitions within the state machine occur at the rising edge of TCK. Therefore, TMS must be set up before the rising edge of TCK. TMS is evaluated on the rising edge of TCK. TCK (2) Test clock input The clock input to the BST circuitry. Some operations occur at the rising edge, while others occur at the falling edge. Notes to Table13–1: (1) The TDI and TMS pins have internal weak pull-up resistors (2) The TCK pin has an internal weak pull-down resistor The IEEE Std. 1149.1 BST circuitry requires the following registers: ■ The instruction register, which is used to determine the action to be performed and the data register to be accessed. ■ The bypass register, which is a 1-bit-long data register used to provide a minimum-length serial path between TDI and TDO. ■ The boundary-scan register that is a shift register composed of all the boundary- scan cells of the device. MAX II Device Handbook © October 2008 Altera Corporation
Chapter 13: IEEE 1149.1 (JTAG) Boundary-Scan Testing for MAXII Devices 13–3 IEEE Std. 1149.1 Boundary-Scan Register Figure13–2 shows a functional model of the IEEE Std. 1149.1 circuitry. Figure13–2. IEEE Std. 1149.1 Circuitry Instruction Register TDI TDO UPDATEIR CLOCKIR SHIFTIR TAP Instruction Decode TMS Controller TCK UPDATEDR Data Registers CLOCKDR Bypass Register SHIFTDR Boundary-Scan Register (1) a Device ID Register ISP Registers Note to Figure13–2: (1) Refer to the JTAG and In-System Programmability chapter in the MAX II Device Handbook for the boundary-scan register length in MAXII devices. IEEE Std. 1149.1 boundary-scan testing is controlled by a TAP controller, which is described in “IEEE Std. 1149.1 BST Operation Control” on page13–6. The TMS and TCK pins operate the TAP controller, and the TDI and TDO pins provide the serial path for the data registers. The TDI pin also provides data to the instruction register, which then generates control logic for the data registers. IEEE Std. 1149.1 Boundary-Scan Register The boundary-scan register is a large serial shift register that uses the TDI pin as an input and the TDO pin as an output. The boundary-scan register consists of 3-bit peripheral elements that are associated with I/O pins of the MAXII devices. You can use the boundary-scan register to test external pin connections or to capture internal data. f Refer to the JTAG and In-System Programmability chapter in the MAX II Device Handbook for the boundary-scan register length of MAXII devices. © October 2008 Altera Corporation MAX II Device Handbook
13–4 Chapter 13: IEEE 1149.1 (JTAG) Boundary-Scan Testing for MAXII Devices IEEE Std. 1149.1 Boundary-Scan Register Figure13–3 shows how test data is serially shifted around the periphery of the IEEE Std. 1149.1 device. Figure13–3. Boundary-Scan Register Each peripheral element is either an I/O pin, dedicated input pin, or Internal Logic dedicated configuration pin. TAP Controller TDI TMS TCK TDO Boundary-Scan Cells of a MAX II Device I/O Pin Except for the four JTAG pins and power pins, all pins of a MAXII device (including clock pins) can be used as user I/O pins and have a boundary-scan cell (BSC). The 3- bit BSC consists of a set of capture registers and a set of update registers. The capture registers can connect to internal device data via the OUTJ and OEJ signals, while the update registers connect to external data through the PIN_OUT and PIN_OE signals. The global control signals for the IEEE Std. 1149.1 BST registers (for example, SHIFT, CLOCK, and UPDATE) are generated internally by the TAP controller; the MODE signal is generated by a decode of the instruction register. The data signal path for the boundary-scan register runs from the serial data in (SDI) signal to the serial data out (SDO) signal. The scan register begins at the TDI pin and ends at the TDO pin of the device. MAX II Device Handbook © October 2008 Altera Corporation
Chapter 13: IEEE 1149.1 (JTAG) Boundary-Scan Testing for MAXII Devices 13–5 IEEE Std. 1149.1 Boundary-Scan Register Figure13–4 shows the User I/O Boundary-Scan Cell of MAXII devices. Figure13–4. MAXII Device’s User I/O BSC with IEEE Std. 1149.1 BST Circuitry SDO PIN_IN INJ 0 D Q 1 Input OEJ 0 PIN_OE 1 0 D Q D Q 0 1 OE OE 1 From or To Device I/O Cell Circuitry And/Or Logic Core OUTJ 0 PIN_OUT 0 1 1 D Q D Q Pin Output Output Output Buffer SHIFT CLOCK UPDATE HIGHZ MODE Global Signals Capture Update SDI Registers Registers Table13–2 describes the capture and update register capabilities of all boundary-scan cells within MAXII devices. Table13–2. MAXII Device’s Boundary-Scan Cell Descriptions (Note1) Captures Drives Output Output Capture OE Capture Input Capture Update OE Update Input Update Pin Type Register Register Register Register Register Register Notes User I/O OUTJ OEJ PIN_IN PIN_OUT PIN_OE — Includes User Clocks Note to Table13–2: (1) TDI, TDO, TMS, and TCK pins, and all VCC and GND pin types do not have boundary-scan cells. JTAG Pins and Power Pins MAXII devices do not have boundary-scan cells for the dedicated JTAG pins (TDI, TDO, TMS, and TCK) and power pins (VCCINT, VCCIO, GNDINT, and GNDIO). © October 2008 Altera Corporation MAX II Device Handbook
13–6 Chapter 13: IEEE 1149.1 (JTAG) Boundary-Scan Testing for MAXII Devices IEEE Std. 1149.1 BST Operation Control IEEE Std. 1149.1 BST Operation Control MAXII devices implement the following IEEE Std. 1149.1 BST instructions: SAMPLE/PRELOAD, EXTEST, BYPASS, IDCODE, USERCODE, CLAMP, and HIGHZ. The length of the BST instructions is 10 bits. These instructions are described in detail later in this chapter. f Refer to the JTAG and In-System Programmability chapter in the MAX II Device Handbook for a summary of the BST instructions and their instruction codes. The IEEE Std. 1149.1 TAP controller, a 16-state state machine clocked on the rising edge of TCK, uses the TMS pin to control IEEE Std. 1149.1 operation in the device. Figure13–5 shows the TAP controller state machine. MAX II Device Handbook © October 2008 Altera Corporation
Chapter 13: IEEE 1149.1 (JTAG) Boundary-Scan Testing for MAXII Devices 13–7 IEEE Std. 1149.1 BST Operation Control Figure13–5. IEEE Std. 1149.1 TAP Controller State Machine TEST_LOGIC/ TMS = 1 RESET TMS = 0 SELECT_DR_SCAN TMS = 1 SELECT_IR_SCAN TMS = 1 TMS = 1 RUN_TEST/ TMS = 0 IDLE TMS = 0 TMS = 0 TMS = 1 TMS = 1 CAPTURE_DR CAPTURE_IR TMS = 0 TMS = 0 SHIFT_DR SHIFT_IR TMS = 0 TMS = 0 TMS = 1 TMS = 1 TMS = 1 TMS = 1 EXIT1_DR EXIT1_IR TMS = 0 TMS = 0 PAUSE_DR PAUSE_IR TMS = 0 TMS = 0 TMS = 1 TMS = 1 TMS = 0 TMS = 0 EXIT2_DR EXIT2_IR TMS = 1 TMS = 1 TMS = 1 TMS = 1 UPDATE_DR UPDATE_IR TMS = 0 TMS = 0 When the TAP controller is in the TEST_LOGIC/RESET state, the BST circuitry is disabled, the device is in normal operation, and the instruction register is initialized with IDCODE as the initial instruction. At device power-up, the TAP controller starts in this TEST_LOGIC/RESET state. In addition, the TAP controller may be forced to the TEST_LOGIC/RESET state by holding TMS high for five TCK clock cycles. Once in the TEST_LOGIC/RESET state, the TAP controller remains in this state as long as TMS continues to be held high while TCK is clocked. Figure13–6 shows the timing requirements for the IEEE Std. 1149.1 signals. © October 2008 Altera Corporation MAX II Device Handbook
13–8 Chapter 13: IEEE 1149.1 (JTAG) Boundary-Scan Testing for MAXII Devices IEEE Std. 1149.1 BST Operation Control Figure13–6. IEEE Std. 1149.1 Timing Waveforms (Note1) TMS TDI tJCP tJPSU tJPH tJCH tJCL TCK tJPZX tJPCO tJPXZ TDO tJSSU tJSH Signal to Be Captured tJSZX tJSCO tJSXZ Signal to Be Driven Note to Figure13–6: (1) For timing parameter values, refer to theDC and Switching Characteristics chapter in the MAX II Device Handbook. To start IEEE Std. 1149.1 operation, select an instruction mode by advancing the TAP controller to the shift instruction register (SHIFT_IR) state and shift in the appropriate instruction code on the TDI pin. The waveform diagram in Figure13–7 represents the entry of the instruction code into the instruction register. It shows the values of TCK, TMS, TDI, and TDO and the states of the TAP controller. From the RESET state, TMS is clocked with the pattern 01100 to advance the TAP controller to SHIFT_IR. Figure13–7. Selecting the Instruction Mode TCK TMS TDI TDO TAP_STATE SHIFT_IR RUN_TEST/IDLE SELECT_IR_SCAN EXIT1_IR SELECT_DR_SCAN CAPTURE_IR TEST_LOGIC/RESET The TDO pin is tri-stated in all states except the SHIFT_IR and SHIFT_DR states. The TDO pin is activated at the first falling edge of TCK after entering either of the shift states and is tri-stated at the first falling edge of TCK after leaving either of the shift states. When the SHIFT_IR state is activated, TDO is no longer tri-stated, and the initial state of the instruction register is shifted out on the falling edge of TCK. TDO continues to shift out the contents of the instruction register as long as the SHIFT_IR state is active. The TAP controller remains in the SHIFT_IR state as long as TMS remains low. MAX II Device Handbook © October 2008 Altera Corporation
Chapter 13: IEEE 1149.1 (JTAG) Boundary-Scan Testing for MAXII Devices 13–9 IEEE Std. 1149.1 BST Operation Control During the SHIFT_IR state, an instruction code is entered by shifting data on the TDI pin on the rising edge of TCK. The last bit of the opcode must be clocked at the same time that the next state, EXIT1_IR, is activated; EXIT1_IR is entered by clocking a logic high on TMS. Once in the EXIT1_IR state, TDO becomes tri-stated again. TDO is always tri-stated except in the SHIFT_IR and SHIFT_DR states. After an instruction code is entered correctly, the TAP controller advances to perform the serial shifting of test data in one of three modes—SAMPLE/PRELOAD, EXTEST, or BYPASS—that are described below. For MAX II devices, there are weak pull-up resistors for TDI and TMS, and pull-down resistors for TCK. However, in a JTAG chain, there might be some devices that do not have internal pull-up or pull-down resistors. In this case, Altera recommends pulling the TMS pin high (through an external 10-k resistor), and pulling TCK low (through an external 1-k resistor) during BST or in-system programmability (ISP) to prevent the TAP controller from going into an unintended state. Pulling-up the TDI signal externally for the MAX II device is optional. f For more information about the pull-up and pull-down resistors, refer to the In-System Programmability Guidelines for MAX II Devices chapter in the MAX II Device Handbook. SAMPLE/PRELOAD Instruction Mode The SAMPLE/PRELOAD instruction mode allows you to take a snapshot of device data without interrupting normal device operation. However, this instruction mode is most often used to preload the test data into the update registers prior to loading the EXTEST instruction. Figure13–8 shows the capture, shift, and update phases of the SAMPLE/PRELOAD mode. © October 2008 Altera Corporation MAX II Device Handbook
13–10 Chapter 13: IEEE 1149.1 (JTAG) Boundary-Scan Testing for MAXII Devices IEEE Std. 1149.1 BST Operation Control Figure13–8. IEEE Std. 1149.1 BST SAMPLE/PRELOAD Mode SDO PIN_IN INJ 0 D Q 1 Input OEJ 0 PIN_OE 1 0 D Q D Q 0 1 OE OE 1 OUTJ 0 PIN_OUT 0 1 1 D Q D Q Pin Output Output Output Buffer SHIFT CLOCK UPDATE HIGHZ MODE Global Signals Capture Update SDI Registers Registers (Capture Phase) SDO PIN_IN INJ 0 D Q 1 Input OEJ 0 PIN_OE 1 0 D Q D Q 0 1 OE OE 1 OUTJ 0 PIN_OUT 0 1 1 D Q D Q Pin Output Output Output Buffer SHIFT CLOCK UPDATE HIGHZ MODE Global Signals Capture Update SDI Registers Registers (Shift and Update Phase) MAX II Device Handbook © October 2008 Altera Corporation
Chapter 13: IEEE 1149.1 (JTAG) Boundary-Scan Testing for MAXII Devices 13–11 IEEE Std. 1149.1 BST Operation Control During the capture phase, multiplexers preceding the capture registers select the active device data signals; this data is then clocked into the capture registers. The multiplexers at the outputs of the update registers also select active device data to prevent functional interruptions to the device. During the shift phase, the boundary- scan shift register is formed by clocking data through capture registers around the device periphery and then out of the TDO pin. New test data can simultaneously be shifted into TDI and replace the contents of the capture registers. During the update phase, data in the capture registers is transferred to the update registers. This data can then be used in the EXTEST instruction mode. Refer to “EXTEST Instruction Mode” on page13–11 for more information. Figure13–9 shows the SAMPLE/PRELOAD waveforms. The SAMPLE/PRELOAD instruction code is shifted in through the TDI pin. The TAP controller advances to the CAPTURE_DR state and then to the SHIFT_DR state, where it remains if TMS is held low. The data shifted out of the TDO pin consists of the data that was present in the capture registers after the capture phase. New test data shifted into the TDI pin appears at the TDO pin after being clocked through the entire boundary-scan register. Figure13–9 shows that the test data that shifted into TDI does not appear at the TDO pin until after the capture register data that is shifted out. If TMS is held high on two consecutive TCK clock cycles, the TAP controller advances to the UPDATE_DR state for the update phase. If the device output enable feature is enabled but the DEV_OE pin is not asserted during boundary-scan testing, the OE boundary-scan registers of the boundary-scan cells capture data from the core of the device during SAMPLE/PRELOAD. These values are not high impedance, although the I/O pins are tri-stated. Figure13–9. SAMPLE/PRELOAD Shift Data Register Waveforms TCK TMS TDI TDO SHIFT_IR SHIFT_DR TAP_STATE EXIT1_IR SELECT_DR_SCAN Data stored in After boundry-scan EXIT1_DR Instruction Code UPDATE_IR CAPTURE_DR boundary- scan rsehgifitsetder o duatt, ad hataas been UPDATE_DR register is shifted entered into TDI will out of TDO. shift out of TDO. EXTEST Instruction Mode The EXTEST instruction mode is used primarily to check external pin connections between devices. Unlike the SAMPLE/PRELOAD mode, EXTEST allows test data to be forced onto the pin signals. By forcing known logic high and low levels on output pins, opens and shorts can be detected at pins of any device in the scan chain. Figure13–10 shows the capture, shift, and update phases of the EXTEST mode. © October 2008 Altera Corporation MAX II Device Handbook
13–12 Chapter 13: IEEE 1149.1 (JTAG) Boundary-Scan Testing for MAXII Devices IEEE Std. 1149.1 BST Operation Control Figure13–10. IEEE Std. 1149.1 BST EXTEST Mode SDO PIN_IN INJ 0 D Q 1 Input OEJ 0 PIN_OE 1 0 D Q D Q 0 1 OE OE 1 OUTJ 0 PIN_OUT 0 1 1 D Q D Q Pin Output Output Output Buffer SHIFT CLOCK UPDATE HIGHZ MODE Global Signals Capture Update SDI Registers Registers (Capture Phase) SDO PIN_IN INJ 0 D Q 1 Input OEJ 0 PIN_OE 1 0 D Q D Q 0 1 OE OE 1 OUTJ 0 PIN_OUT 0 1 1 D Q D Q Pin Output Output Output Buffer SHIFT CLOCK UPDATE HIGHZ MODE Global Signals Capture Update SDI Registers Registers (Shift and Update Phase) MAX II Device Handbook © October 2008 Altera Corporation
Chapter 13: IEEE 1149.1 (JTAG) Boundary-Scan Testing for MAXII Devices 13–13 IEEE Std. 1149.1 BST Operation Control EXTEST selects data differently than SAMPLE/PRELOAD. EXTEST chooses data from the update registers as the source of the output and output enable signals. Once the EXTEST instruction code is entered, the multiplexers select the update register data; thus, data stored in these registers from a previous EXTEST or SAMPLE/PRELOAD test cycle can be forced onto the pin signals. In the capture phase, the results of this test data are stored in the capture registers and then shifted out of TDO during the shift phase. New test data can then be stored in the update registers during the update phase. The waveform diagram in Figure13–11 resembles the SAMPLE/PRELOAD waveform diagram, except that the instruction code for EXTEST is different. The data shifted out of TDO consists of the data that was present in the capture registers after the capture phase. New test data shifted into the TDI pin appears at the TDO pin after being clocked through the entire boundary-scan register. Figure13–11. EXTEST Shift Data Register Waveforms TCK TMS TDI TDO SHIFT_IR SHIFT_DR TAP_STATE EXIT1_IR SELECT_DR_SCAN Data stored in After boundry-scan EXIT1_DR Instruction Code UPDATE_IR CAPTURE_DR boundary- scan rsehgifitsetder o duatt, ad hataas been UPDATE_DR register is shifted entered into TDI will out of TDO. shift out of TDO. BYPASS Instruction Mode The BYPASS instruction mode is activated with an instruction code made up of only ones. The waveforms in Figure13–12 show how scan data passes through a device once the TAP controller is in the SHIFT_DR state. In this state, data signals are clocked into the bypass register from TDI on the rising edge of TCK and out of TDO on the falling edge of the same clock pulse. Figure13–12. BYPASS Shift Data Register Waveforms TCK TMS TDI Bit 1 Bit 2 Bit 3 TDO Bit 1 Bit 2 Bit n SHIFT_IR SHIFT_DR TAP_STATE EXIT1_IR SELECT_DR_SCAN Data shifted into TDI on EXIT1_DR Instruction Code UPDATE_IR CAPTURE_DR the rising edge of TCK is UPDATE_DR shifted out of TDO on the falling edge of the same TCK pulse. © October 2008 Altera Corporation MAX II Device Handbook
13–14 Chapter 13: IEEE 1149.1 (JTAG) Boundary-Scan Testing for MAXII Devices IEEE Std. 1149.1 BST Operation Control IDCODE Instruction Mode The IDCODE instruction mode is used to identify the devices in an IEEE Std. 1149.1 chain. When IDCODE is selected, the device identification register is loaded with the 32-bit vendor-defined identification code. The device ID register is connected between the TDI and TDO ports, and the device IDCODE is shifted out. 1 The IDCODE for MAXII devices are listed in the JTAG and In-System Programmability chapter in the MAX II Device Handbook. USERCODE Instruction Mode The USERCODE instruction mode is used to examine the user electronic signature (UES) within the devices along an IEEE Std. 1149.1 chain. When this instruction is selected, the device identification register is connected between the TDI and TDO ports. The user-defined UES is shifted into the device ID register in parallel from the 32-bit USERCODE register. The UES is then shifted out through the device ID register. The USERCODE information is available to the user only after the device is configured successfully. The non-volatile USERCODE data is written to the configuration flash memory (CFM) block and then written to the SRAM at power-up. The USERCODE instruction reads the data values from the SRAM. When using real-time ISP to update the CFM block and write new USERCODE data, executing the USERCODE instruction returns the current running design’s USERCODE (stored in the SRAM), not the new USERCODE data. The new design’s USERCODE, stored in the CFM, can only be read back correctly if a power cycle or forced SRAM download has transpired after the real-time ISP update. In the Quartus II software, there is an Auto Usercode feature where you can choose to use the checksum value of a programming file as the JTAG user code. If selected, the checksum will be automatically loaded to the USERCODE register. On the Assignments menu, click Device. In the Device dialog box, click Device and Pin Options and click the General tab. Turn on Auto Usercode. CLAMP Instruction Mode The CLAMP instruction mode is used to allow the state of the signals driven from the pins to be determined from the boundary-scan register while the bypass register is selected as the serial path between the TDI and TDO ports. The state of all signals driven from the output pins will be completely defined by the data held in the boundary-scan register. However, CLAMP will not override the I/O weak pull-up resistor or the I/O bus hold if you have any of them selected. HIGHZ Instruction Mode The HIGHZ instruction mode is used to set all of the user I/O pins to an inactive drive state. These pins are tri-stated until a new JTAG instruction is executed. When this instruction is selected, the bypass register is connected between the TDI and TDO ports. HIGHZ will not override the I/O weak pull-up resistor or the I/O bus hold if you have any of them selected. MAX II Device Handbook © October 2008 Altera Corporation
Chapter 13: IEEE 1149.1 (JTAG) Boundary-Scan Testing for MAXII Devices 13–15 I/O Voltage Support in JTAG Chain I/O Voltage Support in JTAG Chain There can be several different Altera or non-Altera devices in a JTAG chain. However, you should be cautious if the chain contains devices that have different V levels. CCIO The TDO pin of a device drives out at the voltage level according to the V of the CCIO device. For MAXII devices, the TDO pin will drive out at the voltage level according to the V of I/O Bank1. The devices can interface with each other although they CCIO might have different V levels. For example, a device with 3.3-V V can drive to a CCIO CCIO device with 5.0-V V because 3.3 V meets the minimum VIH on TTL-level input for CCIO the 5.0-V V device. JTAG pins on MAXII devices can support 1.5-, 1.8-, 2.5-, or CCIO 3.3-V input levels, depending on the V voltage of I/O Bank 1. CCIO f Refer to the MAX II Architecture chapter in the MAX II Device Handbook for more information on MultiVoltTM I/O support. You can interface the TDI and TDO lines of the JTAG pins of devices that have different V levels by inserting a level shifter between the devices. If possible, the CCIO JTAG chain should be built such that a device with a higher V level drives to a CCIO device with an equal or lower V level. By building the JTAG chain in this manner, a CCIO level shifter may be required only to shift the TDO level to a level acceptable to the JTAG tester. Figure13–13 shows the JTAG chain of mixed voltages and how a level shifter is inserted in the chain. Figure13–13. JTAG Chain of Mixed Voltages Must be 5.0-V Must be 3.3-V Tolerant Tolerant TDI 5.0-V 3.3-V 2.5-V VCCIO VCCIO VCCIO Tester TDO Level 1.5-V 1.8-V Shifter VCCIO VCCIO Shift TDO to Level Must be 1.8-V Must be 2.5-V Accepted by Tester Tolerant Tolerant if Necessary BST for Programmed Devices For a programmed device, the input buffers are turned off by default for I/O pins that are set as output only in the design file. You cannot sample on the programmed device output pins with the default BSDL file when the input buffers are turned off. You can set the Quartus II software to always enable the input buffers on a programmed device so it behaves the same as an unprogrammed device for boundary-scan testing, allowing sample function on output pins in the design. This aspect can cause slight increase in standby current as the unused input buffer is always on. 1. On the Assignments menu, click Settings. 2. Under Category, select Assembler. 3. Turn on Always Enable Input Buffers. © October 2008 Altera Corporation MAX II Device Handbook
13–16 Chapter 13: IEEE 1149.1 (JTAG) Boundary-Scan Testing for MAXII Devices Disabling IEEE Std. 1149.1 BST Circuitry Disabling IEEE Std. 1149.1 BST Circuitry The IEEE Std. 1149.1 BST circuitry for MAXII devices is enabled upon device power- up. Because this circuitry may be used for BST or ISP, this circuitry must be enabled only if these features are used. This section describes how to disable the IEEE Std. 1149.1 circuitry to ensure that the circuitry is not inadvertently enabled when it is not needed. Table13–3 shows the pin connections necessary for disabling JTAG in MAXII devices that have dedicated IEEE Std. 1149.1 pins. Table13–3. Disabling IEEE Std. 1149.1 Circuitry JTAG Pins (1) TMS TCK TDI TDO VCC (2) GND (3) VCC (2) Leave Open Notes to Table13–3: (1) There is no software option to disable JTAG in MAXII devices. The JTAG pins are dedicated. (2) VCC refers to V of Bank 1. CCIO (3) The TCK signal may also be tied high. If TCK is tied high, power-up conditions must ensure that TMS is pulled high before TCK. Pulling TCK low avoids this power-up condition. Guidelines for IEEE Std. 1149.1 Boundary-Scan Testing Use the following guidelines when performing boundary-scan testing with IEEE Std. 1149.1 devices: ■ If a pattern (for example, a 10-bit 1010101010 pattern) does not shift out of the instruction register via the TDO pin during the first clock cycle of the SHIFT_IR state, the proper TAP controller state has not been reached. To solve this problem, try one of the following procedures: ■ Verify that the TAP controller has reached the SHIFT_IR state correctly. To advance the TAP controller to the SHIFT_IR state, return to the RESET state and clock the code 01100 on the TMS pin. ■ Check the connections to the VCC, GND, and JTAG pins on the device. ■ Perform a SAMPLE/PRELOAD test cycle prior to the first EXTEST test cycle to ensure that known data is present at the device pins when the EXTEST mode is entered. If the OEJ update register contains a 0, the data in the OUTJ update register will be driven out. The state must be known and correct to avoid contention with other devices in the system. ■ Do not perform EXTEST and SAMPLE/PRELOAD tests during ISP. These instructions are supported before and after ISP but not during ISP. 1 If problems persist, contact Altera Applications. MAX II Device Handbook © October 2008 Altera Corporation
Chapter 13: IEEE 1149.1 (JTAG) Boundary-Scan Testing for MAXII Devices 13–17 Boundary-Scan Description Language (BSDL) Support Boundary-Scan Description Language (BSDL) Support The BSDL—a subset of VHDL—provides a syntax that allows you to describe the features of an IEEE Std. 1149.1 BST-capable device that can be tested. Test software development systems then use the BSDL files for test generation, analysis, failure diagnostics, and in-system programming. f For more information, or to receive BSDL files for IEEEStd.1149.1-compliant MAXII devices, refer to the Altera website at www.altera.com. Conclusion The IEEE Std. 1149.1 BST circuitry available in MAXII devices provides a cost- effective and efficient way to test systems that contain devices with tight lead spacing. Circuit boards with Altera and other IEEE Std. 1149.1-compliant devices can use the EXTEST, SAMPLE/PRELOAD, and BYPASSmodes to create serial patterns that internally test the pin connections between devices and check device operation. 1 Institute of Electrical and Electronics Engineers, Inc. IEEE Standard Test Access Port and Boundary-Scan Architecture (IEEE Std. 1149.1-2001). New York: Institute of Electrical and Electronics Engineers, Inc., 2001. Referenced Documents This chapter references the following documents: ■ DC and Switching Characteristics chapter in the MAX II Device Handbook ■ In-System Programmability Guidelines for MAX II Devices chapter in the MAX II Device Handbook ■ JTAG and In-System Programmability chapter in the MAX II Device Handbook ■ MAX II Architecture chapter in the MAX II Device Handbook © October 2008 Altera Corporation MAX II Device Handbook
13–18 Chapter 13: IEEE 1149.1 (JTAG) Boundary-Scan Testing for MAXII Devices Document Revision History Document Revision History Table13–4 shows the revision history for this chapter. Table13–4. Document Revision History Date and Revision Changes Made Summary of Changes October 2008, ■ Updated New Document Format. — version 1.7 December 2007, ■ Removed Figure 13-14. — version 1.6 ■ Updated Figure13–6. ■ Added “Referenced Documents” section. December 2006, ■ Added document revision history. — version 1.5 August 2006, ■ Updated IEEE Std. 1149.1 BST Operation — version 1.4 ■ Control section. July 2006, ■ Updated “BST for Programmed Devices” section. — version 1.3 June 2005, ■ Added a paragraph under the USERCODE Instruction Mode section. — version 1.2 ■ Added a new section - BST for Programmed Devices. January 2005, ■ Previously published as Chapter 14. No changes to content. — version 1.1 March 2004, ■ Initial Release. — version 1.0 MAX II Device Handbook © October 2008 Altera Corporation
14. Using Jam STAPL for ISP via an Embedded Processor MII51015-1.8 Introduction Advances in programmable logic devices (PLDs) have enabled the innovative in- system programmability (ISP) feature. The Jam™ Standard Test and Programming Language (STAPL), JEDEC standard JESD-71, is compatible with all current PLDs that offer ISP via Joint Test Action Group (JTAG), providing a software-level, vendor- independent standard for in-system programming and configuration. Designers who use Jam STAPL to implement ISP enhance the quality, flexibility, and life-cycle of their end products. Regardless of the number of PLDs that must be programmed or configured, Jam STAPL simplifies in-field upgrades and revolutionizes the programming of PLDs. This chapter describes MAX® II device programming support using Jam STAPL in embedded systems. This chapter contains the following sections: ■ “Embedded Systems” on page14–1 ■ “Software Development” on page14–4 ■ “Updating Devices Using Jam” on page14–14 Embedded Systems All embedded systems are made up of both hardware and software components. When designing an embedded system, the first step is to layout the printed circuit board (PCB). The second step is to develop the firmware that manages the board’s functionality. Connecting the JTAG Chain to the Embedded Processor There are two ways to connect the JTAG chain to the embedded processor. The most straightforward method is to connect the embedded processor directly to the JTAG chain. In this method, four of the processor pins are dedicated to the JTAG interface, thereby saving board space but reducing the number of available embedded processor pins. Figure14–1 illustrates the second method, which is to connect the JTAG chain to an existing bus via an interface PLD. In this method, the JTAG chain becomes an address on the existing bus. The processor then reads from or writes to the address representing the JTAG chain. © October 2008 Altera Corporation MAX II Device Handbook
14–2 Chapter 14: Using Jam STAPL for ISP via an Embedded Processor Embedded Systems Figure14–1. Embedded System Block Diagram Embedded System TDI Interface Logic TMS Download Cable (Optional) TCK TDO TDI Control Control TMS TDI d[7..0] 8 4 d[3..0] TCK TMS Any JTAG TDO Device 20 TCK adr[19..0] TDO Embedded Processor TDI Control EPROM or TMS System 8 d[7..0] Memory TCK MAX II Devices TDO 20 20 adr[19..0] adr[19..0] TDI TMS Any JTAG TCK Device TDO Both JTAG connection methods should include space for the MasterBlaster™, ByteBlaster™ II, or USB-Blaster™ header connection. The header is useful during prototyping because it allows designers to quickly verify or modify the PLD’s contents. During production, the header can be removed to decrease cost. Example Interface PLD Design Figure14–2 shows an example design schematic of an interface PLD. A different design can be implemented; however, important points exemplified in this design are: ■ TMS, TCK, and TDI should be synchronous outputs ■ Multiplexer logic should be included to allow board access for the MasterBlaster, ByteBlaster II, or USB-Blaster download cable 1 This design example is for reference only. All of the inputs except data[3..0] are optional and included only to show how an interface PLD can act as an address decoder on an embedded data bus. MAX II Device Handbook © October 2008 Altera Corporation
Chapter 14: Using Jam STAPL for ISP via an Embedded Processor 14–3 Embedded Systems Figure14–2. Interface Logic Design Example data[1..0][2..0] result[2..0] LPM_MUX Byteblaster_nProcessor_Select PR TDI_Reg D Q EN ByteBlaster_nProcessor_Select CLR ByteBlaster_TDI data[0][0] ByteBlaster_TDI DATA3 TDI_Reg data[1][0] ByteBlaster_TMS ByteBlaster_TMS data[0][1] ByteBlaster_TCK PR TMS_Reg D Q TDO TMS_Reg data[1][1] ByteBlaster_TDO EN CLR ByteBlaster_TCK data[0][2] TCK_Reg data[1][2] DATA2 PR TCK_Reg D Q address_decode EN result0 adr[19..0] adr[19..0] AD_VALID CLR TDI result1 TMS nDS DATA1 result2 TCK DATA0 TDO d[3..0] R_nW R_AS CLK nRESET In Figure14–2, the embedded processor asserts the JTAG chain’s address, and the R_nW and R_AS signals can be set to tell the interface PLD when the processor wants to access the chain. A write involves connecting the data path data[3..0] to the JTAG outputs of the PLD via the three D registers that are clocked by the system clock (CLK). This clock can be the same clock that the processor uses. Likewise, a read involves enabling the tri-state buffers and letting the TDO signal flow back to the processor. The design also provides a hardware connection to read back the values in the TDI, TMS, and TCK registers. This optional feature is useful during the development phase, allowing software to check the valid states of the registers in the interface PLD. In addition, multiplexer logic is included to permit a download cable to program the device chain. This capability is useful during the prototype phase of development, when programming must be verified. Board Layout The following elements are important when laying out a board that programs via the IEEE Std. 1149.1 JTAG chain: ■ Treat the TCK signal trace as a clock tree © October 2008 Altera Corporation MAX II Device Handbook
14–4 Chapter 14: Using Jam STAPL for ISP via an Embedded Processor Software Development ■ Use a pull-down resistor on TCK ■ Make the JTAG signal traces as short as possible ■ Add external resistors to pull outputs to a defined logic level TCK Signal Trace Protection and Integrity TCK is the clock for the entire JTAG chain of devices. These devices are edge-triggered on the TCK signal, so it is imperative that TCK is protected from high-frequency noise and has good signal integrity. Ensure that the signal meets the rise time (t ) and fall R time (t ) parameters in the appropriate device family data sheet. The signal may also F need termination to prevent overshoot, undershoot, or ringing. This step is often overlooked since this signal is software-generated and originates at a processor general-purpose I/O pin. Pull-Down Resistors on TCK TCK should be held low via a pull-down resistor to keep the JTAG Test Access Port (TAP) in a known state at power-up. A missing pull-down resistor can cause a device to power-up in a JTAG BST state, which may cause conflicts on the board. A typical resistor value is 1 k. JTAG Signal Traces Short JTAG signal traces help eliminate noise and drive-strength issues. Special attention should be paid to the TCK and TMS pins. Because TCK and TMS are connected to every device in the JTAG chain, these traces will see higher loading than TDI or TDO. Depending on the length and loading of the JTAG chain, some additional buffering may be required to ensure that the signals propagate to and from the processor with integrity. External Resistors You should add external resistors to output pins to pull outputs to a defined logic level during programming. Output pins will tri-state during programming. Also, on MAX®II devices, the pins will be pulled up by a weak internal resistor. Altera recommends that outputs driving sensitive input pins be tied to the appropriate level by an external resistor. Each preceding board layout element may require further analysis, especially signal integrity. In some cases, you may need to analyze the loading and layout of the JTAG chain to determine whether to use discrete buffers or a termination technique. f For more information, refer to the In-System Programmability Guidelines for MAX II Devices chapter in the MAX II Device Handbook. Software Development Altera’s embedded programming uses the Jam file output from the Quartus®II software tool with the standardized Jam Player software. Designing these tools requires minimal developer intervention because Jam files contain all of the data for programming MAX II devices. The bulk of development time is spent porting the Jam Player to the host embedded processor. MAX II Device Handbook © October 2008 Altera Corporation
Chapter 14: Using Jam STAPL for ISP via an Embedded Processor 14–5 Software Development For more information about porting the Jam Byte-Code Player, see “Porting the Jam STAPL Byte-Code Player” on page14–8. Jam Files (.jam and .jbc) Altera supports the following types of Jam files: ■ ASCII text files (.jam) ■ Jam Byte-Code files (.jbc) ASCII Text Files (.jam) Altera supports two types of Jam files: ■ JEDEC Jam STAPL format ■ Jam version 1.1 (pre-JEDEC format) The JEDEC Jam STAPL format uses the syntax specified by the JEDEC Standard JESD- 71A specification. Altera recommends using JEDEC Jam STAPL files for all new projects. In most cases, Jam files are used in tester environments. Jam Byte-Code Files (.jbc) JBC files are binary files that are compiled versions of Jam files. JBC files are compiled to a virtual processor architecture, where the ASCII Jam commands are mapped to byte-code instructions compatible with the virtual processor. There are two types of JBC files: ■ Jam STAPL Byte-Code (compiled version of JEDEC Jam STAPL file) ■ Jam Byte-Code (compiled version of Jam version 1.1 file) Altera recommends using Jam STAPL Byte-Code files in embedded applications because they use minimal memory. Generating Jam Files The QuartusII software can generate both Jam and JBC file types. In addition, Jam files can be compiled into JBC files via a stand-alone Jam Byte-Code compiler. The compiler produces a functionally equivalent JBC file. Generating JBC files directly from the QuartusII software is simple. The software tool supports the programming and configuration of multiple devices from single or multiple JBC files. Figure 14–3 and Figure14–4 show the dialog boxes that specify the device chain and JBC file generation in the QuartusII software. © October 2008 Altera Corporation MAX II Device Handbook
14–6 Chapter 14: Using Jam STAPL for ISP via an Embedded Processor Software Development Figure 14–3. Multi-Device JTAG Chain’s Name and Sequence in Programmer Window in the QuartusII Software Figure14–4. Generating a JBC File for a Multi-Device JTAG Chain in the QuartusII Software The following steps explain how to generate JBC files using the QuartusII software. 1. On the Tools menu, click Programmer. 2. Click Add File and select programming files for the respective devices. 3. On the File menu, point to Create/Update and click Create JAM, SVF, or ISC File. See Figure14–4. 4. Specify a Jam STAPL Byte-Code File in the File format list. 5. Click OK. MAX II Device Handbook © October 2008 Altera Corporation
Chapter 14: Using Jam STAPL for ISP via an Embedded Processor 14–7 Software Development You can include both Altera and non-Altera JTAG-compliant devices in the JTAG chain. If you do not specify a programming file in the Programming File Names field, devices in the JTAG chain will be bypassed. Using Jam Files with the MAX II User Flash Memory Block The Quartus II Programmer provides the option to individually target the entire device, logic array, or the user flash memory (UFM) block. As you can program the (UFM) section independently from the logic array, separate Jam STAPL and JBC options can be used in the command line to separately program UFM and configuration flash memory (CFM) blocks. f For more information, see “MAX II Jam/JBC Actions and Procedure Commands” on page14–15. Jam Players Jam Players read the descriptive information in Jam files and translate them into data that programs the target PLDs. Jam Players do not program a particular device architecture or vendor; they only read and understand the syntax defined by the Jam file specification. In-field changes are confined to the Jam file, not the Jam Player. As a result, you do not need to modify the Jam Player source code for each in-field upgrade. There are two types of Jam Players to accommodate the two types of Jam files: an ASCII Jam STAPL Player and a Jam STAPL Byte-Code Player. The general concepts within this chapter apply to both player types; however, the following information focuses on the Jam STAPL Byte-Code Player. Jam Players can be used to program or write the MAX II configuration flash memory block and the UFM block separately since Jam STAPL and JBC files can be generated targeting only to either one or both sectors of the MAX II UFM block. Jam Player Compatibility The embedded Jam Player is able to read Jam files that conform to the standard JEDEC file format. The embedded Jam Player is compatible with legacy Jam files that use version 1.1 syntax. Both Players are backward-compatible; they can play version 1.1 files and Jam STAPL files. f For more information about Altera’s support for version 1.1 syntax, refer to AN 122: Using Jam STAPL for ISP & ICR via an Embedded Processor. The Jam STAPL Byte-Code Player The Jam STAPL Byte-Code Player is coded in the C programming language for 16-bit and 32-bit processors. f For more information about Altera’s support for 8-bit processors, refer to AN111: Embedded Programming Using the 8051 & Jam Byte-Code. The 16-bit and 32-bit source code is divided into two categories: ■ Platform-specific code that handles I/O functions and applies to specific hardware (jbistub.c) © October 2008 Altera Corporation MAX II Device Handbook
14–8 Chapter 14: Using Jam STAPL for ISP via an Embedded Processor Software Development ■ Generic code that performs the Player’s internal functions (all other C files) Figure14–5 illustrates the organization of the source code files by function. Keeping the platform-specific code inside the jbistub.c file simplifies the process of porting the Jam STAPL Byte-Code Player to a particular processor. Figure14–5. Jam STAPL Byte-Code Player Source Code Structure Jam STAPL Player Error Message I/O Functions (jbistub.c file) TCK TMS TDI .jbc TDO Main Program Compare Parse Interpret and Export Porting the Jam STAPL Byte-Code Player The default configuration of the jbistub.c file includes code for DOS, 32-bit Windows, and UNIX so that the source code can be easily compiled and evaluated for the correct functionality and debugging of these pre-defined operating systems. For the embedded environment, this code is easily removed using a single preprocessor #define statement. In addition, porting the code involves making minor changes to specific parts of the code in the jbistub.c file. To port the Jam Player, you need to customize several functions in the jbistub.c file, which are shown in Table14–1. Table14–1. Functions Requiring Customization Function Description jbi_jtag_io() Interface to the four IEEE 1149.1 JTAG signals, TDI, TMS, TCK, and TDO jbi_export() Passes information such as the User Electronic Signature (UES) back to the calling program jbi_delay() Implements the programming pulses or delays needed during execution jbi_vector_map() Processes signal-to-pin map for non-IEEE 1149.1 JTAG signals jbi_vector_io() Asserts non-IEEE 1149.1 JTAG signals as defined in the VECTOR MAP To ensure that you have customized all of the necessary code, follow these four steps: 1. Set preprocessor statements to exclude extraneous code. 2. Map JTAG signals to hardware pins. 3. Handle text messages from jbi_export(). 4. Customize delay calibration. MAX II Device Handbook © October 2008 Altera Corporation
Chapter 14: Using Jam STAPL for ISP via an Embedded Processor 14–9 Software Development Step 1: Set Preprocessor Statements to Exclude Extraneous Code At the top of jbistub.c, change the default PORT parameter to EMBEDDED to eliminate all DOS, Windows, and UNIX source code and included libraries. #define PORT EMBEDDED Step 2: Map JTAG Signals to Hardware Pins The jbi_jtag_io() function contains the code that sends and receives the binary programming data. Each of the four JTAG signals should be re-mapped to the embedded processor’s pins. By default, the source code writes to the PC’s parallel port. The jbi_jtag_io() signal maps the JTAG pins to the PC parallel port registers shown in Figure 14–6. Figure 14–6. Default PC Parallel Port Signal Mapping (Note1) 7 6 5 4 3 2 1 0 I/O Port 0 TDI 0 0 0 0 TMS TCK OUTPUT DATA - Base Address TDO X X X X --- --- --- INPUT DATA - Base Address + 1 Note to Figure 14–6: (1) The PC parallel port hardware inverts the most significant bit, TDO. The mapping is highlighted in the following jbi_jtag_io() source code: int jbi_jtag_io(int tms, int tdi, int read_tdo) { int data=0; int tdo=0; if (!jtag_hardware_initialized) { initialize_jtag_hardware(); jtag_hardware_initialized=TRUE; } data = ((tdi?0x40:0)|(tms?0x2:0)); /*TDI,TMS*/ write_byteblaster(0,data); if (read_tdo) { tdo=(read_byteblaster(1)&0x80)?0:1; /*TDO*/ } write_blaster(0,data|0x01); /*TCK*/ write_blaster(0,data); return (tdo); } In the previous code, the PC parallel port inverts the actual value of TDO. The jbi_jtag_io() source code inverts it again to retrieve the original data. The line which inverts the TDO value is as follows: tdo=(read_byteblaster(1)&0x80)?0:1; © October 2008 Altera Corporation MAX II Device Handbook
14–10 Chapter 14: Using Jam STAPL for ISP via an Embedded Processor Software Development If the target processor does not invert TDO, the code should look like: tdo=(read_byteblaster(1)&0x80)?1:0; To map the signals to the correct addresses, use the left shift (<<) or right shift (>>) operators. For example, if TMS and TDI are at ports 2 and 3, respectively, the code would be as follows: data=(((tdi?0x40:0)>>3)|((tms?0x02:0)<<1)); Apply the same process to TCK and TDO. The read_byteblaster and write_byteblaster signals use the inp() and outp() functions from the conio.h library, respectively, to read and write to the port. If these functions are not available, equivalent functions should be substituted. Step 3: Handle Text Messages from jbi_export() The jbi_export() function sends text messages to stdio, using the printf() function. The Jam STAPL Byte-Code Player uses the jbi_export() signal to pass information (for example, the device UES or USERCODE) to the operating system or software that calls the Player. The function passes text (in the form of a string) and numbers (in the form of a decimal integer). f For definitions of these terms, refer to AN 39: IEEE 1149.1 (JTAG) Boundary-Scan Testing in Altera Devices. If there is no device available to stdout, the information can be redirected to a file or storage device, or passed as a variable back to the program that calls the Player. Step 4: Customize Delay Calibration The calibrate_delay() function determines how many loops the host processor runs in a millisecond. This calibration is important because accurate delays are used in programming and configuration. By default, this number is hard-coded as 1,000 loops per millisecond and represented as the following assignment: one_ms_delay = 1000 If this parameter is known, it should be adjusted accordingly. If it is not known, you can use code similar to that for Windows and DOS platforms. Code is included for these platforms that count the number of clock cycles that run in the time it takes to execute a single while loop. This code is sampled over multiple tests and averaged to produce an accurate result upon which the delay can be based. The advantage to this approach is that calibration can vary based on the speed of the host processor. Once the Jam STAPL Byte-Code Player is ported and working, verify the timing and speed of the JTAG port at the target device. Timing parameters in MAX II devices should comply with the values given in the DC and Switching Characteristics chapter in the MAX II Device Handbook. If the Jam STAPL Byte-Code Player does not operate within the timing specifications, the code should be optimized with the appropriate delays. Timing violations can occur if the processor is very powerful and can generate TCK at a rate faster than 18 MHz. MAX II Device Handbook © October 2008 Altera Corporation
Chapter 14: Using Jam STAPL for ISP via an Embedded Processor 14–11 Software Development 1 Other than the jbistub.c file, Altera strongly recommends keeping source code in other files unchanged from their default state. Altering the source code in these files will result in unpredictable Jam Player operation. Jam STAPL Byte-Code Player Memory Usage The Jam STAPL Byte-Code Player uses memory in a predictable manner. This section documents how to estimate both ROM and RAM memory usage. Estimating ROM Usage Use the following equation to estimate the maximum amount of ROM required to store the Jam Player and JBC file: Equation14–1. ROM =JBC file size+Jam player size Size The JBC file size can be separated into two categories: the amount of memory required to store the programming data, and the space required for the programming algorithm. Use the following equation to estimate the JBC file size: Equation14–2. N JBC file size = Alg + Data k=1 Notes to Equation14–2: (1) Alg =Space used by algorithm. (2) Data =Space used by compressed programming data. (3) k =Index representing device being targeted. (4) N =Number of target devices in the chain. This equation provides a JBC file size estimate that may vary by ±10, depending on device utilization. When device utilization is low, JBC file sizes tend to be smaller because the compression algorithm used to minimize file size is more likely to find repetitive data. The equation also indicates that the algorithm size stays constant for a device family, but the programming data size grows slightly as more devices are targeted. For a given device family, the increase in JBC file size (due to the data component) is linear. Table 14–2 shows algorithm file size constants when targeting a single MAX II device. Table 14–2. Algorithm File Size Constants Targeting a Single Altera Device Family Device Typical JBC File Algorithm Size (Kbytes) MAX II 24.3 © October 2008 Altera Corporation MAX II Device Handbook
14–12 Chapter 14: Using Jam STAPL for ISP via an Embedded Processor Software Development Table 14–3 shows data size constants for MAX II devices that support the Jam language for ISP. Table 14–3. Data Constants Typical Jam STAPL Byte-Code Data Size (Kbytes) Device Compressed Uncompressed (1) EPM240 12.4 (2) 12.4 (2) EPM570 11.4 19.6 EPM1270 16.9 31.9 EPM2210 24.7 49.3 Notes to Table 14–3: (1) For more information about how to generate JBC files with uncompressed programming data, contact Altera Applications. (2) There is a minimum limit of 64K bits for compressed arrays with the JBC compiler. Programming data arrays smaller than 64K bits (8K bytes) are not compressed. The EPM240 programming data array is below the limit, which means the JBC files are always uncompressed. The reason for this limit is that a memory buffer is needed for decompression, and for small embedded systems it is more efficient to use small uncompressed arrays directly rather than to uncompress the arrays. After estimating the JBC file size, estimate the Jam Player size using the information in Table 14–4. Table 14–4. Jam STAPL Byte-Code Player Binary Sizes Build Description Size (Kbytes) 16-bit Pentium/486 using the MasterBlaster or ByteBlasterMV download 80 cables 32-bit Pentium/486 using the MasterBlaster or ByteBlasterMV download 85 cables Estimating Dynamic Memory Usage Use the following equation to estimate the maximum amount of DRAM required by the Jam Player: Equation 14–3. N RAM Size = JBC File Size + Data (Uncompressed Data Size)k k=1 The JBC file size is determined by a single- or multi-device equation (see “Estimating ROM Usage” on page14–11). The amount of RAM used by the Jam Player is the size of the JBC file plus the sum of the data required for each device that is targeted. If the JBC file is generated using compressed data, some RAM is used by the Player to uncompress the data and temporarily store it. The uncompressed data sizes are provided in Table 14–3. If an uncompressed JBC file is used, use the following equation: Equation14–4. RAM Size = JBC File Size MAX II Device Handbook © October 2008 Altera Corporation
Chapter 14: Using Jam STAPL for ISP via an Embedded Processor 14–13 Software Development 1 The memory requirements for the stack and heap are negligible, with respect to the total amount of memory used by the Jam STAPL Byte-Code Player. The maximum depth of the stack is set by the JBI_STACK_SIZE parameter in the jbimain.c file. Estimating Memory Example The following example uses a 16-bit Motorola 68000 processor to program an EPM7128AE device and an EPM7064AE device in an IEEE Std. 1149.1 JTAG chain via a JBC file that uses compressed data. To determine memory usage, first determine the amount of ROM required and then estimate the RAM usage. Use the following steps to calculate the amount of DRAM required by the Jam Byte-Code Player: 1. Determine the JBC file size. Use the following multi-device equation to estimate the JBC file size. Because JBC files use compressed data, use the compressed data file size information, listed in Table 14–3, to determine Data size.where: Equation14–5. N JBC File Size = Alg + Data k=1 Notes to Equation14–5: (1) Alg =21 Kbytes. (2) Data =EPM7064AE Data + EPM7128AE Data = 8 + 4 = 12 Kbytes. Thus, the JBC file size equals 33 Kbytes. 2. Estimate the JBC Player size. This example uses a JBC Player size of 62 Kbytes because this 68000 is a 16-bit processor. Use the following equation to determine the amount of ROM needed: Equation14–6. ROM Size=JBC File Size+Jam Player Size ROM Size=95 Kbytes 3. Estimate the RAM usage with the following equation: Equation14–7. N RAM Size = 33 Kbytes + Data (Uncompressed Data Size)k k=1 Because the JBC file uses compressed data, the uncompressed data size for each device must be summed to find the total amount of RAM used. The Uncompressed Data Size constants are as follows: ■ EPM7064AE = 8 Kbytes ■ EPM7128AE = 12 Kbytes © October 2008 Altera Corporation MAX II Device Handbook
14–14 Chapter 14: Using Jam STAPL for ISP via an Embedded Processor Updating Devices Using Jam Calculate the total DRAM usage as follows: Equation 14–8. RAM Size = 33Kbytes +(8 Kbytes + 12 Kbytes) = 53 Kbytes In general, Jam Files use more RAM than ROM, which is desirable because RAM is cheaper and the overhead associated with easy upgrades becomes less of a factor as a larger number of devices are programmed. In most applications, easy upgrades outweigh the memory costs. Updating Devices Using Jam Updating a device in the field means downloading a new JBC file and running the Jam STAPL Byte-Code Player with what in most cases is the “program” action. The main entry point for execution of the Player is jbi_execute(). This routine passes specific information to the Player. When the Player finishes, it returns an exit code and detailed error information for any run-time errors. The interface is defined by the routine’s prototype definition. JBI_RETURN_TYPE jbi_execute ( PROGRAM_PTR program long program_size, char *workspace, long workspace_size, *action, char **init_list, long *error_line, init *exit_code ) The code within main(), in jbistub.c, determines the variables that will be passed to jbi_execute(). In most cases, this code is not applicable to an embedded environment; therefore, this code can be removed and the jbi_execute() routine can be set up for the embedded environment. Table 14–5 describes each parameter. Table 14–5. Parameters (Note1) (Part 1 of 2) Parameter Status Description program Mandatory A pointer to the JBC file. For most embedded systems, setting up this parameter is as easy as assigning an address to the pointer before calling jbi_execute(). program_size Mandatory Amount of memory (in bytes) that the JBC file occupies. workspace Optional A pointer to dynamic memory that can be used by the JBC Player to perform its necessary functions. The purpose of this parameter is to restrict Player memory usage to a pre-defined memory space. This memory should be allocated before calling jbi_execute(). If maximum dynamic memory usage is not a concern, set this parameter to null, which allows the Player to dynamically allocate the necessary memory to perform the specified action. workspace_size Optional A scalar representing the amount of memory (in bytes) to which workspace points. MAX II Device Handbook © October 2008 Altera Corporation
Chapter 14: Using Jam STAPL for ISP via an Embedded Processor 14–15 Updating Devices Using Jam Table 14–5. Parameters (Note1) (Part 2 of 2) Parameter Status Description action Mandatory A pointer to a string (text that directs the Player). Example actions are PROGRAM or VERIFY. In most cases, this parameter will be set to the string PROGRAM. The Player is not case-sensitive, so the text can be either uppercase or lowercase. The Player supports all actions defined in the Jam Standard Test and Programming Language Specification. See Table 14–6. Note that the string must be null terminated. init_list Optional An array of pointers to strings. This parameter is used when applying Jam version 1.1 files. (2) error_line — A pointer to a long integer. If an error is encountered during execution, the Player will record the line of the JBC file where the error occurred. exit_code — A pointer to a long integer. Returns a code if there is an error that applies to the syntax or structure of the JBC file. If this kind of error is encountered, the supporting vendor should be contacted with a detailed description of the circumstances in which the exit code was encountered. Notes to Table 14–5: (1) Mandatory parameters must be passed for the Player to run. (2) For more information, refer to AN 122: Using Jam STAPL for ISP & ICR via an Embedded Processor. MAX II Jam/JBC Actions and Procedure Commands The Jam/JBC supported action commands for MAX II devices are listed in Table 14–6, including their definitions. The optional procedures that you can execute with each action are listed along with their definitions in Table 14–7. Table 14–6. MAX II Jam/JBC Actions (Part 1 of 2) Optional Procedures (Off by Jam/JBC Action Description Default) PROGRAM Programs the device. You can optionally program CFM and DO_BYPASS_CFM UFM separately. DO_BYPASS_UFM DO_SECURE DO_REAL_TIME_ISP DO_READ_USERCODE BLANKCHECK Blank checks the entire device. You can optionally blank check DO_BYPASS_CFM CFM and UFM separately. DO_BYPASS_UFM DO_REAL_TIME_ISP VERIFY Verifies the entire device against the programming data in the DO_BYPASS_CFM Jam file. You can optionally verify CFM and UFM separately. DO_BYPASS_UFM DO_REAL_TIME_ISP DO_READ_USERCODE © October 2008 Altera Corporation MAX II Device Handbook
14–16 Chapter 14: Using Jam STAPL for ISP via an Embedded Processor Updating Devices Using Jam Table 14–6. MAX II Jam/JBC Actions (Part 2 of 2) Optional Procedures (Off by Jam/JBC Action Description Default) ERASE Erases the programming content of the device. You can DO_BYPASS_CFM optionally erase CFM and UFM separately. DO_BYPASS_UFM DO_REAL_TIME_ISP READ_USERCODE Returns the JTAG USERCODE register information from the — device. READ_USERCODE can be set to a specific value in the programming file in the Quartus II software by using the Assignments menu -> Device -> Device and Pin options -> General tab, which has a USERCODE data entry. Table 14–7. MAX II Jam/JBC Optional Procedure Definitions Procedure Description DO_BYPASS_CFM When set =1, DO_BYPASS_CFM bypasses the CFM and performs the specified action on the UFM only. When set =0, this option is ignored (default). DO_BYPASS_UFM When set =1, DO_BYPASS_UFM bypasses the UFM and performs the specified action on the CFM only. When set =0, this option is ignored (default). DO_BLANKCHECK When set =1, the device, CFM, or UFM is blank checked. When set =0, this option is ignored (default). DO_SECURE When set =1, the device’s security bit is set. The security bit only affects the CFM data. The UFM cannot be protected. When set =0, this option is ignored (default). DO_REAL_TIME_ISP When set =1, the real-time ISP feature is enabled for the ISP action being executed. When set =0, the device uses normal ISP mode for any operations. DO_READ_USERCODE When set =1, the player returns the JTAG USERCODE register information from the device. Executing the Jam file from a command prompt requires that an action is specified using the -a option, as shown in the following example: jam -aPROGRAM <filename> This command programs the entire MAX II device with the Jam file specified in the filename. You can execute the optional procedures with its associated actions by using the -d option, as shown in the following example: jam -aPROGRAM -dDO_BYPASS_UFM=1 -dDO_REAL_TIME_ISP=1 <filename> This command programs the MAX II CFM block only with real-time ISP enabled (i.e., the device remains in user mode during the entire process). The JBC player uses the same format except for the executable name. The Player returns a status code of type JBI_RETURN_TYPE or integer. This value indicates whether the action was successful (returns “0”). jbi_execute() can return any one of the following exit codes in Table 14–8, as defined in the Jam Standard Test and Programming Language Specification. MAX II Device Handbook © October 2008 Altera Corporation
Chapter 14: Using Jam STAPL for ISP via an Embedded Processor 14–17 Updating Devices Using Jam Table 14–8. Exit Codes Exit Code Description 0 Success 1 Checking chain failure 2 Reading IDCODE failure 3 Reading USERCODE failure 4 Reading UESCODE failure 5 Entering ISP failure 6 Unrecognized device ID 7 Device version is not supported 8 Erase failure 9 Blank check failure 10 Programming failure 11 Verify failure 12 Read failure 13 Calculating checksum failure 14 Setting security bit failure 15 Querying security bit failure 16 Exiting ISP failure 17 Performing system test failure Running the Jam STAPL Byte-Code Player Calling the Jam STAPL Byte-Code Player is like calling any other sub-routine. In this case, the sub-routine is given actions and a file name, and then it performs its function. In some cases, in-field upgrades can be performed depending on whether the current device design is up-to-date. The JTAG USERCODE is often used as an electronic “stamp” that indicates the PLD design revision. If the USERCODE is set to an older value, the embedded firmware updates the device. The following pseudocode illustrates how the Jam Byte-Code Player could be called multiple times to update the target PLD: result = jbi_execute(jbc_file_pointer, jbc_file_size, 0, 0, “READ_USERCODE”, 0, error_line, exit_code); The Jam STAPL Byte-Code Player will now read the JTAG USERCODE and export it using the jbi_export() routine. The code can then branch based upon the result. © October 2008 Altera Corporation MAX II Device Handbook
14–18 Chapter 14: Using Jam STAPL for ISP via an Embedded Processor Conclusion The following shows example code for the Jam Player. switch (USERCODE) { case "0001": /*Rev 1 is old - update to new Rev*/ result = jbi_execute (rev3_file, file_size_3, 0, 0, “PROGRAM”, 0, error_line, exit_code); case "0002": /*Rev 2 is old - update to new Rev*/ result = jbi_excecute(rev3_file, file_size_3, 0, 0, "PROGRAM", 0, error_line, exit_code); case "0003": ; /*Do nothing - this is the current Rev*/ default: /*Issue warning and update to current Rev*/ Warning - unexpected design revision; /*Program device with newest rev anyway*/ result = jbi_execute(rev3_file, file_size_3, 0, 0, "PROGRAM", 0, error_line, exit_code); } A switch statement can be used to determine which device needs to be updated and which design revision should be used. With JamSTAPL Byte-Code software support, PLD updates become as easy as adding a few lines of code. Conclusion Using Jam STAPL provides an simple way to benefit from ISP. Jam meets all of the necessary embedded system requirements, such as small file sizes, ease of use, and platform independence. In-field upgrades are simplified by confining updates to the Jam STAPL Byte-Code file. Executing the Jam Player is straightforward, as is the calculation of resources that will be used. For the most recent updates and information, visit the Jam website at: www.altera.com/jamisp. Referenced Documents This chapter references the following documents: ■ AN 39: IEEE 1149.1 (JTAG) Boudary-Scan Testing in Altera Devices ■ AN 111: Embedded Programming Using the 8051 & Jam Byte-Code ■ AN 122: Using Jam STAPL for ISP & ICR via an Embedded Processor ■ DC and Switching Characteristics chapter in the MAX II Device Handbook ■ In-System Programmability Guidelines for MAX II Devices chapter in the MAX II Device Handbook MAX II Device Handbook © October 2008 Altera Corporation
Chapter 14: Using Jam STAPL for ISP via an Embedded Processor 14–19 Document Revision History Document Revision History Table 14–9 shows the revision history for this chapter. Table 14–9. Document Revision History Date and Revision Changes Made Summary of Changes October 2008, ■ Updated New Document Format. — version 1.8 December 2007, ■ Added “Referenced Documents” section. — version 1.7 December 2006, ■ Added document revision history. — version 1.6 August 2006, ■ Updated “Embedded Systems” section. — version 1.5 August 2005, ■ Updated Tables 14-2 and 14-3. — version 1.4 June 2005, ■ Removed Table 14-6 from v1.2. — version 1.3 ■ Added a new section “MAX II Jam/JBC Actions and Procedure Commands”. January 2005, ■ Previously published as Chapter 15. No changes to content. — version 1.2 December 2004, ■ Changed document reference from AN 88 to AN 122. — version 1.1 © October 2008 Altera Corporation MAX II Device Handbook
14–20 Chapter 14: Using Jam STAPL for ISP via an Embedded Processor Document Revision History MAX II Device Handbook © October 2008 Altera Corporation
15. Using the Agilent 3070 Tester for In- System Programming MII51016-1.5 Introduction In-system programming is a mainstream feature in programmable logic devices (PLDs), offering system designers and test engineers significant cost benefits by integrating PLD programming into board-level testing. These benefits include reduced inventory of pre-programmed devices, lower costs, fewer devices damaged by handling, and increased flexibility in engineering changes. Altera provides software and device support that integrates in-system programmability (ISP) into the existing test flows for the Agilent 3070 system. This chapter discusses how to use the Agilent 3070 test system to achieve faster programming times for Altera’s MAX® II devices. This chapter contains the following sections: ■ “New PLD Product for Agilent 3070” on page15–1 ■ “Device Support” on page15–1 ■ “Agilent 3070 Development Flow without the PLD ISP Software” on page15–2 ■ “Development Flow for Agilent3070 with PLD ISP Software” on page15–8 ■ “Programming Times” on page15–10 ■ “Guidelines” on page15–10 New PLD Product for Agilent 3070 Agilent Technologies, the manufacturer of the Agilent 3070 tester, has introduced a new PLD ISP software product to help address the issues of programming PLDs. There are several advantages of using the new product that are discussed later in this chapter. Device Support When programming MAX II devices together with devices from other families using the Agilent 3070 tester, ensure that all devices in the chain can be programmed using the tester. © October 2008 Altera Corporation MAX II Device Handbook
15–2 Chapter 15: Using the Agilent 3070 Tester for In-System Programming Agilent 3070 Development Flow without the PLD ISP Software Agilent 3070 Development Flow without the PLD ISP Software Programming devices with the Agilent 3070 tester (using a Serial Vector Format (.svf) File) without Agilent’s PLD ISP software requires the following steps. Refer to Figure15–1. Figure15–1. Agilent 3070 Development Flow for In-System Programming Using SVF File without PLD ISP Start Create a Step 1 Printed Circuit Board (PCB) and Test Fixture Designer Create a Step 2 Serial Vector Format (.svf) File Convert the SVF File to Step 3 Pattern Capture Format (.pcf) File Create Executable Test Engineer Step 4 Tests from Files Compile Executable Step 5 Tests Debug Step 6 Programming No Successful? Yes Done MAX II Device Handbook © October 2008 Altera Corporation
Chapter 15: Using the Agilent 3070 Tester for In-System Programming 15–3 Agilent 3070 Development Flow without the PLD ISP Software Step 1: Create a PCB and Test Fixture Before starting test development, the first step to successful in-system programming is the proper layout of the board and the subsequent creation of the test fixture. Creating the PCB The following recommendations highlight important areas of PCB design issues: ■ The TCK signal trace should be treated as carefully as a clock tree. TCK is the clock for the entire Joint Test Action Group (JTAG) chain of devices. These devices are edge-triggered on the TCK signal, so it is imperative that this signal be protected from high-frequency noise and have good signal integrity. Ensure that the signal meets the tR and tF parameters specified in the device data sheet. ■ Add a pull-down resistor to TCK. The TCK signal should be held low through a pull-down resistor in-between PCF downloads. For more information about pattern capture format (PCF) downloads, refer to “Step 2: Create a Serial Vector Format File”. You should hold TCK low because the Agilent 3070 drivers go into a “high-Z” state in-between tests and briefly drive low as the next PCF is applied. When the TCK line “floats”, the programming data stream is corrupted and the device is not programmed correctly. ■ Provide VCC and GND test access points for the nails of the test fixture. During operation, there should be enough access points to allow quiet PCB operation. Having too few access points results in a noisy system that can disrupt JTAG scans. ■ Turn off on-board oscillators. During programming, on-board oscillators should have the ability to be electrically turned off to reduce system noise. ■ Add external resistors to pull outputs to a defined logic level during programming. 1 Output pins are tri-stated during programming and are pulled up by a weak internal resistor. However, Altera recommends that signals requiring a pre-defined level be externally forced to the appropriate level using an external resistor. f For more information about board design for ISP, refer to the In-System Programmability Guidelines for MAX II Devices chapter in the MAX II Device Handbook. Creating the Fixture Providing a clean interface between the test fixture and the target board is essential for successful in-system programming. To provide a clean interface, use short wires in the test fixture to improve the TCK connection. Longer wires can introduce inductive noise into the system, which can disrupt programming. The wire connecting TCK should be no longer than 1 inch. Use the Agilent Fixture Consultant to manage the layout and creation of the test fixture (see the Agilent Board Test Family Manual). © October 2008 Altera Corporation MAX II Device Handbook
15–4 Chapter 15: Using the Agilent 3070 Tester for In-System Programming Agilent 3070 Development Flow without the PLD ISP Software Step 2: Create a Serial Vector Format File The Quartus II software generates SVF Files for programming one or more devices. When targeting multiple devices in the same MAX II CPLD family, the Quartus II software automatically generates one SVF File to program the devices concurrently. Therefore, the programming time for all of the devices approaches the programming time for the largest CPLD device in the IEEE Std. 1149.1 JTAG chain. Figure 15–2 shows the Create JAM, SVF, or ISC File dialog box (Filemenu), which is used to generate the SVF File. Figure 15–2. Create JAM, SVF, or ISC File Dialog Box Before creating the SVF File, you must open the Programmer in the Quartus II and add the Programmer Object File (.pof) for all the devices in the chain into the programmer. Each POF corresponds to a targeted device, respectively. In the Create JAM, SVF, or ISC File dialog box, the value in the TCK frequency box should match the frequency that TCK runs at during the test. If you enter a different frequency from the one used in actual testing, programming may fail or you may experience an excessively long programming time. You can also select whether to perform a program or verify operation and optionally verify or blank-check the device by turning on programming options. Altera recommends generating SVF Files that include verify vectors, which ensure that programming failures are identified and a limited amount of additional programming time is used. You can generate the necessary SVF File based on the scan-chain topology of the board and the Altera devices to be programmed. Once the SVF File is generated, it can be given to test engineers for development. If a device must be programmed independently, you can generate individual SVF Files for each Altera device in the chain. When creating the SVF File for a single device in the chain, specify the POF for the device and leave the rest of the devices set to <none>. This can be done by selecting Add Device in the Programmer. These devices are bypassed during programming. Repeat this process until all targeted devices have an SVF File. MAX II Device Handbook © October 2008 Altera Corporation
Chapter 15: Using the Agilent 3070 Tester for In-System Programming 15–5 Agilent 3070 Development Flow without the PLD ISP Software Step 3: Convert SVF Files to PCF Files You must convert the SVF Files to PCF Files for use with the Agilent 3070 tester with the Altera svf2pcf conversion utility. The svf2pcf utility can create multiple PCF Files for one device chain; running the utility allows you to specify the number of vectors per file. The amount of memory used by the resulting files varies depending on the data. The Agilent 3070 digital compiler looks for repeating patterns of vectors and optimizes the directory and sequences RAM on the tester control card to apply the maximum number of vectors before re-loading the files. The number of vectors in a compiled PCF File ranges from 100,000 to over one million, depending on the size and density of the targeted devices. You can download the svf2pcf conversion utility from the Agilent ISP Support website at www.altera.com. Step 4: Create Executable Tests from Files Creating digital tests for programming a chain of devices with the Agilent 3070 tester requires the following steps: 1. Create the library for the target device or scan chain. 2. Run the Test Consultant. 3. Create digital tests. 4. Create the wirelist information for the tests. 5. Modify the test plan. Create the Library for the Target Device or Scan Chain The initial program development for the board contains a setup-only node test library for the ISP boundary-scan chain interface. The test library ensures that Agilent 3070 tester resources are reserved in the test fixture for programming the targeted devices. If only one target device is on the board and it is not part of a boundary-scan chain (isolated), use a pin library; otherwise, use a node library. If using a pin library, you must describe every device pin. Do not include test vectors in a test library. The following code example shows a setup-only node test library. !Setup only test for the boundary scan chain assign TCK to nodes "TCK"! Node name for the TCK pin assign TMS to nodes "TMS"! Node name for the TMS pin assign TDI to nodes "TDI"! Node name for the TDI pin assign TDO to nodes "TDO"! Node name for the TDO pin inputs TCK, TMS, TDI outputs TDO pcf order is TCK, TMS, TDI, TDO! The order is defined by the program that ! generates the PCF files. Mark the TCK and TMS boundary-scan nodes as CRITICAL in the Board Consultant. This critical attribute minimizes the nodes’ wire length in the test fixture. © October 2008 Altera Corporation MAX II Device Handbook
15–6 Chapter 15: Using the Agilent 3070 Tester for In-System Programming Agilent 3070 Development Flow without the PLD ISP Software Run the Test Consultant Run the Test Consultant to create all of the files for new board development. Once the Test Consultant finishes running with this setup-only test library, it creates an executable test (without vectors) with the correct fixture wiring resource information. Use this file as a template to create the executable test’s source code. Create Digital Tests Create the digital tests, which are required to program the device(s), by copying the executable template to the desired program names. For example, if svf2pcf created four PCF Files, copy the template file to four executable tests (for example, prog_a, prog_b, prog_c, and prog_d) in the digital directory. Add these test names to your testorder file and mark them permanent using the following syntax: test digital "prog_a"; permanent test digital "prog_b"; permanent test digital "prog_c"; permanent test digital "prog_d"; permanent Create the Wirelist Information for the Tests Compile these executable tests to generate object files (see “Modify the Test Plan”) for the setup only versions of the tests. Run Module Pin Assignment to create the necessary entries in the wirelist file. Next, modify the executable tests so that they contain the vectors to program the target device. An include statement can be used in the executable test, or the vectors can be merged into the file. Use the following syntax for the include statement, which should be the last statement in the executable test. include "pcf1" Remember that the PCF File must reside in the digital directory and must be a digital file. To ensure that the digital file is in the correct directory, run the following command on the BT-Basic command line: load digital "digital/pcf1" | re-save You can also use the chtype command at a shell prompt to verify the location of the file: chtype -n6 digital/pcf1 Repeat this step for each PCF File. Modify the Test Plan Add the test statements to the test plan using the following syntax: test "digital/prog_a" ! First program file test "digital/prog_b" ! Second program file test "digital/prog_c" ! Third program file test "digital/prog_d" ! Fourth program file MAX II Device Handbook © October 2008 Altera Corporation
Chapter 15: Using the Agilent 3070 Tester for In-System Programming 15–7 Agilent 3070 Development Flow without the PLD ISP Software Keep the test execution in the same order in which the SVF File was split. For example, if the SVF File was split into four files (pcf1, pcf2, pcf3, and pcf4), the tests must be executed in the order that they split (execute prog_a followed by prog_b followed by prog_c followed by prog_d). If the order is not preserved, the device(s) will fail to program correctly. Step 5: Compile the Executable Tests Altera recommends batch-driven compilation using either BT-Basic or a UNIX shell. See the following batch file code in BT-Basic (assuming four executable tests to program the target device and generation of debugging object code): compile "digital/prog_a" ; debug compile "digital/prog_b" ; debug compile "digital/prog_c" ; debug compile "digital/prog_d" ; debug This file should be saved in the board directory to allow engineering changes to take place at a later date. See the corresponding shell script (–D option generates debugging information): dcomp -D digital/prog_a dcomp -D digital/prog_b dcomp -D digital/prog_c dcomp -D digital/prog_d 1 Compile times can be long, depending on the number of PCF vectors contained in the source files, the type of controller, and controller loading. Altera recommends using a batch file to automate the compilation of the ISP tests. If a boundary-scan chain containing Altera devices is defined, only the Altera devices will be programmed when the PCF vectors have been applied to the JTAG interface. Step 6: Debug the Test Once the executable tests have been created, the test system can be debugged. The applied vector set ensures that the device is programmed correctly by verifying the contents of the device. The programming algorithm uses the TDO pin to check the bitstream coming from the device. If any vector does not match the expected value, the test fails, indicating one of two things: ■ The device ID does not match what is expected. This scenario is evident if the failure occurs at the beginning of the first test. ■ Device programming failed. Because many vectors are verified, it may not be practical to sift through each vector to determine the cause of the failure. Use the following troubleshooting guidelines if the device fails to program: ■ Check the pull-down resistor in the test fixture. The design engineer may have placed pull-up resistors on the board for the TCK pin. If the pull-down resistor is too large, the TCK pin may be above the device’s threshold for a logic low. Adjust the value of the resistor accordingly. See the appropriate device family data sheet for the specification on input logic levels. © October 2008 Altera Corporation MAX II Device Handbook
15–8 Chapter 15: Using the Agilent 3070 Tester for In-System Programming Development Flow for Agilent3070 with PLD ISP Software ■ If an overpower error on the TCK pin occurs, check the value of the resistors because they may be too low for the test system to back-drive for an extended period of time. ■ Ensure that the test execution order is correct. If the tests are executed out of order, the programming information is incorrect. Also, if the same test is executed twice in a row, the target device will be out of sequence and will not receive the correct programming information. ■ Ensure that the actual vectors match the expected values for the input pins (TCK, TMS, and TDI). If they are not the same, the tests may need to be recompiled. ■ Ensure that the pcf order statement in the test matches the order of the PCF code generated in “Step 2: Create a Serial Vector Format File” on page15–4. If they do not match, the order must be changed and the tests recompiled. ■ If possible, verify that the device is programmed correctly by using the Quartus II software, the ByteBlasterTM II download cable, and the POF that was used to generate the SVF File. This action is not practical in a production situation, but is useful during test development and debugging. ■ If you need to isolate an individual device, you can generate an individual SVF File for each targeted Altera device in the chain. The process of generating the SVF Files is explained in “Step 2: Create a Serial Vector Format File” on page15–4. This process is useful when a verification error occurs and more than one Altera device is programmed in the chain. ■ If you still have problems, look at the boundary-scan chain definition. Make sure that the number of bits for the instruction register are specified correctly for each device in the chain. If an incorrect number of bits have been defined for any device in the chain, the programming test will fail. Once the test is running smoothly, the board is ready for production programming. Altera recommends saving the PCF Files and object code for back-up purposes. Use a compression program to minimize the size of the stored binaries and files. Development Flow for Agilent 3070 with PLD ISP Software Programming devices with the Agilent 3070 tester and PLD ISP software is slightly different than the steps in Figure15–1. Figure 15–3 shows the development flow using the Agilent 3070 tester with Agilent's optional PLD ISP software. MAX II Device Handbook © October 2008 Altera Corporation
Chapter 15: Using the Agilent 3070 Tester for In-System Programming 15–9 Development Flow for Agilent3070 with PLD ISP Software Figure 15–3. Agilent 3070 Development Flow for In-System Programming with Agilent’s PLD ISP Software Start Create a Step 1 Printed Circuit Board (PCB) and Test Fixture Designer Create a Step 2 SVF, Jam, or JBC File Create Executable Step 3 Tests from Files Test Engineer Compile Executable Step 4 Tests Debug Step 5 Programming No Successful? Yes Done Some advantages of using the Agilent PLD ISP software over the SVF2PCF flow for device programming are: ■ The tester can support the programming of devices using SVF, Jam STAPL, or JBC file formats directly (that is, no conversion to PCF or VCL). ■ The Agilent 3070 digital test to program a device is only one file. ■ Pull-up and pull-down resistors are not required on the TCK and TMS lines in the fixture of the tester since the device programming executes entirely as one test. ■ The size of the digital test source file as well as the compiled object file is much smaller than with the SVF2PCF solution. © October 2008 Altera Corporation MAX II Device Handbook
15–10 Chapter 15: Using the Agilent 3070 Tester for In-System Programming Programming Times ■ Execution time for larger CPLDs and configuration devices is faster as only a single digital test file is executed. With Agilent’s PLD ISP software, a Jam Byte-Code Player is implemented in the Control XTP card of the tester. This allows users to program devices using JBC files created directly from Quartus II. The tester also supports Jam or SVF files as it has a JBC compiler to compile these files for programming. The Jam Byte-Code Player is executed via the microcontroller on the Control XTP card and allows users to apply vectors algorithmically rather than executing a sequence of vectors. The Jam Byte- Code Player reads the programming and erase pulse width registers of the devices and uses those values in the programming and erase algorithms. Programming Times Programming times on the Agilent 3070 are very consistent. The only variable is the TCK frequency, which affects programming times. The faster the clock, the less time is spent shifting data into the device. The programming time is a function of the TCK clock rate. MAX II devices support TCK clock rates up to 18 MHz. Guidelines While using the Agilent 3070 tester for programming, use the following guidelines: ■ Use caution if a pin library is used to describe the target device in a stand-alone boundary-scan chain. Altera does not recommend describing all of the ISP device’s I/O pins as bidirectional. This practice uses a large number of hybrid card channels and potentially causes a fixture overflow error when developing the test. ■ Do not include PCF vectors in the test library. Use a setup-only node library. Creating a test library with PCF vectors creates a large library object file and results in a much slower test development time. This delay occurs because the integrated program generator (IPG) looks at the entire vector set of the library object to determine if vectors need to be commented out due to conflicts. Library object compiles are different from executable compiles. Additionally, the IPG may fail due to the large library object file. ■ To save time and disk space, generate SVF Files that include a verify in the programming operation. This process integrates verification vectors into one step, minimizing the amount of work in the test development process. This integrated verify accurately captures any programming errors; therefore, it is not necessary to add an additional stand-alone verify in the test sequence. ■ While this document describes how to generate a test to apply vectors to the device for programming, a boundary-scan description language (BSDL) file is required to functionally test the device. If you need to perform a boundary-scan test or functional test, generate a BSDL file for the programmed state of the target device that contains the pin configuration information (for example, which pins are inputs, outputs, or bidirectional pins). Use the Agilent 3070 boundary-scan software to generate a test. f For more information about Altera’s support for boundary-scan testing, refer to the IEEE 1149.1 (JTAG) Boundary-Scan Testing for MAXII Devices chapter in the MAX II Device Handbook. MAX II Device Handbook © October 2008 Altera Corporation
Chapter 15: Using the Agilent 3070 Tester for In-System Programming 15–11 Conclusion Conclusion Altera provides complete solutions for programming all MAX II devices using the Agilent 3070 test system. All MAX II devices can be programmed together with other ISP-capable devices. With software and device support, the opportunity for cutting costs and increasing manufacturing productivity is available to any Agilent 3070 user. Referenced Documents This chapter references the following documents: ■ IEEE 1149.1 (JTAG) Boundary-Scan Testing for MAX II Devices chapter in the MAX II Device Handbook ■ In-System Programmability Guidelines for MAX II Devices chapter in the MAX II Device Handbook Document Revision History Table 15–1 shows the revision history for this chapter. Table 15–1. Document Revision History Date and Revision Changes Made Summary of Changes October 2008, ■ Updated New Document Format. — version 1.5 December 2007, ■ Added “Referenced Documents” section. — version 1.4 December 2006, ■ Added document revision history. — version 1.3 June 2005, ■ Text edit to the “Programming Times” section (25 MHz to 18MHz). — version 1.2 January 2005, ■ Previously published as Chapter 16. No changes to content. — version 1.1 © October 2008 Altera Corporation MAX II Device Handbook
15–12 Chapter 15: Using the Agilent 3070 Tester for In-System Programming Document Revision History MAX II Device Handbook © October 2008 Altera Corporation
Section V. Design Considerations This section provides information for MAX® II design considerations. This section includes the following chapters: ■ Chapter16, Understanding Timing in MAX II Devices ■ Chapter17, Understanding and Evaluating Power in MAXII Devices Revision History Refer to each chapter for its own specific revision history. For information on when each chapter was updated, refer to the Chapter Revision Dates section, which appears in the complete handbook. © October 2008 Altera Corporation MAX II Device Handbook
V–2 Section V: Design Considerations Revision History MAX II Device Handbook © October 2008 Altera Corporation
16. Understanding Timing in MAX II Devices MII51017-2.1 Introduction Altera® devices provide predictable device performance that is consistent from simulation to application. Before programming a device, you can determine the worst-case timing delays for any design. You can approximate propagation delays with either the Quartus® II Timing Analyzer or the timing models given in this chapter and the timing parameters listed in individual device data sheets. 1 For the most precise timing results, you should use the QuartusII Timing Analyzer, which accounts for the effects of the secondary factors as mentioned later in this chapter. This chapter defines external and internal timing parameters, and illustrates the timing models for the MAX® II device family. 1 Familiarity with device architecture and characteristics is assumed. Refer to specific device or device family data sheets in this handbook for a complete description of the architecture, and for the specific values of the timing parameters listed in this chapter. This chapter contains the following sections: ■ “External Timing Parameters” on page16–1 ■ “Internal Timing Parameters” on page16–2 ■ “Internal Timing Parameters for MAX II UFM” on page16–3 ■ “Timing Models” on page16–4 ■ “Calculating Timing Delays” on page16–5 ■ “Programmable Input Delay” on page16–7 ■ “Timing Model versus QuartusII Timing Analyzer” on page16–7 External Timing Parameters External timing parameters represent actual pin-to-pin timing characteristics. Each external timing parameter consists of a combination of internal timing parameters. You can find the values of the external timing parameters in the DC and Switching Characteristics chapter in the MAX II Device Handbook. These external timing parameters are worst-case values, derived from extensive performance measurements and ensured by testing. All external timing parameters are shown in bold type. Table16–1 defines external timing parameters for the MAX II family. © October 2008 Altera Corporation MAX II Device Handbook
16–2 Chapter 16: Understanding Timing in MAX II Devices Internal Timing Parameters Table16–1. External Timing Parameters Parameter Description t Pin-to-pin delay for the worst case I/O placement with full a diagonal path across the device with PD1 combinational logic implemented in a single look-up table (LUT) in a logic array block (LAB) adjacent to output pin. Fast I/O Connection is used from the adjacent logic element (LE) to the output pin. t Pin-to-pin delay for the best case I/O placement with combinational logic (2-input AND gate) implemented PD2 in a single edge LE adjacent to the input pin. The longest pin path of the two inputs is shown. Fast I/O Connection is used from the adjacent LE to the output pin. t Time to clear register delay. The time required for a low signal to appear at the external output, measured CLR from the input transition. t Global clock setup time. The time that data must be present at the input pin before the global SU (synchronous) clock signal is asserted at the clock pin. t Global clock hold time. The time that data must be present at the input pin after the global clock signal is H asserted at the clock pin. t Global clock to output delay. The time required to obtain a valid output after the global clock is asserted at CO the clock pin. t Minimum global clock period. The minimum period maintained by a globally clocked counter. CNT Internal Timing Parameters Within a device, the timing delays contributed by individual architectural elements are called internal timing parameters, which cannot be measured explicitly. All internal parameters are shown in italic type. Table16–2 defines the internal timing microparameters for the MAX II device family. Table16–2. Internal Timing Microparameters (Part 1 of 2) Parameter Description t LE combinational LUT delay for data-in to data-out. LUT t Combinational path delay. The delay from the time when a combinational logic signal from the LUT COMB bypasses the LE register to the time it becomes available at the LE output. t LE register clear delay. The delay from the assertion of the register’s asynchronous clear input to the time CLR the register output stabilizes at logical low. t LE register preset delay. The delay from the assertion of the register’s asynchronous preset input to the PRE time the register output stabilizes at logical high. t LE register setup time before clock. The time required for a signal to be stable at the register's data and SU enable inputs before the register clock rising edge to ensure that the register correctly stores the input data. t LE register hold time after clock. The time required for a signal to be stable at the register's data and enable H inputs after the register clock's rising edge to ensure that the register correctly stores the input data. t LE register clock-to-output delay. The delay from the rising edge of the register's clock to the time the data CO appears at the register output. t Register control delay. The time required for a signal to be routed to the clock, preset, or clear input of an C LE register. t Combinational output delay. t is the time required for a combinational signal from the LE adjacent to the FASTIO FASTIO I/O block using the fast I/O connection. t I/O input pad and buffer delay. The t applies to I/O pins used as inputs. IN IN t t applies to GCLK pins when used for global signals. t is the delay required for a global signal to be GLOB GLOB GLOB routed from the GCLK pins to the LAB column clocks through the global clock network. MAX II Device Handbook © October 2008 Altera Corporation
Chapter 16: Understanding Timing in MAX II Devices 16–3 Internal Timing Parameters for MAX II UFM Table16–2. Internal Timing Microparameters (Part 2 of 2) Parameter Description t Internal generated output enable delay. The delay from an internally generated signal on the interconnect to IOE the output enable of the tri-state buffer. t Input routing delay. The delay incurred from the row I/O pin used as input to the LE adjacent to it. DL t Output data delay for the row interconnect. The delay incurred by signals routed from an interconnect to an IODR I/O cell. t Output delay buffer and pad delay. Refer to Timing Model and Specifications section in the DCand OD Switching Characteristics chapter in the MAX II Device Handbook for delay adders associated with different I/O standards, drive strengths, and slew rates. t Output buffer disable delay. The delay required for high impedance to appear at the output pin after the XZ output buffer’s enable control is disabled. Refer to Timing Model and Specifications section in the DCand Switching Characteristics chapter in the MAX II Device Handbook for delay adders associated with different I/O standards, drive strengths, and slew rates. t Output buffer enable delay required for the output signal to appear at the output pin after the tri-state ZX buffer's enable control is enabled. Refer to Timing Model and Specifications section in the DCand Switching Characteristics chapter in the MAX II Device Handbook for delay adders associated with different I/O standards, drive strengths, and slew rates. t Delay for a column interconnect with average loading. The t covers a distance of four LAB rows. C4 C4 t Delay for a row interconnect with average loading. The t covers a distance of four LAB columns. R4 R4 t Local interconnect delay. LOCAL Internal Timing Parameters for MAX II UFM Timing parameters for MAX II user flash memory (UFM) are the timing delays contributed by the UFM architectural elements, which cannot be measured explicitly. All timing parameters are shown in italic type. Table16–3 defines the timing microparameters for MAX II UFM. Table16–3. Internal Timing Microparameters for MAX II UFM (Part 1 of 2) Parameter Description t Address register shift signal setup to address register clock. ASU t Address register shift signal hold from address register clock. AH t Address register data in setup to address register clock. ADS t Address register data in hold from address register clock. ADH t Data register shift signal setup to data register clock. DSS t Data register shift signal hold from data register clock. DSH t Data register data in setup to data register clock. DDS t Data register data in hold from data register clock. DDH t Delay incurred from the data register clock to data register output when shifting the data out. DCO t PROGRAM signal to data clock hold time. DP t Maximum delay between PROGRAM rising edge to UFM BUSY signal rising edge. PB t Minimum delay allowed from UFM BUSY signal going low to PROGRAM signal going low. BP t Maximum length of busy pulse during a program. PPMX t Minimum ERASE signal to address clock hold time. AE © October 2008 Altera Corporation MAX II Device Handbook
16–4 Chapter 16: Understanding Timing in MAX II Devices Timing Models Table16–3. Internal Timing Microparameters for MAX II UFM (Part 2 of 2) Parameter Description t Maximum delay between ERASE rising edge to UFM BUSY signal rising edge. EB t Minimum delay allowed from UFM BUSY signal going low to ERASE signal going low. BE t Maximum length of busy pulse during an erase. EPMX t Maximum read access time. The delay incurred between the DRSHFT signal going low to the first bit of RA data observed at the data register output. t Delay from OSC_ENA signal reaching UFM to rising clock of OSC leaving the UFM. OE t Maximum delay between the OSC_ENA rising edge to the ERASE/PROGRAM signal rising edge. OSCS t Minimum delay allowed from the ERASE/PROGRAM signal going low to the OSC_ENA signal going OSCH low. Timing Models Timing models are simplified block diagrams that illustrate the delays through Altera devices. Logic can be implemented on different paths. You can trace the actual paths used in your design by examining the equations listed in the Quartus II Report File (.rpt) for the project. You can then add up the appropriate internal timing parameters to estimate the delays through the device. The MAX II architecture has a globally routed clock. The MultiTrack interconnect ensures predictable performance, accurate simulation, and accurate timing analysis across all MAX II device densities and speed grades. Figure16–1 shows the timing model for MAX II devices. The timing model is the preliminary version which is subject to change. The final version of the timing model will be released once available. Figure16–1. MAX II Device Timing Model Output and Output Enable Data Delay t R4 t IODR t Data-In/LUT Chain IOE User Logic Element Output Routing Output Flash LUT Delay tC4 Delay Delay Memory Input Routing OCAL tLUT tCtOCOMB tFASTIO tttOXDZ I/O InptuINt Delay DetDlaLy tL Regis Dteter laCyontrol tttSHU ZX I/O Pin C PRE t CLR From Adjacent LE t I/O Pin INPUT GLOB Combinational Path Delay Global Input Delay To Adjacent LE Register Delays Data-Out MAX II Device Handbook © October 2008 Altera Corporation
Chapter 16: Understanding Timing in MAX II Devices 16–5 Calculating Timing Delays Calculating Timing Delays You can calculate approximate pin-to-pin timing delays for MAX II devices with the timing model shown in Figure16–1 and by referring to the DC and Switching Characteristics chapter in the MAX II Device Handbook. Each external timing parameter is calculated from a combination of internal timing parameters. Figure16–2 through Figure16–6 show the external timing parameters for the MAX II device family. To calculate the delay for a signal that follows a different path through the MAX II device, refer to the timing model to determine which internal timing parameters to add together. For the most precise timing results, use the Quartus II Timing Analyzer, which accounts for the effects of secondary factors such as placement and fan-out. Figure16–2. External Timing Parameter (t ) Note (1) PD1 TRI MAX II LUT Device Note to Figure16–2: (1) t = t + N x t /4 + M x t /4 + t + t + t + (t + t ) PD1 IN R4 C4 LUT COMB FASTIO OD OD Table16–4 lists the numbers of LABs according to device density. Table16–4. Numbers of LABs According to Device Density Device Density N LAB Rows M LAB Columns EPM240 4 6 EPM570 7 12 EPM1270 10 16 EPM2210 13 20 Dt is the adder delay (see note to Figure16–2) for the t microparameter when OD OD using an I/O standard other than 3.3-V LVTTL with 16 mA current strength. f Refer to the DC and Switching Characteristics chapter in the MAX II Device Handbook for adder delay values. The following is an example: t for the EPM240 device using an I/O standard of 3.3-V LVTTL fast slew rate with a PD1 drive strength of 16 mA: t = t + 4 × t /4 + 6 x t /4 + t + t + t + t ……(a) PD1 IN R4 C4 LUT COMB FASTIO OD t for the EPM240 device using an I/O standard of 2.5-V LVTTL fast slew rate with a PD1 drive strength of 7 mA: t = (a) + (Dt of 2.5-V LVTTL fast slew 7 mA) PD1 OD © October 2008 Altera Corporation MAX II Device Handbook
16–6 Chapter 16: Understanding Timing in MAX II Devices Calculating Timing Delays Figure16–3. External Timing Parameter (t ) Note (1) PD2 TRI MAX II LUT Device Note to Figure16–3: (1) t = t + t + t + t + t + (t + t ) PD2 IN DL LUT COMB FASTIO OD OD Figure16–4. External Timing Parameter (t ) Note (1), (2) CO LE Register Notes to Figure16–4: (1) t = t + t + t + (N x t /4 + M x t /4) + (t or t ) + (t + t ) CO GLOB C CO R4 C4 IODC IODR OD OD (2) The constants N and M are subject to change according to the position of the LAB in the entire device. Figure16–5. LE Register Clear and Preset Time (t ) Note (1) CLR LE Register Note to Figure16–5: (1) t = t + t + t + (N x t /4 + M x t /4) + (t or t ) + (t + t ) CLR GLOB C CLR R4 C4 IODC IODR OD OD Figure16–6. LE Register Clear and Preset Time (t ) Note (1) PRE LE Register Note to Figure16–6: (1) t = t + t + t + t + (N x t /4 + M x t /4) + (t or t ) + (t + t ) PRE GLOB LOCAL C PRE R4 C4 IODC IODR OD OD Setup and Hold Time from an I/O Data and Clock Input The Quartus II software might insert additional routing delays from the input pin to the register input to ensure a zero hold time for the LE register. Altera recommends that you use the Quartus II Timing Analyzer to obtain the setup time and hold time. See Figure16–7 and Figure16–8. MAX II Device Handbook © October 2008 Altera Corporation
Chapter 16: Understanding Timing in MAX II Devices 16–7 Programmable Input Delay Figure16–7. Setup and Hold Time (t ) Note (1) SU Combinational LE Register Logic Note to Figure16–7: (1) t = (t + N x t /4 + M x t /4 + t ) - (t + t ) + t SU IN R4 C4 LUT GLOB C SU Figure16–8. Setup and Hold Time (t ) Note (1) H Combinational LE Register Logic Note to Figure16–8: (1) t = (t + t) - (t + N x t /4 + M x t /4 + t ) + t H GLOB C IN R4 C4 LUT H 1 For Figure16–4 through Figure16–8, the constants N and M are subject to change according to the position of LAB in the entire device for combinational logic implementation. Programmable Input Delay The programmable input delay provides an option to add a delay to the input pin, guaranteeing a zero hold time. You can set this option in the Assignment Editor (Assignments menu) on a pin-by-pin basis. The following procedure shows how to turn on the input delay for the selected input pin in the Quartus II software: 1. Select input pin name in the design file. 2. Right-click and select Locate in the Assignment Editor. 3. Double-click the cell under Assignment Name and select Input Delay from Pin to Internal Cells in the pull-down list. 4. Double-click the Value cell to the right of the assignment name just made and enter 1. 5. On the File menu, click Save. Timing Model versus Quartus II Timing Analyzer Hand calculations based on the timing model provide a good estimate of a design’s performance. However, the Quartus II Timing Analyzer always provides the most accurate information on design performance because it takes into account secondary factors that influence the routing microparameters such as: ■ Fan-out for each signal in the delay path ■ Positions of other loads relative to the signal source and destination © October 2008 Altera Corporation MAX II Device Handbook
16–8 Chapter 16: Understanding Timing in MAX II Devices Conclusion ■ Distance between the signal source and destination ■ Various interconnect lengths where some interconnects are truncated at the edge of the device Conclusion The MAX II device architecture has predictable internal timing delays that can be estimated based on signal synthesis and placement. The Quartus II Timing Analyzer provides the most accurate timing information. However, you can use the timing model along with the timing parameters listed in the DC and Switching Characteristics chapter in the MAX II Device Handbook to estimate a design’s performance before compilation. Both methods enable you to accurately predict your design’s in-system timing performance. Referenced Documents This chapter references the following document: ■ DC and Switching Characteristics chapter in the MAX II Device Handbook Document Revision History Table16–5 shows the revision history for this chapter. Table16–5. Document Revision History Date and Revision Changes Made Summary of Changes October 2008, ■ Updated New Document Format. — version 2.1 December 2007, ■ Updated t information in Table16–1. — PD2 version 2.0 ■ Added t information in Table16–2. COMB ■ Updated Figure16–1. ■ Updated Note (1) to Figure16–2. ■ Updated “Calculating Timing Delays” section. ■ Added “Referenced Documents” section. December 2006, ■ Added document revision history. — version 1.4 January 2005, ■ Previously published as Chapter 17. No changes to content. — version 1.3 December 2004, ■ Added section Programmable Input Delay. — version 1.2 June 2004, ■ Updated Table16–1. Various parameter naming updates. — version 1.1 MAX II Device Handbook © October 2008 Altera Corporation
17. Understanding and Evaluating Power in MAX II Devices MII51018-2.1 Introduction Power consumption has become an important factor for CPLD applications with the increased use of CPLDs in low power designs. Overall low standby (static) and dynamic power is becoming increasingly important to reduce system power, and can be achieved with MAX® II devices which have low stand-by and dynamic power. This chapter contains the following sections: ■ “Power in MAX II Devices” on page17–1 ■ “MAX II Power Estimation Using the PowerPlay Early Power Estimator” on page17–3 ■ “PowerPlay Early Power Estimator Inputs” on page17–3 ■ “Power Estimation Summary” on page17–13 ■ “Power Saving Techniques” on page17–15 Power in MAX II Devices Different from previous CPLD architectures, MAX II logic does not use sense amplifiers that require bias currents to amplify signal voltages within the device. Additionally, with the Quartus® II software, efficient implementation of most interconnects with local routing in MAX II devices significantly lowers the dynamic power. Figure17–1 shows the typical power consumption versus frequency for MAX II devices. The power consumption (mWatts) provided is based on typical conditions using a pattern that fills a device with a 16-bit, loadable, enabled, up/down counter with no output load. © October 2008 Altera Corporation MAX II Device Handbook
17–2 Chapter 17: Understanding and Evaluating Power in MAXII Devices Power in MAX II Devices Figure17–1. Power Consumption versus Frequency for MAX II Devices (Note1), (2) EPM240 EPM570 (3) (3) 120.00 250.00 mW) 100.00 (4) mW) 200.00 on ( 80.00 on ( (4) mpti mpti 150.00 nsu 60.00 nsu (5) o o er C 40.00 ((56)) er C 100.00 (6) w w o o P P al 20.00 al 50.00 c c pi pi Ty Ty 0.00 0.00 0 50 100 150 0 50 100 150 Frequency (MHz) Frequency (MHz) 1000.00 EPM2210 EPM1270 (3) 600.00 (3) 900.00 W) 800.00 mW) 500.00 n (m 700.00 (4) ption ( 400.00 (4) umptio 600.00 pical Power Consum 230000..0000 (5) Typical Power Cons 234500000000....00000000 (5) Ty 100.00 100.00 0.00 0.00 0 50 100 150 0 50 100 150 Frequency (MHz) Frequency (MHz) Notes to Figure17–1: (1) Every device is fully utilized with 16-bit counters for power estimation. (2) The MAX II and MAX IIG devices can operate up to 304MHz. (3) V = 3.3 V CCINT (4) V = 2.5 V CCINT (5) V = 1.8 V (MAX IIG) CCINT (6) V = 1.8 V (MAX IIZ) CCINT The power consumed in MAX II devices is dependent on the design. It is very important to complete a power evaluation early in the design process to ensure that the power dissipation by MAX II devices meets system requirements and specifications. This chapter discusses how to evaluate and manage MAX II power using the MAX II PowerPlay Early Power Estimator spreadsheet, available at www.altera.com. MAX II Device Handbook © October 2008 Altera Corporation
Chapter 17: Understanding and Evaluating Power in MAXII Devices 17–3 MAX II Power Estimation Using the PowerPlay Early Power Estimator MAX II Power Estimation Using the PowerPlay Early Power Estimator The PowerPlay Early Power Estimator spreadsheet allows you to enter information into sections based on architectural features. The PowerPlay Early Power Estimator spreadsheet also provides a subtotal of power consumed by each architectural feature reported in each section in mWatts (mW). Figure17–2 shows the overview of the MAX II PowerPlay Early Power Estimator summary worksheet. Figure17–2. MAX II PowerPlay Early Power Estimator 1 The power estimator results are based on estimated power data from device simulations and typical silicon measurements under nominal conditions. Results obtained should only be used as an estimation of power, not as a specification. The actual I must be verified during device operation, as this measurement is sensitive CC to the actual pattern in the device and the environmental operating conditions. PowerPlay Early Power Estimator Inputs The following sections of the chapter explain what values you need to enter for the PowerPlay Early Power Estimator spreadsheet. The areas of entry in the PowerPlay Early Power Estimator spreadsheet include input parameters, clock, logic, UFM, and input/output (I/O) module. © October 2008 Altera Corporation MAX II Device Handbook
17–4 Chapter 17: Understanding and Evaluating Power in MAXII Devices PowerPlay Early Power Estimator Inputs Input Parameters Different MAX II devices consume different amounts of power for the same design. The larger the device, the more power it consumes because of a larger clock tree. In the Main section, you can enter the following parameters for the device and design: ■ Device ■ Package ■ Temperature grade ■ Power characteristics ■ V supply CCINT ■ Ambient temperature ■ Airflow Figure17–3 shows the Input Parameter section in the PowerPlay Early Power Estimator spreadsheet. Figure17–3. Input Parameter Section Table17–1 describes the values that must be specified in the Input Parameter section of the PowerPlay Early Power Estimator spreadsheet. Table17–1. Input Parameter Section Information (Part 1 of 2) Input Parameter Description Device Select your MAX II device. Larger devices have slightly higher clock dynamic power. MAX IIZ devices have the lowest I compared to the MAX II and MAX IIG devices because MAX IIZ CCINT devices have optimized circuitry to reduce I . Compared to MAX II devices, MAX IIG devices use CCINT less power because they do not use the on-chip voltage regulator. Package Select the package that will be used. Larger packages provide a larger cooling surface and more contact points to the circuit board, leading to lower thermal resistance. Package selection does not affect power consumption. Temperature Grade Commercial devices have a maximum junction operating temperature of 85°C. Industrial devices offer 100°C operation while the MAX II automotive-grade devices can operate up to 125°C. This field affects the maximum junction temperature used in thermal calculations. Power Characteristics For MAX IIZ devices, you can select either typical or maximum power characteristics for the power estimation. The power characteristics are based on typical and theoretical worst-case silicon process. Maximum should be used for thermal design, while Typical gives you the estimation of the average use of the devices. MAX II Device Handbook © October 2008 Altera Corporation
Chapter 17: Understanding and Evaluating Power in MAXII Devices 17–5 PowerPlay Early Power Estimator Inputs Table17–1. Input Parameter Section Information (Part 2 of 2) Input Parameter Description V Supply The voltage of the V power supply. For MAX IIG and MAX IIZ devices, the supply voltage must CCINT CCINT be 1.8 V. For other devices, it can be either 2.5 V or 3.3 V. Devices with lower V have lower total CCINT standby power consumption. Ambient Temperature Enter the air temperature near the CPLD. This value can range from –40°C to 125°C, depending on the device temperature grade. This parameter is used to compute junction temperature based on power dissipation and thermal resistances through the top of the chip. Airflow Select an available ambient airflow in linear feet per minute (lfm) or meters per second (m/s). The options are still air, 100 lfm (0.5 m/s), 200 lfm (1.0 m/s), or 400 lfm (2.0 m/s). Increased airflow results in a lower junction-to-air thermal resistance, and thus lower junction temperature. Clock Section MAX II devices have four global clocks each. Each row in the Clock Domain subsection of the spreadsheet represents a clock network or a separate clock domain. You must enter the clock frequency (f ) in MHz, the total fan-out for each clock MAX network used, and the local clock enable percentage. Figure17–4 shows the Clock section in the PowerPlay Early Power Estimator spreadsheet. Figure17–4. Clock Section Table17–2 describes the parameters in the Clock section of the PowerPlay Early Power Estimator spreadsheet. Table17–2. Clock Section Information Column Heading Description Clock Domain Enter a name for the clock network in this column (optional entry). Clock Frequency (MHz) Enter the frequency of the clock domain. The operating frequency for MAX II and MAX IIG is between 0 and 304 MHz. For MAX IIZ, the operating frequency is between 0 and 152 MHz. Total Fanout Enter the total number of logic element (LE) flipflops fed by this clock. The number of resources driven by every global clock is reported in the Fanout column of the Quartus II Compilation Report under Fitter > Resource Section > Global & Other Fast Signals > Fanout. Local Enable % Enter the average percentage of time that clock enable is high for destination flipflops. Local clock enables for flipflops in the LEs are promoted to logic array block (LAB)-wide signals. When a given flipflop is disabled, the LAB-wide clock is also disabled, cutting clock power in addition to power for downstream logic. This sheet models only the impact on clock tree power. Total Power (mW) Represents the total power dissipation due to clock distribution. User Comments Enter any comments (optional entry). © October 2008 Altera Corporation MAX II Device Handbook
17–6 Chapter 17: Understanding and Evaluating Power in MAXII Devices PowerPlay Early Power Estimator Inputs Logic Section A design is a combination of several design modules operating at different frequencies and toggle rates. Each design module can have a different amount of logic. For the most accurate power estimation, partition the design into different design modules. You can partition your design by grouping modules by clock frequency, location, hierarchy, or entities. Figure17–5 shows the logic section in the PowerPlay Early Power Estimator spreadsheet. Figure17–5. Logic Section Each row in the Logic section represents a separate design module. Table17–3 describes the parameters in the Logic section of the PowerPlay Early Power Estimator spreadsheet. Table17–3. Logic Section Information (Part 1 of 2) Column Heading Description Logic Module Enter a name for each module of the design (optional entry). Clock Frequency (MHz) Enter a clock frequency (MHz). The operating frequency for MAX II and MAXIIG is between 0 and 304 MHz. For MAX IIZ, the operating frequency is between 0 and 152 MHz. A 100MHz input clock with a 12.5% toggle means that each look-up table (LUT) or flipflop output toggles 12.5 million times per second (100×12.5%). # LEs Enter the number of LEs in this module. Toggle % Enter the average percentage of logic toggling on each clock cycle. The toggle percentage ranges from 0 to 100%. Typically, the toggle percentage is 12.5%, which is the toggle percentage of a 16-bit counter. To ensure you do not underestimate the toggle percentage, you can use a higher toggle percentage. Most logic toggles infrequently, and therefore toggle rates of <50% are more realistic. For example, a TFF with its input tied to V has a toggle rate of 100% because its output is CC changing logic states on every clock cycle (see Figure17–6). Figure17–7 shows an example of a 4-bit counter. The first TFF with least significant bit (LSB) output cout0 has a toggle rate of 100% because the signal toggles on every clock cycle. The toggle rate for the second TFF with output cout1 is 50% since the signal only toggles on every two clock cycles. Consequently, the toggle rate for the third TFF with output cout2 and fourth TFF with output cout3 are 25% and 12.5%, respectively. Therefore, the average toggle percentage for this 4-bit counter is (100 + 50 + 25 + 12.5)/4 = 46.875%. MAX II Device Handbook © October 2008 Altera Corporation
Chapter 17: Understanding and Evaluating Power in MAXII Devices 17–7 PowerPlay Early Power Estimator Inputs Table17–3. Logic Section Information (Part 2 of 2) Column Heading Description Routing Represents the power dissipation due to estimated routing. Routing power is highly dependent on placement and routing, which itself is a function of design complexity. The values shown are representative of routing power average based on experimentation on over 100 real-world designs. Use the Quartus II PowerPlay Power Analyzer for detailed analysis based on the routing used in your design. Block Represents the power dissipation due to internal toggling of the LEs. Logic block power is a function of the function implemented and relative toggle rates of the various inputs. The PowerPlay Early Power Estimator spreadsheet uses an estimate based on observed behavior across over 100 real-world designs. Use the Quartus II PowerPlay Power Analyzer for an accurate analysis based on the exact synthesis of your design. Total Represents the total power dissipation. The total power dissipation is the sum of the routing and block power. User Comments Enter any comments (optional entry). Figure17–6. T-Flipflop Figure17–7. 4-Bit Counter © October 2008 Altera Corporation MAX II Device Handbook
17–8 Chapter 17: Understanding and Evaluating Power in MAXII Devices PowerPlay Early Power Estimator Inputs UFM Section When the design utilizes the UFM, the PowerPlay Early Power Estimator spreadsheet considers the time spent during read operations into the power estimation. Figure17–8 shows the UFM section in the PowerPlay Early Power Estimator spreadsheet. Figure17–8. UFM Section Table17–4 describes the parameters in the UFM section of the PowerPlay Early Power Estimator spreadsheet. Table17–4. UFM Section Information Column Heading Description UFM Module Enter a name for the UFM module in this column (optional entry). Read % Enter the percentage of time the UFM spends in Read mode. It takes 16 clock cycles to shift the serial data out after an internal UFM read so the read operation occurs less than 1/17 (or about 6%) of the time. The clock in this calculation is the UFM block’s DRCLK signal. Total Power (mW) Total power dissipation due to reading from the UFM block (mW). Programming and erasing can only be performed a limited number of times over the life of the device so they do not contribute to average power. User Comments Enter any comments (optional entry). I/O Section MAX II devices feature programmable I/O pins that support a wide range of industry I/O standards for increased design flexibility. The I/O section in the PowerPlay Early Power Estimator spreadsheet allows you to estimate the I/O pin power consumption based on the pin’s I/O standards. The total thermal power is the sum of the thermal power consumed by the device based on each power rail. Thermal Power = Thermal P + Thermal P INT IO MAX II Device Handbook © October 2008 Altera Corporation
Chapter 17: Understanding and Evaluating Power in MAXII Devices 17–9 PowerPlay Early Power Estimator Inputs Figure17–9 shows a graphical representation of the thermal power consumption. Figure17–9. Thermal Power Representation VCCINT VCCIO ICCINT ICCIO MAX II Device Thermal PINT Thermal PIO The PowerPlay Early Power Estimator spreadsheet estimates the current for each I/O bank based on the V settings, if you specify the I/O bank for I/O pins in the I/O CCIO section. Figure17–10 shows the I/O bank parameter settings. Figure17–10. I/O Bank Parameter Settings Table17–5 describes the I/O bank parameters in the I/O section of the PowerPlay Early Power Estimator spreadsheet. Table17–5. I/O Bank Information Column Heading Description V Select the V voltage for each bank. Used to cross-check selected I/O CCIO CCIO standards in I/O section for warning purposes. I Shows the total supply current due to the I/O pins in each I/O bank. CCIO Unassigned Represents the I of all I/O modules not assigned to an I/O bank. CCIO Each row in the I/O section represents a design module where the I/O pins have the same frequency, toggle percentage, average capacitive load, I/O standard, and I/O bank. Figure17–11 shows the I/O section of the PowerPlay Early Power Estimator spreadsheet and Table17–6 describes the I/O module parameters. © October 2008 Altera Corporation MAX II Device Handbook
17–10 Chapter 17: Understanding and Evaluating Power in MAXII Devices PowerPlay Early Power Estimator Inputs Figure17–11. I/O Section Table17–6. I/O Section Information (Part 1 of 2) Column Heading Description Module Enter a name for the module in this column (optional entry). I/O Standard Select the I/O standard for the input, output, or bidirectional pins in this module from the pull- down list. The calculated I/O power varies based on the I/O standard. Clock Freq (MHz) Enter the clock frequency (MHz). The operating frequency for MAX II and MAX IIG is between 0 and 304 MHz. For MAX IIZ, the operating frequency is between 0 and 152 MHz. A 100MHz input clock with a 12.5% toggle means that each I/O pin toggles 12.5 million times per second (100 × 12.5%). # Output Pins Enter the number of output pins in this module. # Input Pins Enter the number of input pins in this module. # Bidir Pins Enter the number of bidirectional pins in this module. An I/O pin configured as bidirectional but used only as an output consumes more power than one configured as an output-only, due to the toggling of the input buffer every time the output buffer toggles (they share a common pin). I/O Bank Select the I/O bank for the module. If you do not know which I/O bank the pins will be assigned to, leave the value as “?”. Assigning the I/O module to a bank checks whether your I/O voltage assignments are compatible or not, allowing per-bank I reporting. CCIO The PowerPlay Early Power Estimator spreadsheet does not take any I/O placement constraints into consideration except for I/O standard and bank match, and I/O voltage. Toggle % Enter the average percentage of output, bidirectional, and input pins toggling on each clock cycle. The toggle percentage ranges from 0 to 100% for output pins and can be up to 200% for input pins used as clocks because clocks toggle at twice the clock frequency. Typically, the toggle percentage is 12.5%. To be more conservative, you can use a higher toggle percentage. MAX II Device Handbook © October 2008 Altera Corporation
Chapter 17: Understanding and Evaluating Power in MAXII Devices 17–11 PowerPlay Early Power Estimator Inputs Table17–6. I/O Section Information (Part 2 of 2) Column Heading Description OE % Enter the average percentage of time that: ■ The output I/O pins are enabled. ■ Bidirectional I/O pins are outputs and enabled. During the remaining time: ■ Output I/O pins are tri-stated. ■ Bidirectional I/O pins are inputs. This number must be a percentage between 0% and 100%. Load (pF) Enter the pin loading external to the chip (pF). This parameter only applies to output and bidirectional pins. Pin and package capacitance is already included in the I/O model. Therefore, you only need to include off-chip capacitance in the Load parameter. Bank I/O Std Check Indicates whether the selected I/O standard is available on the selected I/O bank or not. Not all I/O banks can implement every I/O standard. Bank Voltage Check Indicates whether the selected I/O bank has a voltage compatible with the selected I/O standard or not. Routing Represents the power dissipation due to estimated routing. Routing power is highly dependent on placement and routing, which itself is a function of design complexity. The values shown are representative of routing power based on experimentation on over 100 real-world designs. Use the Quartus II PowerPlay Power Analyzer for detailed analysis based on the routing used in your design. Block Represents the power dissipation due to internal and load toggling of the I/O. Use the Quartus II PowerPlay Power Analyzer for accurate analysis based on the exact I/O configuration of your design. Total Represents the total power dissipation. The total power dissipation is the sum of the routing and block power. I Represents the current drawn from the I rail. Powers internal digital circuitry and routing. CCINT CCINT I Represents the current drawn from this bank’s V rail. CCIO CCIO User Comment Enter any comments (optional entry). Other Input Information There are three other buttons below the input parameters section: Set Toggle %, Reset, and Import Quartus File, as shown in Figure17–12. Figure17–12. The Three Buttons Set Toggle % Sets the toggle rate for the Logic Module and I/O Module. © October 2008 Altera Corporation MAX II Device Handbook
17–12 Chapter 17: Understanding and Evaluating Power in MAXII Devices PowerPlay Early Power Estimator Inputs Reset Clears all input values in the PowerPlay Early Power Estimator spreadsheet. Importing the Quartus II Early Power Estimator File If you have created the user design, you can use the Quartus II software to generate the PowerPlay Early Power Estimator file and then import this file into the PowerPlay Early Power Estimator spreadsheet. This power estimation report file contains the device resource information and importing this file saves you time and effort otherwise spent manually entering information into the PowerPlay Early Power Estimator spreadsheet. You can manually change any of the values after importing the file. To generate the PowerPlay Early Power Estimator file, first compile your design in the Quartus II software. After that, on the Project menu, click Generate PowerPlay Early Power Estimator File. The Quartus II software creates a PowerPlay Early Power Estimator file with the name <revision name>_early_pwr.csv. f For more information about generating the PowerPlay Early Power Estimator file in the Quartus II software, refer to the PowerPlay Power Analysis chapter in volume 3 of the Quartus II Handbook. To import data into the PowerPlay Early Power Estimator spreadsheet, perform the following steps: 1. Click Import Quartus File in the PowerPlay Early Power Estimator spreadsheet. 2. Browse to a power estimation file generated from the Quartus II software. Click OK. Clicking OK clears any user-entered values in the PowerPlay Early Power Estimator spreadsheet and populates the PowerPlay Early Power Estimator spreadsheet with device resource information from the specified power estimation file. After importing a file, manually specify some of the input parameters in the main section. These input parameters include: ■ V supply voltage CCINT ■ Ambient temperature ■ Airflow The ambient temperature and airflow are used for thermal analysis only. Refer to the input parameters section for more information on these parameters. The clock frequency values imported into PowerPlay Early Power Estimator Clock Domain, Logic, and I/O modules are the same as the f values of the design. You MAX can manually edit the clock frequency and the toggle percentage in the PowerPlay Early Power Estimator spreadsheet to suit your system requirements. MAX II Device Handbook © October 2008 Altera Corporation
Chapter 17: Understanding and Evaluating Power in MAXII Devices 17–13 Power Estimation Summary Power Estimation Summary The main worksheet of the PowerPlay Early Power Estimator spreadsheet summarizes the power and current estimates for the design. It displays the total power, thermal analysis, and power supply current information. The accuracy of the information depends on the information entered. The power consumed can also vary greatly depending on the toggle rates entered. The following sections provide a description of the results of the PowerPlay Early Power Estimator spreadsheet. Power This section shows the power dissipated in the MAX II device. The total thermal power is shown in mWatts and is a sum of the thermal power of all the resources being used in the device. The total thermal power includes the typical power from standby and dynamic power. Figure17–13 shows the Power section. Figure17–13. Power Section Table17–7 describes the thermal power parameters in the PowerPlay Early Power Estimator spreadsheet. Table17–7. Power Information Column Heading Description Clock Represents the dynamic power consumed by clock networks. Click Clocks for details. Logic Represents the dynamic power consumed by LEs and associated routing. Click Logic for details. UFM Represents the dynamic power consumed by the UFM block. Click UFM for details. I/O Represents the dynamic power consumed by I/O pins and associated routing. Click I/O for details. Voltage Regulator Represents the dynamic power consumed by the on-chip voltage regulator for a device that supports 2.5-V/3.3-V V . CCINT P Represents the standby/static power consumed irrespective of clock frequency. The value STANDBY includes static power consumed by the I/O banks and the voltage regulator. P is dependent on the selected device and the V supply voltage. STANDBY CCINT P Represents the total power consumed by the CPLD. Refer to “Power Supply Current” on TOTAL page17–15 for the current draw from the CPLD supply rails. © October 2008 Altera Corporation MAX II Device Handbook
17–14 Chapter 17: Understanding and Evaluating Power in MAXII Devices Power Estimation Summary Thermal Analysis In the Thermal Analysis part, the PowerPlay Early Power Estimator spreadsheet considers the device’s ambient temperature and the airflow to determine the junction temperature (T) of the device in °C. J The device can be considered a heat source and the junction temperature is the temperature at the device. The thermal resistance of the path is referred to as the junction-to-ambient thermal resistance ( ). Figure17–14 shows the thermal model JA for the PowerPlay Early Power Estimator spreadsheet. Figure17–14. Thermal Model for the PowerPlay Early Power Estimator Heat Source Power (P) TJ θ JA TA The PowerPlay Early Power Estimator spreadsheet determines the junction-to- ambient thermal resistance ( ) based on the device, package, and airflow selected in JA the main input parameters. The PowerPlay Early Power Estimator spreadsheet calculates the total power based on the device properties which provide and the ambient and junction temperature JA using the following equation: Equation17–1. T –T P = ----J-----------A-- JA Figure17–15 shows the Thermal Analysis section and Table17–8 describes the thermal analysis parameters in the PowerPlay Early Power Estimator spreadsheet. Figure17–15. Thermal Analysis Section MAX II Device Handbook © October 2008 Altera Corporation
Chapter 17: Understanding and Evaluating Power in MAXII Devices 17–15 Power Saving Techniques Table17–8. Thermal Analysis Information Column Heading Description Junction Temp, T (°C) Represents the estimated device junction temperature. J Junction-Ambient Represents the junction-to-ambient thermal resistance through the top of the device JA (°C/W). Maximum Allowed T (°C) Represents a guideline for the maximum ambient temperature (°C) that the device can A be subjected to without violating maximum junction temperature. Power Supply Current The power supply current provides the estimated current consumption for power supplies. The I is only applicable during power up when the configuration CCPOWERUP flash memory (CFM) block downloads to the SRAM. The I current is the supply CCINT current required from V . The total I current is the supply current required from CCINT CCIO V for all I/O banks. For estimates of I based on I/O banks, refer to the “I/O CCIO CCIO Section” on page17–8 of the PowerPlay Early Power Estimator spreadsheet. Figure17–16 shows the Power Supply Current section. Figure17–16. Power Supply Current Table17–9 describes the Power Supply Current parameters of the PowerPlay Early Power Estimator spreadsheet. Table17–9. Power Supply Current Information Column Heading Description I Represents the maximum current drawn during power-up. CCPOWERUP I Represents the total current drawn from the I supply. CCINT CCINT I Represents the total current drawn from the I power rail(s). Refer to the CCIO CCIO “I/O Section” on page17–8 for details about the current drawn from each I/O rail. Power Saving Techniques The following guidelines reduce power consumption for an application: ■ Slow the operation in portions of the circuit. I is proportional to the frequency of CC operation. Slowing parts of a circuit lowers the I and therefore reduces the CC power. MAX II devices provide global or array clock source for all registers. Signals that do not require high-speed operation can use a slower array clock that reduces the system power consumption. ■ Reduce the number of outputs. Standby and dynamic current are required to support all I/O pins on the device. Reducing the number of I/O pins can reduce current necessary for the device, and thereby reduce the power. © October 2008 Altera Corporation MAX II Device Handbook
17–16 Chapter 17: Understanding and Evaluating Power in MAXII Devices Conclusion ■ Reduce the loading and/or external capacitance on the outputs. Excessive loading and capacitance of printed circuit board (PCB) traces and other ICs on the output pins significantly increases the power. Keeping excess load and external capacitance to a minimum on the outputs pins whenever possible will significantly reduce the current necessary for the device. ■ Reduce the amount of circuitry in the device. Power depends on the amount of internal logic that switches at any given time. Reducing the amount of logic in a device reduces the current in the device and thus reduces the power. ■ Modify the design to reduce power. Identify areas in the design that can be revised to reduce the power requirements. Common solutions include reducing the number of switching nodes and/or required logic, and removing redundant unnecessary signals. ■ Modify I/O Locations. Grouping I/O pins from common logic blocks allows the Quartus II software to place the associated logic closer together. The more compact a logic block and I/O, the lower its dynamic power (especially true of low utilization designs with I/O spread around the device). ■ Increase the performance requirements in the constraint file. Improving the performance that is beyond the need for operation reduces the power dissipation. The Quartus II software optimizes the design and places logic closer together, uses shorter routing and fewer logic levels, and lowers dynamic power and improves performance. f MAX II devices offer a power-down capability that conserves battery life for portable applications. For more information about the power-down capability in MAX II devices and an application design example, refer to AN 422: Power Management in Portable Systems Using MAX II CPLDs. Conclusion This chapter discusses how to evaluate and manage MAX II power by using the MAX II PowerPlay Early Power Estimator spreadsheet. This power estimation tool estimates the power consumption for your design based on typical conditions. The MAX II board-level designer can exploit the power calculator before board design and layout. The MAX II PowerPlay Early Power Estimator spreadsheet is available on the Altera website at www.altera.com. Referenced Documents This chapter references the following documents: ■ AN 422: Power Management in Portable Systems Using MAX II CPLDs ■ PowerPlay Power Analysis chapter in volume 3 of the Quartus II Handbook MAX II Device Handbook © October 2008 Altera Corporation
Chapter 17: Understanding and Evaluating Power in MAXII Devices 17–17 Document Revision History Document Revision History Table17–10 shows the revision history for this chapter. Table17–10. Document Revision History Date and Revision Changes Made Summary of Changes October 2008, ■ Updated New Document Format. — version 2.1 December 2007, ■ Updated Figure17–1, Figure17–2, and Figure17–3. Updated document version 2.0 with MAX IIZ ■ Updated Table17–1 with information about power characteristics. information. ■ Updated Table17–2, Table17–3, and Table17–6. ■ Added “Referenced Documents” section. December 2006, ■ Added document revision history. — version 1.5 July 2006, ■ Minor content update. — version 1.4 August 2005, ■ Updated the entire MAX II Power Estimation Using the PowerPlay Early — version 1.3 Power Estimator section. January 2005, ■ Previously published as Chapter 18. No changes to content. — version 1.2 December 2004, ■ Added Excel Macro, General I/O AC Power, and General I/O DC Power — version 1.1 sections. ■ Updated figures. ■ Updated Table 17-1. © October 2008 Altera Corporation MAX II Device Handbook
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