F280021PTSR [TI]
具有 100MHz 频率、FPU、TMU、32KB 闪存的 C2000™ 32 位 MCU | PT | 48 | -40 to 125;型号: | F280021PTSR |
厂家: | TEXAS INSTRUMENTS |
描述: | 具有 100MHz 频率、FPU、TMU、32KB 闪存的 C2000™ 32 位 MCU | PT | 48 | -40 to 125 闪存 |
文件: | 总208页 (文件大小:6661K) |
中文: | 中文翻译 | 下载: | 下载PDF数据表文档文件 |
TMS320F280025, TMS320F280025-Q1
TMS320F280025C, TMS320F280025C-Q1, TMS320F280023, TMS320F280023-Q1
TMS320F280023C, TMS320F280021, TMS320F280021-Q1
ZHCSL01B –MARCH 2020 –REVISED DECEMBER 2020
TMS320F28002x 实时微控制器
• 模拟系统
1 特性
– 两个3.45MSPS 12 位模数转换器(ADC)
• TMS320C28x 32 位DSP 内核(在100MHz 下)
– IEEE 754 浮点单元(FPU)
• 多达16 个外部通道
• 每个ADC 具有四个集成后处理块(PPB)
– 四个带12 位参考
• 支持快速整数除法(FINTDIV)
– 三角法数学单元(TMU)
数模转换器(DAC) 的窗口比较器(CMPSS)
• 数字干扰滤波器
• 增强型控制外设
• 支持非线性比例积分微分(NLPID) 控制
– CRC 引擎和指令(VCRC)
– 十个硬件断点(包括ERAD)
• 片上存储器
– 14 个ePWM 通道,包含具有高分辨率功能
(150ps 分辨率)的8 个通道
• 集成式死区支持
• 集成硬件跳匣区域(TZ)
– 三个增强型捕捉(eCAP) 模块
– 128KB (64KW) 闪存(ECC 保护)
– 24KB (12KW) RAM(ECC 保护或奇偶校验保
护)
– 双区域安全
• 时钟和系统控制
• 在三个eCAP 模块中,有一个提供高分辨率
捕捉(HRCAP)
– 两个内部零引脚10MHz 振荡器
– 片上晶体振荡器或外部时钟输入
– 窗口化看门狗计时器模块
– 丢失时钟检测电路
– 两个支持CW/CCW 运行模式的增强型正交编码
器脉冲(eQEP) 模块
• 可配置逻辑块(CLB)
– 增强现有外设功能
– 支持位置管理器解决方案
• 主机接口控制器(HIC)
– 双路时钟比较器(DCC)
• 3.3V 单电源
– 内部VREG 生成
– 欠压复位(BOR) 电路
• 系统外设
– 可从外部主机访问内部存储器
• 背景CRC (BGCRC)
– 关于32 位数据的一个周期CRC 运算
• 诊断特性
– 6 通道直接存储器存取(DMA) 控制器
– 39 个独立可编程多路复用通用输入/输出(GPIO)
引脚
– 在模拟引脚上提供16 路数字输入
– 增强型外设中断扩展(ePIE)
– 支持多个低功耗模式(LPM)
– 嵌入式实时分析和诊断(ERAD)
– 唯一标识(UID) 号
– 存储开机自检(MPOST)
– 硬件内置自检(HWBIST)
• 封装选项:
– 80 引脚薄型四方扁平封装(LQFP)
[后缀PN]
– 64 引脚LQFP [后缀PM]
– 48 引脚LQFP [后缀PT]
• 温度选项:
• 通信外设
– 一个电源管理总线(PMBus) 接口
– 两个内部集成电路(I2C) 端口
– 一个控制器局域网(CAN) 总线端口
– 2 个串行外设接口(SPI) 端口
– 一个UART 兼容的串行通信接口(SCI)
– 两个UART 兼容的本地互连网络(LIN) 接口
– 带一个发送器和一个接收器的快速串行接口
(FSI)(最高200Mbps)
– S:–40°C 至125°C 结温
– Q:在自然通风环境下–40°C 至125°C 的温度
范围
(通过针对汽车应用的AEC Q100 认证)
本文档旨在为方便起见,提供有关TI 产品中文版本的信息,以确认产品的概要。有关适用的官方英文版本的最新信息,请访问
www.ti.com,其内容始终优先。TI 不保证翻译的准确性和有效性。在实际设计之前,请务必参考最新版本的英文版本。
English Data Sheet: SPRSP45
TMS320F280025, TMS320F280025-Q1
TMS320F280025C, TMS320F280025C-Q1, TMS320F280023, TMS320F280023-Q1
TMS320F280023C, TMS320F280021, TMS320F280021-Q1
ZHCSL01B –MARCH 2020 –REVISED DECEMBER 2020
www.ti.com.cn
• 车身电子装置与照明
2 应用
– 汽车HVAC 压缩机模块
– 直流/交流逆变器
– 前照灯
• 电器
– 空调室外机
• 楼宇自动化
• 交流逆变器和变频驱动器
– 交流驱动器控制模块
– 交流驱动器位置反馈
– 交流驱动器功率级模块
• 线性电机运输系统
– 线性电机功率级
– 电梯门自动启闭装置驱动控制
• 工业机械和机床
– 自动分拣设备
– 纺织机
• EV 充电基础设施
• 单轴及多轴伺服驱动器
– 伺服驱动器位置反馈
– 伺服驱动器功率级模块
• 速度控制BLDC 驱动器
– 交流充电(桩)站
– 直流充电(桩)站
– 电动汽车充电站电源模块
– 无线电动汽车充电站
• 可再生能源存储
– 能量存储电源转换系统(PCS)
• 太阳能
– 交流输入BLDC 电机驱动
– 直流输入BLDC 电机驱动器
• 工业电源
– 工业交流/直流转换器
• UPS
– 中央逆变器
– 微型逆变器
– 太阳能电源优化器
– 太阳能电弧保护
– 快速关断
– 电表
– 串式逆变器
– 三相UPS
– 单相在线式UPS
• 电信和服务器电源
– 商用直流/直流
– 商用网络和服务器PSU
– 商用电信整流器
• 混合动力、电动和动力总成系统
– 直流/直流转换器
– 逆变器和电机控制
– 车载充电器(OBC) 和无线充电器
3 说明
TMS320F28002x (F28002x) 是 C2000™ 实时微控制器系列中的一个器件,该系列可扩展、超低延迟器件旨在提
高电力电子设备的效率,包括但不限于:高功率密度、高开关频率,并支持使用GaN 和SiC 技术。
这些应用包括:
• 工业电机驱动
• 电机控制
• 光伏逆变器
• 数字电源
• 电动车辆与运输
• 感应和信号调理
实时控制子系统基于 TI 的 32 位 C28x DSP 内核,可针对从片上闪存或 SRAM 运行的浮点或定点代码提供
100MHz 的信号处理性能。三角函数数学单元 (TMU) 和 VCRC(循环冗余校验)扩展指令集进一步增强了 C28x
CPU 的性能,从而加快了实时控制系统关键常用算法的速度。
高性能模拟模块集成在 F28002x 实时微控制器 (MCU) 上,并与处理单元和 PWM 单元紧密耦合,以提供更好的
实时信号链性能。14 个 PWM 通道均支持与频率无关的分辨率模式,可控制从三相逆变器到高级多级电源拓扑的
各种功率级。
通过加入可配置逻辑模块 (CLB),用户可以添加自定义逻辑,还可将类似 FPGA 的功能集成到 C2000 实时 MCU
中。
各种业界通用通信端口(如 SPI、SCI、I2C、PMBus、LIN 和 CAN)不仅支持连接,还提供了多个引脚复用选
项,可实现出色的信号布局。快速串行接口(FSI) 可跨隔离边界实现高达200Mbps 的稳健通信。
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TMS320F280023 TMS320F280023-Q1 TMS320F280023C TMS320F280021 TMS320F280021-Q1
TMS320F280025, TMS320F280025-Q1
TMS320F280025C, TMS320F280025C-Q1, TMS320F280023, TMS320F280023-Q1
TMS320F280023C, TMS320F280021, TMS320F280021-Q1
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ZHCSL01B –MARCH 2020 –REVISED DECEMBER 2020
C2000 平台新增了主机接口控制器 (HIC),这是一种高吞吐量接口,允许外部主机直接访问 TMS320F28002x 的
资源。
是否想详细了解 C2000 MCU 适用于实时控制系统的特性?查看《使用 C2000™ 实时微控制器的基本开发指
南》,并访问C2000™ 实时控制MCU 页面。
准备好开始了吗?查看TMDSCNCD280025C 评估板并下载C2000Ware。
器件信息
可配置逻辑块(CLB)
器件型号(1)
TMS320F280025C
闪存大小
2 个逻辑块
128KB
TMS320F280025
TMS320F280023C
TMS320F280023
TMS320F280021
–
2 个逻辑块
64KB
32KB
–
–
(1) 如需更多有关这些器件的信息,请参阅器件比较表。
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TMS320F280023 TMS320F280023-Q1 TMS320F280023C TMS320F280021 TMS320F280021-Q1
TMS320F280025, TMS320F280025-Q1
TMS320F280025C, TMS320F280025C-Q1, TMS320F280023, TMS320F280023-Q1
TMS320F280023C, TMS320F280021, TMS320F280021-Q1
ZHCSL01B –MARCH 2020 –REVISED DECEMBER 2020
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3.1 功能方框图
功能方框图展示了CPU 系统及关联的外设。
Boot ROM
Secure Memories
shown in Red
Secure ROM
C28x CPU
FPU32
Bus Legend
Flash Bank0
16 Sectors
64 KW (128 KB)
FINTDIV
TMU
VCRC
CPU
DMA
HIC
BGCRC
CPU Timers
DCC
DCSM
ePIE
ERAD
M0-M1 RAM
2 KW (4 KB)
BGCRC
LS4-LS7 RAM
8 KW (16 KB)
Crystal Oscillator
INTOSC1, INTOSC2
PLL
HIC
GS0 RAM
2 KW (4 KB)
DMA
6 Channles
PF1
PF3
PF4
PF2
PF7
PF8
PF9
Result
2x 12-Bit ADC
Data
14x ePWM Chan.
(8 Hi-Res Capable)
4x CMPSS
1x PMBUS
2x SPI
1x CAN
2x LIN
1x SCI
2x I2C
39x GPIO
Input XBAR
Output XBAR
ePWM XBAR
CLB XBAR
3x eCAP
(1 HRCAP Capable)
2x CLB
1x FSI RX
1x FSI TX
NMI
Watchdog
2x eQEP
(CW/CCW Support)
Windowed
Watchdog
图3-1. 功能方框图
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TMS320F280023 TMS320F280023-Q1 TMS320F280023C TMS320F280021 TMS320F280021-Q1
TMS320F280025, TMS320F280025-Q1
TMS320F280025C, TMS320F280025C-Q1, TMS320F280023, TMS320F280023-Q1
TMS320F280023C, TMS320F280021, TMS320F280021-Q1
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ZHCSL01B –MARCH 2020 –REVISED DECEMBER 2020
Table of Contents
8 Detailed Description....................................................157
8.1 Overview.................................................................157
8.2 Functional Block Diagram.......................................158
8.3 Memory...................................................................159
8.4 Identification............................................................165
8.5 Bus Architecture –Peripheral Connectivity...........166
8.6 C28x Processor...................................................... 167
8.7 Embedded Real-Time Analysis and Diagnostic
(ERAD)......................................................................169
8.8 Background CRC-32 (BGCRC).............................. 169
8.9 Direct Memory Access (DMA).................................170
8.10 Device Boot Modes...............................................171
8.11 Dual Code Security Module.................................. 177
8.12 Watchdog..............................................................178
8.13 C28x Timers..........................................................179
8.14 Dual-Clock Comparator (DCC)............................. 179
8.15 Configurable Logic Block (CLB)............................181
9 Applications, Implementation, and Layout............... 183
9.1 TI 参考设计............................................................. 183
10 Device and Documentation Support........................184
10.1 Getting Started and Next Steps............................ 184
10.2 Device and Development Support Tool
Nomenclature............................................................184
10.3 Markings............................................................... 185
10.4 Tools and Software............................................... 187
10.5 Documentation Support........................................ 188
10.6 支持资源................................................................189
10.7 Trademarks...........................................................190
10.8 静电放电警告........................................................ 190
10.9 术语表................................................................... 190
11 Mechanical, Packaging, and Orderable
1 特性................................................................................... 1
2 应用................................................................................... 2
3 说明................................................................................... 2
3.1 功能方框图..................................................................4
4 Revision History.............................................................. 6
5 Device Comparison.........................................................9
5.1 Related Products...................................................... 10
6 Terminal Configuration and Functions........................11
6.1 Pin Diagrams.............................................................11
6.2 Pin Attributes.............................................................14
6.3 Signal Descriptions................................................... 29
6.4 Pin Multiplexing.........................................................42
6.5 Pins With Internal Pullup and Pulldown.................... 49
6.6 Connections for Unused Pins................................... 50
7 Specifications................................................................ 52
7.1 Absolute Maximum Ratings ..................................... 52
7.2 ESD Ratings –Commercial.....................................52
7.3 ESD Ratings –Automotive......................................53
7.4 Recommended Operating Conditions ......................53
Supply Voltages.............................................................. 54
7.5 Power Consumption Summary................................. 55
7.6 Electrical Characteristics ..........................................59
7.7 Thermal Resistance Characteristics for PN
Package...................................................................... 60
7.8 Thermal Resistance Characteristics for PM
Package...................................................................... 60
7.9 Thermal Resistance Characteristics for PT
Package...................................................................... 61
7.10 Thermal Design Considerations..............................61
7.11 System.................................................................... 62
7.12 Analog Peripherals..................................................90
7.13 Control Peripherals............................................... 110
7.14 Communications Peripherals................................125
Information.................................................................. 191
11.1 Packaging Information.......................................... 191
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TMS320F280023 TMS320F280023-Q1 TMS320F280023C TMS320F280021 TMS320F280021-Q1
TMS320F280025, TMS320F280025-Q1
TMS320F280025C, TMS320F280025C-Q1, TMS320F280023, TMS320F280023-Q1
TMS320F280023C, TMS320F280021, TMS320F280021-Q1
ZHCSL01B –MARCH 2020 –REVISED DECEMBER 2020
www.ti.com.cn
4 Revision History
Changes from October 4, 2020 to December 31, 2020 (from Revision A (October 2020) to
Revision B (December 2020))
Page
• 通篇:添加了TMS320F280025-Q1、TMS320F280025C-Q1、TMS320F280023-Q1 和TMS320F280021-Q1
............................................................................................................................................................................1
• 表5-1(器件比较):添加了TMS320F280025-Q1、TMS320F280025C-Q1、TMS320F280023-Q1 和
TMS320F280021-Q1 更新了表...........................................................................................................................1
• 表6-1 (Pin Attributes): Updated muxed signal names of A7. Updated DESCRIPTION of VDD: Changed
recommended total capacitance from 22 µF to 10 µF.......................................................................................11
• Removed Digital Signals by GPIO section (Section 6.3.2 in SPRSP45A)........................................................29
• 节6.3.2 (Digital Signals): Added section.......................................................................................................... 29
• 表6-4 (Power and Ground): Updated DESCRIPTION of VDD: Changed recommended total capacitance from
22 µF to 10 µF...................................................................................................................................................29
• 节7.2 (ESD Ratings –Commercial): Updated device numbers..................................................................... 52
• 节7.3 (ESD Ratings –Automotive): Updated device numbers. Added data for 64-pin PM package.............53
• 节7.5.1 (System Current Consumption): Updated table.................................................................................. 55
• 节7.11.1.1 (Internal 1.2-V LDO Voltage Regulator (VREG)): Updated Configuration 1...................................62
• 节7.11.3.5.1 (INTOSC Characteristics): Updated table................................................................................... 73
• 表7-5 (Flash Parameters): Changed "Nwec Write/Erase Cycles" to "Nwec Write/Erase Cycles per sector".
Added "Nwec Write/Erase Cycles for entire Flash (combined all sectors)"........................................................74
• 节7.14.8 (Host Interface Controller (HIC)): Updated "The HIC module allows ..." paragraph....................... 153
• 图7-70 (HIC Block Diagram): Removed "Bus Master Interface" label........................................................... 153
• 图10-1 (Device Nomenclature): Updated figure.............................................................................................184
• 节10.4 (Tools and Software): Added LAUNCHXL-F280025C to Development Tools section..................... 187
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TMS320F280025, TMS320F280025-Q1
TMS320F280025C, TMS320F280025C-Q1, TMS320F280023, TMS320F280023-Q1
TMS320F280023C, TMS320F280021, TMS320F280021-Q1
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ZHCSL01B –MARCH 2020 –REVISED DECEMBER 2020
Changes from March 17, 2020 to October 3, 2020 (from Revision * (March 2020) to Revision A
(October 2020))
Page
• 通篇:更新了整个文档中的表格、图和交叉参考的编号格式.............................................................................. 1
• 通篇:此文档当前状态是“量产数据”...............................................................................................................1
• 通篇:删除了TMS320F280024、TMS320F280024C 和TMS320F280022......................................................1
• 通篇:删除了64 QFP-Q 数据.............................................................................................................................1
• 节1(特性):更新了串行通信接口(SCI) 特性更新了本地互连网络(LIN) 特性................................................1
• 表5-1(器件比较):更新了表.......................................................................................................................... 1
• 节2 (应用):更新部分。................................................................................................................................ 2
• 节3(说明):更新部分。................................................................................................................................. 2
• 器件信息:更新表格。........................................................................................................................................2
• 图3-1(功能方框图):更新了图.......................................................................................................................4
• 表6-1 (Pin Attributes): Updated table...............................................................................................................11
• 图6-2 (64-Pin PM Low-Profile Quad Flatpack (Top View)): Updated figure..................................................... 11
• Removed "64-Pin PM Low-Profile Quad Flatpack –Q-Temperature (Top View)" figure................................. 11
• Removed Digital Signals section (Section 4.3.2 in SPRSP45).........................................................................29
• Digital Signals by GPIO: Added section........................................................................................................... 29
• 表6-4 (Power and Ground): Updated DESCRIPTION of VDD and VDDIO..................................................... 29
• 节6.4.1.1 (GPIO Muxed Pins Table): Added Note about AIO pins...................................................................43
• 表6-6 (GPIO Muxed Pins): Updated table....................................................................................................... 43
• 节6.4.4 (GPIO Output X-BAR, CLB X-BAR, CLB Output X-BAR, and ePWM X-BAR): Changed section title
from "GPIO Output X-BAR and ePWM X-BAR" to "GPIO Output X-BAR, CLB X-BAR, CLB Output X-BAR,
and ePWM X-BAR". Updated section...............................................................................................................47
• 图6-5 (Output X-BAR, CLB X-BAR, CLB Output X-BAR, and ePWM X-BAR Sources): Replaced "Output X-
BAR and ePWM X-BAR Sources" figure with "Output X-BAR, CLB X-BAR, CLB Output X-BAR, and ePWM
X-BAR Sources" figure..................................................................................................................................... 47
• 表6-9 (Connections for Unused Pins): Added "Analog input pins" in ANALOG section.................................. 50
• 节7 (Specifications): Updated section and tables............................................................................................52
• 节7.1 (Absolute Maximum Ratings): Updated table.........................................................................................52
• 节7.4 (Recommended Operating Conditions): Updated SRSUPPLY values and unit........................................ 52
• 节7.6 (Electrical Characteristics): Updated ROH and ROL values.....................................................................52
• 节7.3 (ESD Ratings –Automotive): Removed F280024, F280024C, and F280022 data..............................53
• 节7.5.3 (Current Consumption Graphs): Added section..................................................................................56
• 节7.5.4 (Reducing Current Consumption): Updated section........................................................................... 58
• 节7.5.4.1 (Typical Current Reduction per Disabled Peripheral): Updated table.............................................. 58
• 节7.7 (Thermal Resistance Characteristics for PN Package): Added section.................................................60
• 节7.8 (Thermal Resistance Characteristics for PM Package): Added section.................................................60
• 节7.9 (Thermal Resistance Characteristics for PT Package): Added section................................................. 61
• 节7.11.2.2.1 (Reset (XRSn) Timing Requirements): Updated tw(RSL2).............................................................64
• 节7.11.2.2.2 (Reset (XRSn) Switching Characteristics): Added tboot-flash........................................................ 64
• 图7-8 (Power-on Reset): Updated figure......................................................................................................... 64
• 节7.11.3.2.1.6 (Internal Clock Frequencies): Updated MAX f(VCOCLK).............................................................69
• 节7.11.3.5 (Internal Oscillators): Updated section........................................................................................... 73
• 节7.11.3.5.1 (INTOSC Characteristics): Updated fINTOSC MIN values and MAX values..................................73
• 节7.11.4 (Flash Parameters): Updated section................................................................................................74
• 表7-4 (Minimum Required Flash Wait States with Different Clock Sources and Frequencies): Updated table
and footnotes....................................................................................................................................................74
• 表7-5 (Flash Parameters): Added "The on-chip flash memory is in an erased state ..." footnote................... 74
• 节7.11.5 (Emulation/JTAG): Updated link of Hardware Breakpoints and Watchpoints for C28x in CCS.........76
• 图7-31 (Analog Group Connections): Added figure.........................................................................................90
• 图7-35 (ADC Timings): Updated tINT..............................................................................................................102
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TMS320F280023 TMS320F280023-Q1 TMS320F280023C TMS320F280021 TMS320F280021-Q1
TMS320F280025, TMS320F280025-Q1
TMS320F280025C, TMS320F280025C-Q1, TMS320F280023, TMS320F280023-Q1
TMS320F280023C, TMS320F280021, TMS320F280021-Q1
ZHCSL01B –MARCH 2020 –REVISED DECEMBER 2020
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• 节7.14.2.1.1 (I2C Timing Requirements): Updated table...............................................................................129
• 节7.14.2.1.2 (I2C Switching Characteristics): Updated table.........................................................................129
• 图7-54 (I2C Timing Diagram): Added figure.................................................................................................. 129
• 图7-56 (SCI Block Diagram): Updated figure.................................................................................................134
• 图7-59 (SPI Master Mode External Timing (Clock Phase = 1)): Updated parameter 24............................... 138
• 节7.14.5.2.1 (SPI Slave Mode Timing Requirements): Updated MIN value of tsu(STE)S................................ 142
• 节7.14.8 (Host Interface Controller (HIC)): Updated list of features.............................................................. 153
• 图7-70 (HIC Block Diagram): Updated figure................................................................................................ 153
• 节7.14.8.1.1 (HIC Timing Requirements): Updated table.............................................................................. 154
• 节7.14.8.1.2 (HIC Switching Characteristics): Updated table........................................................................154
• 图7-71 (Read/Write Operation With nOE and nWE Pins): Added figure....................................................... 155
• 图7-72 (Read/Write Operation With RnW Pin): Added figure........................................................................ 155
• 图8-1 (Functional Block Diagram): Added "Secure Memories shown in Red" legend box............................158
• 表8-2 (Addresses of Flash Sectors): Updated table...................................................................................... 160
• 表8-4 (Device Identification Registers): Removed PARTIDH for TMS320F280024, TMS320F280024C, and
TMS320F280022............................................................................................................................................165
• 表8-4: Added REVID for Revision A silicon................................................................................................... 165
• 表8-4: Updated ADDRESS of UID_UNIQUE.................................................................................................165
• 节8.10 (Device Boot Modes): Updated section..............................................................................................171
• 节8.10.1 (Device Boot Configurations): Added Note about CAN boot mode turning on the XTAL............... 171
• 图8-3 (Windowed Watchdog): Removed SCSR.WDOVERRIDE...................................................................178
• 节9.1(TI 参考设计):更新了此部分........................................................................................................... 183
• Removed Related Links section (Section 10.5 in SPRSP45).........................................................................184
• 节10.1 (Getting Started and Next Steps): Added section.............................................................................. 184
• 节10.2 (Device and Development Support Tool Nomenclature): Updated section........................................184
• 图10-1 (Device Nomenclature): Removed 280024, 280024C, and 280022 from DEVICE............................184
• 图10-2 (Package Symbolization for PM and PN Packages): Updated figure................................................ 185
• 图10-3 (Package Symbolization for PT Package): Updated figure................................................................185
• 表10-1 (Revision Identification): Added data for Revision A silicon...............................................................185
• 节10.4 (Tools and Software): Updated section.............................................................................................. 187
• 节10.5 (Documentation Support): Updated section.......................................................................................188
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TMS320F280023 TMS320F280023-Q1 TMS320F280023C TMS320F280021 TMS320F280021-Q1
TMS320F280025, TMS320F280025-Q1
TMS320F280025C, TMS320F280025C-Q1, TMS320F280023, TMS320F280023-Q1
TMS320F280023C, TMS320F280021, TMS320F280021-Q1
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ZHCSL01B –MARCH 2020 –REVISED DECEMBER 2020
5 Device Comparison
表5-1. Device Comparison
F280025
F280025-Q1
F280025C
F280023
F280023-Q1
F280023C
F280021
F280021-Q1
FEATURE(1)
F280025C-Q1
PROCESSOR AND ACCELERATORS
Frequency (MHz)
100
FPU32
Yes (with new instructions for Fast Integer Division)
VCRC
Yes
C28x
Yes (with new instructions supporting NLPID)
TMU –Type 1
Fast Integer Division
Yes
Yes
DMA –Type 0
MEMORY
Flash
128KB (64KW)
64KB (32KW)
20KB (10KW)
4KB (2KW)
24KB (12KW)
Yes
32KB (16KW)
Dedicated and Local Shared RAM
Global Shared RAM
RAM
TOTAL RAM
Code security for on-chip flash and RAM
SYSTEM
Configurable Logic Block (CLB)(2)
32-bit CPU timers
(F280025C-2 tiles) (F280023C-2 tiles)
-
3
1
Watchdog-timer
Nonmaskable Interrupt Watchdog (NMIWD) timers
Crystal oscillator/External clock input
0-pin internal oscillator
1
1
2
80-pin PN
39
26
16
64-pin PM
48-pin PT
GPIO pins
4 (When cJTAG is used, TDI and TDO can be GPIO;
When INTOSC is used as clock source, X1 and X2 can be
GPIO)
Additional GPIO
80-pin PN
64-pin PM
48-pin PT
16
16
14
5
AIO inputs
External interrupts
ANALOG PERIPHERALS
Number of ADCs
MSPS
Conversion-time (ns)(3)
2
3.45
290
16
16
14
1
ADC 12-bit
80-pin PN
ADC channels (single-ended)
Temperature sensor
64-pin PM
48-pin PT
CMPSS (each has two comparators and two internal DACs)
4
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TMS320F280023 TMS320F280023-Q1 TMS320F280023C TMS320F280021 TMS320F280021-Q1
TMS320F280025, TMS320F280025-Q1
TMS320F280025C, TMS320F280025C-Q1, TMS320F280023, TMS320F280023-Q1
TMS320F280023C, TMS320F280021, TMS320F280021-Q1
ZHCSL01B –MARCH 2020 –REVISED DECEMBER 2020
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表5-1. Device Comparison (continued)
F280025
F280025-Q1
F280025C
F280023
F280023-Q1
F280023C
F280021
F280021-Q1
FEATURE(1)
F280025C-Q1
CONTROL PERIPHERALS(4)
3 (1 with HRCAP capability)
eCAP/HRCAP modules –Type 1
14 (8 with HRPWM capability)
2
ePWM/HRPWM channels –Type 4
eQEP modules –Type 2
COMMUNICATION PERIPHERALS(4)
1
CAN –Type 0
2
I2C –Type 1
1
SCI –Type 0 (UART-Compatible)
SPI –Type 2
2
2
LIN –Type 1 (UART-Compatible)
PMBus –Type 0
1
1 (1 RX and 1 TX)
FSI –Type 1
PACKAGE, TEMPERATURE, AND QUALIFICATION OPTIONS
80-pin PN
–
–
F280025
F280025C
F280023
F280023C
64-pin PM
S: –40°C to 125°C (TJ)
Q: –40°C to 125°C (TA)(5)
48-pin PT
80-pin PN
F280021
–
–
F280025-Q1
F280025C-Q1
64-pin PM
F280023-Q1
48-pin PT
F280021-Q1
(1) A type change represents a major functional feature difference in a peripheral module. Within a peripheral type, there may be minor
differences between devices that do not affect the basic functionality of the module.
(2) C devices include additional Motor Control libraries in ROM. Contact TI for more information.
(3) Time between start of sample-and-hold window to start of sample-and-hold window of the next conversion.
(4) For devices that are available in more than one package, the peripheral count listed in the smaller package is reduced because the
smaller package has less device pins available. The number of peripherals internally present on the device is not reduced co
(5) The letter Q refers to AEC Q100 qualification for automotive applications.
5.1 Related Products
TMS320F2803x Real-Time Microcontrollers
The F2803x series increases the pin-count and memory size options. The F2803x series also introduces the
parallel control law accelerator (CLA) option.
TMS320F2807x Real-Time Microcontrollers
The F2807x series offers the most performance, largest pin counts, flash memory sizes, and peripheral options.
The F2807x series includes the latest generation of accelerators, ePWM peripherals, and analog technology.
TMS320F28004x Real-Time Microcontrollers
The F28004x series is a reduced version of the F2807x series with the latest generational enhancements.
TMS320F2838x Real-Time Microcontrollers
The F2838x series offers more performance, larger pin counts, flash memory sizes, peripheral and wide variety
of connectivity options. The F2838x series includes the latest generation of accelerators, ePWM peripherals, and
analog technology. Configurable logic block (CLB) versions are available.
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TMS320F280023 TMS320F280023-Q1 TMS320F280023C TMS320F280021 TMS320F280021-Q1
TMS320F280025, TMS320F280025-Q1
TMS320F280025C, TMS320F280025C-Q1, TMS320F280023, TMS320F280023-Q1
TMS320F280023C, TMS320F280021, TMS320F280021-Q1
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ZHCSL01B –MARCH 2020 –REVISED DECEMBER 2020
6 Terminal Configuration and Functions
6.1 Pin Diagrams
图 6-1 shows the pin assignments on the 80-pin PN low-profile quad flatpack (Q temperature). 图 6-2 shows the
pin assignments on the 64-pin PM low-profile quad flatpack. 图 6-3 shows the pin assignments on the 48-Pin PT
low-profile quad flatpack.
GPIO2
GPIO1
GPIO0
GPIO40
GPIO23
GPIO41
GPIO22
GPIO7
GPIO44
VSS
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75
76
77
78
79
80
40
39
38
37
36
35
34
33
32
31
30
29
28
27
26
25
24
23
22
21
GPIO17
GPIO16
GPIO33
GPIO11
GPIO12
GPIO13
FLT1
FLT2
VDDIO
VDD
VDD
VSS
VDDIO
GPIO45
GPIO5
GPIO9
GPIO10
GPIO34
GPIO15
GPIO14
GPIO6
A10,C10
A9,C8
A4,C14
VDDA
VSSA
A8,C11
A7,C3
A12,C1
VREFLO
Not to scale
A. Only the GPIO function is shown on GPIO terminals. See 表6-1 for the complete, muxed signal name.
图6-1. 80-Pin PN Low-Profile Quad Flatpack (Top View)
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TMS320F280023 TMS320F280023-Q1 TMS320F280023C TMS320F280021 TMS320F280021-Q1
TMS320F280025, TMS320F280025-Q1
TMS320F280025C, TMS320F280025C-Q1, TMS320F280023, TMS320F280023-Q1
TMS320F280023C, TMS320F280021, TMS320F280021-Q1
ZHCSL01B –MARCH 2020 –REVISED DECEMBER 2020
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GPIO3
GPIO2
GPIO1
GPIO0
GPIO40
GPIO23
GPIO41
GPIO22
GPIO7
VSS
49
50
51
52
53
54
55
56
57
58
59
60
61
62
63
64
32
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
GPIO33
GPIO11
GPIO12
GPIO13
VDDIO
VDD
VSS
A10,C10
A9,C8
A4,C14
VDDA
VDD
VDDIO
GPIO5
GPIO9
GPIO10
GPIO6
VSSA
A8,C11
A7,C3
A12,C1
VREFLO
Not to scale
A. Only the GPIO function is shown on GPIO terminals. See 表6-1 for the complete, muxed signal name.
图6-2. 64-Pin PM Low-Profile Quad Flatpack (Top View)
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TMS320F280023 TMS320F280023-Q1 TMS320F280023C TMS320F280021 TMS320F280021-Q1
TMS320F280025, TMS320F280025-Q1
TMS320F280025C, TMS320F280025C-Q1, TMS320F280023, TMS320F280023-Q1
TMS320F280023C, TMS320F280021, TMS320F280021-Q1
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ZHCSL01B –MARCH 2020 –REVISED DECEMBER 2020
VSS
GPIO4
GPIO3
GPIO2
GPIO1
GPIO0
GPIO7
VSS
37
38
39
40
41
42
43
44
45
46
47
48
24
23
22
21
20
19
18
17
16
15
14
13
GPIO12
GPIO13
VSS
A10,C10
A9,C8
A4,C14
VDDA
VSSA
VDD
A8,C11
A7,C3
VDDIO
GPIO5
GPIO6
A12,C1
VREFLO
Not to scale
A. Only the GPIO function is shown on GPIO terminals. See 表6-1 for the complete, muxed signal name.
图6-3. 48-Pin PT Low-Profile Quad Flatpack (Top View)
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Product Folder Links: TMS320F280025 TMS320F280025-Q1 TMS320F280025C TMS320F280025C-Q1
TMS320F280023 TMS320F280023-Q1 TMS320F280023C TMS320F280021 TMS320F280021-Q1
TMS320F280025, TMS320F280025-Q1
TMS320F280025C, TMS320F280025C-Q1, TMS320F280023, TMS320F280023-Q1
TMS320F280023C, TMS320F280021, TMS320F280021-Q1
ZHCSL01B –MARCH 2020 –REVISED DECEMBER 2020
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6.2 Pin Attributes
表6-1. Pin Attributes
MUX
POSITION
PIN
TYPE
SIGNAL NAME
80 QFP 64 QFP 48 QFP
ANALOG
DESCRIPTION
A0
I
I
I
I
I
I
I
I
I
I
I
I
I
I
I
I
I
I
I
I
I
I
I
I
I
I
I
I
I
I
I
I
I
I
I
I
I
I
I
I
I
I
I
ADC-A Input 0
ADC-C Input 15
C15
CMP3_HP2
CMP3_LP2
AIO231
CMPSS-3 High Comparator Positive Input 2
CMPSS-3 Low Comparator Positive Input 2
Analog Pin Used For Digital Input 231
HIC Base Address Range Select 1
Analog Input
19
18
15
14
11
10
0, 4, 8, 12
15
HIC_BASESEL1
A1
CMP1_HP4
CMP1_LP4
AIO232
CMPSS-1 High Comparator Positive Input 4
CMPSS-1 Low Comparator Positive Input 4
Analog Pin Used For Digital Input 232
HIC Base Address Range Select 0
ADC-A Input 10
0, 4, 8, 12
15
HIC_BASESEL0
A10
C10
ADC-C Input 10
CMP2_HP3
CMP2_HN0
CMP2_LP3
CMP2_LN0
AIO230
CMPSS-2 High Comparator Positive Input 3
CMPSS-2 High Comparator Negative Input 0
CMPSS-2 Low Comparator Positive Input 3
CMPSS-2 Low Comparator Negative Input 0
Analog Pin Used For Digital Input 230
HIC Base Address Range Select 2
ADC-A Input 11
29
25
21
0, 4, 8, 12
15
HIC_BASESEL2
A11
C0
ADC-C Input 0
CMP1_HP1
CMP1_HN1
CMP1_LP1
CMP1_LN1
AIO237
CMPSS-1 High Comparator Positive Input 1
CMPSS-1 High Comparator Negative Input 1
CMPSS-1 Low Comparator Positive Input 1
CMPSS-1 Low Comparator Negative Input 1
Analog Pin Used For Digital Input 237
HIC Address 6
16
12
8
0, 4, 8, 12
15
HIC_A6
A12
ADC-A Input 12
C1
ADC-C Input 1
CMP2_HP1
CMP4_HP2
CMP2_HN1
CMP2_LP1
CMP4_LP2
CMP2_LN1
AIO238
CMPSS-2 High Comparator Positive Input 1
CMPSS-4 High Comparator Positive Input 2
CMPSS-2 High Comparator Negative Input 1
CMPSS-2 Low Comparator Positive Input 1
CMPSS-4 Low Comparator Positive Input 2
CMPSS-2 Low Comparator Negative Input 1
Analog Pin Used For Digital Input 238
HIC Chip Select
22
18
14
0, 4, 8, 12
15
HIC_NCS
A14
ADC-A Input 14
C4
ADC-C Input 4
CMP3_HP4
CMP3_LP4
AIO239
CMPSS-3 High Comparator Positive Input 4
CMPSS-3 Low Comparator Positive Input 4
Analog Pin Used For Digital Input 239
HIC Address 5
15
11
0, 4, 8, 12
15
HIC_A5
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TMS320F280023 TMS320F280023-Q1 TMS320F280023C TMS320F280021 TMS320F280021-Q1
TMS320F280025, TMS320F280025-Q1
TMS320F280025C, TMS320F280025C-Q1, TMS320F280023, TMS320F280023-Q1
TMS320F280023C, TMS320F280021, TMS320F280021-Q1
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ZHCSL01B –MARCH 2020 –REVISED DECEMBER 2020
表6-1. Pin Attributes (continued)
MUX
POSITION
PIN
TYPE
SIGNAL NAME
80 QFP 64 QFP 48 QFP
DESCRIPTION
A15
I
I
I
I
I
I
I
I
I
I
I
I
I
I
I
I
ADC-A Input 15
ADC-C Input 7
C7
CMP1_HP3
CMP1_HN0
CMP1_LP3
CMP1_LN0
AIO233
HIC_A4
A2
CMPSS-1 High Comparator Positive Input 3
CMPSS-1 High Comparator Negative Input 0
CMPSS-1 Low Comparator Positive Input 3
CMPSS-1 Low Comparator Negative Input 0
Analog Pin Used For Digital Input 233
HIC Address 4
14
10
7
0, 4, 8, 12
15
ADC-A Input 2
C9
ADC-C Input 9
CMP1_HP0
CMP1_LP0
AIO224
HIC_A3
A3
CMPSS-1 High Comparator Positive Input 0
CMPSS-1 Low Comparator Positive Input 0
Analog Pin Used For Digital Input 224
HIC Address 3
13
9
6
0, 4, 8, 12
15
ADC-A Input 3
C5
ADC-C Input 5
Optional external reference voltage for on-chip
CMPSS DACs. There is an internal capacitor to
VSSA on this pin whether used for ADC input or
CMPSS DAC reference which cannot be disabled. If
this pin is being used as a reference for the CMPSS
DACs, place at least a 1-µF capacitor on this pin.
VDAC
I
12
8
5
CMP3_HP3
CMP3_HN0
CMP3_LP3
CMP3_LN0
AIO242
I
I
I
I
I
I
I
I
I
I
I
I
I
I
I
I
I
I
I
I
I
I
I
I
CMPSS-3 High Comparator Positive Input 3
CMPSS-3 High Comparator Negative Input 0
CMPSS-3 Low Comparator Positive Input 3
CMPSS-3 Low Comparator Negative Input 0
Analog Pin Used For Digital Input 242
HIC Address 2
0, 4, 8, 12
15
HIC_A2
A4
ADC-A Input 4
C14
ADC-C Input 14
CMP2_HP0
CMP4_HP3
CMP4_HN0
CMP2_LP0
CMP4_LP3
CMP4_LN0
AIO225
CMPSS-2 High Comparator Positive Input 0
CMPSS-4 High Comparator Positive Input 3
CMPSS-4 High Comparator Negative Input 0
CMPSS-2 Low Comparator Positive Input 0
CMPSS-4 Low Comparator Positive Input 3
CMPSS-4 Low Comparator Negative Input 0
Analog Pin Used For Digital Input 225
HIC Data Write Enable
27
23
19
0, 4, 8, 12
15
HIC_NWE
A5
ADC-A Input 5
C2
ADC-C Input 2
CMP3_HP1
CMP3_HN1
CMP3_LP1
CMP3_LN1
AIO244
CMPSS-3 High Comparator Positive Input 1
CMPSS-3 High Comparator Negative Input 1
CMPSS-3 Low Comparator Positive Input 1
CMPSS-3 Low Comparator Negative Input 1
Analog Pin Used For Digital Input 244
HIC Address 7
17
13
9
0, 4, 8, 12
15
HIC_A7
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TMS320F280023 TMS320F280023-Q1 TMS320F280023C TMS320F280021 TMS320F280021-Q1
TMS320F280025, TMS320F280025-Q1
TMS320F280025C, TMS320F280025C-Q1, TMS320F280023, TMS320F280023-Q1
TMS320F280023C, TMS320F280021, TMS320F280021-Q1
ZHCSL01B –MARCH 2020 –REVISED DECEMBER 2020
www.ti.com.cn
表6-1. Pin Attributes (continued)
MUX
POSITION
PIN
TYPE
SIGNAL NAME
80 QFP 64 QFP 48 QFP
DESCRIPTION
A6
I
I
I
I
I
I
I
I
I
I
I
I
O
I
I
I
I
I
I
I
I
I
I
I
I
I
I
I
I
I
I
I
I
I
Analog Input
CMP1_HP2
CMP1_LP2
AIO228
CMPSS-1 High Comparator Positive Input 2
CMPSS-1 Low Comparator Positive Input 2
Analog Pin Used For Digital Input 228
HIC Address 0
10
6
4
0, 4, 8, 12
15
HIC_A0
A7
ADC-A Input 7
C3
ADC-C Input 3
CMP4_HP1
CMP4_HN1
CMP4_LP1
CMP4_LN1
AIO245
CMPSS-4 High Comparator Positive Input 1
CMPSS-4 High Comparator Negative Input 1
CMPSS-4 Low Comparator Positive Input 1
CMPSS-4 Low Comparator Negative Input 1
Analog Pin Used For Digital Input 245
HIC Output Enable
23
19
15
0, 4, 8, 12
15
HIC_NOE
A8
ADC-A Input 8
C11
ADC-C Input 11
CMP2_HP4
CMP4_HP4
CMP2_LP4
CMP4_LP4
AIO241
CMPSS-2 High Comparator Positive Input 4
CMPSS-4 High Comparator Positive Input 4
CMPSS-2 Low Comparator Positive Input 4
CMPSS-4 Low Comparator Positive Input 4
Analog Pin Used For Digital Input 241
HIC Byte Enable 1
24
20
16
0, 4, 8, 12
15
HIC_NBE1
A9
ADC-A Input 9
C8
ADC-C Input 8
CMP2_HP2
CMP4_HP0
CMP2_LP2
CMP4_LP0
AIO227
CMPSS-2 High Comparator Positive Input 2
CMPSS-4 High Comparator Positive Input 0
CMPSS-2 Low Comparator Positive Input 2
CMPSS-4 Low Comparator Positive Input 0
Analog Pin Used For Digital Input 227
HIC Byte Enable 0
28
24
20
0, 4, 8, 12
15
HIC_NBE0
C6
Analog Input
CMP3_HP0
CMP3_LP0
AIO226
CMPSS-3 High Comparator Positive Input 0
CMPSS-3 Low Comparator Positive Input 0
Analog Pin Used For Digital Input 226
HIC Address 1
11
7
4
0, 4, 8, 12
15
HIC_A1
ADC- High Reference. In external reference mode,
externally drive the high reference voltage onto this
pin. In internal reference mode, a voltage is driven
onto this pin by the device. In either mode, place at
least a 2.2-µF capacitor on this pin. This capacitor
should be placed as close to the device as possible
between the VREFHI and VREFLO pins.
VREFHI
VREFLO
20
21
16
17
12
13
I
I
ADC- Low Reference
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TMS320F280023 TMS320F280023-Q1 TMS320F280023C TMS320F280021 TMS320F280021-Q1
TMS320F280025, TMS320F280025-Q1
TMS320F280025C, TMS320F280025C-Q1, TMS320F280023, TMS320F280023-Q1
TMS320F280023C, TMS320F280021, TMS320F280021-Q1
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ZHCSL01B –MARCH 2020 –REVISED DECEMBER 2020
表6-1. Pin Attributes (continued)
MUX
POSITION
PIN
TYPE
SIGNAL NAME
80 QFP 64 QFP 48 QFP
GPIO
DESCRIPTION
GPIO0
0, 4, 8, 12
I/O
O
General-Purpose Input Output 0
ePWM-1 Output A
EPWM1_A
1
I2CA_SDA
6
I/OD I2C-A Open-Drain Bidirectional Data
SPIA_STE
7
63
52
42
I/O
I
SPI-A Slave Transmit Enable (STE)
FSIRX-A Input Clock
FSIRXA_CLK
CLB_OUTPUTXBAR8
HIC_BASESEL1
GPIO1
9
11
O
I
CLB Output X-BAR Output 8
HIC Base Address Range Select 1
General-Purpose Input Output 1
ePWM-1 Output B
15
0, 4, 8, 12
I/O
O
EPWM1_B
1
6
I2CA_SCL
I/OD I2C-A Open-Drain Bidirectional Clock
SPIA_SOMI
CLB_OUTPUTXBAR7
HIC_A2
7
I/O
O
I
SPI-A Slave Out, Master In (SOMI)
CLB Output X-BAR Output 7
HIC Address 2
62
51
41
11
13
FSITX-A Time Division Multiplexed Additional Data
Input
FSITXA_TDM_D1
14
I
HIC_D10
15
I/O
I/O
O
HIC Data 10
GPIO2
0, 4, 8, 12
General-Purpose Input Output 2
ePWM-2 Output A
EPWM2_A
OUTPUTXBAR1
PMBUSA_SDA
SPIA_SIMO
SCIA_TX
1
5
O
Output X-BAR Output 1
6
I/OD PMBus-A Open-Drain Bidirectional Data
7
I/O
O
I
SPI-A Slave In, Master Out (SIMO)
SCI-A Transmit Data
9
61
50
40
FSIRXA_D1
I2CB_SDA
HIC_A1
10
FSIRX-A Data Input 1
11
I/OD I2C-B Open-Drain Bidirectional Data
13
I
HIC Address 1
CANA_TX
HIC_D9
14
O
CAN-A Transmit
15
I/O
I/O
O
HIC Data 9
GPIO3
0, 4, 8, 12
General-Purpose Input Output 3
ePWM-2 Output B
Output X-BAR Output 2
EPWM2_B
OUTPUTXBAR2
PMBUSA_SCL
SPIA_CLK
SCIA_RX
1
2, 5
6
O
I/OD PMBus-A Open-Drain Bidirectional Clock
7
I/O
SPI-A Clock
9
60
49
39
I
I
SCI-A Receive Data
FSIRX-A Data Input 0
FSIRXA_D0
I2CB_SCL
HIC_NOE
CANA_RX
HIC_D4
10
11
13
14
15
I/OD I2C-B Open-Drain Bidirectional Clock
O
I
HIC Output Enable
CAN-A Receive
HIC Data 4
I/O
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TMS320F280025, TMS320F280025-Q1
TMS320F280025C, TMS320F280025C-Q1, TMS320F280023, TMS320F280023-Q1
TMS320F280023C, TMS320F280021, TMS320F280021-Q1
ZHCSL01B –MARCH 2020 –REVISED DECEMBER 2020
www.ti.com.cn
表6-1. Pin Attributes (continued)
MUX
POSITION
PIN
TYPE
SIGNAL NAME
GPIO4
80 QFP 64 QFP 48 QFP
DESCRIPTION
0, 4, 8, 12
I/O
O
O
O
I/O
I/O
I
General-Purpose Input Output 4
ePWM-3 Output A
EPWM3_A
1
OUTPUTXBAR3
CANA_TX
5
Output X-BAR Output 3
CAN-A Transmit
6
SPIB_CLK
7
SPI-B Clock
59
48
38
EQEP2_STROBE
FSIRXA_CLK
CLB_OUTPUTXBAR6
HIC_BASESEL2
HIC_NWE
9
eQEP-2 Strobe
10
FSIRX-A Input Clock
CLB Output X-BAR Output 6
HIC Base Address Range Select 2
HIC Data Write Enable
General-Purpose Input Output 5
ePWM-3 Output B
11
O
I
13
15
I
GPIO5
0, 4, 8, 12
I/O
O
O
I
EPWM3_B
1
OUTPUTXBAR3
CANA_RX
3
Output X-BAR Output 3
CAN-A Receive
6
SPIA_STE
7
I/O
O
O
I
SPI-A Slave Transmit Enable (STE)
FSITX-A Data Output 1
CLB Output X-BAR Output 5
HIC Address 7
74
61
47
FSITXA_D1
CLB_OUTPUTXBAR5
HIC_A7
9
10
13
HIC_D4
14
I/O
I/O
I/O
O
O
O
I
HIC Data 4
HIC_D15
15
HIC Data 15
GPIO6
0, 4, 8, 12
General-Purpose Input Output 6
ePWM-4 Output A
EPWM4_A
1
OUTPUTXBAR4
SYNCOUT
2
Output X-BAR Output 4
External ePWM Synchronization Pulse
eQEP-1 Input A
3
EQEP1_A
5
SPIB_SOMI
FSITXA_D0
FSITXA_D1
HIC_NBE1
7
80
64
48
I/O
O
O
I
SPI-B Slave Out, Master In (SOMI)
FSITX-A Data Output 0
FSITX-A Data Output 1
HIC Byte Enable 1
9
11
13
CLB_OUTPUTXBAR8
HIC_D14
14
O
I/O
I/O
O
O
I
CLB Output X-BAR Output 8
HIC Data 14
15
GPIO7
0, 4, 8, 12
General-Purpose Input Output 7
ePWM-4 Output B
EPWM4_B
1
3
OUTPUTXBAR5
EQEP1_B
Output X-BAR Output 5
eQEP-1 Input B
5
SPIB_SIMO
FSITXA_CLK
CLB_OUTPUTXBAR2
HIC_A6
7
68
57
43
I/O
O
O
I
SPI-B Slave In, Master Out (SIMO)
FSITX-A Output Clock
CLB Output X-BAR Output 2
HIC Address 6
9
10
13
15
HIC_D14
I/O
HIC Data 14
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TMS320F280025, TMS320F280025-Q1
TMS320F280025C, TMS320F280025C-Q1, TMS320F280023, TMS320F280023-Q1
TMS320F280023C, TMS320F280021, TMS320F280021-Q1
www.ti.com.cn
ZHCSL01B –MARCH 2020 –REVISED DECEMBER 2020
表6-1. Pin Attributes (continued)
MUX
POSITION
PIN
SIGNAL NAME
80 QFP 64 QFP 48 QFP
DESCRIPTION
TYPE
I/O
O
GPIO8
0, 4, 8, 12
General-Purpose Input Output 8
ePWM-5 Output A
EPWM5_A
ADCSOCAO
EQEP1_STROBE
SCIA_TX
1
3
O
ADC Start of Conversion A for External ADC
eQEP-1 Strobe
5
I/O
O
6
SCI-A Transmit Data
SPIA_SIMO
I2CA_SCL
7
I/O
SPI-A Slave In, Master Out (SIMO)
58
47
9
I/OD I2C-A Open-Drain Bidirectional Clock
FSITXA_D1
CLB_OUTPUTXBAR5
HIC_A0
10
O
O
I
FSITX-A Data Output 1
CLB Output X-BAR Output 5
HIC Address 0
11
13
FSITXA_TDM_CLK
HIC_D8
14
I
FSITX-A Time Division Multiplexed Clock Input
HIC Data 8
15
I/O
I/O
O
O
I/O
I
GPIO9
0, 4, 8, 12
General-Purpose Input Output 9
ePWM-5 Output B
EPWM5_B
OUTPUTXBAR6
EQEP1_INDEX
SCIA_RX
1
3
Output X-BAR Output 6
eQEP-1 Index
5
6
SCI-A Receive Data
SPIA_CLK
FSITXA_D0
LINB_RX
7
75
76
37
62
63
31
I/O
O
I
SPI-A Clock
10
FSITX-A Data Output 0
LIN-B Receive
11
HIC_BASESEL0
I2CB_SCL
13
I
HIC Base Address Range Select 0
14
I/OD I2C-B Open-Drain Bidirectional Clock
HIC_NRDY
GPIO10
15
O
I/O
O
HIC Ready
0, 4, 8, 12
General-Purpose Input Output 10
ePWM-6 Output A
EPWM6_A
ADCSOCBO
EQEP1_A
1
3
O
ADC Start of Conversion B for External ADC
eQEP-1 Input A
5
I
SPIA_SOMI
I2CA_SDA
FSITXA_CLK
LINB_TX
7
I/O
SPI-A Slave Out, Master In (SOMI)
9
I/OD I2C-A Open-Drain Bidirectional Data
10
O
O
I
FSITX-A Output Clock
LIN-B Transmit
11
HIC_NWE
13
HIC Data Write Enable
FSITX-A Time Division Multiplexed Data Input
General-Purpose Input Output 11
ePWM-6 Output B
FSITXA_TDM_D0
GPIO11
14
I
0, 4, 8, 12
I/O
O
O
I
EPWM6_B
OUTPUTXBAR7
EQEP1_B
1
3
Output X-BAR Output 7
eQEP-1 Input B
5
SPIA_STE
FSIRXA_D1
LINB_RX
7
I/O
I
SPI-A Slave Transmit Enable (STE)
FSIRX-A Data Input 1
LIN-B Receive
9
10
11
13
14
15
I
EQEP2_A
I
eQEP-2 Input A
SPIA_SIMO
HIC_D6
I/O
I/O
I
SPI-A Slave In, Master Out (SIMO)
HIC Data 6
HIC_NBE0
HIC Byte Enable 0
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TMS320F280025, TMS320F280025-Q1
TMS320F280025C, TMS320F280025C-Q1, TMS320F280023, TMS320F280023-Q1
TMS320F280023C, TMS320F280021, TMS320F280021-Q1
ZHCSL01B –MARCH 2020 –REVISED DECEMBER 2020
www.ti.com.cn
表6-1. Pin Attributes (continued)
MUX
POSITION
PIN
TYPE
SIGNAL NAME
GPIO12
80 QFP 64 QFP 48 QFP
DESCRIPTION
0, 4, 8, 12
I/O
O
General-Purpose Input Output 12
ePWM-7 Output A
EPWM7_A
EQEP1_STROBE
PMBUSA_CTL
FSIRXA_D0
LINB_TX
1
5
I/O
I/O
I
eQEP-1 Strobe
7
PMBus-A Control Signal - Slave Input/Master Output
FSIRX-A Data Input 0
LIN-B Transmit
9
36
35
79
78
30
24
10
O
SPIA_CLK
11
I/O
I
SPI-A Clock
CANA_RX
13
CAN-A Receive
HIC_D13
14
I/O
O
HIC Data 13
HIC_INT
15
HIC Device Interrupt
General-Purpose Input Output 13
ePWM-7 Output B
GPIO13
0, 4, 8, 12
I/O
O
EPWM7_B
EQEP1_INDEX
PMBUSA_ALERT
FSIRXA_CLK
LINB_RX
1
5
I/O
eQEP-1 Index
7
I/OD PMBus-A Open-Drain Bidirectional Alert
9
I
FSIRX-A Input Clock
LIN-B Receive
29
23
10
I
SPIA_SOMI
CANA_TX
11
I/O
O
SPI-A Slave Out, Master In (SOMI)
CAN-A Transmit
13
HIC_D11
14
I/O
I/O
I/O
HIC Data 11
HIC_D5
15
HIC Data 5
GPIO14
0, 4, 8, 12
General-Purpose Input Output 14
I2CB_SDA
5
I/OD I2C-B Open-Drain Bidirectional Data
Output X-BAR Output 3
I/OD PMBus-A Open-Drain Bidirectional Data
OUTPUTXBAR3
PMBUSA_SDA
SPIB_CLK
6
O
7
9
I/O
I
SPI-B Clock
EQEP2_A
10
eQEP-2 Input A
LINB_TX
11
O
LIN-B Transmit
EPWM3_A
CLB_OUTPUTXBAR7
HIC_D15
13
O
ePWM-3 Output A
CLB Output X-BAR Output 7
HIC Data 15
14
O
15
I/O
I/O
GPIO15
0, 4, 8, 12
General-Purpose Input Output 15
I2CB_SCL
5
6
I/OD I2C-B Open-Drain Bidirectional Clock
Output X-BAR Output 4
I/OD PMBus-A Open-Drain Bidirectional Clock
OUTPUTXBAR4
PMBUSA_SCL
SPIB_STE
O
7
9
I/O
I
SPI-B Slave Transmit Enable (STE)
eQEP-2 Input B
EQEP2_B
10
11
13
14
15
LINB_RX
I
LIN-B Receive
EPWM3_B
CLB_OUTPUTXBAR6
HIC_D12
O
O
I/O
ePWM-3 Output B
CLB Output X-BAR Output 6
HIC Data 12
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TMS320F280023 TMS320F280023-Q1 TMS320F280023C TMS320F280021 TMS320F280021-Q1
TMS320F280025, TMS320F280025-Q1
TMS320F280025C, TMS320F280025C-Q1, TMS320F280023, TMS320F280023-Q1
TMS320F280023C, TMS320F280021, TMS320F280021-Q1
www.ti.com.cn
ZHCSL01B –MARCH 2020 –REVISED DECEMBER 2020
表6-1. Pin Attributes (continued)
MUX
POSITION
PIN
SIGNAL NAME
80 QFP 64 QFP 48 QFP
DESCRIPTION
TYPE
I/O
I/O
O
GPIO16
0, 4, 8, 12
General-Purpose Input Output 16
SPI-A Slave In, Master Out (SIMO)
Output X-BAR Output 7
ePWM-5 Output A
SPIA_SIMO
OUTPUTXBAR7
EPWM5_A
1
3
5
O
SCIA_TX
6
O
SCI-A Transmit Data
EQEP1_STROBE
PMBUSA_SCL
9
I/O
eQEP-1 Strobe
39
33
26
10
I/OD PMBus-A Open-Drain Bidirectional Clock
External Clock Output. This pin outputs a divided-
XCLKOUT
11
O
down version of a chosen clock signal from within the
device.
EQEP2_B
13
I
eQEP-2 Input B
SPIB_SOMI
HIC_D1
14
I/O
I/O
I/O
I/O
O
SPI-B Slave Out, Master In (SOMI)
HIC Data 1
15
GPIO17
0, 4, 8, 12
General-Purpose Input Output 17
SPI-A Slave Out, Master In (SOMI)
Output X-BAR Output 8
ePWM-5 Output B
SPIA_SOMI
OUTPUTXBAR8
EPWM5_B
SCIA_RX
1
3
5
O
6
40
34
I
SCI-A Receive Data
EQEP1_INDEX
PMBUSA_SDA
CANA_TX
9
I/O
eQEP-1 Index
10
I/OD PMBus-A Open-Drain Bidirectional Data
11
O
I/O
I/O
I/O
I
CAN-A Transmit
HIC_D2
15
HIC Data 2
GPIO18_X2
SPIA_CLK
CANA_RX
EPWM6_A
I2CA_SCL
EQEP2_A
0, 4, 8, 12
General-Purpose Input Output 18_X2
SPI-A Clock
1
3
CAN-A Receive
5
O
ePWM-6 Output A
6
I/OD I2C-A Open-Drain Bidirectional Clock
9
I
eQEP-2 Input A
PMBUSA_CTL
10
I/O
PMBus-A Control Signal - Slave Input/Master Output
External Clock Output. This pin outputs a divided-
down version of a chosen clock signal from within the
device.
50
41
33
XCLKOUT
11
O
LINB_TX
13
14
15
O
I
LIN-B Transmit
FSITXA_TDM_CLK
HIC_INT
FSITX-A Time Division Multiplexed Clock Input
HIC Device Interrupt
O
Crystal oscillator output. For more information about
the ALT functionality, see the table that is in the
External Oscillator (XTAL) section of the System
Control chapter in the TMS320F28002x Real-Time
Microcontrollers Technical Reference Manual.
X2
ALT
O
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TMS320F280023 TMS320F280023-Q1 TMS320F280023C TMS320F280021 TMS320F280021-Q1
TMS320F280025, TMS320F280025-Q1
TMS320F280025C, TMS320F280025C-Q1, TMS320F280023, TMS320F280023-Q1
TMS320F280023C, TMS320F280021, TMS320F280021-Q1
ZHCSL01B –MARCH 2020 –REVISED DECEMBER 2020
www.ti.com.cn
表6-1. Pin Attributes (continued)
MUX
POSITION
PIN
TYPE
SIGNAL NAME
GPIO19_X1
80 QFP 64 QFP 48 QFP
DESCRIPTION
0, 4, 8, 12
I/O
I/O
O
General-Purpose Input Output 19_X1
SPI-A Slave Transmit Enable (STE)
CAN-A Transmit
SPIA_STE
1
3
CANA_TX
EPWM6_B
5
O
ePWM-6 Output B
I2CA_SDA
6
I/OD I2C-A Open-Drain Bidirectional Data
eQEP-2 Input B
I/OD PMBus-A Open-Drain Bidirectional Alert
EQEP2_B
9
I
PMBUSA_ALERT
CLB_OUTPUTXBAR1
LINB_RX
10
11
13
14
15
O
I
CLB Output X-BAR Output 1
LIN-B Receive
51
42
34
FSITXA_TDM_D0
HIC_NBE0
I
FSITX-A Time Division Multiplexed Data Input
HIC Byte Enable 0
I
Crystal oscillator input or single-ended clock input.
The device initialization software must configure this
pin before the crystal oscillator is enabled. To use this
oscillator, a quartz crystal circuit must be connected
to X1 and X2. This pin can also be used to feed a
single-ended 3.3-V level clock. For more information
about the ALT functionality, see the table that is in the
External Oscillator (XTAL) section of the System
Control chapter in the TMS320F28002x Real-Time
Microcontrollers Technical Reference Manual.
X1
ALT
I
GPIO22
0, 4, 8, 12
I/O
I/O
I/O
O
General-Purpose Input Output 22
eQEP-1 Strobe
EQEP1_STROBE
SPIB_CLK
LINA_TX
1
6
SPI-B Clock
9
LIN-A Transmit
CLB_OUTPUTXBAR1
LINB_TX
10
67
56
O
CLB Output X-BAR Output 1
LIN-B Transmit
11
O
HIC_A5
13
I
HIC Address 5
EPWM4_A
HIC_D13
14
O
ePWM-4 Output A
15
I/O
I/O
I/O
I/O
I
HIC Data 13
GPIO23
0, 4, 8, 12
General-Purpose Input Output 23
eQEP-1 Index
EQEP1_INDEX
SPIB_STE
LINA_RX
1
6
SPI-B Slave Transmit Enable (STE)
LIN-A Receive
9
65
54
LINB_RX
11
I
LIN-B Receive
HIC_A3
13
I
HIC Address 3
EPWM4_B
HIC_D11
14
O
ePWM-4 Output B
15
I/O
I/O
O
HIC Data 11
GPIO24
0, 4, 8, 12
General-Purpose Input Output 24
Output X-BAR Output 1
eQEP-2 Input A
OUTPUTXBAR1
EQEP2_A
SPIB_SIMO
LINB_TX
1
2
I
6
I/O
O
SPI-B Slave In, Master Out (SIMO)
LIN-B Transmit
9
41
35
27
PMBUSA_SCL
SCIA_TX
10
11
I/OD PMBus-A Open-Drain Bidirectional Clock
O
SCI-A Transmit Data
Error Status Output. When used, this signal requires
an external pulldown.
ERRORSTS
HIC_D3
13
15
O
I/O
HIC Data 3
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TMS320F280023 TMS320F280023-Q1 TMS320F280023C TMS320F280021 TMS320F280021-Q1
TMS320F280025, TMS320F280025-Q1
TMS320F280025C, TMS320F280025C-Q1, TMS320F280023, TMS320F280023-Q1
TMS320F280023C, TMS320F280021, TMS320F280021-Q1
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ZHCSL01B –MARCH 2020 –REVISED DECEMBER 2020
表6-1. Pin Attributes (continued)
MUX
POSITION
PIN
TYPE
SIGNAL NAME
80 QFP 64 QFP 48 QFP
DESCRIPTION
GPIO25
0, 4, 8, 12
I/O
O
I
General-Purpose Input Output 25
Output X-BAR Output 2
eQEP-2 Input B
OUTPUTXBAR2
EQEP2_B
1
2
EQEP1_A
5
I
eQEP-1 Input A
SPIB_SOMI
FSITXA_D1
PMBUSA_SDA
SCIA_RX
6
42
I/O
O
SPI-B Slave Out, Master In (SOMI)
FSITX-A Data Output 1
9
10
I/OD PMBus-A Open-Drain Bidirectional Data
11
I
SCI-A Receive Data
HIC_BASESEL0
GPIO26
14
I
HIC Base Address Range Select 0
General-Purpose Input Output 26
Output X-BAR Output 3
0, 4, 8, 12
I/O
O
OUTPUTXBAR3
EQEP2_INDEX
SPIB_CLK
1, 5
2
I/O
I/O
O
eQEP-2 Index
6
SPI-B Clock
FSITXA_D0
PMBUSA_CTL
I2CA_SDA
9
43
FSITX-A Data Output 0
10
I/O
PMBus-A Control Signal - Slave Input/Master Output
11
I/OD I2C-A Open-Drain Bidirectional Data
HIC_D0
14
I/O
I
HIC Data 0
HIC_A1
15
HIC Address 1
GPIO27
0, 4, 8, 12
I/O
O
General-Purpose Input Output 27
Output X-BAR Output 4
eQEP-2 Strobe
OUTPUTXBAR4
EQEP2_STROBE
SPIB_STE
1, 5
2
I/O
I/O
O
6
SPI-B Slave Transmit Enable (STE)
FSITX-A Output Clock
FSITXA_CLK
PMBUSA_ALERT
I2CA_SCL
9
44
10
I/OD PMBus-A Open-Drain Bidirectional Alert
I/OD I2C-A Open-Drain Bidirectional Clock
11
HIC_D1
14
I/O
I
HIC Data 1
HIC_A4
15
HIC Address 4
GPIO28
0, 4, 8, 12
I/O
I
General-Purpose Input Output 28
SCI-A Receive Data
ePWM-7 Output A
Output X-BAR Output 5
eQEP-1 Input A
SCIA_RX
1
3
EPWM7_A
OUTPUTXBAR5
EQEP1_A
O
O
I
5
6
EQEP2_STROBE
LINA_TX
9
I/O
O
I/O
eQEP-2 Strobe
4
2
2
10
11
LIN-A Transmit
SPIB_CLK
SPI-B Clock
Error Status Output. When used, this signal requires
an external pulldown.
ERRORSTS
13
O
I2CB_SDA
HIC_NOE
14
15
I/OD I2C-B Open-Drain Bidirectional Data
HIC Output Enable
O
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TMS320F280025, TMS320F280025-Q1
TMS320F280025C, TMS320F280025C-Q1, TMS320F280023, TMS320F280023-Q1
TMS320F280023C, TMS320F280021, TMS320F280021-Q1
ZHCSL01B –MARCH 2020 –REVISED DECEMBER 2020
www.ti.com.cn
表6-1. Pin Attributes (continued)
MUX
POSITION
PIN
TYPE
SIGNAL NAME
GPIO29
80 QFP 64 QFP 48 QFP
DESCRIPTION
0, 4, 8, 12
I/O
O
General-Purpose Input Output 29
SCI-A Transmit Data
ePWM-7 Output B
SCIA_TX
1
3
EPWM7_B
OUTPUTXBAR6
EQEP1_B
O
5
O
Output X-BAR Output 6
eQEP-1 Input B
6
I
EQEP2_INDEX
LINA_RX
9
I/O
I
eQEP-2 Index
3
1
1
10
11
LIN-A Receive
SPIB_STE
I/O
SPI-B Slave Transmit Enable (STE)
Error Status Output. When used, this signal requires
an external pulldown.
ERRORSTS
13
O
I2CB_SCL
HIC_NCS
14
I/OD I2C-B Open-Drain Bidirectional Clock
15
I
HIC Chip Select
GPIO30
0, 4, 8, 12
I/O
I
General-Purpose Input Output 30
CAN-A Receive
CANA_RX
SPIB_SIMO
OUTPUTXBAR7
EQEP1_STROBE
FSIRXA_CLK
EPWM1_A
HIC_D8
1
3
I/O
O
SPI-B Slave In, Master Out (SIMO)
Output X-BAR Output 7
eQEP-1 Strobe
5
1
6
I/O
I
9
FSIRX-A Input Clock
ePWM-1 Output A
11
O
14
I/O
I/O
O
HIC Data 8
GPIO31
0, 4, 8, 12
General-Purpose Input Output 31
CAN-A Transmit
CANA_TX
SPIB_SOMI
OUTPUTXBAR8
EQEP1_INDEX
FSIRXA_D1
EPWM1_B
HIC_D10
1
3
I/O
O
SPI-B Slave Out, Master In (SOMI)
Output X-BAR Output 8
eQEP-1 Index
5
2
6
I/O
I
9
FSIRX-A Data Input 1
ePWM-1 Output B
11
O
14
I/O
I/O
HIC Data 10
GPIO32
0, 4, 8, 12
General-Purpose Input Output 32
I2CA_SDA
SPIB_CLK
LINA_TX
1
I/OD I2C-A Open-Drain Bidirectional Data
3
I/O
O
SPI-B Clock
6
LIN-A Transmit
49
40
32
FSIRXA_D0
CANA_TX
ADCSOCBO
HIC_INT
9
I
FSIRX-A Data Input 0
CAN-A Transmit
10
O
13
O
ADC Start of Conversion B for External ADC
HIC Device Interrupt
15
O
GPIO33
0, 4, 8, 12
I/O
General-Purpose Input Output 33
I2CA_SCL
SPIB_STE
OUTPUTXBAR4
LINA_RX
1
3
I/OD I2C-A Open-Drain Bidirectional Clock
I/O
SPI-B Slave Transmit Enable (STE)
Output X-BAR Output 4
LIN-A Receive
5
O
6
I
I
38
32
25
FSIRXA_CLK
CANA_RX
EQEP2_B
9
FSIRX-A Input Clock
CAN-A Receive
10
11
13
15
I
I
eQEP-2 Input B
ADCSOCAO
HIC_D0
O
I/O
ADC Start of Conversion A for External ADC
HIC Data 0
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TMS320F280025, TMS320F280025-Q1
TMS320F280025C, TMS320F280025C-Q1, TMS320F280023, TMS320F280023-Q1
TMS320F280023C, TMS320F280021, TMS320F280021-Q1
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ZHCSL01B –MARCH 2020 –REVISED DECEMBER 2020
表6-1. Pin Attributes (continued)
MUX
POSITION
PIN
TYPE
SIGNAL NAME
80 QFP 64 QFP 48 QFP
DESCRIPTION
GPIO34
0, 4, 8, 12
I/O
General-Purpose Input Output 34
Output X-BAR Output 1
OUTPUTXBAR1
PMBUSA_SDA
HIC_NBE1
I2CB_SDA
HIC_D9
1
O
6
I/OD PMBus-A Open-Drain Bidirectional Data
HIC Byte Enable 1
I/OD I2C-B Open-Drain Bidirectional Data
77
13
I
14
15
I/O
I/O
I
HIC Data 9
GPIO35
0, 4, 8, 12
General-Purpose Input Output 35
SCI-A Receive Data
SCIA_RX
1
3
I2CA_SDA
CANA_RX
PMBUSA_SCL
LINA_RX
I/OD I2C-A Open-Drain Bidirectional Data
CAN-A Receive
I/OD PMBus-A Open-Drain Bidirectional Clock
5
I
6
7
I
I
LIN-A Receive
48
39
31
EQEP1_A
9
eQEP-1 Input A
PMBUSA_CTL
HIC_NWE
10
14
I/O
I
PMBus-A Control Signal - Slave Input/Master Output
HIC Data Write Enable
JTAG Test Data Input (TDI) - TDI is the default mux
selection for the pin. The internal pullup is disabled by
default. The internal pullup should be enabled or an
external pullup added on the board if this pin is used
as JTAG TDI to avoid a floating input.
TDI
15
I
GPIO37
0, 4, 8, 12
I/O
O
General-Purpose Input Output 37
Output X-BAR Output 2
OUTPUTXBAR2
I2CA_SCL
SCIA_TX
1
3
I/OD I2C-A Open-Drain Bidirectional Clock
5
O
O
O
I
SCI-A Transmit Data
CAN-A Transmit
LIN-A Transmit
CANA_TX
6
LINA_TX
7
EQEP1_B
9
eQEP-1 Input B
46
37
29
PMBUSA_ALERT
HIC_NRDY
10
14
I/OD PMBus-A Open-Drain Bidirectional Alert
O
HIC Ready
JTAG Test Data Output (TDO) - TDO is the default
mux selection for the pin. The internal pullup is
disabled by default. The TDO function will tristate
when there is no JTAG activity, leaving this pin
floating; the internal pullup should be enabled or an
external pullup added on the board to avoid a floating
GPIO input.
TDO
15
O
GPIO39
0, 4, 8, 12
I/O
I
General-Purpose Input Output 39
FSIRX-A Input Clock
FSIRXA_CLK
EQEP2_INDEX
CLB_OUTPUTXBAR2
SYNCOUT
7
9
I/O
O
eQEP-2 Index
11
13
14
15
56
46
CLB Output X-BAR Output 2
External ePWM Synchronization Pulse
eQEP-1 Index
O
EQEP1_INDEX
HIC_D7
I/O
I/O
HIC Data 7
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TMS320F280025, TMS320F280025-Q1
TMS320F280025C, TMS320F280025C-Q1, TMS320F280023, TMS320F280023-Q1
TMS320F280023C, TMS320F280021, TMS320F280021-Q1
ZHCSL01B –MARCH 2020 –REVISED DECEMBER 2020
www.ti.com.cn
表6-1. Pin Attributes (continued)
MUX
POSITION
PIN
TYPE
SIGNAL NAME
GPIO40
80 QFP 64 QFP 48 QFP
DESCRIPTION
0, 4, 8, 12
I/O
I/O
O
General-Purpose Input Output 40
SPI-B Slave In, Master Out (SIMO)
ePWM-2 Output B
SPIB_SIMO
EPWM2_B
PMBUSA_SDA
FSIRXA_D0
EQEP1_A
1
5
6
I/OD PMBus-A Open-Drain Bidirectional Data
7
64
66
57
53
I
I
FSIRX-A Data Input 0
eQEP-1 Input A
10
LINB_TX
11
O
I
LIN-B Transmit
HIC_NBE1
HIC_D5
14
HIC Byte Enable 1
HIC Data 5
15
I/O
I/O
O
GPIO41
0, 4, 8, 12
General-Purpose Input Output 41
ePWM-2 Output A
EPWM2_A
PMBUSA_SCL
FSIRXA_D1
EQEP1_B
5
6
I/OD PMBus-A Open-Drain Bidirectional Clock
7
I
I
FSIRX-A Data Input 1
eQEP-1 Input B
10
55
LINB_RX
11
I
LIN-B Receive
HIC_A4
13
I
HIC Address 4
SPIB_SOMI
HIC_D12
14
I/O
I/O
I/O
I
SPI-B Slave Out, Master In (SOMI)
HIC Data 12
15
GPIO42
0, 4, 8, 12
General-Purpose Input Output 42
LIN-A Receive
LINA_RX
2
OUTPUTXBAR5
PMBUSA_CTL
I2CA_SDA
3
O
I/O
Output X-BAR Output 5
PMBus-A Control Signal - Slave Input/Master Output
5
6
I/OD I2C-A Open-Drain Bidirectional Data
EQEP1_STROBE
CLB_OUTPUTXBAR3
HIC_D2
10
I/O
O
eQEP-1 Strobe
11
CLB Output X-BAR Output 3
HIC Data 2
14
I/O
I
HIC_A6
15
HIC Address 6
GPIO43
0, 4, 8, 12
I/O
O
General-Purpose Input Output 43
Output X-BAR Output 6
OUTPUTXBAR6
PMBUSA_ALERT
I2CA_SCL
3
5
I/OD PMBus-A Open-Drain Bidirectional Alert
I/OD I2C-A Open-Drain Bidirectional Clock
6
54
EQEP1_INDEX
CLB_OUTPUTXBAR4
HIC_D3
10
I/O
O
eQEP-1 Index
11
CLB Output X-BAR Output 4
HIC Data 3
14
I/O
I
HIC_A7
15
HIC Address 7
GPIO44
0, 4, 8, 12
I/O
O
General-Purpose Input Output 44
Output X-BAR Output 7
eQEP-1 Input A
OUTPUTXBAR7
EQEP1_A
3
5
I
FSITXA_CLK
CLB_OUTPUTXBAR3
HIC_D7
7
69
O
FSITX-A Output Clock
CLB Output X-BAR Output 3
HIC Data 7
10
13
15
O
I/O
I/O
HIC_D5
HIC Data 5
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TMS320F280025, TMS320F280025-Q1
TMS320F280025C, TMS320F280025C-Q1, TMS320F280023, TMS320F280023-Q1
TMS320F280023C, TMS320F280021, TMS320F280021-Q1
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ZHCSL01B –MARCH 2020 –REVISED DECEMBER 2020
表6-1. Pin Attributes (continued)
MUX
POSITION
PIN
SIGNAL NAME
80 QFP 64 QFP 48 QFP
DESCRIPTION
TYPE
I/O
O
GPIO45
0, 4, 8, 12
General-Purpose Input Output 45
Output X-BAR Output 8
OUTPUTXBAR8
FSITXA_D0
CLB_OUTPUTXBAR4
HIC_D6
3
7
73
O
FSITX-A Data Output 0
10
15
O
CLB Output X-BAR Output 4
HIC Data 6
I/O
I/O
O
GPIO46
0, 4, 8, 12
3
General-Purpose Input Output 46
LIN-A Transmit
LINA_TX
6
FSITXA_D1
HIC_NWE
GPIO61
7
O
FSITX-A Data Output 1
15
I
HIC Data Write Enable
0, 4, 8, 12
0, 4, 8, 12
0, 4, 8, 12
I/O
I/O
I/O
General-Purpose Input Output 61
General-Purpose Input Output 62
General-Purpose Input Output 63
GPIO62
GPIO63
TEST, JTAG, AND RESET
Flash test pin 1. Reserved for TI. Must be left
unconnected.
FLT1
34
I/O
Flash test pin 2. Reserved for TI. Must be left
unconnected.
FLT2
TCK
33
45
I/O
36
38
28
30
I
JTAG test clock with internal pullup.
JTAG test-mode select (TMS) with internal pullup.
This serial control input is clocked into the TAP
controller on the rising edge of TCK. This device does
not have a TRSTn pin. An external pullup resistor
(recommended 2.2 kΩ) on the TMS pin to VDDIO
should be placed on the board to keep JTAG in reset
during normal operation.
TMS
47
I/O
Device Reset (in) and Watchdog Reset (out). During a
power-on condition, this pin is driven low by the
device. An external circuit may also drive this pin to
assert a device reset. This pin is also driven low by
the MCU when a watchdog reset occurs. During
watchdog reset, the XRSn pin is driven low for the
watchdog reset duration of 512 OSCCLK cycles. A
resistor between 2.2 kΩand 10 kΩshould be placed
between XRSn and VDDIO. If a capacitor is placed
between XRSn and VSS for noise filtering, it should
be 100 nF or smaller. These values will allow the
watchdog to properly drive the XRSn pin to VOL
within 512 OSCCLK cycles when the watchdog reset
is asserted. This pin is an open-drain output with an
internal pullup. If this pin is driven by an external
device, it should be done using an open-drain device.
XRSn
5
3
3
I/OD
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TMS320F280025, TMS320F280025-Q1
TMS320F280025C, TMS320F280025C-Q1, TMS320F280023, TMS320F280023-Q1
TMS320F280023C, TMS320F280021, TMS320F280021-Q1
ZHCSL01B –MARCH 2020 –REVISED DECEMBER 2020
www.ti.com.cn
表6-1. Pin Attributes (continued)
MUX
POSITION
PIN
TYPE
SIGNAL NAME
80 QFP 64 QFP 48 QFP
DESCRIPTION
POWER AND GROUND
1.2-V Digital Logic Power Pins. TI recommends
placing a decoupling capacitor near each VDD pin
with a minimum total capacitance of approximately 10
µF. It is also recommended that all VDD pins be
externally connected to each other.
8, 31,
53, 71
4, 27,
36, 45
44, 59
VDD
3.3-V Analog Power Pins. Place a minimum 2.2-µF
decoupling capacitor on each pin.
VDDA
26
22
18
3.3-V Digital I/O Power Pins. Place a minimum 0.1-µF
decoupling capacitor on each pin. It is recommended
to place an additional bulk cap of around 20uF shared
by all the pins. However, the exact value of this bulk
cap will depend on the regulator being used.
7, 32,
52, 72
28, 43,
60
VDDIO
35, 46
9, 30,
55, 70
5, 26,
45, 58
22, 37,
44
VSS
Digital Ground
Analog Ground
VSSA
25
21
17
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TMS320F280025, TMS320F280025-Q1
TMS320F280025C, TMS320F280025C-Q1, TMS320F280023, TMS320F280023-Q1
TMS320F280023C, TMS320F280021, TMS320F280021-Q1
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ZHCSL01B –MARCH 2020 –REVISED DECEMBER 2020
6.3 Signal Descriptions
6.3.1 Analog Signals
表6-2. Analog Signals
PIN
SIGNAL NAME
DESCRIPTION
ADC-A Input 0
GPIO
80 QFP
64 QFP
48 QFP
TYPE
A0
I
I
I
I
I
I
I
I
I
I
I
I
I
I
I
I
I
I
I
I
I
I
I
I
I
I
I
I
I
I
I
I
I
I
I
19
18
13
12
27
17
10
23
24
28
29
16
22
15
14
13
27
11
28
10
29
19
18
14
16
22
15
24
12
17
23
16
22
17
23
15
14
9
11
10
6
A1
Analog Input
A2
ADC-A Input 2
A3
ADC-A Input 3
8
5
A4
ADC-A Input 4
23
13
6
19
9
A5
ADC-A Input 5
A6
Analog Input
4
A7
ADC-A Input 7
19
20
24
25
12
18
11
10
9
15
16
20
21
8
A8
ADC-A Input 8
A9
ADC-A Input 9
A10
A11
A12
A14
A15
ADC-A Input 10
ADC-A Input 11
ADC-A Input 12
14
ADC-A Input 14
ADC-A Input 15
7
6
AIO224
AIO225
AIO226
AIO227
AIO228
AIO230
AIO231
AIO232
AIO233
AIO237
AIO238
AIO239
AIO241
AIO242
AIO244
AIO245
C0
Analog Pin Used For Digital Input 224
Analog Pin Used For Digital Input 225
Analog Pin Used For Digital Input 226
Analog Pin Used For Digital Input 227
Analog Pin Used For Digital Input 228
Analog Pin Used For Digital Input 230
Analog Pin Used For Digital Input 231
Analog Pin Used For Digital Input 232
Analog Pin Used For Digital Input 233
Analog Pin Used For Digital Input 237
Analog Pin Used For Digital Input 238
Analog Pin Used For Digital Input 239
Analog Pin Used For Digital Input 241
Analog Pin Used For Digital Input 242
Analog Pin Used For Digital Input 244
Analog Pin Used For Digital Input 245
ADC-C Input 0
23
7
19
4
24
6
20
4
25
15
14
10
12
18
11
20
8
21
11
10
7
8
14
16
5
13
19
12
18
13
19
9
15
8
C1
ADC-C Input 1
14
9
C2
ADC-C Input 2
C3
ADC-C Input 3
15
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TMS320F280025, TMS320F280025-Q1
TMS320F280025C, TMS320F280025C-Q1, TMS320F280023, TMS320F280023-Q1
TMS320F280023C, TMS320F280021, TMS320F280021-Q1
ZHCSL01B –MARCH 2020 –REVISED DECEMBER 2020
www.ti.com.cn
48 QFP
表6-2. Analog Signals (continued)
PIN
SIGNAL NAME
DESCRIPTION
ADC-C Input 4
GPIO
80 QFP
64 QFP
TYPE
C4
I
I
I
I
I
I
I
I
I
I
15
12
11
14
28
13
29
24
27
19
11
8
C5
ADC-C Input 5
Analog Input
5
4
C6
7
C7
ADC-C Input 7
ADC-C Input 8
ADC-C Input 9
ADC-C Input 10
ADC-C Input 11
ADC-C Input 14
ADC-C Input 15
10
24
9
7
C8
20
6
C9
C10
C11
C14
C15
25
20
23
15
21
16
19
11
CMPSS-1 High Comparator Negative
Input 0
CMP1_HN0
CMP1_HN1
CMP1_HP0
CMP1_HP1
CMP1_HP2
CMP1_HP3
CMP1_HP4
CMP1_LN0
CMP1_LN1
CMP1_LP0
CMP1_LP1
CMP1_LP2
CMP1_LP3
CMP1_LP4
CMP2_HN0
CMP2_HN1
I
I
I
I
I
I
I
I
I
I
I
I
I
I
I
I
14
16
13
16
10
14
18
14
16
13
16
10
14
18
29
22
10
12
9
7
8
CMPSS-1 High Comparator Negative
Input 1
CMPSS-1 High Comparator Positive
Input 0
6
CMPSS-1 High Comparator Positive
Input 1
12
6
8
CMPSS-1 High Comparator Positive
Input 2
4
CMPSS-1 High Comparator Positive
Input 3
10
14
10
12
9
7
CMPSS-1 High Comparator Positive
Input 4
10
7
CMPSS-1 Low Comparator Negative
Input 0
CMPSS-1 Low Comparator Negative
Input 1
8
CMPSS-1 Low Comparator Positive
Input 0
6
CMPSS-1 Low Comparator Positive
Input 1
12
6
8
CMPSS-1 Low Comparator Positive
Input 2
4
CMPSS-1 Low Comparator Positive
Input 3
10
14
25
18
7
CMPSS-1 Low Comparator Positive
Input 4
10
21
14
CMPSS-2 High Comparator Negative
Input 0
CMPSS-2 High Comparator Negative
Input 1
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TMS320F280025, TMS320F280025-Q1
TMS320F280025C, TMS320F280025C-Q1, TMS320F280023, TMS320F280023-Q1
TMS320F280023C, TMS320F280021, TMS320F280021-Q1
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ZHCSL01B –MARCH 2020 –REVISED DECEMBER 2020
表6-2. Analog Signals (continued)
PIN
SIGNAL NAME
DESCRIPTION
GPIO
80 QFP
27
22
28
29
24
29
22
27
22
28
29
24
12
17
11
64 QFP
23
18
24
25
20
25
18
23
18
24
25
20
8
48 QFP
19
14
20
21
16
21
14
19
14
20
21
16
5
TYPE
CMPSS-2 High Comparator Positive
Input 0
CMP2_HP0
CMP2_HP1
CMP2_HP2
CMP2_HP3
CMP2_HP4
CMP2_LN0
CMP2_LN1
CMP2_LP0
CMP2_LP1
CMP2_LP2
CMP2_LP3
CMP2_LP4
CMP3_HN0
CMP3_HN1
CMP3_HP0
CMP3_HP1
CMP3_HP2
CMP3_HP3
CMP3_HP4
CMP3_LN0
CMP3_LN1
CMP3_LP0
I
I
I
I
I
I
I
I
I
I
I
I
I
I
I
I
I
I
I
I
I
I
CMPSS-2 High Comparator Positive
Input 1
CMPSS-2 High Comparator Positive
Input 2
CMPSS-2 High Comparator Positive
Input 3
CMPSS-2 High Comparator Positive
Input 4
CMPSS-2 Low Comparator Negative
Input 0
CMPSS-2 Low Comparator Negative
Input 1
CMPSS-2 Low Comparator Positive
Input 0
CMPSS-2 Low Comparator Positive
Input 1
CMPSS-2 Low Comparator Positive
Input 2
CMPSS-2 Low Comparator Positive
Input 3
CMPSS-2 Low Comparator Positive
Input 4
CMPSS-3 High Comparator Negative
Input 0
CMPSS-3 High Comparator Negative
Input 1
13
7
9
CMPSS-3 High Comparator Positive
Input 0
4
CMPSS-3 High Comparator Positive
Input 1
17
19
12
15
12
17
11
13
15
8
9
CMPSS-3 High Comparator Positive
Input 2
11
5
CMPSS-3 High Comparator Positive
Input 3
CMPSS-3 High Comparator Positive
Input 4
11
8
CMPSS-3 Low Comparator Negative
Input 0
5
9
4
CMPSS-3 Low Comparator Negative
Input 1
13
7
CMPSS-3 Low Comparator Positive
Input 0
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TMS320F280023 TMS320F280023-Q1 TMS320F280023C TMS320F280021 TMS320F280021-Q1
TMS320F280025, TMS320F280025-Q1
TMS320F280025C, TMS320F280025C-Q1, TMS320F280023, TMS320F280023-Q1
TMS320F280023C, TMS320F280021, TMS320F280021-Q1
ZHCSL01B –MARCH 2020 –REVISED DECEMBER 2020
www.ti.com.cn
表6-2. Analog Signals (continued)
PIN
SIGNAL NAME
DESCRIPTION
GPIO
80 QFP
17
64 QFP
13
15
8
48 QFP
TYPE
CMPSS-3 Low Comparator Positive
Input 1
CMP3_LP1
I
9
11
5
CMPSS-3 Low Comparator Positive
Input 2
CMP3_LP2
CMP3_LP3
CMP3_LP4
CMP4_HN0
CMP4_HN1
CMP4_HP0
CMP4_HP1
CMP4_HP2
CMP4_HP3
CMP4_HP4
CMP4_LN0
CMP4_LN1
CMP4_LP0
CMP4_LP1
CMP4_LP2
CMP4_LP3
CMP4_LP4
I
I
I
I
I
I
I
I
I
I
I
I
I
I
I
I
I
19
CMPSS-3 Low Comparator Positive
Input 3
12
CMPSS-3 Low Comparator Positive
Input 4
15
11
CMPSS-4 High Comparator Negative
Input 0
27
23
19
24
19
18
23
20
23
19
24
19
18
23
20
19
15
20
15
14
19
16
19
15
20
15
14
19
16
CMPSS-4 High Comparator Negative
Input 1
23
CMPSS-4 High Comparator Positive
Input 0
28
CMPSS-4 High Comparator Positive
Input 1
23
CMPSS-4 High Comparator Positive
Input 2
22
CMPSS-4 High Comparator Positive
Input 3
27
CMPSS-4 High Comparator Positive
Input 4
24
CMPSS-4 Low Comparator Negative
Input 0
27
CMPSS-4 Low Comparator Negative
Input 1
23
CMPSS-4 Low Comparator Positive
Input 0
28
CMPSS-4 Low Comparator Positive
Input 1
23
CMPSS-4 Low Comparator Positive
Input 2
22
CMPSS-4 Low Comparator Positive
Input 3
27
CMPSS-4 Low Comparator Positive
Input 4
24
HIC_A0
HIC_A1
HIC_A2
HIC_A3
HIC_A4
HIC_A5
I
I
I
I
I
I
HIC Address 0
HIC Address 1
HIC Address 2
HIC Address 3
HIC Address 4
HIC Address 5
10
11
12
13
14
15
6
7
4
4
5
6
7
8
9
10
11
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TMS320F280023 TMS320F280023-Q1 TMS320F280023C TMS320F280021 TMS320F280021-Q1
TMS320F280025, TMS320F280025-Q1
TMS320F280025C, TMS320F280025C-Q1, TMS320F280023, TMS320F280023-Q1
TMS320F280023C, TMS320F280021, TMS320F280021-Q1
www.ti.com.cn
ZHCSL01B –MARCH 2020 –REVISED DECEMBER 2020
表6-2. Analog Signals (continued)
PIN
SIGNAL NAME
DESCRIPTION
HIC Address 6
GPIO
80 QFP
64 QFP
48 QFP
TYPE
HIC_A6
I
I
16
17
18
19
29
28
24
22
23
27
12
13
14
15
25
24
20
18
19
23
8
HIC_A7
HIC Address 7
9
HIC_BASESEL0
HIC_BASESEL1
HIC_BASESEL2
HIC_NBE0
HIC_NBE1
HIC_NCS
I
HIC Base Address Range Select 0
HIC Base Address Range Select 1
HIC Base Address Range Select 2
HIC Byte Enable 0
10
11
21
20
16
14
15
19
I
I
I
I
HIC Byte Enable 1
I
HIC Chip Select
HIC_NOE
O
I
HIC Output Enable
HIC_NWE
HIC Data Write Enable
Optional external reference voltage
for on-chip CMPSS DACs. There is
an internal capacitor to VSSA on this
pin whether used for ADC input or
CMPSS DAC reference which cannot
be disabled. If this pin is being used
as a reference for the CMPSS DACs,
place at least a 1-μF capacitor on
this pin.
VDAC
I
12
8
5
ADC- High Reference. In external
reference mode, externally drive the
high reference voltage onto this pin.
In internal reference mode, a voltage
is driven onto this pin by the device.
In either mode, place at least a 2.2-
µF capacitor on this pin. This
VREFHI
I
I
20
21
16
17
12
13
capacitor should be placed as close
to the device as possible between the
VREFHI and VREFLO pins.
VREFLO
ADC- Low Reference
6.3.2 Digital Signals
表6-3. Digital Signals
PIN
SIGNAL NAME
ADCSOCAO
DESCRIPTION
GPIO
80 QFP
38, 58
49, 76
64 QFP
32, 47
40, 63
48 QFP
25
TYPE
ADC Start of Conversion A for
External ADC
O
O
I
33, 8
ADC Start of Conversion B for
External ADC
ADCSOCBO
10, 32
32
12, 18, 3, 30, 1, 36, 38, 48,
33, 35, 5 50, 60, 74
30, 32, 39,
41, 49, 61
24, 25, 31,
33, 39, 47
CANA_RX
CAN-A Receive
13, 17, 19, 2, 2, 35, 40, 46,
29, 34, 37,
23, 29, 32,
34, 38, 40
CANA_TX
O
O
CAN-A Transmit
31, 32, 37, 4 49, 51, 59, 61 40, 42, 48, 50
CLB_OUTPUTXBAR1
CLB Output X-BAR Output 1
19, 22 51, 67 42, 56
34
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TMS320F280023 TMS320F280023-Q1 TMS320F280023C TMS320F280021 TMS320F280021-Q1
TMS320F280025, TMS320F280025-Q1
TMS320F280025C, TMS320F280025C-Q1, TMS320F280023, TMS320F280023-Q1
TMS320F280023C, TMS320F280021, TMS320F280021-Q1
ZHCSL01B –MARCH 2020 –REVISED DECEMBER 2020
www.ti.com.cn
表6-3. Digital Signals (continued)
PIN
SIGNAL NAME
DESCRIPTION
GPIO
80 QFP
64 QFP
48 QFP
TYPE
CLB_OUTPUTXBAR2
CLB_OUTPUTXBAR3
CLB_OUTPUTXBAR4
CLB_OUTPUTXBAR5
CLB_OUTPUTXBAR6
CLB_OUTPUTXBAR7
CLB_OUTPUTXBAR8
EPWM1_A
O
CLB Output X-BAR Output 2
CLB Output X-BAR Output 3
CLB Output X-BAR Output 4
CLB Output X-BAR Output 5
CLB Output X-BAR Output 6
CLB Output X-BAR Output 7
CLB Output X-BAR Output 8
ePWM-1 Output A
39, 7
42, 44
43, 45
5, 8
56, 68
57, 69
54, 73
58, 74
59, 78
62, 79
63, 80
1, 63
46, 57
43
O
O
O
47, 61
48
47
38
O
15, 4
1, 14
6
O
51
41
O
52, 64
52
42, 48
42
O
30
EPWM1_B
O
ePWM-1 Output B
1, 31
2, 41
3, 40
14, 4
15, 5
22, 6
23, 7
16, 8
17, 9
10, 18
11, 19
12, 28
13, 29
2, 62
51
41
EPWM2_A
O
ePWM-2 Output A
61, 66
60, 64
59, 79
74, 78
67, 80
65, 68
39, 58
40, 75
50, 76
37, 51
36, 4
50, 55
49, 53
48
40
EPWM2_B
O
ePWM-2 Output B
39
EPWM3_A
O
ePWM-3 Output A
38
EPWM3_B
O
ePWM-3 Output B
61
47
EPWM4_A
O
ePWM-4 Output A
56, 64
54, 57
33, 47
34, 62
41, 63
31, 42
2, 30
1, 29
48
EPWM4_B
O
ePWM-4 Output B
43
EPWM5_A
O
ePWM-5 Output A
26
EPWM5_B
O
ePWM-5 Output B
EPWM6_A
O
ePWM-6 Output A
33
34
EPWM6_B
O
ePWM-6 Output B
EPWM7_A
O
ePWM-7 Output A
2, 24
1, 23
EPWM7_B
O
ePWM-7 Output B
3, 35
10, 25, 28,
4, 42, 48, 64, 2, 39, 53, 63,
69, 76, 80 64
EQEP1_A
I
I
eQEP-1 Input A
eQEP-1 Input B
2, 31, 48
1, 29, 43
23
35, 40, 44, 6
11, 29, 37, 41, 3, 37, 46, 66, 1, 31, 37, 55,
EQEP1_B
7
68
57
13, 17, 23,
2, 35, 40, 54,
56, 65, 75
29, 34, 46,
54, 62
EQEP1_INDEX
I/O eQEP-1 Index
I/O eQEP-1 Strobe
31, 39, 43, 9
12, 16, 22,
30, 42, 8
1, 36, 39, 57,
58, 67
EQEP1_STROBE
EQEP2_A
30, 33, 47, 56
24, 26
27, 33
I
I
eQEP-2 Input A
eQEP-2 Input B
11, 14, 18, 24 37, 41, 50, 79 31, 35, 41
15, 16, 19,
25, 33
38, 39, 42,
51, 78
EQEP2_B
32, 33, 42
25, 26, 34
EQEP2_INDEX
I/O eQEP-2 Index
I/O eQEP-2 Strobe
26, 29, 39
27, 28, 4
3, 43, 56
4, 44, 59
1, 46
2, 48
1
EQEP2_STROBE
2, 38
Error Status Output. When used, this
ERRORSTS
O
I
24, 28, 29
3, 4, 41
1, 2, 35
1, 2, 27
signal requires an external pulldown.
13, 30, 33,
39, 4
1, 35, 38, 56,
59, 63
29, 32, 46,
48, 52
FSIRXA_CLK
FSIRX-A Input Clock
23, 25, 38, 42
FSIRXA_D0
FSIRXA_D1
I
I
FSIRX-A Data Input 0
FSIRX-A Data Input 1
12, 3, 32, 40 36, 49, 60, 64 30, 40, 49, 53
11, 2, 31, 41 2, 37, 61, 66 31, 50, 55
24, 32, 39
40
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TMS320F280023 TMS320F280023-Q1 TMS320F280023C TMS320F280021 TMS320F280021-Q1
TMS320F280025, TMS320F280025-Q1
TMS320F280025C, TMS320F280025C-Q1, TMS320F280023, TMS320F280023-Q1
TMS320F280023C, TMS320F280021, TMS320F280021-Q1
www.ti.com.cn
ZHCSL01B –MARCH 2020 –REVISED DECEMBER 2020
表6-3. Digital Signals (continued)
PIN
SIGNAL NAME
DESCRIPTION
FSITX-A Output Clock
GPIO
80 QFP
64 QFP
48 QFP
TYPE
FSITXA_CLK
FSITXA_D0
O
O
10, 27, 44, 7 44, 68, 69, 76
26, 45, 6, 9 43, 73, 75, 80
57, 63
62, 64
43
48
FSITX-A Data Output 0
FSITX-A Data Output 1
42, 58, 6, 74,
FSITXA_D1
O
I
25, 46, 5, 6, 8
80
47, 61, 64
41, 47
42, 63
51
47, 48
33
FSITX-A Time Division Multiplexed
Clock Input
FSITXA_TDM_CLK
FSITXA_TDM_D0
FSITXA_TDM_D1
18, 8
10, 19
1
50, 58
51, 76
62
FSITX-A Time Division Multiplexed
Data Input
I
34
FSITX-A Time Division Multiplexed
Additional Data Input
I
41
GPIO0
I/O General-Purpose Input Output 0
I/O General-Purpose Input Output 1
I/O General-Purpose Input Output 2
I/O General-Purpose Input Output 3
I/O General-Purpose Input Output 4
I/O General-Purpose Input Output 5
I/O General-Purpose Input Output 6
I/O General-Purpose Input Output 7
I/O General-Purpose Input Output 8
I/O General-Purpose Input Output 9
I/O General-Purpose Input Output 10
I/O General-Purpose Input Output 11
I/O General-Purpose Input Output 12
I/O General-Purpose Input Output 13
I/O General-Purpose Input Output 14
I/O General-Purpose Input Output 15
I/O General-Purpose Input Output 16
I/O General-Purpose Input Output 17
I/O General-Purpose Input Output 18_X2
I/O General-Purpose Input Output 19_X1
I/O General-Purpose Input Output 22
I/O General-Purpose Input Output 23
I/O General-Purpose Input Output 24
I/O General-Purpose Input Output 25
I/O General-Purpose Input Output 26
I/O General-Purpose Input Output 27
I/O General-Purpose Input Output 28
I/O General-Purpose Input Output 29
I/O General-Purpose Input Output 30
63
62
61
60
59
74
80
68
58
75
76
37
36
35
79
78
39
40
50
51
67
65
41
42
43
44
4
52
51
50
49
48
61
64
57
47
62
63
31
30
29
42
41
40
39
38
47
48
43
GPIO1
1
GPIO2
2
GPIO3
3
GPIO4
4
GPIO5
5
GPIO6
6
GPIO7
7
GPIO8
8
GPIO9
9
GPIO10
GPIO11
GPIO12
GPIO13
GPIO14
GPIO15
GPIO16
GPIO17
GPIO18_X2
GPIO19_X1
GPIO22
GPIO23
GPIO24
GPIO25
GPIO26
GPIO27
GPIO28
GPIO29
GPIO30
10
11
12
13
14
15
16
17
18
19
22
23
24
25
26
27
28
29
30
24
23
33
34
41
42
56
54
35
26
33
34
27
2
1
2
1
3
1
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Product Folder Links: TMS320F280025 TMS320F280025-Q1 TMS320F280025C TMS320F280025C-Q1
TMS320F280023 TMS320F280023-Q1 TMS320F280023C TMS320F280021 TMS320F280021-Q1
TMS320F280025, TMS320F280025-Q1
TMS320F280025C, TMS320F280025C-Q1, TMS320F280023, TMS320F280023-Q1
TMS320F280023C, TMS320F280021, TMS320F280021-Q1
ZHCSL01B –MARCH 2020 –REVISED DECEMBER 2020
www.ti.com.cn
48 QFP
表6-3. Digital Signals (continued)
PIN
SIGNAL NAME
GPIO31
DESCRIPTION
GPIO
80 QFP
64 QFP
TYPE
I/O General-Purpose Input Output 31
I/O General-Purpose Input Output 32
I/O General-Purpose Input Output 33
I/O General-Purpose Input Output 34
I/O General-Purpose Input Output 35
I/O General-Purpose Input Output 37
I/O General-Purpose Input Output 39
I/O General-Purpose Input Output 40
I/O General-Purpose Input Output 41
I/O General-Purpose Input Output 42
I/O General-Purpose Input Output 43
I/O General-Purpose Input Output 44
I/O General-Purpose Input Output 45
I/O General-Purpose Input Output 46
I/O General-Purpose Input Output 61
I/O General-Purpose Input Output 62
I/O General-Purpose Input Output 63
31
32
2
GPIO32
GPIO33
GPIO34
GPIO35
GPIO37
GPIO39
GPIO40
GPIO41
GPIO42
GPIO43
GPIO44
GPIO45
GPIO46
GPIO61
GPIO62
GPIO63
HIC_A0
49
38
77
48
46
56
64
66
57
54
69
73
6
40
32
32
25
33
34
35
39
37
46
53
55
31
29
37
39
40
41
42
43
44
45
46
61
62
63
I
I
I
I
I
I
I
I
I
I
I
HIC Address 0
8
58
43, 61
62
47
50
HIC_A1
HIC Address 1
2, 26
1
40
41
HIC_A2
HIC Address 2
51
HIC_A3
HIC Address 3
23
65
54
HIC_A4
HIC Address 4
27, 41
22
44, 66
67
55
HIC_A5
HIC Address 5
56
HIC_A6
HIC Address 6
42, 7
43, 5
25, 9
57, 68
54, 74
42, 75
63
57
43
47
HIC_A7
HIC Address 7
61
HIC_BASESEL0
HIC_BASESEL1
HIC_BASESEL2
HIC_D0
HIC_D1
HIC_D2
HIC_D3
HIC_D4
HIC_D5
HIC_D6
HIC_D7
HIC_D8
HIC_D9
HIC Base Address Range Select 0
HIC Base Address Range Select 1
HIC Base Address Range Select 2
62
52
42
38
25
26
4
26, 33
16, 27
17, 42
24, 43
3, 5
59
48
I/O HIC Data 0
I/O HIC Data 1
I/O HIC Data 2
I/O HIC Data 3
I/O HIC Data 4
I/O HIC Data 5
I/O HIC Data 6
I/O HIC Data 7
I/O HIC Data 8
I/O HIC Data 9
38, 43
39, 44
40, 57
41, 54
60, 74
35, 64, 69
37, 73
56, 69
1, 58
61, 77
32
33
34
35
27
39, 47
23
49, 61
29, 53
31
13, 40, 44
11, 45
39, 44
30, 8
46
47
2, 34
50
40
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TMS320F280023 TMS320F280023-Q1 TMS320F280023C TMS320F280021 TMS320F280021-Q1
TMS320F280025, TMS320F280025-Q1
TMS320F280025C, TMS320F280025C-Q1, TMS320F280023, TMS320F280023-Q1
TMS320F280023C, TMS320F280021, TMS320F280021-Q1
www.ti.com.cn
ZHCSL01B –MARCH 2020 –REVISED DECEMBER 2020
表6-3. Digital Signals (continued)
PIN
SIGNAL NAME
DESCRIPTION
GPIO
80 QFP
64 QFP
48 QFP
TYPE
HIC_D10
HIC_D11
HIC_D12
HIC_D13
HIC_D14
HIC_D15
HIC_INT
I/O HIC Data 10
I/O HIC Data 11
I/O HIC Data 12
I/O HIC Data 13
I/O HIC Data 14
I/O HIC Data 15
1, 31
13, 23
15, 41
12, 22
6, 7
2, 62
35, 65
66, 78
36, 67
68, 80
74, 79
36, 49, 50
37, 51
64, 77, 80
3
51
29, 54
55
41
23
30, 56
57, 64
61
24
43, 48
47
14, 5
O
I
HIC Device Interrupt
12, 18, 32
11, 19
34, 40, 6
29
30, 40, 41
31, 42
53, 64
1
24, 32, 33
34
HIC_NBE0
HIC_NBE1
HIC_NCS
HIC_NOE
HIC_NRDY
HIC_NWE
HIC Byte Enable 0
HIC Byte Enable 1
HIC Chip Select
HIC Output Enable
HIC Ready
I
48
I
1
O
O
I
28, 3
4, 60
2, 49
2, 39
29
37, 9
46, 75
37, 62
39, 48, 63
HIC Data Write Enable
10, 35, 4, 46 48, 59, 6, 76
31, 38
1, 18, 27, 33,
37, 43, 8
38, 44, 46,
32, 37, 41,
47, 51
I2CA_SCL
I2CA_SDA
I/OD I2C-A Open-Drain Bidirectional Clock
I/OD I2C-A Open-Drain Bidirectional Data
25, 29, 33, 41
31, 32, 34, 42
50, 54, 58, 62
10, 19, 26,
32, 35, 42
43, 48, 49,
39, 40, 42,
52, 63
51, 57, 63, 76
I2CB_SCL
I2CB_SDA
I/OD I2C-B Open-Drain Bidirectional Clock 15, 29, 3, 9
I/OD I2C-B Open-Drain Bidirectional Data
3, 60, 75, 78
1, 49, 62
2, 50
1, 39
2, 40
14, 2, 28, 34 4, 61, 77, 79
23, 29, 33,
35, 42
3, 38, 48, 57,
65
LINA_RX
LINA_TX
LINB_RX
LINB_TX
I
LIN-A Receive
LIN-A Transmit
LIN-B Receive
LIN-B Transmit
1, 32, 39, 54
2, 37, 40, 56
1, 25, 31
2, 29, 32
23, 34
22, 28, 32,
37, 46
4, 46, 49, 6,
67
O
I
11, 13, 15, 19, 35, 37, 51,
29, 31, 42,
54, 55, 62
23, 41, 9
65, 66, 75, 78
10, 12, 14,
36, 41, 50,
30, 35, 41,
53, 56, 63
O
24, 27, 33
18, 22, 24, 40 64, 67, 76, 79
OUTPUTXBAR1
OUTPUTXBAR2
OUTPUTXBAR3
OUTPUTXBAR4
OUTPUTXBAR5
OUTPUTXBAR6
OUTPUTXBAR7
OUTPUTXBAR8
O
O
O
O
O
O
O
O
Output X-BAR Output 1
Output X-BAR Output 2
Output X-BAR Output 3
Output X-BAR Output 4
Output X-BAR Output 5
Output X-BAR Output 6
Output X-BAR Output 7
Output X-BAR Output 8
2, 24, 34
25, 3, 37
41, 61, 77
42, 46, 60
35, 50
37, 49
48, 61
32, 64
2, 57
1, 62
31, 33
34
27, 40
29, 39
38, 47
25, 48
2, 43
1
14, 26, 4, 5 43, 59, 74, 79
15, 27, 33, 6 38, 44, 78, 80
28, 42, 7
29, 43, 9
4, 57, 68
3, 54, 75
11, 16, 30, 44 1, 37, 39, 69
26
17, 31, 45
2, 40, 73
PMBus-A Open-Drain Bidirectional
Alert
13, 19, 27,
37, 43
35, 44, 46,
51, 54
PMBUSA_ALERT
PMBUSA_CTL
I/OD
I/O
29, 37, 42
30, 39, 41
23, 29, 34
24, 31, 33
PMBus-A Control Signal - Slave
Input/Master Output
12, 18, 26,
35, 42
36, 43, 48,
50, 57
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TMS320F280025, TMS320F280025-Q1
TMS320F280025C, TMS320F280025C-Q1, TMS320F280023, TMS320F280023-Q1
TMS320F280023C, TMS320F280021, TMS320F280021-Q1
ZHCSL01B –MARCH 2020 –REVISED DECEMBER 2020
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表6-3. Digital Signals (continued)
PIN
SIGNAL NAME
DESCRIPTION
GPIO
80 QFP
64 QFP
48 QFP
26, 27, 31, 39
40
TYPE
PMBus-A Open-Drain Bidirectional
Clock
15, 16, 24, 3,
35, 41
39, 41, 48,
60, 66, 78
33, 35, 39,
49, 55
PMBUSA_SCL
I/OD
PMBus-A Open-Drain Bidirectional
Data
14, 17, 2, 25,
34, 40
40, 42, 61,
64, 77, 79
PMBUSA_SDA
SCIA_RX
I/OD
34, 50, 53
17, 25, 28, 3, 4, 40, 42, 48, 2, 34, 39, 49,
35, 9 60, 75 62
I
SCI-A Receive Data
SCI-A Transmit Data
2, 31, 39
16, 2, 24, 29, 3, 39, 41, 46, 1, 33, 35, 37, 1, 26, 27, 29,
SCIA_TX
O
37, 8
58, 61
47, 50
40
SPIA_CLK
SPIA_SIMO
SPIA_SOMI
SPIA_STE
I/O SPI-A Clock
12, 18, 3, 9 36, 50, 60, 75 30, 41, 49, 62
11, 16, 2, 8 37, 39, 58, 61 31, 33, 47, 50
1, 10, 13, 17 35, 40, 62, 76 29, 34, 51, 63
24, 33, 39
26, 40
I/O SPI-A Slave In, Master Out (SIMO)
I/O SPI-A Slave Out, Master In (SOMI)
I/O SPI-A Slave Transmit Enable (STE)
23, 41
11, 19, 5
37, 51, 63, 74 31, 42, 52, 61
34, 42, 47
14, 22, 26,
28, 32, 4
4, 43, 49, 59,
2, 40, 48, 56
67, 79
SPIB_CLK
SPIB_SIMO
SPIB_SOMI
I/O SPI-B Clock
2, 32, 38
27, 43
I/O SPI-B Slave In, Master Out (SIMO)
I/O SPI-B Slave Out, Master In (SOMI)
24, 30, 40, 7 1, 41, 64, 68
35, 53, 57
33, 55, 64
16, 25, 31,
41, 6
2, 39, 42, 66,
80
26, 48
15, 23, 27,
29, 33
3, 38, 44, 65,
78
SPIB_STE
SYNCOUT
I/O SPI-B Slave Transmit Enable (STE)
1, 32, 54
46, 64
1, 25
48
External ePWM Synchronization
O
39, 6
56, 80
Pulse
JTAG Test Data Input (TDI) - TDI is
the default mux selection for the pin.
The internal pullup is disabled by
TDI
I
default. The internal pullup should be
enabled or an external pullup added
on the board if this pin is used as
JTAG TDI to avoid a floating input.
35
48
39
31
JTAG Test Data Output (TDO) - TDO
is the default mux selection for the
pin. The internal pullup is disabled by
default. The TDO function will tristate
when there is no JTAG activity,
TDO
O
37
46
37
29
leaving this pin floating; the internal
pullup should be enabled or an
external pullup added on the board to
avoid a floating GPIO input.
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TMS320F280025, TMS320F280025-Q1
TMS320F280025C, TMS320F280025C-Q1, TMS320F280023, TMS320F280023-Q1
TMS320F280023C, TMS320F280021, TMS320F280021-Q1
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ZHCSL01B –MARCH 2020 –REVISED DECEMBER 2020
表6-3. Digital Signals (continued)
PIN
SIGNAL NAME
DESCRIPTION
GPIO
80 QFP
64 QFP
48 QFP
TYPE
Crystal oscillator input or single-
ended clock input. The device
initialization software must configure
this pin before the crystal oscillator is
enabled. To use this oscillator, a
quartz crystal circuit must be
connected to X1 and X2. This pin can
also be used to feed a single-ended
3.3-V level clock. For more
X1
I
19
51
42
34
information about the ALT
functionality, see the table that is in
the External Oscillator (XTAL) section
of the System Control chapter in the
TMS320F28002x Real-Time
Microcontrollers Technical Reference
Manual.
Crystal oscillator output. For more
information about the ALT
functionality, see the table that is in
the External Oscillator (XTAL) section
of the System Control chapter in the
TMS320F28002x Real-Time
Microcontrollers Technical Reference
Manual.
X2
O
O
18
50
41
33
External Clock Output. This pin
outputs a divided-down version of a
chosen clock signal from within the
device.
XCLKOUT
16, 18
39, 50
33, 41
26, 33
6.3.3 Power and Ground
表6-4. Power and Ground
PIN
SIGNAL NAME
DESCRIPTION
GPIO
80 QFP
64 QFP
48 QFP
TYPE
1.2-V Digital Logic Power Pins. TI
recommends placing a decoupling
capacitor near each VDD pin with a
minimum total capacitance of
VDD
31, 53, 71, 8 27, 4, 44, 59
36, 45
approximately 10 µF. It is also
recommended that all VDD pins be
externally connected to each other.
3.3-V Analog Power Pins. Place a
minimum 2.2-µF decoupling capacitor
on each pin.
VDDA
26
22
18
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TMS320F280025, TMS320F280025-Q1
TMS320F280025C, TMS320F280025C-Q1, TMS320F280023, TMS320F280023-Q1
TMS320F280023C, TMS320F280021, TMS320F280021-Q1
ZHCSL01B –MARCH 2020 –REVISED DECEMBER 2020
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48 QFP
表6-4. Power and Ground (continued)
PIN
SIGNAL NAME
DESCRIPTION
GPIO
80 QFP
64 QFP
TYPE
3.3-V Digital I/O Power Pins. Place a
minimum 0.1-µF decoupling capacitor
on each pin. It's recommended to
place an additional bulk cap of
around 20uF shared by all the pins.
However, the exact value of this bulk
cap will depend on the regulator
being used.
VDDIO
32, 52, 7, 72
28, 43, 60
35, 46
VSS
Digital Ground
Analog Ground
30, 55, 70, 9 26, 45, 5, 58
22, 37, 44
17
VSSA
25
21
6.3.4 Test, JTAG, and Reset
表6-5. Test, JTAG, and Reset
PIN
SIGNAL NAME
TYPE
DESCRIPTION
GPIO
80 QFP
64 QFP
48 QFP
Flash test pin 1. Reserved for TI.
Must be left unconnected.
FLT1
I/O
34
Flash test pin 2. Reserved for TI.
Must be left unconnected.
FLT2
TCK
I/O
I
33
45
JTAG test clock with internal pullup.
36
38
28
30
JTAG test-mode select (TMS) with
internal pullup. This serial control
input is clocked into the TAP
controller on the rising edge of TCK.
This device does not have a TRSTn
pin. An external pullup resistor
(recommended 2.2 kΩ) on the TMS
pin to VDDIO should be placed on
the board to keep JTAG in reset
during normal operation.
TMS
I/O
47
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TMS320F280025, TMS320F280025-Q1
TMS320F280025C, TMS320F280025C-Q1, TMS320F280023, TMS320F280023-Q1
TMS320F280023C, TMS320F280021, TMS320F280021-Q1
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ZHCSL01B –MARCH 2020 –REVISED DECEMBER 2020
表6-5. Test, JTAG, and Reset (continued)
PIN
SIGNAL NAME
DESCRIPTION
GPIO
80 QFP
64 QFP
48 QFP
TYPE
Device Reset (in) and Watchdog
Reset (out). During a power-on
condition, this pin is driven low by the
device. An external circuit may also
drive this pin to assert a device reset.
This pin is also driven low by the
MCU when a watchdog reset occurs.
During watchdog reset, the XRSn pin
is driven low for the watchdog reset
duration of 512 OSCCLK cycles. A
resistor between 2.2 kΩand 10 kΩ
should be placed between XRSn and
VDDIO. If a capacitor is placed
between XRSn and VSS for noise
filtering, it should be 100 nF or
XRSn
I/OD
5
3
3
smaller. These values will allow the
watchdog to properly drive the XRSn
pin to VOL within 512 OSCCLK
cycles when the watchdog reset is
asserted. This pin is an open-drain
output with an internal pullup. If this
pin is driven by an external device, it
should be done using an open-drain
device.
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TMS320F280025, TMS320F280025-Q1
TMS320F280025C, TMS320F280025C-Q1, TMS320F280023, TMS320F280023-Q1
TMS320F280023C, TMS320F280021, TMS320F280021-Q1
ZHCSL01B –MARCH 2020 –REVISED DECEMBER 2020
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6.4 Pin Multiplexing
6.4.1 GPIO Muxed Pins
表6-6 lists the GPIO muxed pins. The default mode for each GPIO pin is the GPIO function, except GPIO35 and
GPIO37, which default to TDI and TDO, respectively. Secondary functions can be selected by setting both the
GPyGMUXn.GPIOz and GPyMUXn.GPIOz register bits. The GPyGMUXn register should be configured before
the GPyMUXn to avoid transient pulses on GPIOs from alternate mux selections. Columns that are not shown
and blank cells are reserved GPIO Mux settings. GPIO ALT functions cannot be configured with the GPyMUXn
and GPyGMUXn registers. These are special functions that need to be configured from the module.
Note
GPIO20, GPIO21, GPIO36 and GPIO38 do not exist on this device. GPIO61 to GPIO63 exist but are
not pinned out on any packages. Boot ROM enables pullups on GPIO61 to GPIO63. For more details,
see 节6.5.
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TMS320F280025, TMS320F280025-Q1
TMS320F280025C, TMS320F280025C-Q1, TMS320F280023, TMS320F280023-Q1
TMS320F280023C, TMS320F280021, TMS320F280021-Q1
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ZHCSL01B –MARCH 2020 –REVISED DECEMBER 2020
6.4.1.1 GPIO Muxed Pins Table
表6-6. GPIO Muxed Pins
0, 4, 8, 12
GPIO0
1
2
3
5
6
7
9
10
11
13
14
15
ALT
CLB_OUTPUTX
BAR8
EPWM1_A
I2CA_SDA
SPIA_STE
FSIRXA_CLK
HIC_BASESEL1
CLB_OUTPUTX
BAR7
FSITXA_TDM_D
1
GPIO1
EPWM1_B
I2CA_SCL
SPIA_SOMI
HIC_A2
HIC_D10
GPIO2
GPIO3
EPWM2_A
EPWM2_B
OUTPUTXBAR1 PMBUSA_SDA
SPIA_SIMO
SPIA_CLK
SCIA_TX
SCIA_RX
FSIRXA_D1
FSIRXA_D0
I2CB_SDA
I2CB_SCL
HIC_A1
CANA_TX
CANA_RX
HIC_D9
HIC_D4
OUTPUTXBAR2
OUTPUTXBAR4
OUTPUTXBAR2
OUTPUTXBAR3
PMBUSA_SCL
CANA_TX
HIC_NOE
EQEP2_STROB
E
CLB_OUTPUTX
BAR6
GPIO4
GPIO5
GPIO6
GPIO7
EPWM3_A
EPWM3_B
EPWM4_A
EPWM4_B
SPIB_CLK
SPIA_STE
SPIB_SOMI
SPIB_SIMO
FSIRXA_CLK
HIC_BASESEL2
HIC_A7
HIC_NWE
HIC_D15
HIC_D14
HIC_D14
CLB_OUTPUTX
BAR5
OUTPUTXBAR3
SYNCOUT
CANA_RX
FSITXA_D1
FSITXA_D0
FSITXA_CLK
I2CA_SCL
HIC_D4
CLB_OUTPUTX
BAR8
EQEP1_A
EQEP1_B
FSITXA_D1
HIC_NBE1
HIC_A6
CLB_OUTPUTX
BAR2
OUTPUTXBAR5
ADCSOCAO
EQEP1_STROB
E
CLB_OUTPUTX
BAR5
FSITXA_TDM_C
LK
GPIO8
EPWM5_A
EPWM5_B
EPWM6_A
EPWM6_B
EPWM7_A
SCIA_TX
SCIA_RX
SPIA_SIMO
SPIA_CLK
FSITXA_D1
FSITXA_D0
FSITXA_CLK
LINB_RX
HIC_A0
HIC_BASESEL0
HIC_NWE
HIC_D8
GPIO9
OUTPUTXBAR6 EQEP1_INDEX
LINB_RX
LINB_TX
I2CB_SCL
HIC_NRDY
FSITXA_TDM_D
0
GPIO10
GPIO11
GPIO12
ADCSOCBO
EQEP1_A
EQEP1_B
SPIA_SOMI
SPIA_STE
I2CA_SDA
FSIRXA_D1
FSIRXA_D0
OUTPUTXBAR7
EQEP2_A
SPIA_CLK
SPIA_SIMO
CANA_RX
HIC_D6
HIC_NBE0
HIC_INT
EQEP1_STROB
E
PMBUSA_CTL
LINB_TX
HIC_D13
PMBUSA_ALER
T
GPIO13
GPIO14
GPIO15
EPWM7_B
EQEP1_INDEX
I2CB_SDA
FSIRXA_CLK
SPIB_CLK
SPIB_STE
LINB_RX
EQEP2_A
EQEP2_B
SPIA_SOMI
LINB_TX
CANA_TX
EPWM3_A
EPWM3_B
EQEP2_B
HIC_D11
HIC_D5
HIC_D15
HIC_D12
CLB_OUTPUTX
BAR7
OUTPUTXBAR3 PMBUSA_SDA
CLB_OUTPUTX
BAR6
I2CB_SCL
OUTPUTXBAR4
PMBUSA_SCL
LINB_RX
EQEP1_STROB
E
GPIO16
SPIA_SIMO
SPIA_SOMI
SPIA_CLK
OUTPUTXBAR7
OUTPUTXBAR8
CANA_RX
EPWM5_A
EPWM5_B
EPWM6_A
SCIA_TX
SCIA_RX
I2CA_SCL
PMBUSA_SCL
PMBUSA_SDA
PMBUSA_CTL
XCLKOUT
CANA_TX
XCLKOUT
SPIB_SOMI
HIC_D1
HIC_D2
HIC_INT
GPIO17
EQEP1_INDEX
EQEP2_A
FSITXA_TDM_C
LK
GPIO18_X2
LINB_TX
LINB_RX
HIC_A5
X2
X1
PMBUSA_ALER CLB_OUTPUTX
FSITXA_TDM_D
0
GPIO19_X1
GPIO22
SPIA_STE
CANA_TX
EPWM6_B
I2CA_SDA
SPIB_CLK
EQEP2_B
LINA_TX
HIC_NBE0
HIC_D13
T
BAR1
EQEP1_STROB
E
CLB_OUTPUTX
BAR1
LINB_TX
EPWM4_A
EPWM4_B
GPIO23
GPIO24
GPIO25
GPIO26
EQEP1_INDEX
OUTPUTXBAR1
OUTPUTXBAR2
SPIB_STE
SPIB_SIMO
SPIB_SOMI
SPIB_CLK
LINA_RX
LINB_TX
LINB_RX
SCIA_TX
SCIA_RX
I2CA_SDA
HIC_A3
HIC_D11
HIC_D3
EQEP2_A
EQEP2_B
PMBUSA_SCL
PMBUSA_SDA
PMBUSA_CTL
ERRORSTS
EQEP1_A
FSITXA_D1
FSITXA_D0
HIC_BASESEL0
HIC_D0
OUTPUTXBAR3 EQEP2_INDEX
OUTPUTXBAR3
HIC_A1
HIC_A4
EQEP2_STROB
PMBUSA_ALER
T
GPIO27
OUTPUTXBAR4
E
OUTPUTXBAR4
SPIB_STE
FSITXA_CLK
I2CA_SCL
HIC_D1
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TMS320F280025, TMS320F280025-Q1
TMS320F280025C, TMS320F280025C-Q1, TMS320F280023, TMS320F280023-Q1
TMS320F280023C, TMS320F280021, TMS320F280021-Q1
ZHCSL01B –MARCH 2020 –REVISED DECEMBER 2020
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表6-6. GPIO Muxed Pins (continued)
0, 4, 8, 12
GPIO28
1
2
3
5
6
7
9
10
11
13
14
15
ALT
EQEP2_STROB
E
SCIA_RX
SCIA_TX
CANA_RX
EPWM7_A
EPWM7_B
SPIB_SIMO
OUTPUTXBAR5
OUTPUTXBAR6
OUTPUTXBAR7
EQEP1_A
EQEP1_B
LINA_TX
LINA_RX
SPIB_CLK
SPIB_STE
EPWM1_A
EPWM1_B
ERRORSTS
ERRORSTS
I2CB_SDA
I2CB_SCL
HIC_D8
HIC_NOE
HIC_NCS
GPIO29
EQEP2_INDEX
FSIRXA_CLK
EQEP1_STROB
E
GPIO30
GPIO31
GPIO32
GPIO33
GPIO34
GPIO35
CANA_TX
I2CA_SDA
SPIB_SOMI
SPIB_CLK
SPIB_STE
OUTPUTXBAR8 EQEP1_INDEX
LINA_TX
FSIRXA_D1
FSIRXA_D0
FSIRXA_CLK
HIC_D10
CANA_TX
CANA_RX
ADCSOCBO
ADCSOCAO
HIC_NBE1
HIC_INT
HIC_D0
HIC_D9
TDI
I2CA_SCL
OUTPUTXBAR4
LINA_RX
EQEP2_B
OUTPUTXBAR1
SCIA_RX
PMBUSA_SDA
PMBUSA_SCL
I2CB_SDA
HIC_NWE
I2CA_SDA
I2CA_SCL
CANA_RX
SCIA_TX
LINA_RX
LINA_TX
EQEP1_A
EQEP1_B
PMBUSA_CTL
PMBUSA_ALER
T
GPIO37
GPIO39
OUTPUTXBAR2
CANA_TX
HIC_NRDY
TDO
CLB_OUTPUTX
BAR2
FSIRXA_CLK
EQEP2_INDEX
SYNCOUT
HIC_A4
EQEP1_INDEX
HIC_D7
GPIO40
GPIO41
SPIB_SIMO
EPWM2_B
EPWM2_A
PMBUSA_SDA
PMBUSA_SCL
FSIRXA_D0
FSIRXA_D1
EQEP1_A
EQEP1_B
LINB_TX
LINB_RX
HIC_NBE1
HIC_D5
SPIB_SOMI
HIC_D12
EQEP1_STROB CLB_OUTPUTX
GPIO42
GPIO43
GPIO44
GPIO45
LINA_RX
OUTPUTXBAR5
OUTPUTXBAR6
OUTPUTXBAR7
PMBUSA_CTL
I2CA_SDA
I2CA_SCL
HIC_D2
HIC_D3
HIC_A6
HIC_A7
HIC_D5
E
BAR3
PMBUSA_ALER
T
CLB_OUTPUTX
BAR4
EQEP1_INDEX
CLB_OUTPUTX
BAR3
EQEP1_A
FSITXA_CLK
HIC_D7
CLB_OUTPUTX
BAR4
OUTPUTXBAR8
LINA_TX
FSITXA_D0
FSITXA_D1
HIC_D6
GPIO46
GPIO61
GPIO62
GPIO63
AIO224
AIO225
AIO226
AIO227
AIO228
AIO230
AIO231
AIO232
AIO233
AIO237
AIO238
AIO239
AIO241
AIO242
HIC_NWE
HIC_A3
HIC_NWE
HIC_A1
HIC_NBE0
HIC_A0
HIC_BASESEL2
HIC_BASESEL1
HIC_BASESEL0
HIC_A4
HIC_A6
HIC_NCS
HIC_A5
HIC_NBE1
HIC_A2
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TMS320F280025, TMS320F280025-Q1
TMS320F280025C, TMS320F280025C-Q1, TMS320F280023, TMS320F280023-Q1
TMS320F280023C, TMS320F280021, TMS320F280021-Q1
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ZHCSL01B –MARCH 2020 –REVISED DECEMBER 2020
表6-6. GPIO Muxed Pins (continued)
0, 4, 8, 12
AIO244
1
2
3
5
6
7
9
10
11
13
14
15
ALT
HIC_A7
HIC_NOE
AIO245
Note
The analog pins that contain AIOs are in analog mode by default. AIO mode is enabled by configuring the AMSEL option of GPIOH for the
analog pin. In addition, if using the HIC mux options on the AIO pins, an external pullup is required.
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TMS320F280023C TMS320F280021 TMS320F280021-Q1
TMS320F280025, TMS320F280025-Q1
TMS320F280025C, TMS320F280025C-Q1, TMS320F280023, TMS320F280023-Q1
TMS320F280023C, TMS320F280021, TMS320F280021-Q1
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6.4.2 Digital Inputs on ADC Pins (AIOs)
GPIOs on port H (GPIO224–GPIO245) are multiplexed with analog pins. These are also referred to as AIOs.
These pins can only function in input mode. By default, these pins will function as analog pins and the GPIOs
are in a high-Z state. The GPHAMSEL register is used to configure these pins for digital or analog operation.
Note
If digital signals with sharp edges (high dv/dt) are connected to the AIOs, cross-talk can occur with
adjacent analog signals. The user should therefore limit the edge rate of signals connected to AIOs if
adjacent channels are being used for analog functions.
6.4.3 GPIO Input X-BAR
The Input X-BAR is used to route signals from a GPIO to many different IP blocks such as the ADCs, eCAPs,
ePWMs, and external interrupts (see 图6-4). 表6-7 lists the input X-BAR destinations. For details on configuring
the Input X-BAR, see the Crossbar (X-BAR) chapter of the TMS320F28002x Real-Time Microcontrollers
Technical Reference Manual.
GPIO0
Asynchronous
Synchronous
Sync. + Qual.
Input X-BAR
Other Sources
127:16
GPIOx
eCAP
Modules
15:0
INPUT[16:1]
DCCx Clock Source-1
DCCx Clock Source-0
TZ1,TRIP1
TZ2,TRIP2
TZ3,TRIP3
TRIP6
XINT1
TRIP4
TRIP5
XINT2
XINT3
XINT4
XINT5
ePWM
Modules
CPU PIE
TRIP7
TRIP8
TRIP9
TRIP10
TRIP11
TRIP12
ePWM
X-BAR
Other
Sources
ADCEXTSOC
Other Sources
ADC
EXTSYNCIN1
EXTSYNCIN2
ePWM and eCAP
Sync Scheme
Output X-BAR
图6-4. Input X-BAR
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TMS320F280025, TMS320F280025-Q1
TMS320F280025C, TMS320F280025C-Q1, TMS320F280023, TMS320F280023-Q1
TMS320F280023C, TMS320F280021, TMS320F280021-Q1
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表6-7. Input X-BAR Destinations
INPUT
ECAP / HRCAP
EPWM X-BAR
CLB X-BAR
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes Yes Yes Yes Yes Yes
Yes Yes Yes Yes Yes Yes
Yes Yes Yes Yes Yes Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
OUTPUT X-BAR
CPU XINT
Yes
XINT1 XINT2
XINT3
XINT4 XINT5
TZ1, TZ2, TZ3,
TRIP1 TRIP2 TRIP3
EPWM TRIP
TRIP6
ADC START OF
CONVERSION
ADCEX
TSOC
EPWM / ECAP
SYNC
EXTSY EXTSY
NCIN1 NCIN2
DCCx
CLK1 CLK0
6.4.4 GPIO Output X-BAR, CLB X-BAR, CLB Output X-BAR, and ePWM X-BAR
The Output X-BAR has eight outputs that can be selected on the GPIO mux as OUTPUTXBARx. The CLB X-
BAR has eight outputs that are connected to the CLB global mux as AUXSIGx. The CLB Output X-BAR has
eight outputs that can be selected on the GPIO mux as CLB_OUTPUTXBARx. The ePWM X-BAR has eight
outputs that are connected to the TRIPx inputs of the ePWM. The sources for the Output X-BAR, CLB X-BAR,
CLB Output X-BAR, and ePWM X-BAR are shown in 图6-5. For details on the Output X-BAR, CLB X-BAR, CLB
Output X-BAR, and ePWM X-BAR, see the Crossbar (X-BAR) chapter of the TMS320F28002x Real-Time
Microcontrollers Technical Reference Manual.
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TMS320F280025, TMS320F280025-Q1
TMS320F280025C, TMS320F280025C-Q1, TMS320F280023, TMS320F280023-Q1
TMS320F280023C, TMS320F280021, TMS320F280021-Q1
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CTRIPOUTH
CTRIPOUTL
(Output X-BAR only)
CMPSSx
CTRIPH
CTRIPL
(ePWM X-BAR only)
ePWM and eCAP
EXTSYNCOUT
Sync Chain
AUXSIG1
AUXSIG2
AUXSIG3
AUXSIG4
AUXSIG5
AUXSIG6
AUXSIG7
AUXSIG8
CLB
Global
Mux
ADCSOCA0
Select Circuit
CLB
X-BAR
ADCSOCA0
ADCSOCB0
Select Circuit
ADCSOCB0
ECAPxOUT
TRIP4
TRIP5
eCAPx
ADCx
EVT1
EVT2
EVT3
EVT4
All
ePWM
Modules
TRIP7
TRIP8
TRIP9
TRIP10
TRIP11
TRIP12
EPWM
X-BAR
INPUT1-6
INPUT7-14
(ePWM X-BAR only)
Input X-BAR
eQEPx
OUTPUTXBAR1
OUTPUTXBAR2
OUTPUTXBAR3
OUTPUTXBAR4
OUTPUTXBAR5
OUTPUTXBAR6
OUTPUTXBAR7
OUTPUTXBAR8
Output
X-BAR
GPIO
Mux
X-BAR Flags
(shared)
CLB_OUTPUTXBAR1
CLB_OUTPUTXBAR2
CLB_OUTPUTXBAR3
CLB_OUTPUTXBAR4
CLB_OUTPUTXBAR5
CLB_OUTPUTXBAR6
CLB_OUTPUTXBAR7
CLB_OUTPUTXBAR8
CLB
Output
X-BAR
CLB Input X-BAR
CLB TILEx
图6-5. Output X-BAR, CLB X-BAR, CLB Output X-BAR, and ePWM X-BAR Sources
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TMS320F280025, TMS320F280025-Q1
TMS320F280025C, TMS320F280025C-Q1, TMS320F280023, TMS320F280023-Q1
TMS320F280023C, TMS320F280021, TMS320F280021-Q1
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6.5 Pins With Internal Pullup and Pulldown
Some pins on the device have internal pullups or pulldowns. 表 6-8 lists the pull direction and when it is active.
The pullups on GPIO pins are disabled by default and can be enabled through software. To avoid any floating
unbonded inputs, the Boot ROM will enable internal pullups on GPIO pins that are not bonded out in a particular
package. Other pins noted in 表6-8 with pullups and pulldowns are always on and cannot be disabled.
表6-8. Pins With Internal Pullup and Pulldown
RESET
(XRSn = 0)
PIN
DEVICE BOOT
APPLICATION
GPIOx
Pullup disabled
Pullup disabled(1)
Application defined
Application defined
Application defined
GPIO35/TDI
GPIO37/TDO
TCK
Pullup disabled
Pullup disabled
Pullup active
Pullup active
Pullup active
TMS
XRSn
Other pins (including AIOs)
No pullup or pulldown present
(1) Pins not bonded out in a given package will have the internal pullups enabled by the Boot ROM.
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TMS320F280025, TMS320F280025-Q1
TMS320F280025C, TMS320F280025C-Q1, TMS320F280023, TMS320F280023-Q1
TMS320F280023C, TMS320F280021, TMS320F280021-Q1
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6.6 Connections for Unused Pins
For applications that do not need to use all functions of the device, 表 6-9 lists acceptable conditioning for any
unused pins. When multiple options are listed in 表 6-9, any option is acceptable. Pins not listed in 表 6-9 must
be connected according to 节6.
表6-9. Connections for Unused Pins
SIGNAL NAME
ACCEPTABLE PRACTICE
ANALOG
VREFHI
VREFLO
Tie to VDDA (applies only if ADC is not used in the application)
Tie to VSSA
•
•
•
No Connect
Tie to VSSA
Analog input pins
Tie to VSSA through resistor
DIGITAL
•
•
No Connect
FLT1 (Flash Test pin 1)
FLT2 (Flash Test pin 2)
Tie to VSS through 4.7-kΩor larger resistor
•
•
No Connect
Tie to VSS through 4.7-kΩor larger resistor
•
•
•
No connection (input mode with internal pullup enabled)
No connection (output mode with internal pullup disabled)
GPIOx
Pullup or pulldown resistor (any value resistor, input mode, and with internal pullup disabled)
When TDI mux option is selected (default), the GPIO is in Input mode.
•
•
Internal pullup enabled
External pullup resistor
GPIO35/TDI
When TDO mux option is selected (default), the GPIO is in Output mode only during JTAG activity;
otherwise, it is in a tri-state condition. The pin must be biased to avoid extra current on the input buffer.
GPIO37/TDO
•
•
Internal pullup enabled
External pullup resistor
•
•
No Connect
TCK
TMS
Pullup resistor
Pullup resistor
Turn XTAL off and:
•
•
•
Input mode with internal pullup enabled
GPIO19/X1
GPIO18/X2
Input mode with external pullup or pulldown resistor
Output mode with internal pullup disabled
Turn XTAL off and:
•
•
•
Input mode with internal pullup enabled
Input mode with external pullup or pulldown resistor
Output mode with internal pullup disabled
POWER AND GROUND
VDD
All VDD pins must be connected per 节6.3. Pins should not be used to bias any external circuits.
If a dedicated analog supply is not used, tie to VDDIO.
VDDA
VDDIO
VSS
All VDDIO pins must be connected per 节6.3.
All VSS pins must be connected to board ground.
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TMS320F280025, TMS320F280025-Q1
TMS320F280025C, TMS320F280025C-Q1, TMS320F280023, TMS320F280023-Q1
TMS320F280023C, TMS320F280021, TMS320F280021-Q1
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表6-9. Connections for Unused Pins (continued)
ACCEPTABLE PRACTICE
SIGNAL NAME
VSSA
If an analog ground is not used, tie to VSS.
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TMS320F280025, TMS320F280025-Q1
TMS320F280025C, TMS320F280025C-Q1, TMS320F280023, TMS320F280023-Q1
TMS320F280023C, TMS320F280021, TMS320F280021-Q1
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7 Specifications
Stresses beyond those listed under Absolute Maximum Ratings may cause permanent damage to the device.
These are stress ratings only and functional operation of the device beyond the Recommended Operating
Conditions is not implied. Exposure to absolute-maximum-rated conditions for extended periods may affect
device reliability. All voltage values are with respect to VSS, unless otherwise noted.
7.1 Absolute Maximum Ratings
over operating free-air temperature range (unless otherwise noted)
MIN
–0.3
–0.3
–0.3
–0.3
MAX
4.6
UNIT
VDDIO with respect to VSS
VDDA with respect to VSSA
VIN (3.3 V)
Supply voltage
V
4.6
Input voltage
4.6
V
V
Output voltage
VO
4.6
Digital/analog input (per pin), IIK (VIN < VSS/VSSA or VIN
VDDIO/VDDA)(2)
>
20
20
–20
–20
Input clamp current
mA
Total for all inputs, IIKTOTAL
(VIN < VSS/VSSA or VIN > VDDIO/VDDA)
Output current
Digital output (per pin), IOUT
20
125
150
150
mA
°C
°C
°C
–20
–40
–40
–65
Free-Air temperature
Operating junction temperature
Storage temperature(1)
TA
TJ
Tstg
(1) Long-term high-temperature storage or extended use at maximum temperature conditions may result in a reduction of overall device
life. For additional information, see the Semiconductor and IC Package Thermal Metrics Application Report.
(2) Continuous clamp current per pin is ±2 mA. Do not operate in this condition continuously as VDDIO/VDDA voltage may internally rise and
impact other electrical specifications.
7.2 ESD Ratings –Commercial
VALUE
UNIT
F280025, F280025C, F280023, F280023C in 80-pin PN package
Human-body model (HBM), per ANSI/ESDA/JEDEC
±2000
±500
JS-001(1)
Electrostatic discharge
(ESD)
V(ESD)
V
Charged-device model (CDM), per JEDEC specification
JESD22-C101 or ANSI/ESDA/JEDEC JS-002(2)
F280025, F280025C, F280023, F280023C in 64-pin PM package
Human-body model (HBM), per ANSI/ESDA/JEDEC
±2000
±500
JS-001(1)
Electrostatic discharge
(ESD)
V(ESD)
V
V
Charged-device model (CDM), per JEDEC specification
JESD22-C101 or ANSI/ESDA/JEDEC JS-002(2)
F280025, F280025C, F280023, F280023C, F280021 in 48-pin PT package
Human-body model (HBM), per ANSI/ESDA/JEDEC
±2000
±500
JS-001(1)
Electrostatic discharge
(ESD)
V(ESD)
Charged-device model (CDM), per JEDEC specification
JESD22-C101 or ANSI/ESDA/JEDEC JS-002(2)
(1) JEDEC document JEP155 states that 500-V HBM allows safe manufacturing with a standard ESD control process.
(2) JEDEC document JEP157 states that 250-V CDM allows safe manufacturing with a standard ESD control process.
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TMS320F280025, TMS320F280025-Q1
TMS320F280025C, TMS320F280025C-Q1, TMS320F280023, TMS320F280023-Q1
TMS320F280023C, TMS320F280021, TMS320F280021-Q1
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7.3 ESD Ratings –Automotive
VALUE
UNIT
F280025-Q1, F280025C-Q1, F280023-Q1 in 80-pin PN package
Human body model (HBM), per
All pins
All pins
±2000
AEC Q100-002(1)
V(ESD)
Electrostatic discharge
Charged device model (CDM),
per AEC Q100-011
±500
±750
V
Corner pins on 80-pin PN:
1, 20, 21, 40, 41, 60, 61, 80
F280025-Q1, F280025C-Q1, F280023-Q1 in 64-pin PM package
Human body model (HBM), per
All pins
All pins
±2000
AEC Q100-002(1)
V(ESD)
Electrostatic discharge
Charged device model (CDM),
per AEC Q100-011
±500
±750
V
V
Corner pins on 64-pin PM:
1, 16, 17, 32, 33, 48, 49, 64
F280025-Q1, F280025C-Q1, F280023-Q1, F280021-Q1 in 48-pin PT package
Human body model (HBM), per
AEC Q100-002(1)
All pins
All pins
±2000
V(ESD)
Electrostatic discharge
Charged device model (CDM),
per AEC Q100-011
±500
±750
Corner pins on 48-pin PT:
1, 12, 13, 24, 25, 36, 37, 48
(1) AEC Q100-002 indicates HBM stressing is done in accordance with the ANSI/ESDA/JEDEC JS-001 specification.
7.4 Recommended Operating Conditions
MIN
NOM
3.3
3.3
0
MAX UNIT
Internal BOR enabled(3)
Internal BOR disabled
VBOR-VDDIO(MAX) + VBOR-GB
3.63
V
3.63
(2)
Device supply voltage, VDDIO and
VDDA
2.8
Device ground, VSS
Analog ground, VSSA
V
V
0
Supply ramp rate of VDDIO,
VDDA with respect to VSS.(4)
SRSUPPLY
20
100 mV/us
10 ms
VDDIO supply ramp time from
1 V to VBOR-VDDIO(MAX)
tVDDIO-RAMP
Digital input voltage
Analog input voltage
VDDIO BOR guard band(5)
S version(1)
VDDIO + 0.3
VDDA + 0.3
V
V
V
VSS –0.3
VIN
VSSA –0.3
VBOR-GB
0.1
Junction temperature, TJ
125 °C
125 °C
–40
–40
Q version(1)
(AEC Q100 qualification)
Free-Air temperature, TA
(1) Operation above TJ = 105°C for extended duration will reduce the lifetime of the device. See Calculating Useful Lifetimes of Embedded
Processors for more information.
(2) The VDDIO BOR voltage (VBOR-VDDIO[MAX]) in Electrical Characteristics table determines the lower voltage bound for device
operation. TI recommends that system designers budget an additional guard band (VBOR-GB) as shown in Supply Voltages figure.
(3) Internal BOR is enabled by default.
(4) Supply ramp rate faster than this can trigger the on-chip ESD protection.
(5) TI recommends VBOR-GB to avoid BOR resets due to normal supply noise or load-transient events on the 3.3-V VDDIO system
regulator. Good system regulator design and decoupling capacitance (following the system regulator specifications) are important to
prevent activation of the BOR during normal device operation. The value of VBOR-GB is a system-level design consideration; the voltage
listed here is typical for many applications.
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TMS320F280025, TMS320F280025-Q1
TMS320F280025C, TMS320F280025C-Q1, TMS320F280023, TMS320F280023-Q1
TMS320F280023C, TMS320F280021, TMS320F280021-Q1
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Supply Voltages
3.63 V
+10%
Recommended
System Voltage
Regulator Range
3.3 V
0%
F28002x
VDDIO
Operating
Range
3.1 V
3.0 V
–6.1%
–9.1%
VBOR-GB
BOR Guard Band
VBOR-VDDIO
Internal BOR Threshold
–14.8%
–15.1%
2.81 V
2.80 V
图7-1. Supply Voltages
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TMS320F280025, TMS320F280025-Q1
TMS320F280025C, TMS320F280025C-Q1, TMS320F280023, TMS320F280023-Q1
TMS320F280023C, TMS320F280021, TMS320F280021-Q1
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7.5 Power Consumption Summary
Current values listed in this section are representative for the test conditions given and not the absolute
maximum possible. The actual device currents in an application will vary with application code and pin
configurations. 节7.5.1 lists the system current consumption values.
7.5.1 System Current Consumption
over operating free-air temperature range (unless otherwise noted).
TYP : Vnom, 30℃
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
OPERATING MODE
VDDIO current consumption during
operational usage
This is an estimation of current
for a typical heavily loaded
application. Actual currents will
vary depending on system
activity, I/O electrical loading and
switching frequency.
IDDIO
35
3
72
5
mA
mA
VDDA current consumption during
operational usage
IDDA
IDLE MODE
VDDIO current consumption while
device is in Idle mode
- CPU is in IDLE mode
IDDIO
16
33
mA
mA
- Flash is powered down
- XCLKOUT is turned off
- Pull up is enabled for IO pins
VDDA current consumption while
device is in Idle mode
IDDA
0.01
0.1
STANDBY MODE
VDDIO current consumption while
device is in Standby mode
- CPU is in STANDBY mode
- Flash is powered down
- XCLKOUT is turned off
- Pull up is enabled for IO pins
IDDIO
8
22
mA
mA
VDDA current consumption while
device is in Standby mode
IDDA
0.01
0.1
HALT MODE
IDDIO
VDDIO current consumption while
device is in Halt mode
- CPU is in HALT mode
- Flash is powered down
- XCLKOUT is turned off
- Pull up is enabled for IO pins
1
16
mA
mA
VDDA current consumption while
device is in Halt mode
IDDA
0.01
0.1
FLASH ERASE/PROGRAM
VDDIO current consumption during
- CPU is running from RAM.
- SYSCLK at 100 MHz.
- I/Os are inputs with pullups
enabled.
IDDIO
72
106
2.5
mA
mA
Erase/Program cycle(1)
VDDA current consumption during
Erase/Program cycle
- Peripheral clocks are turned off.
IDDA
0.1
RESET MODE
VDDIO current consumption while
reset is active(2)
IDDIO
8.6
0.1
mA
mA
VDDA current consumption while reset
is active(2)
IDDA
(1) Brownout events during flash programming can corrupt flash data and permanently lock the device. Programming environments using
alternate power sources (such as a USB programmer) must be capable of supplying the rated current for the device and other system
components with sufficient margin to avoid supply brownout conditions.
(2) This is the current consumption while reset is active, i.e XRSn is low.
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TMS320F280025, TMS320F280025-Q1
TMS320F280025C, TMS320F280025C-Q1, TMS320F280023, TMS320F280023-Q1
TMS320F280023C, TMS320F280021, TMS320F280021-Q1
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7.5.2 Operating Mode Test Description
节 7.5.1 and 节 7.5.4.1 list the current consumption values for the operational mode of the device. The
operational mode provides an estimation of what an application might encounter. The test condition for these
measurements has the following properties:
• Code is executing from RAM.
• FLASH is read and kept in active state.
• No external components are driven by I/O pins.
• All peripherals have clocks enabled.
• All CPUs are actively executing code.
• All analog peripherals are powered up. ADCs and DACs are periodically converting.
7.5.3 Current Consumption Graphs
图 7-2, 图 7-3, 图 7-4, 图 7-5, and 图 7-6 show a typical representation of the relationship between frequency,
temperature, core supply, and current consumption on the device. Actual results will vary based on the system
implementation and conditions.
图 7-3 shows the typical operating current profile across temperature and core supply voltage. 图 7-4 shows the
typical idle current profile across temperature and core supply voltage. 图 7-5 shows the typical standby current
profile across temperature and core supply voltage. 图 7-6 shows the typical halt current profile across
temperature and core supply voltage.
图7-2. Operating Current Versus Frequency
图7-3. Operating Current Versus Temperature
图7-4. Current Versus Temperature –
图7-5. Current Versus Temperature –STANDBY
IDLE Mode
Mode
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图7-6. Current Versus Temperature –HALT Mode
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7.5.4 Reducing Current Consumption
The F28002x devices provide some methods to reduce the device current consumption:
• One of the two low-power modes—IDLE or STANDBY—could be entered during idle periods in the
application.
• The flash module may be powered down if the code is run from RAM.
• Disable the pullups on pins that assume an output function.
• Each peripheral has an individual clock-enable bit (PCLKCRx). Reduced current consumption may be
achieved by turning off the clock to any peripheral that is not used in a given application. 节7.5.4.1 lists the
typical current reduction that may be achieved by disabling the clocks using the PCLKCRx register.
• To realize the lowest VDDA current consumption in an LPM, see the Analog-to-Digital Converter (ADC)
chapter of the TMS320F28002x Real-Time Microcontrollers Technical Reference Manual to ensure each
module is powered down as well.
7.5.4.1 Typical Current Reduction per Disabled Peripheral
PERIPHERAL
IDDIO CURRENT REDUCTION (mA)
ADC(1)
BGCRC
CAN
0.67
0.26
1.18
1.18
0.34
0.02
0.01
0.18
0.56
0.22
0.28
0.78
0.11
0.74
0.21
0.87
0.24
0.32
0.19
0.26
0.16
0.08
CLB
CMPSS(1)
CPU TIMER
CPUCRC
DCC
DMA
eCAP1 and eCAP2
eCAP3(2)
ePWM
eQEP
FSI
HIC
HRPWM
I2C
LIN
PBIST
PMBUS
SCI
SPI
(1) This current represents the current drawn by the digital portion of the each module.
(2) eCAP3 can also be configured as HRCAP.
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7.6 Electrical Characteristics
over recommended operating conditions (unless otherwise noted)
TEST
CONDITIONS
PARAMETER
MIN
TYP
MAX UNIT
Digital and Analog IO
VOH High-level output voltage
IOH = IOH MIN
IOH = –100 μA
IOL = IOL MAX
IOL = 100 µA
VDDIO * 0.8
V
VDDIO –0.2
0.4
V
VOL
Low-level output voltage
0.2
IOH
High-level output source current for all output pins
Low-level output sink current for all output pins
High-level output impedance for all output pins
Low-level output impedance for all output pins
High-level input voltage
mA
–4
IOL
4
100
90
mA
ROH
45
45
65
60
Ω
Ω
ROL
VIH
2.0
V
VIL
Low-level input voltage
0.8
V
VHYSTERESIS
Input hysteresis
125
mV
VDDIO = 3.3 V
VIN = VDDIO
IPULLDOWN
IPULLUP
Input current
Input current
Pins with pulldown
120
160
µA
µA
Digital inputs with pullup VDDIO = 3.3 V
enabled(1)
VIN = 0 V
Pullups and outputs
disabled
0 V ≤VIN ≤
VDDIO
Digital inputs
0.1
ILEAK
Pin leakage
µA
Analog pins (except
ADCINA3/VDAC)
Analog drivers
disabled
0 V ≤VIN ≤VDDA
0.1
11
ADCINA3/VDAC
Digital inputs
2
2
CI
Input capacitance
pF
V
Analog pins(2)
VREG and BOR
VDDIO power on reset VDDIO power on reset
voltage voltage
VPOR-VDDIO
2.3
1.2
VBOR-VDDIO
VVREG
VDDIO brown out reset voltage(3)
2.81
1.14
3.0
V
V
Internal voltage regulator output
1.32
(1) See Pins With Internal Pullup and Pulldown table for a list of pins with a pullup or pulldown.
(2) The analog pins are specified separately; see Per-Channel Parasitic Capacitance table.
(3) See the Supply Voltages figure in the Recommended Operating Conditions section.
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7.7 Thermal Resistance Characteristics for PN Package
°C/W(1)
14.2
21.9
49.9
38.3
36.7
34.4
0.8
AIR FLOW (lfm)(2)
Junction-to-case thermal resistance
Junction-to-board thermal resistance
N/A
N/A
0
RΘJC
RΘJB
150
250
500
0
Junction-to-free air thermal resistance
Junction-to-package top
RΘJA (High k PCB)
1.18
1.34
1.62
21.6
20.7
20.5
20.1
150
250
500
0
PsiJT
150
250
500
PsiJB
Junction-to-board
(1) These values are based on a JEDEC-defined 2S2P system (with the exception of the Theta JC [RΘJC] value, which is based on a
JEDEC-defined 1S0P system) and will change based on environment as well as application. For more information, see these EIA/
JEDEC standards:
•
•
•
•
JESD51-2, Integrated Circuits Thermal Test Method Environmental Conditions - Natural Convection (Still Air)
JESD51-3, Low Effective Thermal Conductivity Test Board for Leaded Surface Mount Packages
JESD51-7, High Effective Thermal Conductivity Test Board for Leaded Surface Mount Packages
JESD51-9, Test Boards for Area Array Surface Mount Package Thermal Measurements
(2) lfm = linear feet per minute
7.8 Thermal Resistance Characteristics for PM Package
°C/W(1)
12.4
25.6
51.8
42.2
39.4
36.5
0.5
AIR FLOW (lfm)(2)
Junction-to-case thermal resistance
Junction-to-board thermal resistance
Junction-to-free air thermal resistance
N/A
N/A
0
RΘJC
RΘJB
RΘJA (High k PCB)
150
250
500
0
Junction-to-moving air thermal resistance
RΘJMA
0.9
150
250
500
0
PsiJT
Junction-to-package top
1.1
1.4
25.1
23.8
23.4
22.7
150
250
500
PsiJB
Junction-to-board
(1) These values are based on a JEDEC-defined 2S2P system (with the exception of the Theta JC [RΘJC] value, which is based on a
JEDEC-defined 1S0P system) and will change based on environment as well as application. For more information, see these EIA/
JEDEC standards:
•
•
•
•
JESD51-2, Integrated Circuits Thermal Test Method Environmental Conditions - Natural Convection (Still Air)
JESD51-3, Low Effective Thermal Conductivity Test Board for Leaded Surface Mount Packages
JESD51-7, High Effective Thermal Conductivity Test Board for Leaded Surface Mount Packages
JESD51-9, Test Boards for Area Array Surface Mount Package Thermal Measurements
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(2) lfm = linear feet per minute
7.9 Thermal Resistance Characteristics for PT Package
°C/W(1)
13.6
30.6
64
AIR FLOW (lfm)(2)
Junction-to-case thermal resistance
Junction-to-board thermal resistance
N/A
N/A
0
RΘJC
RΘJB
50.4
48.2
45
150
250
500
0
Junction-to-free air thermal resistance
Junction-to-package top
RΘJA (High k PCB)
0.56
0.94
1.1
150
250
500
0
PsiJT
1.38
30.1
28.7
28.4
28
150
250
500
PsiJB
Junction-to-board
(1) These values are based on a JEDEC-defined 2S2P system (with the exception of the Theta JC [RΘJC] value, which is based on a
JEDEC-defined 1S0P system) and will change based on environment as well as application. For more information, see these EIA/
JEDEC standards:
•
•
•
•
JESD51-2, Integrated Circuits Thermal Test Method Environmental Conditions - Natural Convection (Still Air)
JESD51-3, Low Effective Thermal Conductivity Test Board for Leaded Surface Mount Packages
JESD51-7, High Effective Thermal Conductivity Test Board for Leaded Surface Mount Packages
JESD51-9, Test Boards for Area Array Surface Mount Package Thermal Measurements
(2) lfm = linear feet per minute
7.10 Thermal Design Considerations
Based on the end application design and operational profile, the IDD and IDDIO currents could vary. Systems that
exceed the recommended maximum power dissipation in the end product may require additional thermal
enhancements. Ambient temperature (TA) varies with the end application and product design. The critical factor
that affects reliability and functionality is TJ, the junction temperature, not the ambient temperature. Hence, care
should be taken to keep TJ within the specified limits. Tcase should be measured to estimate the operating
junction temperature TJ. Tcase is normally measured at the center of the package top-side surface. The thermal
application report Semiconductor and IC Package Thermal Metrics helps to understand the thermal metrics and
definitions.
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7.11 System
7.11.1 Power Management
TMS320F28002x real-time MCUs use an internal 1.2-V LDO Voltage Regulator (VREG) to supply the required
1.2 V to the core (VDD).
7.11.1.1 Internal 1.2-V LDO Voltage Regulator (VREG)
The internal VREG is supplied by VDDIO and generates the 1.2 V required to power the VDD pins. The internal
VREG is always enabled and, as such, is the required supply source for the VDD pins. Although the internal
VREG eliminates the need to use an external power supply for VDD, decoupling capacitors are required on each
VDD pin for VREG stability. There are two recommended capacitor configurations (described in the list that
follows) for the VDD rail when using the internal VREG. The signal description for VDD can be found in 表6-4.
• Configuration 1: Place a small decoupling capacitor to VSS on each pin as close to the device as possible. In
addition, a bulk capacitance must be placed on the VDD node to VSS (one 10-µF capacitor or two parallel
4.7-µF capacitors).
• Configuration 2: Distribute the total capacitance to VSS evenly across all VDD pins (total capacitance divided
by number of available VDD pins).
7.11.1.2 Power Sequencing
Signal Pin Requirements: Before powering the device, no voltage larger than 0.3 V above VDDIO can be
applied to any digital pin, and no voltage larger than 0.3 V above VDDA can be applied to any analog pin
(including VREFHI).
VDDIO and VDDA Requirements: The 3.3-V supplies VDDIO and VDDA should be powered up together and
kept within 0.3 V of each other during functional operation.
VDD Requirements: The VDD sequencing requirements are handled by the device.
7.11.1.3 Power-On Reset (POR)
An internal power-on reset (POR) circuit holds the device in reset and keeps the I/Os in a high-impedance state
during power up. The POR is in control and forces XRSn low internally until the voltage on VDDIO crosses the
POR threshold. When the voltage crosses the POR threshold, the internal brownout-reset (BOR) circuit takes
control and holds the device in reset until the voltage crosses the BOR threshold (for internal BOR details, see
节7.11.1.4).
7.11.1.4 Brownout Reset (BOR)
An internal BOR circuit monitors the VDDIO rail for dips in voltage which result in the supply voltage dropping out
of operational range. When the VDDIO voltage drops below the BOR threshold, the device is forced into reset,
and XRSn is pulled low. XRSn will remain in reset until the voltage returns to the operational range. The BOR is
enabled by default. To disable the BOR, set the BORLVMONDIS bit in the VMONCTL register. The internal BOR
circuit monitors only the VDDIO rail. See 节 7.6 for BOR characteristics. External supply voltage supervisor
(SVS) devices can be used to monitor the voltage on the 3.3-V rail and to drive XRSn low if supplies fall outside
operational specifications.
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7.11.2 Reset Timing
XRSn is the device reset pin. It functions as an input and open-drain output. The device has a built-in power-on
reset (POR). During power up, the POR circuit drives the XRSn pin low. A watchdog or NMI watchdog reset will
also drive the pin low. An external open-drain circuit may drive the pin to assert a device reset.
A resistor with a value from 2.2 kΩ to 10 kΩ should be placed between XRSn and VDDIO. A capacitor should
be placed between XRSn and VSS for noise filtering, it should be 100 nF or smaller. These values will allow the
watchdog to properly drive the XRSn pin to VOL within 512 OSCCLK cycles when the watchdog reset is
asserted. 图7-7 shows the recommended reset circuit.
VDDIO
2.2 kW to 10 kW
Optional open-drain
Reset source
XRSn
£100 nF
图7-7. Reset Circuit
7.11.2.1 Reset Sources
表7-1 summarizes the various reset signals and their effect on the device.
表7-1. Reset Signals
CPU CORE
RESET
(C28x, FPU, VCU)
JTAG/
DEBUG LOGIC
RESET
PERIPHERALS
RESET
RESET SOURCE
I/Os
XRSn OUTPUT
POR
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
No
No
No
No
No
Hi-Z
Hi-Z
Hi-Z
Hi-Z
Hi-Z
Hi-Z
Yes
XRSn Pin
WDRS
–
Yes
Yes
No
NMIWDRS
SYSRS (Debugger Reset)
SCCRESET
No
The parameter th(boot-mode) must account for a reset initiated from any of these sources.
See the Resets section of the System Control chapter in the TMS320F28002x Real-Time Microcontrollers
Technical Reference Manual.
CAUTION
Some reset sources are internally driven by the device. Some of these sources will drive XRSn low,
use this to disable any other devices driving the boot pins. The SCCRESET and debugger reset
sources do not drive XRSn; therefore, the pins used for boot mode should not be actively driven by
other devices in the system. The boot configuration has a provision for changing the boot pins in
OTP; for more details, see the TMS320F28002x Real-Time Microcontrollers Technical Reference
Manual.
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7.11.2.2 Reset Electrical Data and Timing
节 7.11.2.2.1 lists the reset (XRSn) timing requirements. 节 7.11.2.2.2 lists the reset (XRSn) switching
characteristics. 图7-8 shows the power-on reset. 图7-9 shows the warm reset.
7.11.2.2.1 Reset (XRSn) Timing Requirements
MIN
1.5
MAX
UNIT
th(boot-mode)
Hold time for boot-mode pins
ms
All cases
3.2
Pulse duration, XRSn low on
warm reset
tw(RSL2)
µs
Low-power modes used in
application and SYSCLKDIV > 16
3.2 * (SYSCLKDIV/16)
7.11.2.2.2 Reset (XRSn) Switching Characteristics
over recommended operating conditions (unless otherwise noted)
PARAMETER
MIN
TYP
100
MAX
UNIT
Pulse duration, XRSn driven low by device after supplies are
tw(RSL1)
µs
stable
tw(WDRS)
tboot-flash
Pulse duration, reset pulse generated by watchdog
512tc(OSCCLK)
cycles
µs
Boot-ROM execution time to first instruction fetch in flash
900
7.11.2.2.3 Reset Timing Diagrams
VDDIO VDDA
(3.3V)
VDD (1.2V)
tw(RSL1)
XRSn(A)
tboot-flash
Boot ROM
CPU
Execution
Phase
User code
User code dependent
(B)
th(boot-mode)
Boot-Mode
Pins
GPIO pins as input
Boot-ROM execution starts
Peripheral/GPIO function
Based on boot code
GPIO pins as input (pullups are disabled)
User code dependent
I/O Pins
A. The XRSn pin can be driven externally by a supervisor or an external pullup resistor, see 表6-1. On-chip POR logic will hold this pin low
until the supplies are in a valid range.
B. After reset from any source (see 节7.11.2.1), the boot ROM code samples Boot Mode pins. Based on the status of the Boot Mode pin,
the boot code branches to destination memory or boot code function. If boot ROM code executes after power-on conditions (in
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debugger environment), the boot code execution time is based on the current SYSCLK speed. The SYSCLK will be based on user
environment and could be with or without PLL enabled.
图7-8. Power-on Reset
tw(RSL2)
XRSn
User code
CPU
Execution
Phase
Boot ROM
User code
Boot ROM execution starts
(initiated by any reset source)
(A)
th(boot-mode)
Boot-Mode
Pins
Peripheral/GPIO function
GPIO Pins as Input
Peripheral/GPIO function
User-Code Execution Starts
I/O Pins
GPIO Pins as Input (Pullups are Disabled)
User-Code Dependent
User-Code Dependent
A. After reset from any source (see 节7.11.2.1), the Boot ROM code samples BOOT Mode pins. Based on the status of the Boot Mode
pin, the boot code branches to destination memory or boot code function. If Boot ROM code executes after power-on conditions (in
debugger environment), the Boot code execution time is based on the current SYSCLK speed. The SYSCLK will be based on user
environment and could be with or without PLL enabled.
图7-9. Warm Reset
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7.11.3 Clock Specifications
7.11.3.1 Clock Sources
表7-2 lists clock sources. 图7-10 shows the clocking system. 图7-11 shows the PLL.
表7-2. Possible Reference Clock Sources
CLOCK SOURCE
DESCRIPTION
INTOSC1
Internal oscillator 1.
Zero-pin overhead 10-MHz internal oscillator.
INTOSC2(1)
X1 (XTAL)
Internal oscillator 2.
Zero-pin overhead 10-MHz internal oscillator.
External crystal or resonator connected between the X1 and X2 pins or single-ended clock connected to the X1
pin.
(1) On reset, internal oscillator 2 (INTOSC2) is the default clock source for the PLL (OSCCLK).
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SYSCLKDIVSEL
PLLSYSCLK
NMIWD
Watchdog
Timer
SYS
Divider
PLLRAWCLK
FPU
TMU
Flash
SYSPLL
INTOSC1
INTOSC2
X1 (XTAL)
CPUCLK
OSCCLK
SYSPLLCLKEN
OSCCLKSRCSEL
CPU
ePIE
GPIO
Mx RAMs
Lx RAMs
Boot ROM
DCSM
System Control
WD
SYSCLK
SYSCLK
GSx RAMs
XINT
CPUTIMERs
CLB
ECAP
I2C
ADC
CMPSS
CAN
HIC
DCC
HWBIST
BGCRC
One per SYSCLK peripheral
PCLKCRx
EQEP
PERx.SYSCLK
EPWM
HRCAL
PMBUS
LIN
FSI
ERAD
One per LSPCLK peripheral
PCLKCRx
LOSPCP
PERx.LSPCLK
SCI
SPI
LSPCLK
LSP
Divider
CLKSRCCTL2.CANxBCLKSEL
CAN Bit Clock
图7-10. Clocking System
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SYSPLL
OSCCLK
INTCLK
VCOCLK
PLLRAWCLK
÷
(REFDIV+1)
÷
(ODIV+1)
VCO
÷
IMULT
图7-11. System PLL
In 图7-11,
IMULT
fOSCCLK
REFDIV +1
=
ì
fPLLRAWCLK
ODIV +1
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7.11.3.2 Clock Frequencies, Requirements, and Characteristics
This section provides the frequencies and timing requirements of the input clocks, PLL lock times, frequencies of
the internal clocks, and the frequency and switching characteristics of the output clock.
7.11.3.2.1 Input Clock Frequency and Timing Requirements, PLL Lock Times
节 7.11.3.2.1.1 lists the frequency requirements for the input clocks. 节 7.11.3.2.1.2 lists the XTAL oscillator
characteristics. 节 7.11.3.2.1.3 lists the X1 timing requirements. 节 7.11.3.2.1.4 lists the APLL characteristics. 节
7.11.3.2.1.5 lists the switching characteristics of the output clock, XCLKOUT. 节 7.11.3.2.1.6 provides the clock
frequencies for the internal clocks.
7.11.3.2.1.1 Input Clock Frequency
MIN
10
MAX UNIT
20 MHz
25 MHz
f(XTAL)
f(X1)
Frequency, X1/X2, from external crystal or resonator
Frequency, X1, from external oscillator
10
7.11.3.2.1.2 XTAL Oscillator Characteristics
over recommended operating conditions (unless otherwise noted)
PARAMETER
MIN
–0.3
TYP
MAX
UNIT
V
X1 VIL
X1 VIH
Valid low-level input voltage
Valid high-level input voltage
0.3 * VDDIO
VDDIO + 0.3
0.7 * VDDIO
V
7.11.3.2.1.3 X1 Timing Requirements
MIN
MAX UNIT
tf(X1)
Fall time, X1
6
6
ns
ns
tr(X1)
Rise time, X1
tw(X1L)
tw(X1H)
Pulse duration, X1 low as a percentage of tc(X1)
Pulse duration, X1 high as a percentage of tc(X1)
45%
45%
55%
55%
7.11.3.2.1.4 APLL Characteristics
over operating free-air temperature range (unless otherwise noted)
PARAMETER
MIN
TYP
MAX
UNIT
PLL Lock time
SYS PLL Lock Time(1)
5µs + (1024 * (REFDIV + 1) * tc(OSCCLK)
)
us
(1) The PLL lock time here defines the typical time that takes for the PLL to lock once PLL is enabled (SYSPLLCTL1[PLLENA]=1).
Additional time to verify the PLL clock using Dual Clock Comparator (DCC) is not accounted here. TI recommends using the latest
example software from C2000Ware for initializing the PLLs. For the system PLL, see InitSysPll() or SysCtl_setClock().
7.11.3.2.1.5 XCLKOUT Switching Characteristics
over recommended operating conditions (unless otherwise noted)
PARAMETER(1)
MIN
MAX
5
UNIT
ns
tf(XCO)
Fall time, XCLKOUT
Rise time, XCLKOUT
tr(XCO)
tw(XCOL)
tw(XCOH)
f(XCO)
5
ns
H –2(2)
H –2(2)
Pulse duration, XCLKOUT low
Pulse duration, XCLKOUT high
Frequency, XCLKOUT
H + 2(2)
H + 2(2)
50
ns
ns
MHz
(1) A load of 40 pF is assumed for these parameters.
(2) H = 0.5tc(XCO)
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7.11.3.2.1.6 Internal Clock Frequencies
MIN
NOM
MAX
UNIT
MHz
ns
f(SYSCLK)
Frequency, device (system) clock
Period, device (system) clock
2
100
500
tc(SYSCLK)
10
Frequency, system PLL going into VCO (after
REFDIV)
f(INTCLK)
10
220
6
20
600
200
100
MHz
MHz
MHz
f(VCOCLK)
f(PLLRAWCLK)
Frequency, system PLL VCO (before ODIV)
Frequency, system PLL output (before SYSCLK
divider)
f(PLL)
Frequency, PLLSYSCLK
Frequency, PLL Limp Frequency (1)
Frequency, LSPCLK
2
MHz
MHz
MHz
ns
f(PLL_LIMP)
f(LSP)
45/(ODIV+1)
2
100
500
tc(LSPCLK)
Period, LSPCLK
10
Frequency, OSCCLK (INTOSC1 or INTOSC2 or
XTAL or X1)
f(OSCCLK)
See respective clock
MHz
f(EPWM)
Frequency, EPWMCLK
Frequency, HRPWMCLK
100
100
MHz
MHz
f(HRPWM)
60
(1) PLL output frequency when OSCCLK is dead (Loss of OSCCLK causes PLL to Limp).
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7.11.3.3 Input Clocks and PLLs
In addition to the internal 0-pin oscillators, three types of external clock sources are supported:
• A single-ended 3.3-V external clock. The clock signal should be connected to X1, as shown in 图7-12, with
the XTALCR.SE bit set to 1.
• An external crystal. The crystal should be connected across X1 and X2 with its load capacitors connected to
VSS as shown in 图7-13.
• An external resonator. The resonator should be connected across X1 and X2 with its ground connected to
VSS as shown in 图7-14.
Microcontroller
Microcontroller
GPIO19
X1
GPIO18
X2
GPIO18*
X2
GPIO19
X1
VSS
VSS
* Available as a
GPIO when X1 is
used as a clock
+3.3 V
VDD
Out
3.3-V Oscillator
Gnd
图7-13. External Crystal
图7-12. Single-ended 3.3-V External Clock
Microcontroller
GPIO18
X2
GPIO19
X1
VSS
图7-14. External Resonator
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7.11.3.4 Crystal Oscillator
When using a quartz crystal, it may be necessary to include a damping resistor (RD) in the crystal circuit to
prevent overdriving the crystal (drive level can be found in the crystal data sheet). In higher-frequency
applications (10 MHz or greater), RD is generally not required. If a damping resistor is required, RD should be as
small as possible because the size of the resistance affects start-up time (smaller RD = faster start-up time). TI
recommends that the crystal manufacturer characterize the crystal with the application board. 节 7.11.3.4.1 lists
the crystal oscillator parameters. 表 7-3 lists the crystal equivalent series resistance (ESR) requirements. 节
7.11.3.4.2 lists the crystal oscillator electrical characteristics.
7.11.3.4.1 Crystal Oscillator Parameters
MIN
MAX UNIT
CL1, CL2
C0
Load capacitance
12
24
7
pF
pF
Crystal shunt capacitance
For 表7-3:
1. Crystal shunt capacitance (C0) should be less than or equal to 7 pF.
2. ESR = Negative Resistance/3
表7-3. Crystal Equivalent Series Resistance (ESR) Requirements
MAXIMUM ESR (Ω)
(CL1 = CL2 = 12 pF)
MAXIMUM ESR (Ω)
(CL1 = CL2 = 24 pF)
CRYSTAL FREQUENCY (MHz)
10
12
14
16
18
20
55
50
50
45
45
45
110
95
90
75
65
50
7.11.3.4.2 Crystal Oscillator Electrical Characteristics
over recommended operating conditions (unless otherwise noted)
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
ms
f = 20 MHz
ESR MAX = 50 Ω
CL1 = CL2 = 24 pF
C0 = 7 pF
Start-up time(1)
2
Crystal drive level (DL)
1
mW
(1) Start-up time is dependent on the crystal and tank circuit components. TI recommends that the crystal vendor characterize the
application with the chosen crystal.
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7.11.3.5 Internal Oscillators
To reduce production board costs and application development time, all F28002x devices contain two
independent internal oscillators, referred to as INTOSC1 and INTOSC2. By default, INTOSC2 is set as the
source for the system reference clock (OSCCLK) and INTOSC1 is set as the backup clock source.
Applications requiring tighter clock tolerance can use the SCI baud tuning example available in C2000Ware
(C2000Ware_3_03_00_00\driverlib\f28002x\examples\sci\baud_tune_via_uart) to enable baud matching better
than 1% accuracy.
节7.11.3.5.1 provides the electrical characteristics of the internal oscillators.
7.11.3.5.1 INTOSC Characteristics
over recommended operating conditions (unless otherwise noted)
TEST
PARAMETER
MIN
TYP
MAX
UNIT
CONDITIONS
-40°C to 125°C
-30°C to 90°C
10
10
10.15 (1.5%)
10.15 (1.5%)
MHz
MHz
9.8 (–2.0%)
9.85 (–1.5%)
Frequency, INTOSC1 and
INTOSC2
fINTOSC
30°C, Nominal
VDDIO
fINTOSC-STABILITY Frequency stability
±0.1
%
tINT0SC-ST
Start-up and settling time
20
µs
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7.11.4 Flash Parameters
表7-4 lists the minimum required Flash wait states with different clock sources and frequencies. Wait state is the
value set in register FRDCNTL[RWAIT].
表7-4. Minimum Required Flash Wait States with Different Clock Sources and Frequencies
EXTERNAL OSCILLATOR OR CRYSTAL
INTOSC1 OR INTOSC2
CPUCLK (MHz)
BANK OR PUMP
NORMAL OPERATION
BANK OR PUMP
NORMAL OPERATION
SLEEP(1)
SLEEP(1)
5
4
4
3
3
2
2
1
1
0
97 < CPUCLK ≤100
80 < CPUCLK ≤97
77 < CPUCLK ≤80
60 < CPUCLK ≤77
58 < CPUCLK ≤60
40 < CPUCLK ≤58
38 < CPUCLK ≤40
20 < CPUCLK ≤38
19 < CPUCLK ≤20
CPUCLK ≤19
4
3
2
1
0
4
3
2
1
0
(1) Flash SLEEP operations require an extra wait state when using INTOSC as the clock source for the frequency ranges indicated. Any
wait state FRDCNTL[RWAIT] change must be made before beginning a SLEEP mode operation. This setting impacts both flash banks.
The F28002x devices have an improved 128-bit prefetch buffer that provides high flash code execution efficiency
across wait states. 图 7-15 and 图 7-16 illustrate typical efficiency across wait-state settings compared to
previous-generation devices with a 64-bit prefetch buffer. Wait-state execution efficiency with a prefetch buffer
will depend on how many branches are present in application software. Two examples of linear code and if-then-
else code are provided.
100%
90%
80%
70%
60%
50%
40%
30%
100%
95%
90%
85%
80%
75%
70%
65%
60%
55%
Flash with 64-Bit Prefetch
Flash with 128-Bit Prefetch
Flash with 64-Bit Prefetch
Flash with 128-Bit Prefetch
0
1
2
3
4
5
0
1
2
3
4
5
Wait State
Wait State
D005
D006
图7-15. Application Code With Heavy 32-Bit
图7-16. Application Code With 16-Bit If-Else
Floating-Point Math Instructions
Instructions
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表7-5 lists the Flash parameters.
表7-5. Flash Parameters
PARAMETER
MIN
TYP
150
50
MAX
300
UNIT
µs
128 data bits + 16 ECC bits
8KB sector
Program Time(1)
100
ms
EraseTime(2) (3) at < 25 cycles
EraseTime(2) (3) at 1000 cycles
EraseTime(2) (3) at 2000 cycles
EraseTime(2) (3) at 20K cycles
Nwec Write/Erase Cycles per sector
8KB sector
15
100
ms
8KB sector
25
350
ms
8KB sector
30
600
ms
8KB sector
120
4000
20000
ms
cycles
Nwec Write/Erase Cycles for entire Flash (combined all
sectors)
100000
cycles
years
tretention Data retention duration at TJ = 85oC
20
(1) Program time is at the maximum device frequency. Program time includes overhead of the flash state machine but does not include
the time to transfer the following into RAM:
•Code that uses flash API to program the flash
•Flash API itself
•Flash data to be programmed
In other words, the time indicated in this table is applicable after all the required code/data is available in the device RAM, ready for
programming. The transfer time will significantly vary depending on the speed of the JTAG debug probe used.
Program time calculation is based on programming 144 bits at a time at the specified operating frequency. Program time includes
Program verify by the CPU. The program time does not degrade with write/erase (W/E) cycling, but the erase time does.
Erase time includes Erase verify by the CPU and does not involve any data transfer.
(2) Erase time includes Erase verify by the CPU.
(3) The on-chip flash memory is in an erased state when the device is shipped from TI. As such, erasing the flash memory is not required
prior to programming, when programming the device for the first time. However, the erase operation is needed on all subsequent
programming operations.
Note
The Main Array flash programming must be aligned to 64-bit address boundaries and each 64-bit
word may only be programmed once per write/erase cycle.
The DCSM OTP programming must be aligned to 128-bit address boundaries and each 128-bit word
may only be programmed once. The exceptions are:
1. The DCSM Zx-LINKPOINTER1 and Zx-LINKPOINTER2 values in the DCSM OTP should be
programmed together, and may be programmed 1 bit at a time as required by the DCSM
operation.
2. The DCSM Zx-LINKPOINTER3 values in the DCSM OTP may be programmed 1 bit at a time on a
64-bit boundary to separate it from Zx-PSWDLOCK, which must only be programmed once.
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7.11.5 Emulation/JTAG
The JTAG (IEEE Standard 1149.1-1990 Standard Test Access Port and Boundary Scan Architecture) port has
four dedicated pins: TMS, TDI, TDO, and TCK. The cJTAG (IEEE Standard 1149.7-2009 for Reduced-Pin and
Enhanced-Functionality Test Access Port and Boundary-Scan Architecture) port is a compact JTAG interface
requiring only two pins (TMS and TCK), which allows other device functionality to be muxed to the traditional
GPIO35 (TDI) and GPIO37 (TDO) pins.
Typically, no buffers are needed on the JTAG signals when the distance between the MCU target and the JTAG
header is smaller than 6 inches (15.24 cm), and no other devices are present on the JTAG chain. Otherwise,
each signal should be buffered. Additionally, for most JTAG debug probe operations at 10 MHz, no series
resistors are needed on the JTAG signals. However, if high emulation speeds are expected (35 MHz or so), 22-Ω
resistors should be placed in series on each JTAG signal.
The PD (Power Detect) terminal of the JTAG debug probe header should be connected to the board's 3.3-V
supply. Header GND terminals should be connected to board ground. TDIS (Cable Disconnect Sense) should
also be connected to board ground. The JTAG clock should be looped from the header TCK output terminal back
to the RTCK input terminal of the header (to sense clock continuity by the JTAG debug probe). This MCU does
not support the EMU0 and EMU1 signals that are present on 14-pin and 20-pin emulation headers. These
signals should always be pulled up at the emulation header through a pair of board pullup resistors ranging from
2.2 kΩ to 4.7 kΩ (depending on the drive strength of the debugger ports). Typically, a 2.2-kΩ value is used.
Header terminal RESET is an open-drain output from the JTAG debug probe header that enables board
components to be reset through JTAG debug probe commands (available only through the 20-pin header). 图
7-17 shows how the 14-pin JTAG header connects to the MCU’s JTAG port signals. 图 7-18 shows how to
connect to the 20-pin JTAG header. The 20-pin JTAG header terminals EMU2, EMU3, and EMU4 are not used
and should be grounded.
For more information about hardware breakpoints and watchpoints, see Hardware Breakpoints and Watchpoints
for C28x in CCS.
For more information about JTAG emulation, see the XDS Target Connection Guide.
Note
JTAG Test Data Input (TDI) is the default mux selection for the pin. The internal pullup is disabled by
default. If this pin is used as JTAG TDI, the internal pullup should be enabled or an external pullup
added on the board to avoid a floating input. In the cJTAG option, this pin can be used as GPIO.
JTAG Test Data Output (TDO) is the default mux selection for the pin. The internal pullup is disabled
by default. The TDO function will be in a tri-state condition when there is no JTAG activity, leaving this
pin floating. The internal pullup should be enabled or an external pullup added on the board to avoid a
floating GPIO input. In the cJTAG option, this pin can be used as GPIO.
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Distance between the header and the target
should be less than 6 inches (15.24 cm).
3.3 V
4.7 kΩ
2
1
TMS
TMS
TRST
3.3 V
10 kΩ
3.3 V
10 kΩ
TDI(A)
TDI
TDIS
KEY
3
5
4
GND
MCU
100 Ω
6
3.3 V
PD
TDO(A)
TCK
TDO
RTCK
TCK
EMU0
GND
GND
GND
EMU1
7
8
9
10
12
14
11
13
4.7 kΩ
4.7 kΩ
3.3 V
3.3 V
A. TDI and TDO connections are not required for cJTAG option and these pins can be used as GPIOs instead.
图7-17. Connecting to the 14-Pin JTAG Header
Distance between the header and the target
should be less than 6 inches (15.24 cm).
3.3 V
4.7 kΩ
3.3 V
10 kΩ
3.3 V
10 kΩ
2
1
TMS
TMS
TRST
TDI(A)
TDI
TDIS
KEY
GND
3
5
4
MCU
100 Ω
6
3.3V
PD
TDO(A)
TDO
GND
GND
GND
EMU1
GND
EMU3
GND
7
8
9
10
12
14
16
18
20
RTCK
TCK
11
13
15
17
19
TCK
Ω
4.7 kΩ
4.7 k
3.3 V
EMU0
RESET
EMU2
EMU4
3.3 V
Open
Drain
A low pulse from the JTAG debug probe
can be tied with other reset sources
to reset the board.
GND
GND
A. TDI and TDO connections are not required for cJTAG option and these pins can be used as GPIOs instead.
图7-18. Connecting to the 20-Pin JTAG Header
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7.11.5.1 JTAG Electrical Data and Timing
节 7.11.5.1.1 lists the JTAG timing requirements. 节 7.11.5.1.2 lists the JTAG switching characteristics. 图 7-19
shows the JTAG timing.
7.11.5.1.1 JTAG Timing Requirements
NO.
MIN
66.66
26.66
26.66
13
MAX
UNIT
ns
1
tc(TCK)
Cycle time, TCK
1a
1b
tw(TCKH)
Pulse duration, TCK high (40% of tc)
Pulse duration, TCK low (40% of tc)
Input setup time, TDI valid to TCK high
Input setup time, TMS valid to TCK high
Input hold time, TDI valid from TCK high
Input hold time, TMS valid from TCK high
ns
tw(TCKL)
ns
tsu(TDI-TCKH)
tsu(TMS-TCKH)
th(TCKH-TDI)
th(TCKH-TMS)
3
4
ns
ns
13
7
7
7.11.5.1.2 JTAG Switching Characteristics
over recommended operating conditions (unless otherwise noted)
NO.
PARAMETER
MIN
MAX
UNIT
2
td(TCKL-TDO)
Delay time, TCK low to TDO valid
6
25
ns
7.11.5.1.3 JTAG Timing Diagram
1
1a
1b
TCK
2
TDO
3
4
TDI/TMS
图7-19. JTAG Timing
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TMS320F280025, TMS320F280025-Q1
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7.11.5.2 cJTAG Electrical Data and Timing
节7.11.5.2.1 lists the cJTAG timing requirements. 节7.11.5.2.2 lists the cJTAG switching characteristics. 图7-20
shows the cJTAG timing.
7.11.5.2.1 cJTAG Timing Requirements
NO.
MIN
100
40
40
15
15
2
MAX
UNIT
ns
1
tc(TCK)
Cycle time, TCK
1a
1b
tw(TCKH)
Pulse duration, TCK high (40% of tc)
Pulse duration, TCK low (40% of tc)
Input setup time, TMS valid to TCK high
Input setup time, TMS valid to TCK low
Input hold time, TMS valid from TCK high
Input hold time, TMS valid from TCK low
ns
tw(TCKL)
ns
tsu(TMS-TCKH)
tsu(TMS-TCKL)
th(TCKH-TMS)
th(TCKL-TMS)
ns
3
4
ns
ns
2
ns
7.11.5.2.2 cJTAG Switching Characteristics
over recommended operating conditions (unless otherwise noted)
NO.
PARAMETER
MIN
MAX
20
UNIT
ns
2
5
td(TCKL-TMS)
Delay time, TCK low to TMS valid
Delay time, TCK high to TMS disable
6
tdis(TCKH-TMS)
20
ns
7.11.5.2.3 cJTAG Timing Diagram
1
1a
1b
2
3
3
4
4
5
TCK
TMS
TMS Input
TMS Output
TMS Input
图7-20. cJTAG Timing
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TMS320F280025, TMS320F280025-Q1
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7.11.6 GPIO Electrical Data and Timing
The peripheral signals are multiplexed with general-purpose input/output (GPIO) signals. On reset, GPIO pins
are configured as inputs. For specific inputs, the user can also select the number of input qualification cycles to
filter unwanted noise glitches.
The GPIO module contains an Output X-BAR which allows an assortment of internal signals to be routed to a
GPIO in the GPIO mux positions denoted as OUTPUTXBARx. The GPIO module also contains an Input X-BAR
which is used to route signals from any GPIO input to different IP blocks such as the ADCs, eCAPs, ePWMs,
and external interrupts. For more details, see the X-BAR chapter in the TMS320F28002x Real-Time
Microcontrollers Technical Reference Manual.
7.11.6.1 GPIO –Output Timing
节 7.11.6.1.1 lists the general-purpose output switching characteristics. 图 7-21 shows the general-purpose
output timing.
7.11.6.1.1 General-Purpose Output Switching Characteristics
over recommended operating conditions (unless otherwise noted)
PARAMETER
MIN
MAX
8(1)
8(1)
25
UNIT
ns
tr(GPIO)
tf(GPIO)
fGPIO
Rise time, GPIO switching low to high
All GPIOs
All GPIOs
Fall time, GPIO switching high to low
Toggling frequency, all GPIOs
ns
MHz
(1) Rise time and fall time vary with load. These values assume a 40-pF load.
GPIO
tr(GPIO)
tf(GPIO)
图7-21. General-Purpose Output Timing
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7.11.6.2 GPIO –Input Timing
节7.11.6.2.1 lists the general-purpose input timing requirements. 图7-22 shows the sampling mode.
7.11.6.2.1 General-Purpose Input Timing Requirements
MIN
1tc(SYSCLK)
MAX
UNIT
cycles
cycles
cycles
QUALPRD = 0
tw(SP)
Sampling period
2tc(SYSCLK) * QUALPRD
QUALPRD ≠0
tw(SP) * (n(1) –1)
2tc(SYSCLK)
tw(IQSW)
Input qualifier sampling window
Pulse duration, GPIO low/high
Synchronous mode
With input qualifier
(2)
tw(GPI)
tw(IQSW) + tw(SP) + 1tc(SYSCLK)
(1) "n" represents the number of qualification samples as defined by GPxQSELn register.
(2) For tw(GPI), pulse width is measured from VIL to VIL for an active low signal and VIH to VIH for an active high signal.
7.11.6.2.2 Sampling Mode
(A)
GPIO Signal
GPxQSELn = 1,0 (6 samples)
1
1
0
0
0
0
0
0
0
1
0
0
0
1
1
1
1
1
1
1
1
1
tw(SP)
Sampling Period determined
by GPxCTRL[QUALPRD](B)
tw(IQSW)
(SYSCLK cycle * 2 * QUALPRD) * 5(C)
Sampling Window
SYSCLK
QUALPRD = 1
(SYSCLK/2)
(D)
Output From
Qualifier
A. This glitch will be ignored by the input qualifier. The QUALPRD bit field specifies the qualification sampling period. It can vary from 00 to
0xFF. If QUALPRD = 00, then the sampling period is 1 SYSCLK cycle. For any other value "n", the qualification sampling period in 2n
SYSCLK cycles (that is, at every 2n SYSCLK cycles, the GPIO pin will be sampled).
B. The qualification period selected through the GPxCTRL register applies to groups of eight GPIO pins.
C. The qualification block can take either three or six samples. The GPxQSELn Register selects which sample mode is used.
D. In the example shown, for the qualifier to detect the change, the input should be stable for 10 SYSCLK cycles or greater. In other words,
the inputs should be stable for (5 × QUALPRD × 2) SYSCLK cycles. This would ensure 5 sampling periods for detection to occur.
Because external signals are driven asynchronously, an 13-SYSCLK-wide pulse ensures reliable recognition.
图7-22. Sampling Mode
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7.11.6.3 Sampling Window Width for Input Signals
The following section summarizes the sampling window width for input signals for various input qualifier
configurations.
Sampling frequency denotes how often a signal is sampled with respect to SYSCLK.
Sampling frequency = SYSCLK/(2 × QUALPRD), if QUALPRD ≠0
Sampling frequency = SYSCLK, if QUALPRD = 0
Sampling period = SYSCLK cycle × 2 × QUALPRD, if QUALPRD ≠0
In the previous equations, SYSCLK cycle indicates the time period of SYSCLK.
Sampling period = SYSCLK cycle, if QUALPRD = 0
In a given sampling window, either 3 or 6 samples of the input signal are taken to determine the validity of the
signal. This is determined by the value written to GPxQSELn register.
Case 1:
Qualification using 3 samples
Sampling window width = (SYSCLK cycle × 2 × QUALPRD) × 2, if QUALPRD ≠0
Sampling window width = (SYSCLK cycle) × 2, if QUALPRD = 0
Case 2:
Qualification using 6 samples
Sampling window width = (SYSCLK cycle × 2 × QUALPRD) × 5, if QUALPRD ≠0
Sampling window width = (SYSCLK cycle) × 5, if QUALPRD = 0
图7-23 shows the general-purpose input timing.
SYSCLK
GPIOxn
tw(GPI)
图7-23. General-Purpose Input Timing
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7.11.7 Interrupts
The C28x CPU has fourteen peripheral interrupt lines. Two of them (INT13 and INT14) are connected directly to
CPU timers 1 and 2, respectively. The remaining twelve are connected to peripheral interrupt signals through the
enhanced Peripheral Interrupt Expansion (ePIE) module. The ePIE multiplexes up to sixteen peripheral
interrupts into each CPU interrupt line. It also expands the vector table to allow each interrupt to have its own
ISR. This allows the CPU to support a large number of peripherals.
An interrupt path is divided into three stages—the peripheral, the ePIE, and the CPU. Each stage has its own
enable and flag registers. This system allows the CPU to handle one interrupt while others are pending,
implement and prioritize nested interrupts in software, and disable interrupts during certain critical tasks.
图7-24 shows the interrupt architecture for this device.
TINT0
TIMER0
LPMINT
WDINT
LPM Logic
WD
WAKEINT
NMI module
ERAD
NMI
RTOSINT
CPU
INPUTXBAR4
XINT1 Control
INPUTXBAR5
INPUTXBAR6
INPUTXBAR13
INPUTXBAR14
XINT2 Control
XINT3 Control
XINT4 Control
XINT5 Control
GPIO0
to
GPIOx
ePIE
INT1
to
INT12
Input
X-BAR
TIMER1
TIMER2
INT13
INT14
Peripherals
See ePIE Table
图7-24. Device Interrupt Architecture
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TMS320F280025, TMS320F280025-Q1
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7.11.7.1 External Interrupt (XINT) Electrical Data and Timing
节 7.11.7.1.1 lists the external interrupt timing requirements. 节 7.11.7.1.2 lists the external interrupt switching
characteristics. 图 7-25 shows the external interrupt timing. For an explanation of the input qualifier parameters,
see 节7.11.6.2.1.
7.11.7.1.1 External Interrupt Timing Requirements
MIN
2tc(SYSCLK)
MAX
UNIT
Synchronous
With qualifier
tw(INT)
Pulse duration, INT input low/high
cycles
tw(IQSW) + tw(SP) + 1tc(SYSCLK)
7.11.7.1.2 External Interrupt Switching Characteristics
over recommended operating conditions (unless otherwise noted)
PARAMETER
MIN
MAX
UNIT
td(INT) Delay time, INT low/high to interrupt-vector fetch(1)
tw(IQSW) + 14tc(SYSCLK)
tw(IQSW) + tw(SP) + 14tc(SYSCLK) cycles
(1) This assumes that the ISR is in a single-cycle memory.
7.11.7.1.3 External Interrupt Timing
tw(INT)
XINT1, XINT2, XINT3,
XINT4, XINT5
td(INT)
Address bus
(internal)
Interrupt Vector
图7-25. External Interrupt Timing
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TMS320F280025, TMS320F280025-Q1
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7.11.8 Low-Power Modes
This device has HALT, IDLE and STANDBY as clock-gating low-power modes.
Further details, as well as the entry and exit procedure, for all of the low-power modes can be found in the Low
Power Modes section of the TMS320F28002x Real-Time Microcontrollers Technical Reference Manual.
7.11.8.1 Clock-Gating Low-Power Modes
IDLE and HALT modes on this device are similar to those on other C28x devices. 表 7-6 describes the effect on
the system when any of the clock-gating low-power modes are entered.
表7-6. Effect of Clock-Gating Low-Power Modes on the Device
MODULES/
CLOCK DOMAIN
IDLE
STANDBY
HALT
SYSCLK
Active
Gated
Active
Gated
Gated
Gated
Gated
Gated
Gated
CPUCLK
Clock to modules connected
to PERx.SYSCLK
WDCLK
PLL
Active
Active
Gated if CLKSRCCTL1.WDHALTI = 0
Software must power down PLL before entering HALT.
Powered down if CLKSRCCTL1.WDHALTI = 0
Powered down if CLKSRCCTL1.WDHALTI = 0
Powered
Powered
Powered
Powered
Powered
Powered
Powered
Powered
Powered
Powered
Powered
INTOSC1
INTOSC2
Flash(1)
XTAL(2)
Powered
(1) The Flash module is not powered down by hardware in any LPM. It may be powered down using software if required by the
application. For more information, see the Flash and OTP Memory section of the System Control chapter in the TMS320F28002x Real-
Time Microcontrollers Technical Reference Manual.
(2) The XTAL is not powered down by hardware in any LPM. It may be powered down by software setting the XTALCR.OSCOFF bit to 1.
This can be done at any time during the application if the XTAL is not required.
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7.11.8.2 Low-Power Mode Wake-up Timing
节 7.11.8.2.1 lists the IDLE mode timing requirements, 节 7.11.8.2.2 lists the IDLE mode switching
characteristics, and 图 7-26 shows the timing diagram for IDLE mode. For an explanation of the input qualifier
parameters, see 节7.11.6.2.1.
7.11.8.2.1 IDLE Mode Timing Requirements
MIN
2tc(SYSCLK)
MAX
UNIT
Without input qualifier
With input qualifier
tw(WAKE)
Pulse duration, external wake-up signal
cycles
2tc(SYSCLK) + tw(IQSW)
7.11.8.2.2 IDLE Mode Switching Characteristics
over recommended operating conditions (unless otherwise noted)
PARAMETER
TEST CONDITIONS
MIN
MAX UNIT
Without input qualifier
With input qualifier
40tc(SYSCLK) cycles
From Flash (active
state)
40tc(SYSCLK) + tw(WAKE) cycles
(2)
Without input qualifier
6700tc(SYSCLK)
cycles
cycles
Delay time, external wake signal to
program execution resume(1)
From Flash (sleep
state)
(2)
td(WAKE-IDLE)
6700tc(SYSCLK)
+
With input qualifier
tw(WAKE)
Without input qualifier
With input qualifier
25tc(SYSCLK) cycles
From RAM
25tc(SYSCLK) + tw(WAKE) cycles
(1) This is the time taken to begin execution of the instruction that immediately follows the IDLE instruction. Execution of an ISR (triggered
by the wake-up signal) involves additional latency.
(2) This value is based on the flash power-up time, which is a function of the SYSCLK frequency, flash wait states (RWAIT), and
FPAC1[PSLEEP]. This value can be realized when SYSCLK is 200 MHz, RWAIT is 3, and FPAC1[PSLEEP] is 0x860.
7.11.8.2.3 IDLE Entry and Exit Timing Diagram
td(WAKE-IDLE)
Address/Data
(internal)
XCLKOUT
tw(WAKE)
WAKE(A)
A. WAKE can be any enabled interrupt, WDINT or XRSn. After the IDLE instruction is executed, a delay of five OSCCLK cycles (minimum)
is needed before the wake-up signal could be asserted.
图7-26. IDLE Entry and Exit Timing Diagram
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节 7.11.8.2.4 lists the STANDBY mode timing requirements, 节 7.11.8.2.5 lists the STANDBY mode switching
characteristics, and 图7-27 shows the timing diagram for STANDBY mode.
7.11.8.2.4 STANDBY Mode Timing Requirements
MIN
MAX
UNIT
QUALSTDBY = 0 | 2tc(OSCCLK)
QUALSTDBY > 0 |
3tc(OSCCLK)
Pulse duration, external
wake-up signal
tw(WAKE-INT)
cycles
(2 + QUALSTDBY) * tc(OSCCLK)
(1)
(2 + QUALSTDBY)tc(OSCCLK)
(1) QUALSTDBY is a 6-bit field in the LPMCR register.
7.11.8.2.5 STANDBY Mode Switching Characteristics
over recommended operating conditions (unless otherwise noted)
PARAMETER
TEST CONDITIONS
MIN
MAX UNIT
Delay time, IDLE instruction executed to
XCLKOUT stop
td(IDLE-XCOS)
16tc(INTOSC1) cycles
Wakeup from flash
(Flash module in
active state)
td(WAKE-STBY)
175tc(SYSCLK) + tw(WAKE-INT) cycles
Delay time, external wake signal to program
execution resume(1)
Wakeup from flash
(Flash module in
sleep state)
td(WAKE-STBY)
td(WAKE-STBY)
6700tc(SYSCLK) (2) + tw(WAKE-INT) cycles
Wakeup from RAM
3tc(OSC) + 15tc(SYSCLK) + tw(WAKE-INT) cycles
(1) This is the time taken to begin execution of the instruction that immediately follows the IDLE instruction. Execution of an ISR (triggered
by the wake-up signal) involves additional latency.
(2) This value is based on the flash power-up time, which is a function of the SYSCLK frequency, flash wait states (RWAIT), and
FPAC1[PSLEEP]. This value can be realized when SYSCLK is 200 MHz, RWAIT is 3, and FPAC1[PSLEEP] is 0x860.
7.11.8.2.6 STANDBY Entry and Exit Timing Diagram
(C)
(F)
(A)
(B)
(D)(E)
(G)
Device
Status
STANDBY
STANDBY
Normal Execution
Flushing Pipeline
Wake-up
Signal
tw(WAKE-INT)
td(WAKE-STBY)
OSCCLK
XCLKOUT
td(IDLE-XCOS)
A. IDLE instruction is executed to put the device into STANDBY mode.
B. The LPM block responds to the STANDBY signal, SYSCLK is held for a maximum 16 INTOSC1 clock cycles before being turned off.
This delay enables the CPU pipeline and any other pending operations to flush properly.
C. Clock to the peripherals are turned off. However, the PLL and watchdog are not shut down. The device is now in STANDBY mode. After
the IDLE instruction is executed, a delay of five OSCCLK cycles (minimum) is needed before the wake-up signal could be asserted.
D. The external wake-up signal is driven active.
E. The wake-up signal fed to a GPIO pin to wake up the device must meet the minimum pulse width requirement. Furthermore, this signal
must be free of glitches. If a noisy signal is fed to a GPIO pin, the wakeup behavior of the device will not be deterministic and the device
may not exit low-power mode for subsequent wakeup pulses.
F. After a latency period, the STANDBY mode is exited.
G. Normal execution resumes. The device will respond to the interrupt (if enabled).
图7-27. STANDBY Entry and Exit Timing Diagram
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节 7.11.8.2.7 lists the HALT mode timing requirements, 节 7.11.8.2.8 lists the HALT mode switching
characteristics, and 图7-28 shows the timing diagram for HALT mode.
7.11.8.2.7 HALT Mode Timing Requirements
MIN
toscst + 2tc(OSCCLK)
toscst + 8tc(OSCCLK)
MAX
UNIT
cycles
cycles
tw(WAKE-GPIO)
tw(WAKE-XRS)
Pulse duration, GPIO wake-up signal(1)
Pulse duration, XRS wake-up signal(1)
(1) For applications using X1/X2 for OSCCLK, the user must characterize their specific oscillator start-up time as it is dependent on circuit/
layout external to the device. See Crystal Oscillator Electrical Characteristics table for more information. For applications using
INTOSC1 or INTOSC2 for OSCCLK, see Internal Oscillators section for toscst. Oscillator start-up time does not apply to applications
using a single-ended crystal on the X1 pin, as it is powered externally to the device.
7.11.8.2.8 HALT Mode Switching Characteristics
over recommended operating conditions (unless otherwise noted)
PARAMETER
MIN
MAX
UNIT
Delay time, IDLE instruction executed to XCLKOUT
stop
td(IDLE-XCOS)
16tc(INTOSC1) cycles
Delay time, external wake signal end to CPU1 program
execution resume
Wakeup from Flash - Flash module in active state
Wakeup from Flash - Flash module in sleep state
Wakeup from RAM
75tc(OSCCLK)
td(WAKE-HALT)
cycles
(1)
17500tc(OSCCLK)
75tc(OSCCLK)
(1) This value is based on the flash power-up time, which is a function of the SYSCLK frequency, flash wait states (RWAIT), and
FPAC1[PSLEEP]. This value can be realized when SYSCLK is 200 MHz, RWAIT is 3, and FPAC1[PSLEEP] is 0x860.
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7.11.8.2.9 HALT Entry and Exit Timing Diagram
(C)
(F)
(A)
(B)
(D)(E)
HALT
(G)
Device
Status
HALT
Flushing Pipeline
Normal
Execution
GPIOn
td(WAKE-HALT)
tw(WAKE-GPIO)
OSCCLK
Oscillator Start-up Time
XCLKOUT
td(IDLE-XCOS)
A. IDLE instruction is executed to put the device into HALT mode.
B. The LPM block responds to the HALT signal, SYSCLK is held for a maximum 16 INTOSC1 clock cycles before being turned off. This
delay enables the CPU pipeline and any other pending operations to flush properly.
C. Clocks to the peripherals are turned off and the PLL is shut down. If a quartz crystal or ceramic resonator is used as the clock source,
the internal oscillator is shut down as well. The device is now in HALT mode and consumes very little power. It is possible to keep the
zero-pin internal oscillators (INTOSC1 and INTOSC2) and the watchdog alive in HALT MODE. This is done by writing 1 to
CLKSRCCTL1.WDHALTI. After the IDLE instruction is executed, a delay of five OSCCLK cycles (minimum) is needed before the wake-
up signal could be asserted.
D. When the GPIOn pin (used to bring the device out of HALT) is driven low, the oscillator is turned on and the oscillator wake-up
sequence is initiated. The GPIO pin should be driven high only after the oscillator has stabilized. This enables the provision of a clean
clock signal during the PLL lock sequence. Because the falling edge of the GPIO pin asynchronously begins the wake-up procedure,
care should be taken to maintain a low noise environment before entering and during HALT mode.
E. The wake-up signal fed to a GPIO pin to wake up the device must meet the minimum pulse width requirement. Furthermore, this signal
must be free of glitches. If a noisy signal is fed to a GPIO pin, the wake-up behavior of the device will not be deterministic and the
device may not exit low-power mode for subsequent wake-up pulses.
F. When CLKIN to the core is enabled, the device will respond to the interrupt (if enabled), after some latency. The HALT mode is now
exited.
G. Normal operation resumes.
H. The user must relock the PLL upon HALT wakeup to ensure a stable PLL lock.
图7-28. HALT Entry and Exit Timing Diagram
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7.12 Analog Peripherals
The analog subsystem module is described in this section.
The analog modules on this device include the ADC, temperature sensor, and CMPSS.
The analog subsystem has the following features:
• Flexible voltage references
– The ADCs are referenced to VREFHI and VSSA pins
• VREFHI pin voltage can be driven in externally or can be generated by an internal bandgap voltage
reference
• The internal voltage reference range can be selected to be 0V to 3.3V or 0V to 2.5V
– The comparator DACs are referenced to VDDA and VSSA
• Alternately, these DACs can be referenced to the VDAC pin and VSSA
• Flexible pin usage
– Comparator subsystem inputs and digital inputs are multiplexed with ADC inputs
– Internal connection to VREFLO on all ADCs for offset self-calibration
图7-29 shows the Analog Subsystem Block Diagram for the 80-pin PN and 64-pin PM LQFPs.
图7-30 shows the Analog Subsystem Block Diagram for the 48-pin PT LQFP.
表 7-7 lists the analog pins and internal connections. 表 7-8 lists descriptions of analog signals.图 7-31 shows
the analog group connections.
图7-29. Analog Subsystem Block Diagram (80-Pin PN and 64-Pin PM LQFPs)
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图7-30. Analog Subsystem Block Diagram (48-Pin PT LQFP)
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CMPSSx Input MUX
CMPxHPMX
CMPx_HP0
CMPx_HP1
CMPx_HP2
CMPx_HP3
CMPx_HP4
0
1
2
3
CMPx_HP
4
CMPxHNMX
CMPxLNMX
CMPx_HN0
CMPx_HN1
0
1
CMPx_HN
CMPx_LN
CMPx_LN0
CMPx_LN1
0
1
CMPxLPMX
CMPx_LP0
CMPx_LP1
CMPx_LP2
CMPx_LP3
CMPx_LP4
0
1
2
3
CMPx_LP
4
Gx_ADCA
Gx_ADCA
AIO
Gx_ADCC
Gx_ADCC
AIO
图7-31. Analog Group Connections
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Analog Pins and Internal Connections
表7-7. Analog Pins and Internal Connections
Package Pin
ADC
Comparator Subsystem (MUX)
Pin Name
AIO Input
High
Positive
High
Negative
Low
Positive
Low
Negative
80 QFP 64 QFP 48 QFN
A
C
VREFHI
20
21
16
17
12
13
VREFLO
Analog Group 1
A6
A13
C13
CMP1
10
13
14
16
18
6
4(3)
6
A6
A2
-
CMP1 (HPMXSEL=2)
CMP1 (HPMXSEL=0)
CMP1 (LPMXSEL=2)
CMP1 (LPMXSEL=0)
CMP1 (LPMXSEL=3)
CMP1 (LPMXSEL=1)
CMP1 (LPMXSEL=4)
CMP2
AIO228
AIO224
AIO233
AIO237
AIO232
A2/C9
9
C9
C7
C0
-
A15/C7
10
12
14
7
A15
A11
A1
CMP1 (HPMXSEL=3) CMP1 (HNMXSEL=0)
CMP1 (HPMXSEL=1) CMP1 (HNMXSEL=1)
CMP1 (HPMXSEL=4)
CMP1 (LNMXSEL=0)
CMP1 (LNMXSEL=1)
A11/C0
8
A1
10
Analog Group 2
A10/C10
Analog Group 3
C6
29
25
21
A10
C10
CMP2 (HPMXSEL=3) CMP2 (HNMXSEL=0)
CMP2 (LPMXSEL=3)
CMP3
CMP2 (LNMXSEL=0)
AIO230
11
12
15
17
19
7
4(3)
5
-
C6
C5
CMP3 (HPMXSEL=0)
CMP3 (LPMXSEL=0)
CMP3 (LPMXSEL=3)
CMP3 (LPMXSEL=4)
CMP3 (LPMXSEL=1)
CMP3 (LPMXSEL=2)
CMP4
AIO226
AIO242
AIO239
AIO244
AIO231
A3/C5/VDAC(1)
8
A3
A14
A5
A0
CMP3 (HPMXSEL=3) CMP3 (HNMXSEL=0)
CMP3 (HPMXSEL=4)
CMP3 (LNMXSEL=0)
CMP3 (LNMXSEL=1)
A14/C4
11
13
15
-
C4
A5/C2
9
C2
CMP3 (HPMXSEL=1) CMP3 (HNMXSEL=1)
CMP3 (HPMXSEL=2)
A0/C15
11
C15
Analog Group 4
A7/C3
23
19
15
A7
C3
CMP4 (HPMXSEL=1) CMP4 (HNMXSEL=1)
CMP4 (LPMXSEL=1)
CMP2/4
CMP4 (LNMXSEL=1)
CMP2 (LNMXSEL=1)
AIO245
Combined Analog Group 2/4
CMP2 (HPMXSEL=1)
CMP2 (HNMXSEL=1)
CMP4 (HPMXSEL=2)
CMP2 (LPMXSEL=1)
CMP4 (LPMXSEL=2)
A12/C1
A8/C11
A4/C14
A9/C8
22
24
27
28
18
20
23
24
14
16
19
20
A12
A8
C1
C11
C14
C8
AIO238
AIO241
AIO225
AIO227
CMP2 (HPMXSEL=4)
CMP4 (HPMXSEL=4)
CMP2 (LPMXSEL=4)
CMP4 (LPMXSEL=4)
CMP2 (HPMXSEL=0)
CMP4 (HNMXSEL=0)
CMP4 (HPMXSEL=3)
CMP2 (LPMXSEL=0)
CMP4 (LPMXSEL=3)
A4
CMP4 (LNMXSEL=0)
CMP2 (HPMXSEL=2)
CMP4 (HPMXSEL=0)
CMP2 (LPMXSEL=2)
CMP4 (LPMXSEL=0)
A9
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AIO Input
表7-7. Analog Pins and Internal Connections (continued)
Package Pin
ADC
Comparator Subsystem (MUX)
Pin Name
High
Positive
High
Low
Low
Negative
80 QFP 64 QFP 48 QFN
A
C
Negative
Positive
Other Analog
TempSensor(2)
-
-
-
-
C12
(1) Optional external reference voltage for on-chip COMPDACs. There is an internal capacitance to VSSA on this pin whether used for ADC input or COMPDAC reference. If used as a
VDAC reference, place at least a 1-µF capacitor on this pin.
(2) Internal connection only; does not come to a device pin.
(3) A6 and C6 is double bonded as pin # 4.
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Analog Signal Descriptions
表7-8. Analog Signal Descriptions
SIGNAL NAME
DESCRIPTION
AIOx
Digital input on ADC pin
Ax
ADC A Input
ADC C Input
Cx
CMPx_HNy
CMPx_HPy
CMPx_LNy
CMPx_LPy
TempSensor
Comparator subsystem high comparator negative input
Comparator subsystem high comparator positive input
Comparator subsystem low comparator negative input
Comparator subsystem low comparator positive input
Internal temperature sensor
Optional external reference voltage for on-chip COMPDACs. There is an internal capacitance to VSSA on this
pin whether used for ADC input or COMPDAC reference which cannot be disabled. If this pin is being used as
a reference for the on-chip COMPDACs, place at least a 1-uF capacitor on this pin.
VDAC
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7.12.1 Analog-to-Digital Converter (ADC)
The ADC module described here is a successive approximation (SAR) style ADC with resolution of 12 bits. This
section refers to the analog circuits of the converter as the “core,” and includes the channel-select MUX, the
sample-and-hold (S/H) circuit, the successive approximation circuits, voltage reference circuits, and other analog
support circuits. The digital circuits of the converter are referred to as the “wrapper” and include logic for
programmable conversions, result registers, interfaces to analog circuits, interfaces to the peripheral buses,
post-processing circuits, and interfaces to other on-chip modules.
Each ADC module consists of a single sample-and-hold (S/H) circuit. The ADC module is designed to be
duplicated multiple times on the same chip, allowing simultaneous sampling or independent operation of multiple
ADCs. The ADC wrapper is start-of-conversion (SOC)-based (see the SOC Principle of Operation section of the
Analog-to-Digital Converter (ADC) chapter in the TMS320F28002x Real-Time Microcontrollers Technical
Reference Manual).
Each ADC has the following features:
• Resolution of 12 bits
• Ratiometric external reference set by VREFHI/VREFLO
• Selectable internal reference of 2.5 V or 3.3 V
• Single-ended signaling
• Input multiplexer with up to 16 channels
• 16 configurable SOCs
• 16 individually addressable result registers
• Multiple trigger sources
– S/W: software immediate start
– All ePWMs: ADCSOC A or B
– GPIO XINT2
– CPU Timers 0/1/2
– ADCINT1/2
• Four flexible PIE interrupts
• Burst-mode triggering option
• Four post-processing blocks, each with:
– Saturating offset calibration
– Error from setpoint calculation
– High, low, and zero-crossing compare, with interrupt and ePWM trip capability
– Trigger-to-sample delay capture
Note
Not every channel may be pinned out from all ADCs. See 节 6 to determine which channels are
available.
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The block diagram for the ADC core and ADC wrapper are shown in 图7-32.
Analog-to-Digital Core
Analog-to-Digital Wrapper Logic
Input Circuit
SOCx (0-15)
CHSEL
[15:0]
[15:0]
[15:0]
SOC Arbitration
& Control
ACQPS
CHSEL
ADCIN0
ADCIN1
ADCIN2
ADCIN3
ADCIN4
ADCIN5
ADCIN6
ADCIN7
ADCIN8
ADCIN9
ADCIN10
ADCIN11
ADCIN12
ADCIN13
ADCIN14
ADCIN15
0
1
ADCSOC
2
3
.
.
.
.
.
.
4
5
ADCCOUNTER
TRIGGER[15:0]
6
VIN
+
DOUT
7
8
VIN-
9
10
11
12
13
14
15
SOC Delay
Timestamp
Trigger
Timestamp
Converter
S/H Circuit
RESULT
-
+
ADCPPBxOFFCAL
ꢀ
saturate
+
ADCPPBxOFFREF
-
ADCPPBxRESULT
ADCEVT
ꢀ
VREFHI
Event
Logic
CONFIG
ADCEVTINT
Bandgap
Reference Circuit
1.65-V Output
(3.3-V Range)
or
1
Post Processing Block (1-4)
Interrupt Block (1-4)
0
2.5-V Output
(2.5-V Range)
ADCINT1-4
VREFLO
Analog System Control
ANAREFSEL
ANAREFx2PSSEL
Reference Voltage Levels
图7-32. ADC Module Block Diagram
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7.12.1.1 ADC Configurability
Some ADC configurations are individually controlled by the SOCs, while others are globally controlled per ADC
module. 表7-9 summarizes the basic ADC options and their level of configurability.
表7-9. ADC Options and Configuration Levels
OPTIONS
CONFIGURABILITY
Clock
Per module(1)
Resolution
Signal mode
Not configurable (12-bit resolution only)
Not configurable (single-ended signal mode only)
Reference voltage source
Trigger source
Common for both ADC modules
Per SOC(1)
Converted channel
Acquisition window duration
EOC location
Per SOC
Per SOC(1)
Per module
Burst mode
Per module(1)
(1) Writing these values differently to different ADC modules could cause the ADCs to operate
asynchronously. For guidance on when the ADCs are operating synchronously or asynchronously,
see the Ensuring Synchronous Operation section of the Analog-to-Digital Converter (ADC) chapter
in the TMS320F28002x Real-Time Microcontrollers Technical Reference Manual.
7.12.1.1.1 Signal Mode
The ADC supports single-ended signaling. The input voltage to the converter is sampled through a single pin
(ADCINx), referenced to VREFLO. 图7-33 shows the single-ended signaling mode.
Pin Voltage
VREFHI
VREFHI
ADCINx
ADCINx
ADC
VREFHI/2
VREFLO
VREFLO
(VSSA)
Digital Output
2n - 1
ADC Vin
0
图7-33. Single-ended Signaling Mode
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7.12.1.2 ADC Electrical Data and Timing
节7.12.1.2.1 lists the ADC operating conditions. 节7.12.1.2.2 lists the ADC electrical characteristics.
Note
The ADC inputs should be kept below VDDA + 0.3 V during operation. If an ADC input exceeds this
level, the VREF internal to the device may be disturbed, which can impact results for other ADC inputs
using the same VREF
.
Note
The VREFHI pin must be kept below VDDA + 0.3 V to ensure proper functional operation. If the
VREFHI pin exceeds this level, a blocking circuit may activate, and the internal value of VREFHI may
float to 0 V internally, giving improper ADC conversion.
7.12.1.2.1 ADC Operating Conditions
over operating free-air temperature range (unless otherwise noted)
PARAMETER
ADCCLK (derived from PERx.SYSCLK)
Sample rate
TEST CONDITIONS
MIN
TYP
MAX
50
UNIT
MHz
5
100-MHz SYSCLK
3.45
MSPS
Sample window duration (set by ACQPS and
PERx.SYSCLK)(1)
75
ns
With 50 Ωor less Rs
VREFHI
External Reference
2.4
2.5 or 3.0
1.65
VDDA
V
V
V
V
V
V
V
V
Internal Reference = 3.3V Range
Internal Reference = 2.5V Range
VREFHI(2)
2.5
VREFLO
VSSA
VSSA
VDDA
3.3
VREFHI - VREFLO
2.4
Internal Reference = 3.3 V Range
Internal Reference = 2.5 V Range
External Reference
0
0
Conversion range
2.5
VREFLO
VREFHI
(1) The sample window must also be at least as long as 1 ADCCLK cycle for correct ADC operation.
(2) In internal reference mode, the reference voltage is driven out of the VREFHI pin by the device. The user should not drive a voltage
into the pin in this mode.
7.12.1.2.2 ADC Characteristics
over operating free-air temperature range (unless otherwise noted)
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
General
ADCCLK Conversion Cycles
Power Up Time
100-MHz SYSCLK
10.1
11 ADCCLKs
External Reference mode
Internal Reference mode
500
µs
µs
5000
5000
Internal Reference mode, when switching between
2.5-V range and 3.3-V range.
µs
µA
µF
VREFHI input current(1)
130
Internal Reference Capacitor
Value(2)
2.2
2.2
External Reference Capacitor
Value(2)
µF
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7.12.1.2.2 ADC Characteristics (continued)
over operating free-air temperature range (unless otherwise noted)
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
DC Characteristics
Internal reference
45
5
–45
–5
Gain Error
LSB
External reference
±3
±2
2
Offset Error
5
LSB
LSB
–5
Channel-to-Channel Gain Error(4)
Channel-to-Channel Offset
Error(4)
2
LSB
ADC-to-ADC Gain Error(5)
ADC-to-ADC Offset Error(5)
DNL Error
Identical VREFHI and VREFLO for all ADCs
Identical VREFHI and VREFLO for all ADCs
4
2
LSB
LSB
LSB
LSB
LSBs
±0.5
±1.0
1
2
1
>–1
–2
INL Error
ADC-to-ADC Isolation
AC Characteristics
VREFHI = 2.5 V, synchronous ADCs
–1
VREFHI = 2.5 V, fin = 100 kHz, SYSCLK from X1
68.8
60.1
SNR(3)
dB
VREFHI = 2.5 V, fin = 100 kHz, SYSCLK from
INTOSC
THD(3)
VREFHI = 2.5 V, fin = 100 kHz
dB
dB
–80.6
79.2
SFDR(3)
VREFHI = 2.5 V, fin = 100 kHz
VREFHI = 2.5 V, fin = 100 kHz, SYSCLK from X1
68.5
SINAD(3)
ENOB(3)
dB
VREFHI = 2.5 V, fin = 100 kHz, SYSCLK from
INTOSC
60.0
11.0
11.0
VREFHI = 2.5 V, fin = 100 kHz, SYSCLK from
X1, Single ADC
VREFHI = 2.5 V, fin = 100 kHz, SYSCLK from
X1, synchronous ADCs
bits
VREFHI = 2.5 V, fin = 100 kHz, SYSCLK from
X1, asynchronous ADCs
Not
Supported
VDD = 1.2-V DC + 100mV
DC up to Sine at 1 kHz
60
57
60
57
VDD = 1.2-V DC + 100 mV
DC up to Sine at 300 kHz
PSRR
dB
VDDA = 3.3-V DC + 200 mV
DC up to Sine at 1 kHz
VDDA = 3.3-V DC + 200 mV
Sine at 900 kHz
(1) Load current on VREFHI increases when ADC input is greater than VDDA. This causes inaccurate conversions.
(2) A ceramic capacitor with package size of 0805 or smaller is preferred. Up to ±20% tolerance is acceptable.
(3) IO activity is minimized on pins adjacent to ADC input and VREFHI pins as part of best practices to reduce capacitive coupling and
crosstalk.
(4) Variation across all channels belonging to the same ADC module.
(5) Worst case variation compared to other ADC modules.
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7.12.1.2.3 ADC Input Model
The ADC input characteristics are given by 表7-10 and 图7-34.
表7-10. Input Model Parameters
DESCRIPTION
REFERENCE MODE
VALUE
Cp
Parasitic input capacitance
All
See 表7-11
External Reference, 2.5-V Internal
Reference
500 Ω
860 Ω
Ron
Sampling switch resistance
3.3-V Internal Reference
External Reference, 2.5-V Internal
Reference
12.5 pF
Ch
Rs
Sampling capacitor
3.3-V Internal Reference
All
7.5 pF
Nominal source impedance
50 Ω
ADC
ADCINx
Rs
Switch
Ron
AC
Cp
Ch
VREFLO
图7-34. Input Model
This input model should be used with actual signal source impedance to determine the acquisition window
duration. For more information, see the Choosing an Acquisition Window Duration section of the Analog-to-
Digital Converter (ADC) chapter in the TMS320F28002x Real-Time Microcontrollers Technical Reference
Manual.
表7-11 lists the parasitic capacitance on each channel.
表7-11. Per-Channel Parasitic Capacitance
Cp (pF)
ADC CHANNEL
COMPARATOR DISABLED
COMPARATOR ENABLED
ADCINA0/ADCINC15
ADCINA1
3.3
2.4
2.9
71.4
4.5
2.7
2.6
4.2
4.5
3.4
2.9
2.9
4.7
2.5
3.3
2.9
15.8
4.9
5.4
73.9
7
ADCINA2/ADCINC9
ADCINA3/ADCINC5(1)
ADCINA4/ADCINC14
ADCINA5/ADCINC2
ADCINA6
5.2
5.1
6.7
7
ADCINA7/ADCINC3
ADCINA8/ADCINC11
ADCINA9/ADCINC8
ADCINA10/ADCINC10
ADCINA11/ADCINC0
ADCINA12/ADCINC1
ADCINA14/ADCINC4
ADCINA15/ADCINC7
ADCINC6
5.9
5.4
5.4
7.2
5
5.8
5.4
(1) Pin also used to supply reference voltage for COMPDAC and includes an internal decoupling
capacitor.
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7.12.1.2.4 ADC Timing Diagrams
图7-35 shows the ADC conversion timings for two SOCs given the following assumptions:
• SOC0 and SOC1 are configured to use the same trigger.
• No other SOCs are converting or pending when the trigger occurs.
• The round-robin pointer is in a state that causes SOC0 to convert first.
• ADCINTSEL is configured to set an ADCINT flag upon end of conversion for SOC0 (whether this flag
propagates through to the CPU to cause an interrupt is determined by the configurations in the PIE module).
表7-12 lists the descriptions of the ADC timing parameters. 表7-13 lists the ADC timings.
Sample n
Input on SOC0.CHSEL
Input on SOC1.CHSEL
Sample n+1
ADC S+H
SOC0
SOC1
SYSCLK
ADCCLK
ADCTRIG
ADCSOCFLG.SOC0
ADCSOCFLG.SOC1
ADCRESULT0
Sample n
(old data)
(old data)
ADCRESULT1
Sample n+1
ADCINTFLG.ADCINTx
tSH
tLAT
tEOC
tINT
图7-35. ADC Timings
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表7-12. ADC Timing Parameters
PARAMETER
DESCRIPTION
The duration of the S+H window.
At the end of this window, the value on the S+H capacitor becomes the voltage to be converted into a digital
value. The duration is given by (ACQPS + 1) SYSCLK cycles. ACQPS can be configured individually for each
SOC, so tSH will not necessarily be the same for different SOCs.
tSH
Note: The value on the S+H capacitor will be captured approximately 5 ns before the end of the S+H window
regardless of device clock settings.
The time from the end of the S+H window until the ADC results latch in the ADCRESULTx register.
tLAT
If the ADCRESULTx register is read before this time, the previous conversion results will be returned.
The time from the end of the S+H window until the S+H window for the next ADC conversion can begin. The
subsequent sample can start before the conversion results are latched.
tEOC
The time from the end of the S+H window until an ADCINT flag is set (if configured).
If the INTPULSEPOS bit in the ADCCTL1 register is set, tINT will coincide with the conversion results being
latched into the result register.
If the INTPULSEPOS bit is 0, tINT will coincide with the end of the S+H window. If tINT triggers a read of the
ADC result register (directly through DMA or indirectly by triggering an ISR that reads the result), care must be
taken to ensure the read occurs after the results latch (otherwise, the previous results will be read).
tINT
If the INTPULSEPOS bit is 0, and the OFFSET field in the ADCINTCYCLE register is not 0, then there will be a
delay of OFFSET SYSCLK cycles before the ADCINT flag is set. This delay can be used to enter the ISR or
trigger the DMA at exactly the time the sample is ready.
表7-13. ADC Timings
ADCCLK PRESCALE
SYSCLK CYCLES
ADCCLK CYCLES
RATIO
ADCCLK:SYSCLK
(1)
(2)
ADCCTL2 [PRESCALE]
tEOC
tLAT
tINT(EARLY)
tINT(LATE)
tEOC
0
2
1
2
3
4
5
6
7
8
11
21
31
41
51
61
71
81
13
1
1
1
1
1
1
1
1
11
21
31
41
51
61
71
81
11
23
34
44
55
65
76
86
10.5
10.3
10.3
10.2
10.2
10.1
10.1
4
6
8
10
12
14
(1) Refer to the "ADC: DMA Read of Stale Result" advisory in the TMS320F28002x Real-Time MCUs Silicon Errata.
(2) By default, tINT occurs one SYSCLK cycle after the S+H window if INTPULSEPOS is 0. This can be changed by writing to the OFFSET
field in the ADCINTCYCLE register.
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7.12.2 Temperature Sensor
7.12.2.1 Temperature Sensor Electrical Data and Timing
The temperature sensor can be used to measure the device junction temperature. The temperature sensor is
sampled through an internal connection to the ADC and translated into a temperature through TI-provided
software. When sampling the temperature sensor, the ADC must meet the acquisition time in 节7.12.2.1.1.
7.12.2.1.1 Temperature Sensor Characteristics
over recommended operating conditions (unless otherwise noted)
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
Tacc
tstartup
tacq
Temperature Accuracy
External reference
±15
°C
Start-up time
(TSNSCTL[ENABLE] to
sampling temperature sensor)
500
µs
ns
ADC acquisition time
450
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TMS320F280025, TMS320F280025-Q1
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7.12.3 Comparator Subsystem (CMPSS)
Each CMPSS contains two comparators, two reference 12-bit DACs, two digital filters, and one ramp generator.
Comparators are denoted "H" or "L" within each module, where “H” and “L” represent high and low,
respectively. Each comparator generates a digital output that indicates whether the voltage on the positive input
is greater than the voltage on the negative input. The positive input of the comparator can be driven from an
external pin or by the PGA . The negative input can be driven by an external pin or by the programmable
reference 12-bit DAC. Each comparator output passes through a programmable digital filter that can remove
spurious trip signals. An unfiltered output is also available if filtering is not required. A ramp generator circuit is
optionally available to control the reference 12-bit DAC value for the high comparator in the subsystem. There
are two outputs from each CMPSS module. These two outputs pass through the digital filters and crossbar
before connecting to the ePWM modules or GPIO pin. 图7-36 shows the CMPSS connectivity.
Comparator Subsystem1
CTRIP1H
CTRIP1L
CTRIP2H
CTRIP2L
CMP1_HP
CMP1_HN
CTRIP1H
Digital
Filter
VDDA or VDAC
CTRIPOUT1H
DAC12
DAC12
Digital
Filter
CTRIP1L
CMP1_LN
CMP1_LP
CTRIPOUT1L
ePWM X- BAR
ePWMs
Comparator Subsystem2
CMP2_HP
CMP2_HN
CTRIP2H
Digital
Filter
VDDA or VDAC
CTRIPOUT2H
DAC12
DAC12
CTRIP4H
CTRIP4L
Digital
Filter
CTRIP2L
CMP2_LN
CMP2_LP
CTRIPOUT2L
CTRIPOUT1H
CTRIPOUT1L
CTRIPOUT2H
CTRIPOUT2L
Comparator Subsystem4
CMP4_HP
CMP4_HN
CTRIP4H
Digital
Filter
VDDA or VDAC
CTRIPOUT4H
Output X- BAR
GPIO Mux
DAC12
DAC12
Digital
Filter
CTRIP4L
CMP4_LN
CMP4_LP
CTRIPOUT4L
CTRIPOUT4H
CTRIPOUT4L
图7-36. CMPSS Connectivity
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7.12.3.1 CMPSS Electrical Data and Timing
节7.12.3.1.1 lists the comparator electrical characteristics. 图7-37 shows the CMPSS comparator input referred
offset. 图7-38 shows the CMPSS comparator hysteresis.
7.12.3.1.1 Comparator Electrical Characteristics
over recommended operating conditions (unless otherwise noted)
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
500
UNIT
µs
TPU
Power-up time
Comparator input (CMPINxx) range
Input referred offset error
0
VDDA
V
Low common mode, inverting
input set to 50mV
20
mV
–20
1x
12
24
36
48
21
26
30
46
2x
Hysteresis(1)
LSB
3x
4x
Step response
60
Response time (delay from CMPINx input
ns
change to output on ePWM X-BAR or Output Ramp response (1.65V/µs)
X-BAR)
Ramp response (8.25mV/µs)
ns
PSRR
CMRR
Power Supply Rejection Ratio Up to 250 kHz
dB
Common Mode Rejection
Ratio
40
dB
(1) The CMPSS DAC is used as the reference to determine how much hysteresis to apply. Therefore, hysteresis will scale with the
CMPSS DAC reference voltage. Hysteresis is available for all comparator input source configurations.
CMPSS Comparator Input Referred Offset and Hysteresis
Note
The CMPSS inputs must be kept below VDDA + 0.3 V to ensure proper functional operation. If a
CMPSS input exceeds this level, an internal blocking circuit isolates the internal comparator from the
external pin until the external pin voltage returns below VDDA + 0.3 V. During this time, the internal
comparator input is floating and can decay below VDDA within approximately 0.5 µs. After this time,
the comparator could begin to output an incorrect result depending on the value of the other
comparator input.
Input Referred Offset
CTRIPx
Logic Level
CTRIPx = 1
CTRIPx = 0
COMPINxP
Voltage
0
CMPINxN or
DACxVAL
图7-37. CMPSS Comparator Input Referred Offset
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TMS320F280025, TMS320F280025-Q1
TMS320F280025C, TMS320F280025C-Q1, TMS320F280023, TMS320F280023-Q1
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Hysteresis
CTRIPx
Logic Level
CTRIPx = 1
CTRIPx = 0
COMPINxP
Voltage
0
CMPINxN or
DACxVAL
图7-38. CMPSS Comparator Hysteresis
节7.12.3.1.2 lists the CMPSS DAC static electrical characteristics.
7.12.3.1.2 CMPSS DAC Static Electrical Characteristics
over recommended operating conditions (unless otherwise noted)
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
Internal reference
0
0
VDDA
CMPSS DAC output range
V
External reference
VDAC(4)
Static offset error(1)
Static gain error(1)
Static DNL
25
2
mV
% of FSR
LSB
–25
–2
Endpoint corrected
Endpoint corrected
4
>–1
–16
Static INL
16
LSB
Settling to 1LSB after full-scale output
change
Settling time
Resolution
1
µs
12
bits
Error induced by comparator trip or
CMPSS DAC code change within the
same CMPSS module
CMPSS DAC output disturbance(2)
100
LSB
–100
CMPSS DAC disturbance time(2)
VDAC reference voltage
VDAC load(3)
200
VDDA
10
ns
V
When VDAC is reference
When VDAC is reference
2.4
6
2.5 or 3.0
8
kΩ
(1) Includes comparator input referred errors.
(2) Disturbance error may be present on the CMPSS DAC output for a certain amount of time after a comparator trip.
(3) Per active CMPSS module.
(4) The maximum output voltage is VDDA when VDAC > VDDA.
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7.12.3.1.3 CMPSS Illustrative Graphs
图 7-39 shows the CMPSS DAC static offset. 图 7-40 shows the CMPSS DAC static gain. 图 7-41 shows the
CMPSS DAC static linearity.
Offset Error
图7-39. CMPSS DAC Static Offset
Ideal Gain
Actual Gain
图7-40. CMPSS DAC Static Gain
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Linearity Error
图7-41. CMPSS DAC Static Linearity
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TMS320F280025, TMS320F280025-Q1
TMS320F280025C, TMS320F280025C-Q1, TMS320F280023, TMS320F280023-Q1
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7.13 Control Peripherals
7.13.1 Enhanced Pulse Width Modulator (ePWM)
The ePWM peripheral is a key element in controlling many of the power electronic systems found in both
commercial and industrial equipment. The ePWM type-4 module is able to generate complex pulse width
waveforms with minimal CPU overhead by building the peripheral up from smaller modules with separate
resources that can operate together to form a system. Some of the highlights of the ePWM type-4 module
include complex waveform generation, dead-band generation, a flexible synchronization scheme, advanced trip-
zone functionality, and global register reload capabilities.
图7-42 shows the ePWM module. 图7-43 shows the ePWM trip input connectivity.
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TMS320F280025, TMS320F280025-Q1
TMS320F280025C, TMS320F280025C-Q1, TMS320F280023, TMS320F280023-Q1
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Time-Base (TB)
TBPRD Shadow (24)
ePWM
SYNC
Scheme
EXTSYNCIN
EXTSYNCOUT
TBPRDHR (8)
TBPRD Active (24)
CTR=PRD
EPWMxSYNCI
TBCTL[PHSEN]
TBCTL[SWFSYNC]
DCAEVT1/sync(A)
DCBEVT1/sync(A)
Counter
Up/Down
(16 bit)
CTR=ZERO
CTR_Dir
TBCTR
Active (16)
CTR=PRD
EPWMx_INT
CTR=ZERO
TBPHSHR (8)
EPWMxSOCA
EPWMxSOCB
CTR=PRD or ZERO
CTR=CMPA
16
8
On-chip
ADC
Event
Trigger
And
Interrupt
(ET)
Phase
Control
TBPHS Active (24)
CTR=CMPB
CTR=CMPC
CTR=CMPD
CTR_Dir
DCAEVT1.soc(A)
DCBEVT1.soc(A)
ADCSOCOUTSELECT
Counter Compare (CC)
Action
Qualifier
(AQ)
CTR=CMPA
CMPAHR (8)
Select and pulse stretch
for external ADC
16
HiRes PWM (HRPWM)
CMPAHR (8)
EPWMA
ADCSOCAO
ADCSOCBO
CMPA Active (24)
CMPA Shadow (24)
ePWMxA
Trip
Zone
(TZ)
Dead
Band
(DB)
PWM
Chopper
(DB)
CTR=CMPB
CMPBHR (8)
16
CMPB Active (16)
EPWMB
ePWMxB
CMPB Shadow (16)
CMPBHR (8)
CTR=CMPC
EPWMx_TZ_INT
TZ1 to TZ3
TBCNT (16)
CMPC[15-0]
CTR=ZERO
DCAEVT1.inter
DCBEVT1.inter
DCAEVT2.inter
EMUSTOP
16
CLOCKFAIL
CMPC Active (16)
EQEPxERR
DCBEVT2.inter
DCAEVT1.force(A)
DCBEVT1.force(A)
DCAEVT2.force(A)
CMPC Shadow (16)
TBCNT (16)
CTR=CMPD
DCBEVT2.force(A)
CMPD[15-0]
16
CMPD Active (16)
CMPD Shadow (16)
A. These events are generated by the ePWM digital compare (DC) submodule based on the levels of the TRIPIN inputs.
图7-42. ePWM Submodules and Critical Internal Signal Interconnects
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GPIO0
Async/
Sync/
Input X-Bar
Sync+Filter
GPIOx
Other Sources
INPUT[1:16]
16:127
0:15
eCAPx
XINT1
XINT2
XINT3
XINT4
XINT5
ADC
Wrapper(s)
PIE
ePWM
eCAP
Sync Mux
EXTSYNCIN1
EXTSYNCIN2
TZ1
TZ2
TZ3
EPWMINT
TZINT
TRIP1
TRIP2
TRIP3
TRIP6
EPWMx.EPWMCLK
PCLKCR2[EPWMx]
TBCLKSYNC
PCLKCR0[TBCLKSYNC]
TRIP4
TRIP5
TRIP7
TRIP8
TRIP9
TRIP10
TRIP11
TRIP12
INPUT[1:14]
CMPSSx.TRIPH
CMPSSx.TRIPHORL
CMPSSx.TRIPL
ADCx.EVT1-4
ECAPx.OUT
All
ePWM
Modules
ePWM
X-Bar
ADCSOCAO Select
ADCSOCBO Select
EXTSYNCOUT
ADCSOCx
SOCA
SOCB
ADC
Wrapper(s)
Reserved
ECCERR
TRIP13
TRIP14
TRIP15
TZ4
TZ5
TZ6
PIEVECTERROR
EQEPERR
CLKFAIL
EMUSTOP
EPWMSYNCPER
Blanking Window
CMPSS
图7-43. ePWM Trip Input Connectivity
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TMS320F280025, TMS320F280025-Q1
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7.13.1.1 Control Peripherals Synchronization
The ePWM and eCAP synchronization scheme on the device provides flexibility in partitioning the ePWM and
eCAP modules and allows localized synchronization within the modules. Like the other peripherals, the
partitioning of the ePWM and eCAP modules needs to be done using the CPUSELx registers. 图7-44 shows the
synchronization scheme.
TBCTL
SWFSYNC
CTR=ZERO
CTR=CMPB
CTR=CMPC
CTR=CMPD
CLR
DCAEVT1.sync
One Shot
Latch
DCBEVT1.sync
0
Set
Q
EPWMSYNCOUTEN
1
SWEN
ZEROEN
0
0
1
CMPBEN
EPWMxSYNCOUT
1
0
OR
CMPCEN
CMPDEN
DCARVT1EN
DCBEVT1EN
TBCTL2[SELFCLRTRREM]
Clear
Register
Disable
0
EPWM1SYNCOUT
|
|
|
EPWMxSYNCOUT
ECAP1SYNCOUT
HRPCTL[PWMSYNCSELX]
CTR=CMPC UP
EPWMxSYNCIN
|
|
|
CTR=CMPC DOWN
CTR=CMPD UP
ECAPySYNCOUT
Other Sources
EPWMxSYNCPER
CTR=CMPD DOWN
HRPCTL[PWMSYNCSEL]
CTR=PRD
CMPSS
DAC
EPWMSYNCINSEL
Note: SYNCO and SYNCOUT are used interchangeably
CTR=ZERO
图7-44. Synchronization Chain Architecture
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7.13.1.2 ePWM Electrical Data and Timing
节7.13.1.2.1 lists the ePWM timing requirements and 节7.13.1.2.2 lists the ePWM switching characteristics. For
an explanation of the input qualifier parameters, see 节7.11.6.2.1.
7.13.1.2.1 ePWM Timing Requirements
MIN
2tc(EPWMCLK)
MAX
UNIT
Asynchronous
Synchronous
tw(SYNCIN)
Sync input pulse width
2tc(EPWMCLK)
cycles
With input qualifier
1tc(EPWMCLK) + tw(IQSW)
7.13.1.2.2 ePWM Switching Characteristics
over recommended operating conditions (unless otherwise noted)
PARAMETER
MIN
20
MAX
UNIT
ns
tw(PWM)
Pulse duration, PWMx output high/low
Sync output pulse width
tw(SYNCOUT)
8tc(SYSCLK)
cycles
Delay time, trip input active to PWM forced high
Delay time, trip input active to PWM forced low
Delay time, trip input active to PWM Hi-Z
td(TZ-PWM)
25
ns
7.13.1.2.3 Trip-Zone Input Timing
节 7.13.1.2.3.1 lists the trip-zone input timing requirements. 图 7-45 shows the PWM Hi-Z characteristics. For an
explanation of the input qualifier parameters, see 节7.11.6.2.1.
7.13.1.2.3.1 Trip-Zone Input Timing Requirements
MIN
1tc(EPWMCLK)
MAX UNIT
cycles
Asynchronous
Synchronous
tw(TZ)
Pulse duration, TZx input low
2tc(EPWMCLK)
cycles
With input qualifier
1tc(EPWMCLK) + tw(IQSW)
cycles
EPWMCLK
tw(TZ)
TZ(A)
td(TZ-PWM)
PWM(B)
A. TZ: TZ1, TZ2, TZ3, TRIP1–TRIP12
B. PWM refers to all the PWM pins in the device. The state of the PWM pins after TZ is taken high depends on the PWM recovery
software.
图7-45. PWM Hi-Z Characteristics
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7.13.1.3 External ADC Start-of-Conversion Electrical Data and Timing
节7.13.1.3.1 lists the external ADC start-of-conversion switching characteristics. 图7-46 shows the ADCSOCAO
or ADCSOCBO timing.
7.13.1.3.1 External ADC Start-of-Conversion Switching Characteristics
over recommended operating conditions (unless otherwise noted)
PARAMETER
MIN
MAX
UNIT
tw(ADCSOCL)
Pulse duration, ADCSOCxO low
32tc(SYSCLK)
cycles
tw(ADCSOCL)
ADCSOCAO
or
ADCSOCBO
图7-46. ADCSOCAO or ADCSOCBO Timing
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7.13.2 High-Resolution Pulse Width Modulator (HRPWM)
The HRPWM combines multiple delay lines in a single module and a simplified calibration system by using a
dedicated calibration delay line. For each ePWM module, there are two HR outputs:
• HR Duty and Deadband control on Channel A
• HR Duty and Deadband control on Channel B
The HRPWM module offers PWM resolution (time granularity) that is significantly better than what can be
achieved using conventionally derived digital PWM methods. The key points for the HRPWM module are:
• Significantly extends the time resolution capabilities of conventionally derived digital PWM
• This capability can be used in both single edge (duty cycle and phase-shift control) as well as dual edge
control for frequency/period modulation.
• Finer time granularity control or edge positioning is controlled through extensions to the Compare A, B,
phase, period and deadband registers of the ePWM module.
Note
The minimum HRPWMCLK frequency allowed for HRPWM is 60 MHz.
7.13.2.1 HRPWM Electrical Data and Timing
节7.13.2.1.1 lists the high-resolution PWM switching characteristics.
7.13.2.1.1 High-Resolution PWM Characteristics
PARAMETER
MIN
TYP
MAX UNIT
310 ps
Micro Edge Positioning (MEP) step size(1)
150
(1) The MEP step size will be largest at high temperature and minimum voltage on VDD. MEP step size will increase with higher
temperature and lower voltage and decrease with lower temperature and higher voltage.
Applications that use the HRPWM feature should use MEP Scale Factor Optimizer (SFO) estimation software functions. See the TI
software libraries for details of using SFO functions in end applications. SFO functions help to estimate the number of MEP steps per
SYSCLK period dynamically while the HRPWM is in operation.
7.13.3 Enhanced Capture and High-Resolution Capture (eCAP, HRCAP)
The eCAP module can be used in systems where accurate timing of external events is important. eCAP/HRCAP
on this device is Type-2.
Applications for eCAP include:
• Speed measurements of rotating machinery (for example, toothed sprockets sensed through Hall sensors)
• Elapsed time measurements between position sensor pulses
• Period and duty cycle measurements of pulse train signals
• Decoding current or voltage amplitude derived from duty cycle encoded current/voltage sensors
The eCAP module includes the following features:
• 4-event time-stamp registers (each 32 bits)
• Edge-polarity selection for up to four sequenced time-stamp capture events
• Interrupt on either of the four events
• Single shot capture of up to four event timestamps
• Continuous mode capture of timestamps in a four-deep circular buffer
• Absolute time-stamp capture
• Difference (Delta) mode time-stamp capture
• All of the above resources dedicated to a single input pin
• When not used in capture mode, the eCAP module can be configured as a single-channel PWM output
(APWM).
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The capture functionality of the Type-1 eCAP is enhanced from the Type-0 eCAP with the following added
features:
• Event filter reset bit
– Writing a 1 to ECCTL2[CTRFILTRESET] will clear the event filter, the modulo counter, and any pending
interrupts flags. Resetting the bit is useful for initialization and debug.
• Modulo counter status bits
– The modulo counter (ECCTL2 [MODCTRSTS]) indicates which capture register will be loaded next. In the
Type-0 eCAP, it was not possible to know current state of modulo counter.
• DMA trigger source
– eCAPxDMA is added as a DMA trigger. CEVT[1–4] can be configured as the source for eCAPxDMA.
• Input multiplexer
– ECCTL0 [INPUTSEL] selects one of 128 input signals.
• EALLOW protection
– EALLOW protection is added to critical registers. To maintain software compatibility with the Type-0 eCAP,
configure DEV_CFG_REGS.ECAPTYPE to make these registers unprotected.
The capture functionality of the Type-2 eCAP is enhanced from the Type-1 eCAP with the following added
features:
• ECAPxSYNCINSEL register
– The ECAPSxYNCINSEL register is added for each eCAP to select an external SYNCIN. Every eCAP can
have a separate SYNCIN signal.
The eCAP inputs connect to any GPIO input through the Input X-BAR. The APWM outputs connect to GPIO pins
through the Output X-BAR to OUTPUTx positions in the GPIO mux. See 节6.4.3 and 节6.4.4.
The eCAP module is clocked by PERx.SYSCLK.
The clock enable bits (ECAP1–ECAP3) in the PCLKCR3 register turn off the eCAP module individually (for low-
power operation). Upon reset, ECAP1ENCLK is set to low, indicating that the peripheral clock is off.
7.13.3.1 High-Resolution Capture (HRCAP)
The eCAP3 module can be configured as high-resolution capture (HRCAP) submodules. The HRCAP
submodule measures the difference, in time, between pulses asynchronously to the system clock. This
submodule is new to the eCAP Type 1 module, and features many enhancements over the Type 0 HRCAP
module.
Applications for the HRCAP include:
• Capacitive touch applications
• High-resolution period and duty-cycle measurements of pulse train cycles
• Instantaneous speed measurements
• Instantaneous frequency measurements
• Voltage measurements across an isolation boundary
• Distance/sonar measurement and scanning
• Flow measurements
The HRCAP submodule includes the following features:
• Pulse-width capture in either non-high-resolution or high-resolution modes
• Absolute mode pulse-width capture
• Continuous or "one-shot" capture
• Capture on either falling or rising edge
• Continuous mode capture of pulse widths in 4-deep buffer
• Hardware calibration logic for precision high-resolution capture
• All of the resources in this list are available on any pin using the Input X-BAR.
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The HRCAP submodule includes one high-resolution capture channel in addition to a calibration block. The
calibration block allows the HRCAP submodule to be continually recalibrated, at a set interval, with no “down
time”. Because the HRCAP submodule now uses the same hardware as its respective eCAP, if the HRCAP is
used, the corresponding eCAP will be unavailable.
Each high-resolution-capable channel has the following independent key resources.
• All hardware of the respective eCAP
• High-resolution calibration logic
• Dedicated calibration interrupt
eCAP and HRCAP Block Diagram
图7-47 shows the eCAP and HRCAP block diagram.
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ECCTL2 [ SYNCI_EN, SYNCOSEL, SWSYNC]
ECCTL2[CAP/APWM]
APWM Mode
CTRPHS
(phase register−32 bit)
ECAPxSYNCIN
OVF
RST
CTR_OVF
CTR [0−31]
PRD [0−31]
CMP [0−31]
TSCTR
ECAPxSYNCOUT
PWM
Compare
Logic
Output
X-Bar
(counter−32 bit)
Delta−Mode
32
CTR=PRD
CTR=CMP
CTR [0−31]
PRD [0−31]
32
ECCTL1 [ CAPLDEN, CTRRSTx]
HRCTRL[HRE]
32
32
LD1
CAP1
Polarity
Select
LD
(APRD Active)
APRD
32
shadow
CMP [0−31]
32
HRCTRL[HRE]
32
HRCTRL[HRE]
32
CAP2
Polarity
Select
LD2
LD
Other
Sources
(ACMP Active)
[127:16]
[15:0]
Event
Prescale
Event
32
ACMP
16
qualifier
Input
shadow
LD
ECCTL1[PRESCALE]
HRCTRL[HRE]
32
X-Bar
32
Polarity
Select
LD3
LD4
CAP3
(APRD Shadow)
HRCTRL[HRE]
32
32
CAP4
Polarity
Select
LD
(ACMP Shadow)
Edge Polarity Select
ECCTL1[CAPxPOL]
4
Capture Events
4
CEVT[1:4]
ECAPxDMA_INT
ECCTL2[CTRFILTRESET]
Interrupt
Continuous /
Oneshot
Trigger
and
MODCNTRSTS
CTR_OVF
CTR=PRD
CTR=CMP
Capture Control
ECCTL2[DMAEVTSEL]
Flag
Control
ECAPx
(to ePIE)
ECCTL2 [ REARM, CONT_ONESHT, STOP_WRAP]
Registers: ECEINT, ECFLG, ECCLR, ECFRC
Capture Pulse
HR Input
SYSCLK
HRCLK
(A)
HR Submodule
ECAPx_HRCAL
(to ePIE)
Copyright © 2018, Texas Instruments Incorporated
A. The HRCAP submodule is not available on all eCAP modules; in this case, the high-resolution muxes and hardware are not
implemented.
图7-47. eCAP and HRCAP Block Diagram
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7.13.3.2 eCAP/HRCAP Synchronization
The eCAP modules can be synchronized with each other by selecting a common SYNCIN source. SYNCIN
source for eCAP can be either software sync-in or external sync-in. The external sync-in signal can come from
EPWM, eCAP, or X-Bar. The SYNC signal is defined by the selection in the ECAPxSYNCINSEL[SEL] bit for
ECAPx as shown in 图7-48.
ECAPx
Disable
EPWM[1..7]SYNCOUT
0x0
0x1
ECAPxSYNCIN
ECAPxSYNCOUT
EPWMxSYNCOUT
ECCTL2[SWSYNC]
CTR=PRD
EXTSYNCOUT
ECAP[1..3]SYNCOUT
INPUT5 (Input X-Bar)
Disable
Disable
INPUT6 (Input X-Bar)
0x19
SYNCSELECT[SYNCOUT]
ECCTL2[SYNCOSEL]
ECAPSYNCINSEL[SEL]
图7-48. eCAPSynchronization Scheme
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7.13.3.3 eCAP Electrical Data and Timing
节7.13.3.3.1 lists the eCAP timing requirements and 节7.13.3.3.2 lists the eCAP switching characteristics.
7.13.3.3.1 eCAP Timing Requirements
MIN
2tc(SYSCLK)
NOM
MAX
UNIT
Asynchronous
Synchronous
tw(CAP)
Capture input pulse width
2tc(SYSCLK)
ns
With input qualifier
1tc(SYSCLK) + tw_(IQSW)
7.13.3.3.2 eCAP Switching Characteristics
over recommended operating conditions (unless otherwise noted)
PARAMETER
MIN
TYP
MAX
UNIT
ns
tw(APWM)
Pulse duration, APWMx output high/low
20
7.13.3.4 HRCAP Electrical Data and Timing
节 7.13.3.4.1 lists the HRCAP switching characteristics. 图 7-49 shows the HRCAP accuracy precision and
resolution. 图7-50 shows the HRCAP standard deviation characteristics.
7.13.3.4.1 HRCAP Switching Characteristics
over recommended operating conditions (unless otherwise noted)
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
ns
Input pulse width
110
±390
±450
540
ps
Measurement length ≤5 µs
Accuracy(1) (2) (3) (4)
Measurement length > 5 µs
1450
ps
See HRCAP
Standard
Standard deviation
Resolution
Deviation
Characteristics
figure
300
ps
(1) Value obtained using an oscillator of 100 PPM, oscillator accuracy directly affects the HRCAP accuracy.
(2) Measurement is completed using rising-rising or falling-falling edges
(3) Opposite polarity edges will have an additional inaccuracy due to the difference between VIH and VIL. This effect is dependent on the
signal’s slew rate.
(4) Accuracy only applies to time-converted measurements.
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HRCAP Figure and Graph
HRCAP’s Mean
Accuracy
Resolution
(Step Size)
Precision
(Standard Deviation)
Actual
Input Signal
A. The HRCAP has some variation in performance, this results in a probability distribution which is described using the following terms:
•
•
•
Accuracy: The time difference between the input signal and the mean of the HRCAP’s distribution.
Precision: The width of the HRCAP’s distribution, this is given as a standard deviation.
Resolution: The minimum measurable increment.
图7-49. HRCAP Accuracy Precision and Resolution
2
7.4
Typical Core Conditions
Noisy Core Supply
1.8
1.6
1.4
1.2
1
6.66
5.92
5.18
4.44
3.7
0.8
0.6
0.4
0.2
2.96
2.22
1.48
0.74
0
1000
2000
3000
4000
5000
Time Between Edges(nS)
6000
7000
8000
9000
10000
A. Typical core conditions: All peripheral clocks are enabled.
B. Noisy core supply: All core clocks are enabled and disabled with a regular period during the measurement.
C. Fluctuations in current and voltage on the 1.2-V rail cause the standard deviation of the HRCAP to rise. Care should be taken to ensure
that the 1.2-V supply is clean, and that noisy internal events, such as enabling and disabling clock trees, have been minimized while
using the HRCAP.
图7-50. HRCAP Standard Deviation Characteristics
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7.13.4 Enhanced Quadrature Encoder Pulse (eQEP)
The eQEP module on this device is Type-2. The eQEP interfaces directly with linear or rotary incremental
encoders to obtain position, direction, and speed information from rotating machines used in high-performance
motion and position control systems.
The eQEP peripheral contains the following major functional units (see 图7-51):
• Programmable input qualification for each pin (part of the GPIO MUX)
• Quadrature decoder unit (QDU)
• Position counter and control unit for position measurement (PCCU)
• Quadrature edge-capture unit for low-speed measurement (QCAP)
• Unit time base for speed/frequency measurement (UTIME)
• Watchdog timer for detecting stalls (QWDOG)
• Quadrature Mode Adapter (QMA)
System
control registers
To CPU
EQEPxENCLK
SYSCLK
QCPRD
Enhanced QEP (eQEP) peripheral
QCAPCTL
16
QCTMR
16
16
Quadrature
capture unit
(QCAP)
QCTMRLAT
QCPRDLAT
QUTMR
QUPRD
QWDTMR
QWDPRD
Registers
used by
multiple units
32
16
QDECCTL
16
QEPCTL
QEPSTS
QFLG
UTOUT
UTIME
QWDOG
EQEPx_A
EQEPx_B
EQEPxAIN
EQEPxBIN
WDTOUT
QMA
EQEPxINT
QCLK
QDIR
QI
PIE
EQEPxIIN
Quadrature
decoder
(QDU)
32
GPIO
MUX
EQEPx_INDEX
EQEPxIOUT
EQEPxIOE
Position counter/
control unit
(PCCU)
QS
QPOSLAT
PHE
QPOSSLAT
QPOSILAT
PCSOUT
EQEPxSIN
EQEPx_STROBE
EQEPxSOUT
EQEPxSOE
32
32
16
QEINT
QPOSCNT
QPOSINIT
QPOSMAX
QPOSCMP
QFRC
QCLR
QPOSCTL
Copyright © 2017, Texas Instruments Incorporated
图7-51. eQEP Block Diagram
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7.13.4.1 eQEP Electrical Data and Timing
节 7.13.4.1.1 lists the eQEP timing requirements and 节 7.13.4.1.2 lists the eQEP switching characteristics. For
an explanation of the input qualifier parameters, see 节7.11.6.2.1.
7.13.4.1.1 eQEP Timing Requirements
MIN
MAX
UNIT
Synchronous(1)
2tc(SYSCLK)
tw(QEPP)
QEP input period
cycles
Synchronous with input qualifier
Synchronous(1)
2[1tc(SYSCLK) + tw(IQSW)]
2tc(SYSCLK)
2tc(SYSCLK) + tw(IQSW)
2tc(SYSCLK)
tw(INDEXH)
tw(INDEXL)
tw(STROBH)
tw(STROBL)
QEP Index Input High time
QEP Index Input Low time
QEP Strobe High time
QEP Strobe Input Low time
cycles
cycles
cycles
cycles
Synchronous with input qualifier
Synchronous(1)
Synchronous with input qualifier
Synchronous(1)
2tc(SYSCLK) + tw(IQSW)
2tc(SYSCLK)
2tc(SYSCLK) + tw(IQSW)
2tc(SYSCLK)
Synchronous with input qualifier
Synchronous(1)
Synchronous with input qualifier
2tc(SYSCLK) + tw(IQSW)
(1) The GPIO GPxQSELn Asynchronous mode should not be used for eQEP module input pins.
7.13.4.1.2 eQEP Switching Characteristics
over recommended operating conditions (unless otherwise noted)
PARAMETER
MIN
MAX
5tc(SYSCLK)
7tc(SYSCLK)
UNIT
cycles
cycles
td(CNTR)xin
Delay time, external clock to counter increment
td(PCS-OUT)QEP
Delay time, QEP input edge to position compare sync output
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7.14 Communications Peripherals
7.14.1 Controller Area Network (CAN)
Note
The CAN module uses the IP known as DCAN. This document uses the names CAN and DCAN
interchangeably to reference this peripheral.
The CAN module implements the following features:
• Complies with ISO11898-1 ( Bosch® CAN protocol specification 2.0 A and B)
• Bit rates up to 1 Mbps
• Multiple clock sources
• 32 message objects (mailboxes), each with the following properties:
– Configurable as receive or transmit
– Configurable with standard (11-bit) or extended (29-bit) identifier
– Supports programmable identifier receive mask
– Supports data and remote frames
– Holds 0 to 8 bytes of data
– Parity-checked configuration and data RAM
• Individual identifier mask for each message object
• Programmable FIFO mode for message objects
• Programmable loopback modes for self-test operation
• Suspend mode for debug support
• Software module reset
• Automatic bus on after bus-off state by a programmable 32-bit timer
• Two interrupt lines
• DMA support
Note
For a CAN bit clock of 100 MHz, the smallest bit rate possible is 3.90625 kbps.
Note
The accuracy of the on-chip zero-pin oscillator is in 节 7.11.3.5.1. Depending on parameters such as
the CAN bit timing settings, bit rate, bus length, and propagation delay, the accuracy of this oscillator
may not meet the requirements of the CAN protocol. In this situation, an external clock source must be
used.
图7-52 shows the CAN block diagram.
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CAN_H
CAN Bus
CAN_L
3.3V CAN Transceiver
External connections
Device
CANx RX pin
CANx TX pin
CAN
CAN Core
Message RAM
Message Handler
Message
RAM
Interface
Register and Message
Object Access (IFx)
32
Message
Objects
(Mailboxes)
Test Modes
Only
Module Interface
CANINT0 CANINT1
DMA
CPU Bus
图7-52. CAN Block Diagram
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7.14.2 Inter-Integrated Circuit (I2C)
The I2C module has the following features:
• Compliance with the NXP Semiconductors I2C-bus specification (version 2.1):
– Support for 8-bit format transfers
– 7-bit and 10-bit addressing modes
– General call
– START byte mode
– Support for multiple master-transmitters and slave-receivers
– Support for multiple slave-transmitters and master-receivers
– Combined master transmit/receive and receive/transmit mode
– Data transfer rate from 10 kbps up to 400 kbps (Fast-mode)
• One 16-byte receive FIFO and one 16-byte transmit FIFO
• Supports two ePIE interrupts
– I2Cx interrupt –Any of the below conditions can be configured to generate an I2Cx interrupt:
• Transmit Ready
• Receive Ready
• Register-Access Ready
• No-Acknowledgment
• Arbitration-Lost
• Stop Condition Detected
• Addressed-as-Slave
– I2Cx_FIFO interrupts:
• Transmit FIFO interrupt
• Receive FIFO interrupt
• Module enable and disable capability
• Free data format mode
图7-53 shows how the I2C peripheral module interfaces within the device.
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TMS320F280025, TMS320F280025-Q1
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I2C module
I2CXSR
I2CDXR
TX FIFO
RX FIFO
FIFO Interrupt
to CPU/PIE
SDA
Peripheral bus
I2CRSR
I2CDRR
Control/status
registers
CPU
Clock
synchronizer
SCL
Prescaler
Noise filters
Arbitrator
Interrupt to
CPU/PIE
I2C INT
图7-53. I2C Peripheral Module Interfaces
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7.14.2.1 I2C Electrical Data and Timing
节 7.14.2.1.1 lists the I2C timing requirements. 节 7.14.2.1.2 lists the I2C switching characteristics. 图 7-54
shows the I2C timing diagram.
Note
To meet all of the I2C protocol timing specifications, the I2C module clock must be configured in the
range from 7 MHz to 12 MHz.
7.14.2.1.1 I2C Timing Requirements
NO.
MIN
MAX
UNIT
Standard mode
T0
T1
fmod
I2C module frequency
7
12
MHz
µs
Hold time, START condition, SCL fall delay after
SDA fall
th(SDA-SCL)START
4.0
Setup time, Repeated START, SCL rise before SDA
fall delay
T2
tsu(SCL-SDA)START
4.7
µs
T3
T4
T5
T6
T7
T8
th(SCL-DAT)
tsu(DAT-SCL)
tr(SDA)
Hold time, data after SCL fall
Setup time, data before SCL rise
Rise time, SDA
0
µs
ns
ns
ns
ns
ns
250
1000
1000
300
tr(SCL)
Rise time, SCL
tf(SDA)
Fall time, SDA
tf(SCL)
Fall time, SCL
300
Setup time, STOP condition, SCL rise before SDA
rise delay
T9
tsu(SCL-SDA)STOP
4.0
0
µs
Pulse duration of spikes that will be suppressed by
filter
T10
tw(SP)
Cb
50
ns
T11
capacitance load on each bus line
400
pF
Fast mode
T0
fmod
I2C module frequency
7
12
MHz
µs
Hold time, START condition, SCL fall delay after
SDA fall
T1
T2
th(SDA-SCL)START
0.6
Setup time, Repeated START, SCL rise before SDA
fall delay
tsu(SCL-SDA)START
0.6
µs
T3
T4
T5
T6
T7
T8
th(SCL-DAT)
tsu(DAT-SCL)
tr(SDA)
Hold time, data after SCL fall
Setup time, data before SCL rise
Rise time, SDA
0
100
20
µs
ns
ns
ns
ns
ns
300
300
300
300
tr(SCL)
Rise time, SCL
20
tf(SDA)
Fall time, SDA
11.4
11.4
tf(SCL)
Fall time, SCL
Setup time, STOP condition, SCL rise before SDA
rise delay
T9
tsu(SCL-SDA)STOP
0.6
0
µs
Pulse duration of spikes that will be suppressed by
filter
T10
T11
tw(SP)
Cb
50
ns
capacitance load on each bus line
400
pF
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MAX UNIT
7.14.2.1.2 I2C Switching Characteristics
over recommended operating conditions (unless otherwise noted)
NO.
PARAMETER
TEST CONDITIONS
MIN
Standard mode
S1
S2
S3
S4
fSCL
SCL clock frequency
0
10
100
kHz
µs
TSCL
SCL clock period
tw(SCLL)
tw(SCLH)
Pulse duration, SCL clock low
Pulse duration, SCL clock high
4.7
4.0
µs
µs
Bus free time between STOP and START
conditions
S5
tBUF
4.7
µs
S6
S7
S8
tv(SCL-DAT)
tv(SCL-ACK)
II
Valid time, data after SCL fall
Valid time, Acknowledge after SCL fall
Input current on pins
3.45
3.45
10
µs
µs
µA
0.1 Vbus < Vi < 0.9 Vbus
–10
Fast mode
S1
S2
S3
S4
fSCL
SCL clock frequency
0
2.5
1.3
0.6
400
kHz
µs
TSCL
SCL clock period
tw(SCLL)
tw(SCLH)
Pulse duration, SCL clock low
Pulse duration, SCL clock high
µs
µs
Bus free time between STOP and START
conditions
S5
tBUF
1.3
µs
S6
S7
S8
tv(SCL-DAT)
tv(SCL-ACK)
II
Valid time, data after SCL fall
Valid time, Acknowledge after SCL fall
Input current on pins
0.9
0.9
10
µs
µs
µA
0.1 Vbus < Vi < 0.9 Vbus
–10
7.14.2.1.3 I2C Timing Diagram
STOP
START
SDA
SCL
ACK
Contd...
Contd...
S7
S6
T10
T5
T7
S3
S4
9th
clock
T6
T8
S2
Repeated
START
STOP
S5
SDA
ACK
T2
T9
T1
SCL
9th
clock
图7-54. I2C Timing Diagram
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7.14.3 Power Management Bus (PMBus) Interface
The PMBus module has the following features:
• Compliance with the SMI Forum PMBus Specification (Part I v1.0 and Part II v1.1)
• Support for master and slave modes
• Support for I2C mode
• Support for two speeds:
– Standard Mode: Up to 100 kHz
– Fast Mode: 400 kHz
• Packet error checking
• CONTROL and ALERT signals
• Clock high and low time-outs
• Four-byte transmit and receive buffers
• One maskable interrupt, which can be generated by several conditions:
– Receive data ready
– Transmit buffer empty
– Slave address received
– End of message
– ALERT input asserted
– Clock low time-out
– Clock high time-out
– Bus free
图7-55 shows the PMBus block diagram.
PCLKCR20
SYSCLK
PMBCTRL
Div
ALERT
CTL
DMA
CPU
PIE
Bit clock
Other registers
GPIO Mux
PMBTXBUF
SCL
Shift register
PMBRXBUF
SDA
PMBUSA_INT
PMBus Module
图7-55. PMBus Block Diagram
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7.14.3.1 PMBus Electrical Data and Timing
节 7.14.3.1.1 lists the PMBus electrical characteristics. 节 7.14.3.1.2 lists the PMBUS fast mode switching
characteristics. 节7.14.3.1.3 lists the PMBUS standard mode switching characteristics.
7.14.3.1.1 PMBus Electrical Characteristics
over recommended operating conditions (unless otherwise noted)
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
0.8
UNIT
V
VIL
VIH
VOL
IOL
Valid low-level input voltage
Valid high-level input voltage
Low-level output voltage
Low-level output current
2.1
VDDIO
0.4
V
At Ipullup = 4 mA
V
4
0
mA
VOL ≤0.4 V
Pulse width of spikes that must be
suppressed by the input filter
tSP
50
ns
Ii
Input leakage current on each pin
Capacitance on each pin
0.1 Vbus < Vi < 0.9 Vbus
10
10
µA
pF
–10
Ci
7.14.3.1.2 PMBus Fast Mode Switching Characteristics
over recommended operating conditions (unless otherwise noted)
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
fSCL
tBUF
SCL clock frequency
10
400
kHz
Bus free time between STOP and
START conditions
1.3
0.6
0.6
0.6
µs
µs
µs
µs
START condition hold time -- SDA fall
to SCL fall delay
tHD;STA
tSU;STA
tSU;STO
Repeated START setup time -- SCL
rise to SDA fall delay
STOP condition setup time -- SCL rise
to SDA rise delay
tHD;DAT
tSU;DAT
tTimeout
tLOW
Data hold time after SCL fall
Data setup time before SCL rise
Clock low time-out
300
100
25
ns
ns
ms
µs
µs
35
Low period of the SCL clock
High period of the SCL clock
1.3
0.6
tHIGH
50
25
Cumulative clock low extend time
(slave device)
tLOW;SEXT
tLOW;MEXT
From START to STOP
Within each byte
ms
ms
Cumulative clock low extend time
(master device)
10
tr
tf
Rise time of SDA and SCL
Fall time of SDA and SCL
5% to 95%
95% to 5%
20
20
300
300
ns
ns
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7.14.3.1.3 PMBus Standard Mode Switching Characteristics
over recommended operating conditions (unless otherwise noted)
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
fSCL
tBUF
SCL clock frequency
10
100
kHz
Bus free time between STOP and
START conditions
4.7
4
µs
µs
µs
µs
START condition hold time -- SDA fall
to SCL fall delay
tHD;STA
tSU;STA
tSU;STO
Repeated START setup time -- SCL
rise to SDA fall delay
4.7
4
STOP condition setup time -- SCL rise
to SDA rise delay
tHD;DAT
tSU;DAT
tTimeout
tLOW
Data hold time after SCL fall
Data setup time before SCL rise
Clock low time-out
300
250
25
ns
ns
ms
µs
µs
35
Low period of the SCL clock
High period of the SCL clock
4.7
4
tHIGH
50
25
Cumulative clock low extend time
(slave device)
tLOW;SEXT
tLOW;MEXT
From START to STOP
Within each byte
ms
ms
Cumulative clock low extend time
(master device)
10
tr
tf
Rise time of SDA and SCL
Fall time of SDA and SCL
1000
300
ns
ns
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7.14.4 Serial Communications Interface (SCI)
The SCI is a 2-wire asynchronous serial port, commonly known as a UART. The SCI module supports digital
communications between the CPU and other asynchronous peripherals that use the standard non-return-to-zero
(NRZ) format
The SCI receiver and transmitter each have a 16-level-deep FIFO for reducing servicing overhead, and each has
its own separate enable and interrupt bits. Both can be operated independently for half-duplex communication,
or simultaneously for full-duplex communication. To specify data integrity, the SCI checks received data for break
detection, parity, overrun, and framing errors. The bit rate is programmable to different speeds through a 16-bit
baud-select register.
Features of the SCI module include:
• Two external pins:
– SCITXD: SCI transmit-output pin
– SCIRXD: SCI receive-input pin
– Baud rate programmable to 64K different rates
• Data-word format
– 1 start bit
– Data-word length programmable from 1 to 8 bits
– Optional even/odd/no parity bit
– 1 or 2 stop bits
• Four error-detection flags: parity, overrun, framing, and break detection
• Two wake-up multiprocessor modes: idle-line and address bit
• Half- or full-duplex operation
• Double-buffered receive and transmit functions
• Transmitter and receiver operations can be accomplished through interrupt-driven or polled algorithms with
status flags.
– Transmitter: TXRDY flag (transmitter-buffer register is ready to receive another character) and TX EMPTY
flag (transmitter-shift register is empty)
– Receiver: RXRDY flag (receiver-buffer register is ready to receive another character), BRKDT flag (break
condition occurred), and RX ERROR flag (monitoring four interrupt conditions)
• Separate enable bits for transmitter and receiver interrupts (except BRKDT)
• NRZ format
• Auto baud-detect hardware logic
• 16-level transmit and receive FIFO
Note
All registers in this module are 8-bit registers. When a register is accessed, the register data is in the
lower byte (bits 7–0), and the upper byte (bits 15–8) is read as zeros. Writing to the upper byte has
no effect.
图7-56 shows the SCI block diagram.
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TXENA
SCICTL1.1
TXSHF
SCITXD
Register
Frame
Format and Mode
8
Parity
Even/Odd
TXEMPTY
0
1
SCICTL2.6
SCICCR.6
8
Enable
TX FIFO_0
TX FIFO_1
TXINT
To CPU
SCICCR.5
TX Interrupt
Logic
TX FIFO Interrupts
8
TX FIFO_N
TXINTENA
SCICTL2.0
TXRDY
8
1
0
TXWAKE
SCICTL2.7
SCICTL1.3
SCI TX Interrupt Select Logic
8
WUT
Transmit Data
Buffer Register
SCITXBUF.7-0
Auto Baud Detect Logic
RXENA
Baud Rate
MSB/LSB
Registers
SCICTL1.0
LSPCLK
RXSHF
Register
SCIRXD
SCIHBAUD.15-8
SCILBAUD.7-0
RXWAKE
8
SCIRXST.1
0
1
8
SCIFFENA
SCIFFTX.14
RX FIFO_0
RX FIFO_1
RXINT
To CPU
8
RX FIFO Interrupts
RX Interrupt
Logic
RX FIFO_N
RXFFOVF
8
1
SCIFFRX.15
0
RXBKINTENA
SCICTL2.1
RXRDY
SCIRXST.6
RXENA
BRKDT
RXERRINTENA
SCICTL1.6
SCICTL1.0
SCIRXST.5
SCI RX Interrupt Select Logic
8
SCIRXST.5-2
BRKDT FE OE PE
RXERROR
Receive Data
Buffer Register
SCIRXBUF.7-0
SCIRXST.7
图7-56. SCI Block Diagram
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7.14.5 Serial Peripheral Interface (SPI)
The serial peripheral interface (SPI) is a high-speed synchronous serial input and output (I/O) port that allows a
serial bit stream of programmed length (1 to 16 bits) to be shifted into and out of the device at a programmed bit-
transfer rate. The SPI is normally used for communications between the MCU controller and external peripherals
or another controller. Typical applications include external I/O or peripheral expansion through devices such as
shift registers, display drivers, and analog-to-digital converters (ADCs). Multidevice communications are
supported by the master or slave operation of the SPI. The port supports a 16-level, receive and transmit FIFO
for reducing CPU servicing overhead.
The SPI module features include:
• SPISOMI: SPI slave-output/master-input pin
• SPISIMO: SPI slave-input/master-output pin
• SPISTE: SPI slave transmit-enable pin
• SPICLK: SPI serial-clock pin
• Two operational modes: Master and Slave
• Baud rate: 125 different programmable rates. The maximum baud rate that can be employed is limited by the
maximum speed of the I/O buffers used on the SPI pins.
• Data word length: 1 to 16 data bits
• Four clocking schemes (controlled by clock polarity and clock phase bits) include:
– Falling edge without phase delay: SPICLK active-high. SPI transmits data on the falling edge of the
SPICLK signal and receives data on the rising edge of the SPICLK signal.
– Falling edge with phase delay: SPICLK active-high. SPI transmits data one half-cycle ahead of the falling
edge of the SPICLK signal and receives data on the falling edge of the SPICLK signal.
– Rising edge without phase delay: SPICLK inactive-low. SPI transmits data on the rising edge of the
SPICLK signal and receives data on the falling edge of the SPICLK signal.
– Rising edge with phase delay: SPICLK inactive-low. SPI transmits data one half-cycle ahead of the rising
edge of the SPICLK signal and receives data on the rising edge of the SPICLK signal.
• Simultaneous receive and transmit operation (transmit function can be disabled in software)
• Transmitter and receiver operations are accomplished through either interrupt-driven or polled algorithm
• 16-level transmit/receive FIFO
• DMA support
• High-speed mode
• Delayed transmit control
• 3-wire SPI mode
• SPISTE inversion for digital audio interface receive mode on devices with two SPI modules
图7-57 shows the SPI CPU interfaces.
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PCLKCR8
Low-Speed
Prescaler
CPU
LSPCLK
SYSCLK
Bit Clock
SYSRS
SPISIMO
SPISOMI
SPICLK
SPISTE
SPI
GPIO MUX
SPIINT
PIE
SPITXINT
SPIRXDMA
SPITXDMA
DMA
图7-57. SPI CPU Interface
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TMS320F280025, TMS320F280025-Q1
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7.14.5.1 SPI Master Mode Timings
The following section contains the SPI Master Mode Timings. For more information about the SPI in High-Speed
mode, see the Serial Peripheral Interface (SPI) chapter of the TMS320F28002x Real-Time Microcontrollers
Technical Reference Manual.
节7.14.5.1.1 lists the SPI master mode timing requirements.
节 7.14.5.1.2 lists the SPI master mode switching characteristics where the clock phase = 0. 图 7-58 shows the
SPI master mode external timing where the clock phase = 0.
节 7.14.5.1.3 lists the SPI master mode switching characteristics where the clock phase = 1. 图 7-59 shows the
SPI master mode external timing where the clock phase = 1.
Note
All timing parameters for SPI High-Speed Mode assume a load capacitance of 5 pF on SPICLK,
SPISIMO, and SPISOMI.
7.14.5.1.1 SPI Master Mode Timing Requirements
NO.
(BRR + 1) (1)
MIN
MAX UNIT
High-Speed Mode
8
9
tsu(SOMI)M
th(SOMI)M
Setup time, SPISOMI valid before SPICLK
Hold time, SPISOMI valid after SPICLK
Even, Odd
Even, Odd
1
5
ns
ns
Normal Mode
8
9
tsu(SOMI)M
th(SOMI)M
Setup time, SPISOMI valid before SPICLK
Hold time, SPISOMI valid after SPICLK
Even, Odd
Even, Odd
15
0
ns
ns
(1) The (BRR + 1) condition is Even when (SPIBRR + 1) is even or SPIBRR is 0 or 2. It is Odd when (SPIBRR + 1) is odd and SPIBRR is
greater than 3.
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7.14.5.1.2 SPI Master Mode Switching Characteristics (Clock Phase = 0)
over recommended operating conditions (unless otherwise noted)
NO.
PARAMETER
(BRR + 1)(1)
MIN
MAX UNIT
General
Even
Odd
4tc(LSPCLK)
5tc(LSPCLK)
128tc(LSPCLK)
1
tc(SPC)M
Cycle time, SPICLK
ns
ns
127tc(LSPCLK)
Even
0.5tc(SPC)M + 1
0.5tc(SPC)M –1
2
tw(SPC1)M Pulse duration, SPICLK, first pulse
0.5tc(SPC)M
+
Odd
Even
Odd
0.5tc(SPC)M + 0.5tc(LSPCLK) –1
0.5tc(SPC)M –1
0.5tc(LSPCLK) + 1
0.5tc(SPC)M + 1
3
tw(SPC2)M Pulse duration, SPICLK, second pulse
ns
ns
ns
0.5tc(SPC)M
–
0.5tc(SPC)M –0.5tc(LSPCLK) –1
0.5tc(LSPCLK) + 1
1.5tc(SPC)M
–
Even
1.5tc(SPC)M –3tc(SYSCLK) –3
3tc(SYSCLK) + 3
23
24
td(SPC)M
Delay time, SPISTE active to SPICLK
Valid time, SPICLK to SPISTE inactive
1.5tc(SPC)M
–
Odd
Even
Odd
1.5tc(SPC)M –4tc(SYSCLK) –3
0.5tc(SPC)M –3
4tc(SYSCLK) + 3
0.5tc(SPC)M + 3
tv(STE)M
0.5tc(SPC)M
–
0.5tc(SPC)M –0.5tc(LSPCLK) –3
0.5tc(LSPCLK) + 3
High-Speed Mode
4
td(SIMO)M Delay time, SPICLK to SPISIMO valid Even, Odd
1
ns
ns
Even
0.5tc(SPC)M –3
Valid time, SPISIMO valid after
5
tv(SIMO)M
SPICLK
Odd
0.5tc(SPC)M –0.5tc(LSPCLK) –3
Normal Mode
4
td(SIMO)M Delay time, SPICLK to SPISIMO valid Even, Odd
1
ns
ns
Even
Odd
0.5tc(SPC)M –3
Valid time, SPISIMO valid after
SPICLK
5
tv(SIMO)M
0.5tc(SPC)M –0.5tc(LSPCLK) –3
(1) The (BRR + 1) condition is Even when (SPIBRR + 1) is even or SPIBRR is 0 or 2. It is Odd when (SPIBRR + 1) is odd and SPIBRR is
greater than 3.
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MAX UNIT
7.14.5.1.3 SPI Master Mode Switching Characteristics (Clock Phase = 1)
over recommended operating conditions (unless otherwise noted)
NO.
PARAMETER
(BRR + 1)
MIN
General
Even
Odd
4tc(LSPCLK)
5tc(LSPCLK)
128tc(LSPCLK)
1
tc(SPC)M
Cycle time, SPICLK
ns
ns
127tc(LSPCLK)
Even
0.5tc(SPC)M + 1
0.5tc(SPC)M –1
2
tw(SPCH)M Pulse duration, SPICLK, first pulse
0.5tc(SPC)M
–
Odd
Even
Odd
0.5tc(SPC)M –0.5tc(LSPCLK) –1
0.5tc(SPC)M –1
0.5tc(LSPCLK) + 1
0.5tc(SPC)M + 1
3
tw(SPC2)M Pulse duration, SPICLK, second pulse
ns
0.5tc(SPC)M
+
0.5tc(SPC)M + 0.5tc(LSPCLK) –1
0.5tc(LSPCLK) + 1
2tc(SPC)M
3tc(SYSCLK) + 2
–
23
24
td(SPC)M
Delay time, SPISTE valid to SPICLK
Delay time, SPICLK to SPISTE invalid
Even, Odd
ns
ns
2tc(SPC)M –3tc(SYSCLK) –3
Even
Odd
2
2
–3
–3
td(STE)M
High-Speed Mode
Even
Odd
0.5tc(SPC)M –2
0.5tc(SPC)M + 0.5tc(LSPCLK) –2
0.5tc(SPC)M –3
4
5
td(SIMO)M Delay time, SPISIMO valid to SPICLK
ns
ns
Even
Odd
Valid time, SPISIMO valid after
tv(SIMO)M
SPICLK
0.5tc(SPC)M –0.5tc(LSPCLK) –3
Normal Mode
Even
Odd
0.5tc(SPC)M –2
0.5tc(SPC)M + 0.5tc(LSPCLK) –2
0.5tc(SPC)M –3
4
5
td(SIMO)M Delay time, SPISIMO valid to SPICLK
ns
ns
Even
Odd
Valid time, SPISIMO valid after
SPICLK
tv(SIMO)M
0.5tc(SPC)M –0.5tc(LSPCLK) –3
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7.14.5.1.4 SPI Master Mode Timing Diagrams
1
SPICLK
(clock polarity = 0)
2
3
SPICLK
(clock polarity = 1)
4
5
SPISIMO
Master Out Data Is Valid
8
9
Master In Data
Must Be Valid
SPISOMI
SPISTE(A)
24
23
A. On the trailing end of the word, SPISTE will go inactive except between back-to-back transmit words in both FIFO and non-FIFO
modes.
图7-58. SPI Master Mode External Timing (Clock Phase = 0)
1
SPICLK
(clock polarity = 0)
2
3
SPICLK
(clock polarity = 1)
4
5
SPISIMO
Master Out Data Is Valid
8
9
Master In Data Must
Be Valid
SPISOMI
SPISTE(A)
24
23
A. On the trailing end of the word, SPISTE will go inactive except between back-to-back transmit words in both FIFO and non-FIFO
modes.
图7-59. SPI Master Mode External Timing (Clock Phase = 1)
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7.14.5.2 SPI Slave Mode Timings
The following section contains the SPI Slave Mode Timings. For more information about the SPI in High-Speed
mode, see the Serial Peripheral Interface (SPI) chapter of the TMS320F28002x Real-Time Microcontrollers
Technical Reference Manual.
节 7.14.5.2.1 lists the SPI slave mode timing requirements. 节 7.14.5.2.2 lists the SPI slave mode switching
characteristics.
图 7-60 shows the SPI slave mode external timing where the clock phase = 0. 图 7-61 shows the SPI slave
mode external timing where the clock phase = 1.
7.14.5.2.1 SPI Slave Mode Timing Requirements
NO.
MIN
4tc(SYSCLK)
MAX UNIT
12
tc(SPC)S
Cycle time, SPICLK
ns
ns
ns
ns
ns
13
14
19
20
tw(SPC1)S
tw(SPC2)S
tsu(SIMO)S
th(SIMO)S
Pulse duration, SPICLK, first pulse
Pulse duration, SPICLK, second pulse
Setup time, SPISIMO valid before SPICLK
Hold time, SPISIMO valid after SPICLK
2tc(SYSCLK) –1
2tc(SYSCLK) –1
1.5tc(SYSCLK)
1.5tc(SYSCLK)
Setup time, SPISTE valid before SPICLK
(Clock Phase = 0)
2tc(SYSCLK) + 3
ns
25
26
tsu(STE)S
Setup time, SPISTE valid before SPICLK
(Clock Phase = 1)
2tc(SYSCLK) + 23
1.5tc(SYSCLK)
ns
ns
th(STE)S
Hold time, SPISTE invalid after SPICLK
7.14.5.2.2 SPI Slave Mode Switching Characteristics
over recommended operating conditions (unless otherwise noted)
NO.
15
16
PARAMETER
MIN
MAX UNIT
td(SOMI)S
tv(SOMI)S
Delay time, SPICLK to SPISOMI valid
Valid time, SPISOMI valid after SPICLK
12
ns
ns
0
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7.14.5.2.3 SPI Slave Mode Timing Diagrams
12
SPICLK
(clock polarity = 0)
13
14
SPICLK
(clock polarity = 1)
15
16
SPISOMI
SPISOMI Data Is Valid
19
20
SPISIMO Data
Must Be Valid
SPISIMO
SPISTE
25
26
图7-60. SPI Slave Mode External Timing (Clock Phase = 0)
12
SPICLK
(clock polarity = 0)
13
14
SPICLK
(clock polarity = 1)
15
SPISOMI
SPISOMI Data Is Valid
Data Valid
Data Valid
16
19
20
SPISIMO Data
Must Be Valid
SPISIMO
SPISTE
26
25
图7-61. SPI Slave Mode External Timing (Clock Phase = 1)
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7.14.6 Local Interconnect Network (LIN)
This device contains one Local Interconnect Network (LIN) module. The LIN module adheres to the LIN 2.1
standard as defined by the LIN Specification Package Revision 2.1. The LIN is a low-cost serial interface
designed for applications where the CAN protocol may be too expensive to implement, such as small
subnetworks for cabin comfort functions like interior lighting or window control in an automotive application.
The LIN standard is based on the SCI (UART) serial data link format. The communication concept is single-
master and multiple-slave with a message identification for multicast transmission between any network nodes.
The LIN module can be programmed to work either as an SCI or as a LIN as the core of the module is an SCI.
The hardware features of the SCI are augmented to achieve LIN compatibility. The SCI module is a universal
asynchronous receiver-transmitter (UART) that implements the standard non-return-to-zero format.
Though the registers are common for LIN and SCI, the register descriptions have notes to identify the register/bit
usage in different modes. Because of this, code written for this module cannot be directly ported to the stand-
alone SCI module and vice versa.
The LIN module has the following features:
• Compatibility with LIN 1.3, 2.0 and 2.1 protocols
• Configurable baud rate up to 20 kbps (as per LIN 2.1 protocol)
• Two external pins: LINRX and LINTX
• Multibuffered receive and transmit units
• Identification masks for message filtering
• Automatic master header generation
– Programmable synchronization break field
– Synchronization field
– Identifier field
• Slave automatic synchronization
– Synchronization break detection
– Optional baud rate update
– Synchronization validation
• 231 programmable transmission rates with 7 fractional bits
• Wakeup on LINRX dominant level from transceiver
• Automatic wakeup support
– Wakeup signal generation
– Expiration times on wakeup signals
• Automatic bus idle detection
• Error detection
– Bit error
– Bus error
– No-response error
– Checksum error
– Synchronization field error
– Parity error
• Capability to use direct memory access (DMA) for transmit and receive data
• Two interrupt lines with priority encoding for:
– Receive
– Transmit
– ID, error, and status
• Support for LIN 2.0 checksum
• Enhanced synchronizer finite state machine (FSM) support for frame processing
• Enhanced handling of extended frames
• Enhanced baud rate generator
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• Update wakeup/go to sleep
图7-62 shows the LIN block diagram.
READ DATA BUS
WRITE DATA BUS
ADDRESS BUS
CHECKSUM
CALCULATOR
INTERFACE
ID PARTY
CHECKER
BIT
MONITOR
TXRX ERROR
DETECTOR (TED)
TIME-OUT
CONTROL
COUNTER
COMPARE
LINRX/
SCIRX
LINTX/
SCITX
DMA
CONTROL
MASK
FILTER
8 RECEIVE
BUFFERS
FSM
8 TRANSMIT
BUFFERS
SYNCHRONIZER
图7-62. LIN Block Diagram
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7.14.7 Fast Serial Interface (FSI)
The Fast Serial Interface (FSI) module is a serial communication peripheral capable of reliable and robust high-
speed communications. The FSI is designed to ensure data robustness across many system conditions such as
chip-to-chip as well as board-to-board across an isolation barrier. Payload integrity checks such as CRC, start-
and end-of-frame patterns, and user-defined tags, are encoded before transmit and then verified after receipt
without additional CPU interaction. Line breaks can be detected using periodic transmissions, all managed and
monitored by hardware. The FSI is also tightly integrated with other control peripherals on the device. To ensure
that the latest sensor data or control parameters are available, frames can be transmitted on every control loop
period. An integrated skew-compensation block has been added on the receiver to handle skew that may occur
between the clock and data signals due to a variety of factors, including trace-length mismatch and skews
induced by an isolation chip. With embedded data robustness checks, data-link integrity checks, skew
compensation, and integration with control peripherals, the FSI can enable high-speed, robust communication in
any system. These and many other features of the FSI follow.
The FSI module includes the following features:
• Independent transmitter and receiver cores
• Source-synchronous transmission
• Dual data rate (DDR)
• One or two data lines
• Programmable data length
• Skew adjustment block to compensate for board and system delay mismatches
• Frame error detection
• Programmable frame tagging for message filtering
• Hardware ping to detect line breaks during communication (ping watchdog)
• Two interrupts per FSI core
• Externally triggered frame generation
• Hardware- or software-calculated CRC
• Embedded ECC computation module
• Register write protection
• DMA support
• SPI compatibility mode (limited features available)
Operating the FSI at maximum speed (50 MHz) at dual data rate (100 Mbps) may require the integrated skew
compensation block to be configured according to the specific operating conditions on a case-by-case basis.
The Fast Serial Interface (FSI) Skew Compensation Application Report provides example software on how to
configure and set up the integrated skew compensation block on the Fast Serial Interface.
The FSI consists of independent transmitter (FSITX) and receiver (FSIRX) cores. The FSITX and FSIRX cores
are configured and operated independently. The features available on the FSITX and FSIRX are described in 节
7.14.7.1 and 节7.14.7.2, respectively.
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7.14.7.1 FSI Transmitter
The FSI transmitter module handles the framing of data, CRC generation, signal generation of TXCLK, TXD0,
and TXD1, as well as interrupt generation. The operation of the transmitter core is controlled and configured
through programmable control registers. The transmitter control registers let the CPU program, control, and
monitor the operation of the FSI transmitter. The transmit data buffer is accessible by the CPU and the DMA.
The transmitter has the following features:
• Automated ping frame generation
• Externally triggered ping frames
• Externally triggered data frames
• Software-configurable frame lengths
• 16-word data buffer
• Data buffer underrun and overrun detection
• Hardware-generated CRC on data bits
• Software ECC calculation on select data
• DMA support
图 7-63 shows the FSITX CPU interface. 图 7-64 shows the high-level block diagram of the FSITX. Not all data
paths and internal connections are shown. This diagram provides a high-level overview of the internal modules
present in the FSITX.
PLLRAWCLK
PCLKCR18
SYSCLK
SYSRSN
C28x
ePIE
FSITXyINT1
FSITXyINT2
FSITXyCLK
FSITXyD0
FSITXyD1
FSITX
DMA
FSITXyDMA
32
A. The signals connected to the trigger muxes are described in the External Frame Trigger Mux section of the Fast Serial Interface (FSI)
chapter in the TMS320F28002x Real-Time Microcontrollers Technical Reference Manual.
图7-63. FSITX CPU Interface
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FSITX
PLLRAWCLK
SYSRSN
SYSCLK
FSI Mode:
TXCLKIN
Transmit Clock
Generator
TXCLK = TXCLKIN/2
SPI Signaling Mode:
TXCLK = TXCLKIN
Register Interface
Core Reset
FSITXINT1
FSITXINT2
Control Registers,
Interrupt Management
TXCLK
Ping Time-out Counter
FSITX_DMA_EVT
TXD0
TXD1
Transmitter Core
External Frame Triggers
Transmit Data
Buffer
ECC Logic
图7-64. FSITX Block Diagram
7.14.7.1.1 FSITX Electrical Data and Timing
节7.14.7.1.1.1 lists the FSITX switching characteristics. 图7-65 shows the FSITX timings.
7.14.7.1.1.1 FSITX Switching Characteristics
over operating free-air temperature range (unless otherwise noted)
NO.
PARAMETER
MIN
20
MAX
UNIT
ns
1
2
tc(TXCLK)
tw(TXCLK)
Cycle time, TXCLK
Pulse width, TXCLK low or TXCLK high
(0.5tc(TXCLK)) + 1
(0.25tc(TXCLK)) + 2
ns
(0.5tc(TXCLK)) –1
Delay time, TXCLK rising or falling toTXD
valid
3
td(TXCLK–TXD)
ns
ns
(0.25tc(TXCLK)) –2
Delay skew introduced between TXCLK-
TDM_CLK delay and TXDx-TDM_Dx delays
TDM1
tskew(TDM_CLK-TDM_Dx )
-2
2
7.14.7.1.1.2 FSITX Timings
1
2
FSITXCLK
FSITXD0
FSITXD1
3
图7-65. FSITX Timings
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7.14.7.2 FSI Receiver
The receiver module interfaces to the FSI clock (RXCLK), and data lines (RXD0 and RXD1) after they pass
through an optional programmable delay line. The receiver core handles the data framing, CRC computation,
and frame-related error checking. The receiver bit clock and state machine are run by the RXCLK input, which is
asynchronous to the device system clock.
The receiver control registers let the CPU program, control, and monitor the operation of the FSIRX. The receive
data buffer is accessible by the CPU, HIC, and the DMA.
The receiver core has the following features:
• 16-word data buffer
• Multiple supported frame types
• Ping frame watchdog
• Frame watchdog
• CRC calculation and comparison in hardware
• ECC detection
• Programmable delay line control on incoming signals
• DMA support
• SPI compatibility mode
图 7-66 shows the FSIRX CPU interface. 图 7-67 provides a high-level overview of the internal modules present
in the FSIRX. Not all data paths and internal connections are shown.
PCLKCR18
SYSCLK
SYSRSN
C28x
ePIE
FSIRXyINT1
FSIRXyINT2
FSIRXyCLK
FSIRXyD0
FSIRXyD1
FSIRX
DMA
FSIRXyDMA
图7-66. FSIRX CPU Interface
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FSIRX
SYSRSn
SYSCLK
Frame Watchdog
Register Interface
Core Reset
FSIRXINT1
Control Registers,
Interrupt Management
FSIRXINT2
RXCLK
RXD0
Ping Watchdog
FSIRX_DMA_EVT
Receiver Core
Skew
Control
RXD1
Receive Data
Buffer
ECC Check
Logic
图7-67. FSIRX Block Diagram
7.14.7.2.1 FSIRX Electrical Data and Timing
节 7.14.7.2.1.1 lists the FSIRX timing requirements. 节 7.14.7.2.1.2 lists the FSIRX switching characteristics. 图
7-68 shows the FSIRX Timings.
7.14.7.2.1.1 FSIRX Timing Requirements
NO.
MIN
20
MAX
UNIT
ns
1
2
tc(RXCLK)
tw(RXCLK)
Cycle time, RXCLK
Pulse width, RXCLK low or RXCLK high.
0.35tc(RXCLK)
0.65tc(RXCLK)
ns
Setup time with respect to RXCLK, applies to
both edges of the clock
3
4
tsu(RXCLK–RXD)
th(RXCLK–RXD)
1.7
2
ns
ns
Hold time with respect to RXCLK, applies to
both edges of the clock
7.14.7.2.1.2 FSIRX Switching Characteristics
NO.
PARAMETER
MIN
MAX
UNIT
RXCLK delay compensation at
RX_DLYLINE_CTRL[RXCLK_DLY]=31
1
2
3
4
td(RXCLK)
10
30
ns
RXD0 delay compensation at
RX_DLYLINE_CTRL[RXD0_DLY]=31
td(RXD0)
10
10
30
30
1
ns
ns
ns
RXD1 delay compensation
at RX_DLYLINE_CTRL[RXD1_DLY]=31
td(RXD1)
Incremental delay of each delay line element
for RXCLK, RXD0, and RXD1
td(DELAY_ELEMENT)
0.3
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7.14.7.2.1.3 FSIRX Timings
1
2
FSIRXCLK
FSIRXD0
FSIRXD1
3
4
图7-68. FSIRX Timings
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TMS320F280025, TMS320F280025-Q1
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7.14.7.3 FSI SPI Compatibility Mode
The FSI supports a SPI compatibility mode to enable communication with programmable SPI devices. In this
mode, the FSI transmits its data in the same manner as a SPI in a single clock configuration mode. While the
FSI is able to physically interface with a SPI in this mode, the external device must be able to encode and
decode an FSI frame to communicate successfully. This is because the FSI transmits all SPI frame phases with
the exception of the preamble and postamble. The FSI provides the same data validation and frame checking as
if it was in standard FSI mode, allowing for more robust communication without consuming CPU cycles. The
external SPI is required to send all relevant information and can access standard FSI features such as the ping
frame watchdog on the FSIRX, frame tagging, or custom CRC values. The list of features of SPI compatibility
mode follows:
• Data will transmit on rising edge and receive on falling edge of the clock.
• Only 16-bit word size is supported.
• TXD1 will be driven like an active-low chip-select signal. The signal will be low for the duration of the full
frame transmission.
• No receiver chip-select input is required. RXD1 is not used. Data is shifted into the receiver on every active
clock edge.
• No preamble or postamble clocks will be transmitted. All signals return to the idle state after the frame phase
is finished.
• It is not possible to transmit in the SPI slave configuration because the FSI TXCLK cannot take an external
clock source.
7.14.7.3.1 FSITX SPI Signaling Mode Electrical Data and Timing
节 7.14.7.3.1.1 lists the FSITX SPI signaling mode switching characteristics. 图 7-69 shows the FSITX SPI
signaling mode timings. Special timings are not required for the FSIRX in SPI signaling mode. FSIRX timings
listed in 节 7.14.7.2.1.1 are applicable in SPI compatibility mode. Setup and Hold times are only valid on the
falling edge of FSIRXCLK because this is the active edge in SPI signaling mode.
7.14.7.3.1.1 FSITX SPI Signaling Mode Switching Characteristics
over operating free-air temperature range (unless otherwise noted)
NO.
PARAMETER
MIN
20
MAX
UNIT
ns
1
2
3
4
5
tc(TXCLK)
Cycle time, TXCLK
tw(TXCLK)
Pulse width, TXCLK low or TXCLK high
Delay time, TXD0 valid after TXCLK high
Delay time, TXCLK high after TXD1 low
Delay time, TXD1 high after TXCLK low
(0.5tc(TXCLK)) + 1
3
ns
(0.5tc(TXCLK)) –1
td(TXCLKH–TXD0)
td(TXD1-TXCLK)
td(TXCLK-TXD1)
ns
ns
t
w(TXCLK) –3
tw(TXCLK)
ns
7.14.7.3.1.2 FSITX SPI Signaling Mode Timings
1
2
FSITXCLK
3
FSITXD0
5
4
FSITXD1
图7-69. FSITX SPI Signaling Mode Timings
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7.14.8 Host Interface Controller (HIC)
The HIC module allows an external host controller to directly access resources of the device by emulating the
ASRAM protocol. It has two modes of operation: direct access and mailbox access. In direct access mode,
device resources is written to and read from directly by the external host. In mailbox access mode, external host
and device write to and read from a buffer and notify each other when the buffer write/read is complete. For
security reasons, the HIC has to be enabled by the device before the external host can access it. 图 7-70 shows
the block diagram of the HIC.
Features of the HIC include:
• Configurable I/O data lines of 8 bits and 16 bits
• Direct and mailbox access modes
• 8 address lines and 8 configurable base addresses for a total of 2048 possible addressable regions
• Two 64-byte buffers for external host and device when using mailbox access mode
• Interrupt generation on buffer full/empty
• High throughput
• Trigger HIC activity from other peripherals
• Error indicators to the system or interface
Legend
HIC Pins
HIC Registers
HIC
I/O Interface
A[7:0]
D[15:0]
nBE[1:0]
nCS
A[31:0]
H2DINT to PIE
D2HINT to Pin
WDATA[31:0]
RDATA[31:0]
Memory Mapped HIC
Configuration Interface
Host
To
Device
Device
To
Host
CTRL Regs
STATUS Regs
nWE
BASE_ADDR0
BASE_ADDR1
nOE
.
Mailbox
Buffer
Mailbox
Buffer
.
BASE_ADDRn
BASESEL[2:0]
nRDY
EVT_TRIGGER[15:0]
图7-70. HIC Block Diagram
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TMS320F280025, TMS320F280025-Q1
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7.14.8.1 HIC Electrical Data and Timing
节 7.14.8.1.1 lists the HIC timing requirements. 节 7.14.8.1.2 lists the HIC switching characteristics. 图 7-71
shows the read/write operation with nOE and nWE pins. 图7-72 shows the read/write operation with RnW pin.
7.14.8.1.1 HIC Timing Requirements
over operating free-air temperature range (unless otherwise noted)
REFID
MIN
MAX UNIT
Read/Write Parameters with nOE and nWE pins - Dual Read/Write pins
T1
tsu(ABBV-OEV)
tsu(ABBV-WEV)
tsu(CSV-OEV)
tsu(CSV-WEV)
th(ABBV-OEIV)
th(ABBV-WEIV)
tw(OEV)
Setup time, A/BASESEL/nBE before nOE active
Setup time, A/BASESEL/nBE before nWE active
Setup time, nCS active before nOE active
Setup time, nCS active before nWE active
Hold time, A/BASESEL/nBE/nCS after nOE inactive
Hold time, A/BASESEL/nBE/nCS after nWE inactive
Active pulse width of nOE (Read)(1)
0
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
T2
0
0.5tc(SYSCLK)
0.5tc(SYSCLK)
6
T3
T4
T5
T6
6
T7
4tc(SYSCLK)
4tc(SYSCLK)
3tc(SYSCLK)
3tc(SYSCLK)
3tc(SYSCLK)
0
T8
tw(WEV)
Active pulse width of nWE (Write)
T9
tw(CSIV)
Inactive pulse width of nCS(2)
T10
T11
T12
T13
tw(OEIV)
Inactive Read pulse width of nOE(2)
tw(WEIV)
Inactive Write pulse width of nWE(2)
tsu(DV-WEV)
th(DV-WEIV)
Setup time, D before nWE active
Hold time, D after nWE inactive
6
Read/Write Parameters with RnW pin - Single Read/Write pin
T14
T15
T16
T17
T18
T19
T20
T21
T22
tsu(ABBV-CSV)
tsu(RNWV-CSV)
th(ABBV-CSIV)
tw(CSV_RD)
tw(CSV_WR)
tw(CSIV)
Setup time, A/BASESEL/nBE before nCS active
Setup time, RnW before nCS active
Hold time, A/BASESEL/nBE/RnW after nCS inactive
Active pulse width of nCS for read operation(1)
Active pulse width of nCS for write operation
Inactive pulse width of nCS(2)
0
0.5tc(SYSCLK)
6
ns
ns
ns
ns
ns
ns
ns
ns
ns
4tc(SYSCLK)
4tc(SYSCLK)
3tc(SYSCLK)
3tc(SYSCLK)
0
tw(RNWIV)
Inactive pulse width of RnW(2)
tsu(DV-CSV)
th(DV-CSIV)
Setup time, D before nCS active
Hold time, D after nCS inactive
5
(1) For accesses to the device region, additional 2 SYSCLK cycles are required.
(2) For accesses to the device region with nRDY pin, additional SYSCLK cycle is required.
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7.14.8.1.2 HIC Switching Characteristics
over operating free-air temperature range (unless otherwise noted)
REFID
PARAMETER
MIN
MAX UNIT
Read/Write Parameters with nOE and nWE pins
S1
S2
S3
S4
S5
S6
td(OEV-DV)
Output data delay time : nOE to D output valid (1)
Output data hold time : nOE invalid to D output invalid (tri-state)
Read Ready delay time : nOE to nRDY output valid
Write Ready delay time : nWE to nRDY output valid
Ready to Data delay time : nRDY output valid to D output valid
Active pulse width of nRDY output
3tc(SYSCLK)
4tc(SYSCLK) + 14 ns
2tc(SYSCLK) + 14 ns
11 ns
td(OEIV-DIV)
td(OEV-RDYV)
td(WEV-RDYV)
td(RDYV-DV)
tw(RDYACT)
1tc(SYSCLK)
0
0
-3
11 ns
3
ns
ns
2tc(SYSCLK)
Read/Write Parameters with RnW pin
S7
td(CSV-DV)
Output delay time : nCS active to D output valid (1)
Output hold time : nCS inactive to D output invalid (tri-state)
Output delay time : nCS to nRDY output valid
3tc(SYSCLK)
1tc(SYSCLK)
0
4tc(SYSCLK) + 14 ns
2tc(SYSCLK) + 14 ns
11 ns
S8
td(CSIV-DIV)
td(CSV-RDYV)
td(RDYV-DV)
tw(RDYACT)
S9
S10
S11
Ready to Data delay time : nRDY output valid to D output valid
Active pulse width of nRDY output
-3
3
ns
ns
2tc(SYSCLK)
(1) Applicable to mailbox accesses only. Direct memory map (Device) accesses are qualified with nRDY pin.
7.14.8.1.3 HIC Timing Diagrams
SETUP SIGNALS
T9
nCS
A[7:0]
BASESEL[2:0]
nBE[3:0]
READ SIGNALS
T1
T5
T3
T10
nOE
T7
S2
S1
T8
D[15:0]
7
WRITE SIGNALS
T6
T2
T4
T11
nWE
T12
T13
D[15:0]
READY/WAIT SIGNAL
S5
S6
S3
S4
nRDY
图7-71. Read/Write Operation With nOE and nWE Pins
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TMS320F280025, TMS320F280025-Q1
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SETUP SIGNALS
T19
nCS
T17 or T18
T16
T14
T15
A[7:0]
BASESEL[2:0]
nBE[3:0]
READ SIGNALS
T20
RnW
(Read)
S8
S7
D[15:0]
S10
WRITE SIGNALS
T20
T15
T21
RnW
(Write)
T22
D[15:0]
nRDY
READY/WAIT SIGNAL
S9
S11
图7-72. Read/Write Operation With RnW Pin
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8 Detailed Description
8.1 Overview
C2000™ 32-bit microcontrollers are optimized for processing, sensing, and actuation to improve closed-loop
performance in real-time control applications such as industrial motor drives; solar inverters and digital power;
electrical vehicles and transportation; motor control; and sensing and signal processing.
The TMS320F28002x (F28002x) is a powerful 32-bit floating-point microcontroller unit (MCU) that lets designers
incorporate crucial control peripherals, differentiated analog, and nonvolatile memory on a single device.
The real-time control subsystem is based on TI’s 32-bit C28x CPU, which provides 100 MHz of signal
processing performance. The C28x CPU is further boosted by the new TMU extended instruction set, which
enables fast execution of algorithms with trigonometric operations commonly found in transforms and torque
loop calculations; and the VCRC extended instruction set, which reduces the latency for complex math
operations commonly found in encoded applications.
The F28002x supports up to 128KB (64KW) of flash memory in one bank. Up to 24KB (12KW) of on-chip SRAM
is also available in blocks of 4KB (2KW) for efficient system partitioning. Flash ECC, SRAM ECC/parity, and
dual-zone security are also supported.
High-performance analog blocks are integrated on the F28002x real-time MCU to further enable system
consolidation. Two separate 12-bit ADCs provide precise and efficient management of multiple analog signals,
which ultimately boosts system throughput. Four analog comparator modules provide continuous monitoring of
input voltage levels for trip conditions.
The TMS320C2000™ devices contain industry-leading control peripherals with frequency-independent ePWM/
HRPWM and eCAP allow for a best-in-class level of control to the system.
Connectivity is supported through various industry-standard communication ports (such as SPI, SCI, I2C,
PMBus, LIN, and CAN) and offers multiple muxing options for optimal signal placement in a variety of
applications. New to the C2000™ platform is Host Interface Controller (HIC), a high throughput interface that
allows an external host to access resources of the TMS320F28002x. Additionally, in an industry first, the FSI
enables high-speed, robust communication to complement the rich set of peripherals that are embedded in the
device.
A specially enabled device variant, TMS320F28002xC, allows access to the Configurable Logic Block (CLB) for
additional interfacing features and allows access to the secure ROM, which includes a library to enable
InstaSPIN-FOC™. See 表5-1 for more information.
The Embedded Real-Time Analysis and Diagnostic (ERAD) module enhances the debug and system analysis
capabilities of the device by providing additional hardware breakpoints and counters for profiling.
To learn more about the C2000 real-time MCUs, visit the C2000™ real-time control MCUs page.
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TMS320F280025, TMS320F280025-Q1
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8.2 Functional Block Diagram
图8-1 shows the CPU system and associated peripherals.
Boot ROM
Secure Memories
shown in Red
Secure ROM
C28x CPU
FPU32
Bus Legend
Flash Bank0
16 Sectors
64 KW (128 KB)
FINTDIV
TMU
VCRC
CPU
DMA
HIC
BGCRC
CPU Timers
DCC
DCSM
ePIE
ERAD
M0-M1 RAM
2 KW (4 KB)
BGCRC
LS4-LS7 RAM
8 KW (16 KB)
Crystal Oscillator
INTOSC1, INTOSC2
PLL
HIC
GS0 RAM
2 KW (4 KB)
DMA
6 Channles
PF1
PF3
PF4
PF2
PF7
PF8
PF9
Result
2x 12-Bit ADC
Data
14x ePWM Chan.
(8 Hi-Res Capable)
4x CMPSS
1x PMBUS
2x SPI
1x CAN
2x LIN
1x SCI
2x I2C
39x GPIO
Input XBAR
Output XBAR
ePWM XBAR
CLB XBAR
3x eCAP
(1 HRCAP Capable)
2x CLB
1x FSI RX
1x FSI TX
NMI
Watchdog
2x eQEP
(CW/CCW Support)
Windowed
Watchdog
图8-1. Functional Block Diagram
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8.3 Memory
8.3.1 Memory Map
The Memory Map table describes the memory map. See the Memory Controller Module section of the System
Control chapter in the TMS320F28002x Real-Time Microcontrollers Technical Reference Manual.
表8-1. Memory Map
START
HIC
DMA
ECC/
ACCESS
MEMORY
SIZE
END ADDRESS
SECURITY
ADDRESS
ACCESS
ACCESS
PARITY
PROTECTION
M0 RAM
M1 RAM
1K x 16
1K x 16
512 x 16
2K x 16
2K x 16
2K x 16
2K x 16
2K x 16
2K x 16
1K x 16
1K x 16
64K x 16
32K x 16
64K x 16
0x0000 0000
0x0000 0400
0x0000 0D00
0x0000 A000
0x0000 A800
0x0000 B000
0x0000 B800
0x0000 C000
0x0004 9000
0x0007 0000
0x0007 8000
0x0008 0000
0x003E 8000
0x003F 0000
0x0000 03FF
0x0000 07FF
0x0000 0EFF
0x0000 A7FF
0x0000 AFFF
0x0000 B7FF
0x0000 BFFF
0x0000 C7FF
0x0004 97FF
0x0007 03FF
0x0007 83FF
0x0008 FFFF
0x003E FFFF
0x003F FFFF
-
-
ECC
ECC
-
Yes
-
-
-
-
Yes
PieVectTable
LS4 RAM
-
-
-
-
-
-
ECC
ECC
ECC
ECC
Parity
Parity
ECC
ECC
ECC
Parity
Parity
Yes
Yes
Yes
Yes
Yes
-
LS5 RAM
-
-
Yes
LS6 RAM
-
-
Yes
LS7 RAM
-
-
Yes
GS0 RAM
CAN A Message RAM
TI OTP(1)
Yes
Yes
Yes
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
User OTP
Yes
Yes
Yes
-
Flash
Secure ROM
Boot ROM
Pie Vector Fetch Error
(part of Boot ROM)
1 x 16
0x003F FFBE
0x003F FFC0
0x003F FFBF
0x003F FFFF
-
-
-
-
Parity
Parity
-
-
-
-
Default Vectors
64 x 16
(part of Boot ROM)
(1) TI OTP is for TI internal use only.
8.3.1.1 Dedicated RAM (Mx RAM)
The CPU subsystem has two dedicated ECC-capable RAM blocks: M0 and M1. These memories are small
nonsecure blocks that are tightly coupled with the CPU (that is, only the CPU has access to them).
8.3.1.2 Local Shared RAM (LSx RAM)
Local shared RAMs (LSx RAMs) are accessible to the CPU, HIC, and BGCRC. All LSx RAM blocks have ECC.
These memories are secure and have CPU access protection (CPU write/CPU fetch).
8.3.1.3 Global Shared RAM (GSx RAM)
Global shared RAMs (GSx RAMs) are accessible from the CPU, HIC, and DMA. The CPU, HIC, and DMA have
full read and write access to these memories. All GSx RAM blocks have parity. The GSx RAMs have access
protection (CPU write/CPU fetch/DMA write/HIC write).
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TMS320F280025, TMS320F280025-Q1
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8.3.2 Flash Memory Map
On the F28002x devices one flash bank (128KB [64KW]) is available. Code to program the flash should be
executed out of RAM, there should not be any kind of access to the flash bank when an erase or program
operation is in progress. 表8-2 lists the addresses of flash sectors available for each part number.
8.3.2.1 Addresses of Flash Sectors
表8-2. Addresses of Flash Sectors
ADDRESS
ECC ADDRESS
START
PART NUMBER
SECTOR
SIZE
START
END
SIZE
END
OTP Sectors
TI OTP
1K x 16
1K x 16
0x0007 0000
0x0007 8000
0x0007 03FF
0x0007 83FF
128 x 16
128 x 16
0x0107 0000
0x0107 1000
0x0107 007F
0x0107 107F
All F28002x
DCSM OTP
Bank 0 Sectors
Sector 0
Sector 1
Sector 2
Sector 3
Sector 4
Sector 5
Sector 6
Sector 7
Sector 8
Sector 9
Sector 10
Sector 11
Sector 12
Sector 13
Sector 14
Sector 15
4K x 16
4K x 16
4K x 16
4K x 16
4K x 16
4K x 16
4K x 16
4K x 16
4K x 16
4K x 16
4K x 16
4K x 16
4K x 16
4K x 16
4K x 16
4K x 16
0x0008 0000
0x0008 1000
0x0008 2000
0x0008 3000
0x0008 4000
0x0008 5000
0x0008 6000
0x0008 7000
0x0008 8000
0x0008 9000
0x0008 A000
0x0008 B000
0x0008 C000
0x0008 D000
0x0008 E000
0x0008 F000
0x0008 0FFF
0x0008 1FFF
0x0008 2FFF
0x0008 3FFF
0x0008 4FFF
0x0008 5FFF
0x0008 6FFF
0x0008 7FFF
0x0008 8FFF
0x0008 9FFF
0x0008 AFFF
0x0008 BFFF
0x0008 CFFF
0x0008 DFFF
0x0008 EFFF
0x0008 FFFF
512 x 16
512 x 16
512 x 16
512 x 16
512 x 16
512 x 16
512 x 16
512 x 16
512 x 16
512 x 16
512 x 16
512 x 16
512 x 16
512 x 16
512 x 16
512 x 16
0x0108 0000
0x0108 0200
0x0108 0400
0x0108 0600
0x0108 0800
0x0108 0A00
0x0108 0C00
0x0108 0E00
0x0108 1000
0x0108 1200
0x0108 1400
0x0108 1600
0x0108 1800
0x0108 1A00
0x0108 1C00
0x0108 1E00
0x0108 01FF
0x0108 03FF
0x0108 05FF
0x0108 07FF
0x0108 09FF
0x0108 0BFF
0x0108 0DFF
0x0108 0FFF
0x0108 11FF
0x0108 13FF
0x0108 15FF
0x0108 17FF
0x0108 19FF
0x0108 1BFF
0x0108 1DFF
0x0108 1FFF
All F28002x
F280025,
F280023
F280025
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TMS320F280025, TMS320F280025-Q1
TMS320F280025C, TMS320F280025C-Q1, TMS320F280023, TMS320F280023-Q1
TMS320F280023C, TMS320F280021, TMS320F280021-Q1
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8.3.3 Peripheral Registers Memory Map
The Peripheral Registers Memory Map (C28x) table lists the peripheral registers.
表8-3. Peripheral Registers Memory Map (C28x)
Bit Field Name
Pipeline
DMA
HIC
DriverLib Name
Base Address
Protected
Access
Access
Instance
Structure
Peripheral Frame 0 (PF0)
ADCARESULT_BASE
ADCCRESULT_BASE
CPUTIMER0_BASE
CPUTIMER1_BASE
CPUTIMER2_BASE
PIECTRL_BASE
AdcaResultRegs
AdccResultRegs
CpuTimer0Regs
CpuTimer1Regs
CpuTimer2Regs
PieCtrlRegs
ADC_RESULT_REGS
ADC_RESULT_REGS
CPUTIMER_REGS
CPUTIMER_REGS
CPUTIMER_REGS
PIE_CTRL_REGS
DMA_REGS
0x0000_0B00
0x0000_0B40
0x0000_0C00
0x0000_0C08
0x0000_0C10
0x0000_0CE0
0x0000_1000
0x0000_1020
0x0000_1040
0x0000_1060
0x0000_1080
0x0000_10A0
0x0000_10C0
-
-
-
-
-
-
-
-
-
-
-
-
-
YES
YES
YES
YES
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
DmaRegs
DMA_BASE
Dmach1Regs
Dmach2Regs
Dmach3Regs
Dmach4Regs
Dmach5Regs
Dmach6Regs
DMA_CH_REGS
DMA_CH_REGS
DMA_CH_REGS
DMA_CH_REGS
DMA_CH_REGS
DMA_CH_REGS
DMA_CH1_BASE
DMA_CH2_BASE
DMA_CH3_BASE
DMA_CH4_BASE
DMA_CH5_BASE
DMA_CH6_BASE
Peripheral Frame 1 (PF1)
CLB1_LOGICCFG_BASE
CLB1_LOGICCTRL_BASE
CLB1_DATAEXCH_BASE
CLB2_LOGICCFG_BASE
CLB1_DATAEXCH_BASE
CLB2_LOGICCFG_BASE
EPWM1_BASE
Clb1LogicCfgRegs
Clb1LogicCtrlRegs
Clb1DataExchRegs
Clb2LogicCfgRegs
Clb1DataExchRegs
Clb2LogicCfgRegs
EPwm1Regs
CLB_LOGIC_CONFIG_REGS
CLB_LOGIC_CONTROL_REGS
CLB_DATA_EXCHANGE_REGS
CLB_LOGIC_CONFIG_REGS
CLB_DATA_EXCHANGE_REGS
CLB_LOGIC_CONFIG_REGS
EPWM_REGS
0x0000_3000
0x0000_3100
0x0000_3180
0x0000_3200
0x0000_3300
0x0000_3380
0x0000_4000
0x0000_4100
0x0000_4200
0x0000_4300
0x0000_4400
0x0000_4500
0x0000_4600
0x0000_5100
0x0000_5140
0x0000_5200
0x0000_5240
0x0000_5280
0x0000_52A0
0x0000_5C80
-
YES
YES
YES
YES
YES
YES
YES
YES
YES
YES
YES
YES
YES
YES
YES
YES
YES
YES
YES
YES
YES
YES
YES
YES
YES
YES
YES
YES
YES
YES
YES
YES
YES
YES
YES
YES
YES
YES
YES
YES
-
-
-
-
-
YES
YES
YES
YES
YES
YES
YES
YES
YES
YES
YES
YES
YES
YES
EPwm2Regs
EPWM_REGS
EPWM2_BASE
EPwm3Regs
EPWM_REGS
EPWM3_BASE
EPwm4Regs
EPWM_REGS
EPWM4_BASE
EPwm5Regs
EPWM_REGS
EPWM5_BASE
EPwm6Regs
EPWM_REGS
EPWM6_BASE
EPwm7Regs
EPWM_REGS
EPWM7_BASE
EQep1Regs
EQEP_REGS
EQEP1_BASE
EQep2Regs
EQEP_REGS
EQEP2_BASE
ECap1Regs
ECAP_REGS
ECAP1_BASE
ECap2Regs
ECAP_REGS
ECAP2_BASE
ECap3Regs
ECAP_REGS
ECAP3_BASE
Hrcap3Regs
HRCAP_REGS
HRCAP3_BASE
Cmpss1Regs
CMPSS_REGS
CMPSS1_BASE
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TMS320F280025, TMS320F280025-Q1
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DMA HIC
表8-3. Peripheral Registers Memory Map (C28x) (continued)
Bit Field Name
Pipeline
DriverLib Name
Base Address
Protected
Access
Access
Instance
Cmpss2Regs
Structure
CMPSS_REGS
CMPSS_REGS
CMPSS_REGS
CMPSS2_BASE
CMPSS3_BASE
0x0000_5CA0
0x0000_5CC0
0x0000_5CE0
YES
YES
YES
YES
YES
YES
YES
YES
YES
Cmpss3Regs
Cmpss4Regs
CMPSS4_BASE
Peripheral Frame 2 (PF2)
SPIA_BASE
SpiaRegs
SPI_REGS
SPI_REGS
0x0000_6100
0x0000_6110
0x0000_6340
0x0000_6400
0x0000_6500
0x0000_6600
0x0000_6680
YES
YES
YES
YES
YES
YES
YES
YES
YES
YES
YES
YES
YES
YES
YES
YES
YES
YES
YES
YES
YES
SpibRegs
SPIB_BASE
BgcrcCpuRegs
PmbusaRegs
HicRegs
BGCRC_REGS
PMBUS_REGS
HIC_CFG_REGS
FSI_TX_REGS
FSI_RX_REGS
BGCRC_CPU_BASE
PMBUSA_BASE
HIC_BASE
FsiTxaRegs
FsiRxaRegs
FSITXA_BASE
FSIRXA_BASE
Peripheral Frame 3 (PF3)
ADCA_BASE
AdcaRegs
AdccRegs
ADC_REGS
ADC_REGS
0x0000_7400
0x0000_7500
YES
YES
-
-
-
-
ADCC_BASE
Peripheral Frame 4 (PF4)
INPUTXBAR_BASE
XBAR_BASE
InputXbarRegs
XbarRegs
INPUT_XBAR_REGS
XBAR_REGS
0x0000_7900
0x0000_7920
0x0000_7940
0x0000_7960
0x0000_7980
0x0000_7A00
0x0000_7A40
0x0000_7A80
0x0000_7BC0
0x0000_7C00
0x0000_7F00
0x0000_7F80
YES
YES
YES
YES
YES
YES
YES
YES
YES
YES
YES
YES
-
-
-
-
-
-
-
-
-
-
-
-
-
-
SyncSocRegs
SYNC_SOC_REGS
SYNCSOC_BASE
INPUTXBAR2_BASE
DMACLASRCSEL_BASE
EPWMXBAR_BASE
CLBXBAR_BASE
-
InputXbar2Regs
DmaClaSrcSelRegs
EPwmXbarRegs
ClbXbarRegs
INPUT_XBAR_REGS
DMA_CLA_SRC_SEL_REGS
EPWM_XBAR_REGS
CLB_XBAR_REGS
-
-
-
-
OutputXbarRegs
OutputXbar2Regs
GpioCtrlRegs
OUTPUT_XBAR_REGS
OUTPUT_XBAR_REGS
GPIO_CTRL_REGS
OUTPUTXBAR_BASE
OUTPUTXBAR2_BASE
GPIOCTRL_BASE
GPIODATA_BASE
GPIODATAREAD_BASE
Peripheral Frame 5 (PF5)
DEVCFG_BASE
-
-
-
-
GpioDataRegs
GpioDataReadRegs
GPIO_DATA_REGS
GPIO_DATA_READ_REGS
YES
DevCfgRegs
DEV_CFG_REGS
CLK_CFG_REGS
0x0005_D000
0x0005_D200
0x0005_D300
0x0005_D500
0x0005_D700
0x0005_F000
0x0005_F040
0x0005_F070
0x0005_F080
YES
YES
YES
YES
YES
YES
YES
YES
YES
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
ClkCfgRegs
CLKCFG_BASE
CpuSysRegs
CPU_SYS_REGS
CPUSYS_BASE
PeriphAcRegs
PERIPH_AC_REGS
PERIPHAC_BASE
ANALOGSUBSYS_BASE
DCSM_BANK0_Z1_BASE
DCSM_BANK0_Z2_BASE
DCSMCOMMON_BASE
DCSMCOMMON2_BASE
AnalogSubsysRegs
DcsmBank0Z1Regs
DcsmBank0Z2Regs
DcsmCommonRegs
DcsmCommon2Regs
ANALOG_SUBSYS_REGS
DCSM_BANK0_Z1_REGS
DCSM_BANK0_Z2_REGS
DCSM_COMMON_REGS
DCSM_COMMON2_REGS
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TMS320F280025, TMS320F280025-Q1
TMS320F280025C, TMS320F280025C-Q1, TMS320F280023, TMS320F280023-Q1
TMS320F280023C, TMS320F280021, TMS320F280021-Q1
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Instance
ZHCSL01B –MARCH 2020 –REVISED DECEMBER 2020
表8-3. Peripheral Registers Memory Map (C28x) (continued)
Bit Field Name
Pipeline
DMA
HIC
DriverLib Name
Base Address
Protected
Access
Access
Structure
Peripheral Frame 6 (PF6)
MEMCFG_BASE
MemCfgRegs
MEM_CFG_REGS
ACCESSPROTECTION_REGS
MEMORY_ERROR_REGS
ROM_WAIT_STATE_REGS
ROM_PREFETCH_REGS
FLASH_CTRL_REGS
0x0005_F400
0x0005_F500
0x0005_F540
0x0005_F580
0x0005_F588
0x0005_F800
0x0005_FB00
YES
YES
YES
YES
YES
YES
YES
-
-
-
-
-
-
-
-
-
-
-
-
-
-
AccessProtectionRegs
MemoryErrorRegs
RomWaitStateRegs
RomPrefetchRegs
Flash0CtrlRegs
ACCESSPROTECTION_BASE
MEMORYERROR_BASE
ROMWAITSTATE_BASE
ROMPREFETCH_BASE
FLASH0CTRL_BASE
FLASH0ECCREGS_BASE
Peripheral Frame 7 (PF7)
CANA_BASE
Flash0EccRegs
FLASH_ECC_REGS
CanaRegs
CAN_REGS
CAN_MBOX
0x0004_8000
0x0004_9000
0x0005_E000
0x0005_E200
0x0005_E700
0x0005_E740
0x0005_E800
0x0005_E900
0x0005_E908
0x0005_E910
0x0005_E918
0x0005_E920
0x0005_E928
0x0005_E930
0x0005_E938
0x0005_E980
0x0005_E990
0x0005_E9A0
0x0005_E9B0
0x0005_EA00
0x0005_EA10
0x0005_EA20
0x0005_EA30
0x0005_EA40
0x0005_EA50
0x0005_EA60
0x0005_EA70
0x0005_EA80
YES
YES
YES
YES
YES
YES
YES
YES
YES
YES
YES
YES
YES
YES
YES
YES
YES
YES
YES
YES
YES
YES
YES
YES
YES
YES
YES
YES
YES
YES
CanaMboxRegs
HwbistRegs
CANAMBOX_BASE
HWBIST_BASE
YES
YES
HWBIST_REGS
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
MpostRegs
MPOST_REGS
MPOST_BASE
Dcc0Regs
DCC_REGS
DCC0_BASE
Dcc1Regs
DCC_REGS
DCC1_BASE
EradGlobalRegs
EradHWBP1Regs
EradHWBP2Regs
EradHWBP3Regs
EradHWBP4Regs
EradHWBP5Regs
EradHWBP6Regs
EradHWBP7Regs
EradHWBP8Regs
EradCounter1Regs
EradCounter2Regs
EradCounter3Regs
EradCounter4Regs
EradCRCGlobalRegs
EradCRC1Regs
EradCRC2Regs
EradCRC3Regs
EradCRC4Regs
EradCRC5Regs
EradCRC6Regs
EradCRC7Regs
EradCRC8Regs
ERAD_GLOBAL_REGS
ERAD_HWBP_REGS
ERAD_HWBP_REGS
ERAD_HWBP_REGS
ERAD_HWBP_REGS
ERAD_HWBP_REGS
ERAD_HWBP_REGS
ERAD_HWBP_REGS
ERAD_HWBP_REGS
ERAD_COUNTER_REGS
ERAD_COUNTER_REGS
ERAD_COUNTER_REGS
ERAD_COUNTER_REGS
ERAD_CRC_GLOBAL_REGS
ERAD_CRC_REGS
ERAD_CRC_REGS
ERAD_CRC_REGS
ERAD_CRC_REGS
ERAD_CRC_REGS
ERAD_CRC_REGS
ERAD_CRC_REGS
ERAD_CRC_REGS
ERADGLOBAL_BASE
ERADHWBP1_BASE
ERADHWBP2_BASE
ERADHWBP3_BASE
ERADHWBP4_BASE
ERADHWBP5_BASE
ERADHWBP6_BASE
ERADHWBP7_BASE
ERADHWBP8_BASE
ERADCOUNTER1_BASE
ERADCOUNTER2_BASE
ERADCOUNTER3_BASE
ERADCOUNTER4_BASE
ERADCRCGLOBAL_BASE
ERADCRC1_BASE
ERADCRC2_BASE
ERADCRC3_BASE
ERADCRC4_BASE
ERADCRC5_BASE
ERADCRC6_BASE
ERADCRC7_BASE
ERADCRC8_BASE
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TMS320F280025, TMS320F280025-Q1
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TMS320F280023C, TMS320F280021, TMS320F280021-Q1
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DMA HIC
表8-3. Peripheral Registers Memory Map (C28x) (continued)
Bit Field Name
Pipeline
DriverLib Name
Base Address
Protected
Access
Access
Instance
Structure
Peripheral Frame 8 (PF8)
LINA_BASE
LinaRegs
LIN_REGS
LIN_REGS
0x0000_6A00
0x0000_6B00
YES
YES
YES
YES
YES
YES
LinbRegs
LINB_BASE
Peripheral Frame 9 (PF9)
WD_BASE
WdRegs
WD_REGS
NMI_INTRUPT_REGS
XINT_REGS
0x0000_7000
0x0000_7060
0x0000_7070
0x0000_7200
0x0000_7300
0x0000_7340
YES
YES
YES
YES
YES
YES
-
-
-
-
-
-
YES
YES
YES
YES
YES
YES
NmiIntruptRegs
XintRegs
NMI_BASE
XINT_BASE
SciaRegs
I2caRegs
I2cbRegs
SCI_REGS
SCIA_BASE
I2C_REGS
I2CA_BASE
I2C_REGS
I2CB_BASE
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TMS320F280025, TMS320F280025-Q1
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TMS320F280023C, TMS320F280021, TMS320F280021-Q1
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8.4 Identification
表 8-4 lists the Device Identification Registers. Additional information on these device identification registers can
be found in the TMS320F28002x Real-Time Microcontrollers Technical Reference Manual.
表8-4. Device Identification Registers
NAME
ADDRESS
SIZE (x16)
DESCRIPTION
Device part identification number
TMS320F280025
TMS320F280025C
TMS320F280023
TMS320F280023C
TMS320F280021
Silicon revision number
Revision 0
0x04FF 0500
0x04FF 0500
0x04FD 0500
0x04FD 0500
0x04FB 0500
PARTIDH
REVID
0x0005 D00A
2
0x0005 D00C
0x0007 01F4
2
2
0x0000 0000
0x0000 0001
Revision A
Unique identification number. This number is different on each
individual device with the same PARTIDH. This unique number
can be used as a serial number in the application. This number
is present only on TMS devices.
UID_UNIQUE
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TMS320F280025, TMS320F280025-Q1
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8.5 Bus Architecture –Peripheral Connectivity
The Peripheral Connectivity table lists a broad view of the peripheral and configuration register accessibility from
each bus master.
表8-5. Peripheral Connectivity
PERIPHERAL
C28
DMA
HIC
BGCRC
SYSTEM PERIPHERALS
CPU Timers
ERAD
Y
Y
GPIO Data
Y
Y
GPIO Pin Mapping and Configuration
XBAR Configuration
System Configuration
DCC
Y
Y
Y
Y
MEMORY
M0/M1
LSx
Y
Y
Y
Y
Y
Y
GS0
Y
Y
Y
ROM
FLASH
Y
Y
CONTROL PERIPHERALS
ePWM/HRPWM
eCAP
Y
Y
Y
Y
Y
Y
Y
Y
Y
eQEP(1)
ANALOG PERIPHERALS
CMPSS(1)
Y
Y
Y
Y
Y
Y
Y
ADC Configuration
ADC Results(1)
COMMUNICATION PERIPHERALS
CAN
Y
Y
Y
Y
Y
Y
Y
Y
Y
Y
Y
Y
Y
Y
Y
Y
FSITX/FSIRX
I2C
LIN
Y
Y
PMBus
SCI
SPI
Y
(1) These modules are accessible from DMA but cannot trigger a DMA transfer.
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8.6 C28x Processor
The CPU is a 32-bit fixed-point processor. This device draws from the best features of digital signal processing;
reduced instruction set computing (RISC); and microcontroller architectures, firmware, and tool sets.
The CPU features include a modified Harvard architecture and circular addressing. The RISC features are
single-cycle instruction execution, register-to-register operations, and modified Harvard architecture. The
microcontroller features include ease of use through an intuitive instruction set, byte packing and unpacking, and
bit manipulation. The modified Harvard architecture of the CPU enables instruction and data fetches to be
performed in parallel. The CPU can read instructions and data while it writes data simultaneously to maintain the
single-cycle instruction operation across the pipeline. The CPU does this over six separate address/data buses.
For more information on CPU architecture and instruction set, see the TMS320C28x CPU and Instruction Set
Reference Guide. For more information on the C28x Floating Point Unit (FPU), Trigonometric Math Unit, and
Cyclic Redundancy Check (VCRC) instruction sets, see the TMS320C28x Extended Instruction Sets Technical
Reference Manual. A brief overview of the FPU, TMU, and VCRC are provided here.
8.6.1 Floating-Point Unit (FPU)
The C28x plus floating-point (C28x+FPU) processor extends the capabilities of the C28x fixed-point CPU by
adding registers and instructions to support IEEE single-precision floating-point operations.
Devices with the C28x+FPU include the standard C28x register set plus an additional set of floating-point unit
registers. The additional floating-point unit registers are the following:
• Eight floating-point result registers, RnH (where n = 0–7)
• Floating-point Status Register (STF)
• Repeat Block Register (RB)
All of the floating-point registers, except the RB, are shadowed. This shadowing can be used in high-priority
interrupts for fast context save and restore of the floating-point registers.
8.6.2 Fast Integer Division Unit
The Fast Integer Division (FINTDIV) unit of the C28x CPU uniquely supports three types of integer division
(Truncated, Modulus, Euclidean) of varying data type sizes (16/16, 32/16, 32/32, 64/32, 64/64) in unsigned or
signed formats.
• Truncated integer division is naturally supported by C language (/, % operators).
• Modulus and Euclidean divisions are variants that are more efficient for control algorithms and are supported
by C intrinsics.
All three types of integer division produce both a quotient and remainder component, are interruptible, and
execute in a minimum number of deterministic cycles (10 cycles for a 32/32 division). In addition, the Fast
Division capabilities of the C28x CPU uniquely support fast execution of floating-point 32-bit (in 5 cycles) and 64-
bit (in 20 cycles) division.
For more information about fast integer division, see the Fast Integer Division – A Differentiated Offering From
C2000™ Product Family Application Report.
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8.6.3 Trigonometric Math Unit (TMU)
The TMU extends the capabilities of a C28x+FPU by adding instructions and leveraging existing FPU
instructions to speed up the execution of common trigonometric and arithmetic operations listed in 表8-6.
表8-6. TMU Supported Instructions
INSTRUCTIONS
MPY2PIF32 RaH,RbH
C EQUIVALENT OPERATION
PIPELINE CYCLES
a = b * 2pi
a = b / 2pi
a = b/c
2/3
2/3
5
DIV2PIF32 RaH,RbH
DIVF32 RaH,RbH,RcH
SQRTF32 RaH,RbH
a = sqrt(b)
5
SINPUF32 RaH,RbH
COSPUF32 RaH,RbH
ATANPUF32 RaH,RbH
QUADF32 RaH,RbH,RcH,RdH
a = sin(b*2pi)
4
a = cos(b*2pi)
4
a = atan(b)/2pi
4
Operation to assist in calculating ATANPU2
5
No changes have been made to existing instructions, pipeline or memory bus architecture. All TMU instructions
use the existing FPU register set (R0H to R7H) to carry out their operations.
Exponent instruction IEXP2F32 and logarithmic instruction LOG2F32 have been added to support computation
of floating-point power function for the non-linear proportional integral derivative control (NLPID) component of
the C2000 Digital Control Library. These two added instructions reduce the power function calculations from a
typical of 300 cycles using library emulation to less than 10 cycles.
8.6.4 VCRC Unit
Cyclic redundancy check (CRC) algorithms provide a straightforward method for verifying data integrity over
large data blocks, communication packets, or code sections. The C28x+VCRC can perform 8-bit, 16-bit, 24-bit,
and 32-bit CRCs. For example, the VCRC can compute the CRC for a block length of 10 bytes in 10 cycles. A
CRC result register contains the current CRC, which is updated whenever a CRC instruction is executed.
The following are the CRC polynomials used by the CRC calculation logic of the VCRC:
• CRC8 polynomial = 0x07
• CRC16 polynomial 1 = 0x8005
• CRC16 polynomial 2 = 0x1021
• CRC24 polynomial = 0x5d6dcb
• CRC32 polynomial 1 = 0x04c11db7
• CRC32 polynomial 2 = 0x1edc6f41
This module can calculate CRCs for a byte of data in a single cycle. The CRC calculation for CRC8, CRC16,
CRC24, and CRC32 is done byte-wise (instead of computing on a complete 16-bit or 32-bit data read by the
C28x core) to match the byte-wise computation requirement mandated by various standards.
The VCRC Unit also allows the user to provide the size (1b-32b) and value of any polynomial to fit custom CRC
requirements. The CRC execution time increases to three cycles when using a custom polynomial.
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8.7 Embedded Real-Time Analysis and Diagnostic (ERAD)
The ERAD module enhances the debug and system-analysis capabilities of the device. The debug and system-
analysis enhancements provided by the ERAD module is done outside of the CPU. The ERAD module consists
of the Enhanced Bus Comparator units and the System Event Counter units. The Enhanced Bus Comparator
units are used to generate hardware breakpoints, hardware watch points, and other output events. The System
Event Counter units are used to analyze and profile the system. The ERAD module is accessible by the
debugger and by the application software, which significantly increases the debug capabilities of many real-time
systems, especially in situations where debuggers are not connected. In the TMS320F28002x devices, the
ERAD module contains eight Enhanced Bus Comparator units (which increases the number of Hardware
breakpoints from two to ten) and four Benchmark System Event Counter units.
8.8 Background CRC-32 (BGCRC)
The Background CRC (BGCRC) module computes a CRC-32 on a configurable block of memory. It
accomplishes this by fetching the specified block of memory during idle cycles (when the CPU, HIC, or DMA is
not accessing the memory block). The calculated CRC-32 value is compared against a golden CRC-32 value to
indicate a pass or fail. In essence, the BGCRC helps identify memory faults and corruption.
The BGCRC module has the following features:
• One cycle CRC-32 computation on 32 bits of data
• No CPU bandwidth impact for zero wait state memory
• Minimal CPU bandwidth impact for non-zero wait state memory
• Dual operation modes (CRC-32 mode and scrub mode)
• Watchdog timer to time CRC-32 completion
• Ability to pause and resume CRC-32 computation
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8.9 Direct Memory Access (DMA)
The DMA module provides a hardware method of transferring data between peripherals and/or memory without
intervention from the CPU, thereby freeing up bandwidth for other system functions. Additionally, the DMA has
the capability to orthogonally rearrange the data as it is transferred as well as “ping-pong” data between
buffers. These features are useful for structuring data into blocks for optimal CPU processing. 图 8-2 shows a
device-level block diagram of the DMA.
DMA features include:
• Six channels with independent PIE interrupts
• Peripheral interrupt trigger sources
– ADC interrupts and EVT signals
– External Interrupts
– ePWM SOC signals
– CPU timers
– eCAP
– SPI transmit and receive
– CAN transmit and receive
– LIN transmit and receive
• Data sources and destinations:
– GSx RAM
– ADC result registers
– Control peripheral registers (ePWM, eQEP, eCAP)
– SPI, LIN, CAN, and PMBus registers
• Word Size: 16-bit or 32-bit (SPI limited to 16-bit)
• Throughput: Four cycles per word without arbitration
Global Shared
(GS0) RAM
ADC
WRAPPER
ADC
RESULTS
XINT
TIMER
CAN
LIN
C28x bus
DMA bus
DMA Trigger
TINT(0-2)
XINT(1-5)
Source Selection
ADCx.INT(1-5), ADCx.EVT
CANxIF(1-3)
C28x
DMACHSRCSEL1.CHx
DMACHSRCSEL2.CHx
CHx.MODE.PERINTSEL
(x = 1 to 6)
DMA
ECAP(1-3)DMA
EPWM(1-7).SOCA, EPWM(1-7.SOCB
SPITXDMA(A-B), SPIRXDMA(A-B)
FSITXADMA, FSIRXADMA
PIE
eCAP EPWM
SPI
PMBUS
FSI
图8-2. DMA Block Diagram
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8.10 Device Boot Modes
This section explains the default boot modes, as well as all the available boot modes supported on this device.
The boot ROM uses the boot mode select, general-purpose input/output (GPIO) pins to determine the boot
mode configuration.
表 8-7 shows the boot mode options available for selection by the default boot mode select pins. Users have the
option to program the device to customize the boot modes selectable in the boot-up table as well as the boot
mode select pin GPIOs used.
All the peripheral boot modes that are supported use the first instance of the peripheral module (SCIA, SPIA,
I2CA, CANA, and so forth). Whenever these boot modes are referred to in this chapter, such as SCI boot, it is
actually referring to the first module instance, which means the SCI boot on the SCIA port. The same applies to
the other peripheral boots.
See 节7.11.2.2.2 and 图7-8 for tboot-flash, the boot ROM execution time to first instruction fetch in flash.
表8-7. Device Default Boot Modes
GPIO24
GPIO32
BOOT MODE
(DEFAULT BOOT MODE SELECT PIN 1)
(DEFAULT BOOT MODE SELECT PIN 0)
Parallel IO
SCI / Wait Boot(1)
CAN
0
0
1
1
0
1
0
1
Flash
(1) SCI boot mode can be used as a wait boot mode as long as SCI continues to wait for an 'A' or 'a' during the SCI autobaud lock
process.
8.10.1 Device Boot Configurations
This section details what boot configurations are available and how to configure them. This device supports from
0 boot mode select pins up to 3 boot mode select pins as well as from 1 configured boot mode up to 8
configured boot modes.
To change and configure the device from the default settings to custom settings for your application, use the
following process:
1. Determine all the various ways you want application to be able to boot. (For example: Primary boot option of
Flash boot for your main application, secondary boot option of CAN boot for firmware updates, tertiary boot
option of SCI boot for debugging, etc)
2. Based on the number of boot modes needed, determine how many boot mode select pins (BMSPs) are
required to select between your selected boot modes. (For example: 2 BMSPs are required to select
between 3 boot mode options)
3. Assign the required BMSPs to a physical GPIO pin. (For example, BMSP0 to GPIO10, BMSP1 to GPIO51,
and BMSP2 left as default which is disabled). Refer to 节8.10.1.1 for all the details on performing these
configurations.
4. Assign the determined boot mode definitions to indexes in your custom boot table that correlate to the
decoded value of the BMSPs. For example, BOOTDEF0=Boot to Flash, BOOTDEF1=CAN Boot,
BOOTDEF2=SCI Boot; all other BOOTDEFx are left as default/nothing). Refer to 节8.10.1.2 for all the
details on setting up and configuring the custom boot mode table.
Additionally, the Boot Mode Example Use Cases section of the TMS320F28002x Real-Time Microcontrollers
Technical Reference Manual provides some example use cases on how to configure the BMSPs and custom
boot tables.
Note
The CAN boot mode turns on the XTAL. Be sure an XTAL is installed in the application before using
CAN boot mode.
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8.10.1.1 Configuring Boot Mode Pins
This section explains how the boot mode select pins can be customized by the user, by programming the
BOOTPIN-CONFIG location (refer to 表 8-8) in the user-configurable dual-zone security module (DCSM) OTP.
The location in the DCSM OTP is Z1-OTP-BOOTPIN-CONFIG or Z2-OTP-BOOTPIN-CONFIG. When
debugging, EMU-BOOTPIN-CONFIG is the emulation equivalent of Z1-OTP-BOOTPIN-CONFIG/Z2-OTP-
BOOTPIN-CONFIG, and can be programmed to experiment with different boot modes without writing to OTP.
The device can be programmed to use 0, 1, 2, or 3 boot mode select pins as needed.
Note
When using Z2-OTP-BOOTPIN-CONFIG, the configurations programmed in this location will take
priority over the configurations in Z1-OTP-BOOTPIN-CONFIG. It is recommended to use Z1-OTP-
BOOTPIN-CONFIG first and then if OTP configurations need to be altered, switch to using Z2-OTP-
BOOTPIN-CONFIG.
表8-8. BOOTPIN-CONFIG Bit Fields
BIT
31:24
23:16
15:8
NAME
DESCRIPTION
Key
Write 0x5A to these 8-bits to indicate the bits in this register are valid
Refer to BMSP0 description except for BMSP2
Refer to BMSP0 description except for BMSP1
Boot Mode Select Pin 2 (BMSP2)
Boot Mode Select Pin 1 (BMSP1)
Set to the GPIO pin to be used during boot (up to 255):
- 0x0 = GPIO0
- 0x01 = GPIO1
7:0
Boot Mode Select Pin 0 (BMSP0)
- and so on
Writing 0xFF disables BMSP0 and this pin is no longer used to select
the boot mode.
The following GPIOs cannot be used as a BMSP. If selected for a particular BMSP, the boot ROM automatically
selects the factory default GPIO (the factory default for BMSP2 is 0xFF, which disables the BMSP).
• GPIO 20 and GPIO 21
• GPIO 36 and GPIO 38
• GPIO 47 to GPIO 60
• GPIO 63 to GPIO 223
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表8-9. Standalone Boot Mode Select Pin Decoding
BOOTPIN_CONFIG
BMSP0
BMSP1
BMSP2
REALIZED BOOT MODE
KEY
!= 0x5A
Boot as defined by the factory default BMSPs
Don’t Care
Don’t Care
Don’t Care
Boot as defined in the boot table for boot mode
0xFF
0xFF
0xFF
0
(All BMSPs disabled)
Boot as defined by the value of BMSP0
(BMSP1 and BMSP2 disabled)
Valid GPIO
0xFF
0xFF
Valid GPIO
0xFF
0xFF
0xFF
Boot as defined by the value of BMSP1
(BMSP0 and BMSP2 disabled)
Boot as defined by the value of BMSP2
(BMSP0 and BMSP1 disabled)
0xFF
Valid GPIO
Boot as defined by the values of BMSP0 and
Valid GPIO
Valid GPIO
Valid GPIO
0xFF
0xFF
BMSP1
(BMSP2 disabled)
Boot as defined by the values of BMSP0 and
BMSP2
Valid GPIO
(BMSP1 disabled)
Boot as defined by the values of BMSP1 and
= 0x5A
0xFF
Valid GPIO
Valid GPIO
Valid GPIO
Valid GPIO
BMSP2
(BMSP0 disabled)
Boot as defined by the values of BMSP0,
BMSP1, and BMSP2
Valid GPIO
BMSP0 is reset to the factory default BMSP0
GPIO
Boot as defined by the values of BMSP0,
BMSP1, and BMSP2
Invalid GPIO
Valid GPIO
Valid GPIO
Valid GPIO
Invalid GPIO
Valid GPIO
Valid GPIO
Valid GPIO
Invalid GPIO
BMSP1 is reset to the factory default BMSP1
GPIO
Boot as defined by the values of BMSP0,
BMSP1, and BMSP2
BMSP2 is reset to the factory default state,
which is disabled
Boot as defined by the values of BMSP0 and
BMSP1
Note
When decoding the boot mode, BMSP0 is the least-significant-bit and BMSP2 is the most-significant-
bit of the boot table index value. It is recommended when disabling BMSPs to start with disabling
BMSP2. For example, in an instance when only using BMSP2 (BMSP1 and BMSP0 are disabled),
then only the boot table indexes of 0 and 4 will be selectable. In the instance when using only BMSP0,
then the selectable boot table indexes are 0 and 1.
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8.10.1.2 Configuring Boot Mode Table Options
This section explains how to configure the boot definition table, BOOTDEF, for the device and the associated
boot options. The 64-bit location is located in user-configurable DCSM OTP in the Z1-OTP-BOOTDEF-LOW and
Z1-OTP-BOOTDEF-HIGH locations. When debugging, EMU-BOOTDEF-LOW and EMU-BOOTDEF-HIGH are
the emulation equivalents of Z1-OTP-BOOTDEF-LOW and Z1-OTP-BOOTDEF-HIGH, and can be programmed
to experiment with different boot mode options without writing to OTP. The range of customization to the boot
definition table depends on how many boot mode select pins (BMSP) are being used. For example, 0 BMSPs
equals to 1 table entry, 1 BMSP equals to 2 table entries, 2 BMSPs equals to 4 table entries, and 3 BMSPs
equals to 8 table entries. Refer to the TMS320F28002x Real-Time Microcontrollers Technical Reference Manual
for examples on how to set up the BOOTPIN_CONFIG and BOOTDEF values.
Note
The locations Z2-OTP-BOOTDEF-LOW and Z2-OTP-BOOTDEF-HIGH will be used instead of Z1-
OTP-BOOTDEF-LOW and Z1-OTP-BOOTDEF-HIGH locations when Z2-OTP-BOOTPIN-CONFIG is
configured. Refer to Configuring Boot Mode Pins for more details on BOOTPIN_CONFIG usage.
表8-10. BOOTDEF Bit Fields
BYTE
POSITION
BOOTDEF NAME
NAME
DESCRIPTION
Set the boot mode for index 0 of the boot table.
Different boot modes and their options can include,
for example, a boot mode that uses different GPIOs
for a specific bootloader or a different flash entry
point address. Any unsupported boot mode will
cause the device to either go to wait boot or boot to
flash.
BOOT_DEF0
7:0
BOOT_DEF0 Mode/Options
Refer to GPIO Assignments for valid BOOTDEF
values to set in the table.
BOOT_DEF1
BOOT_DEF2
BOOT_DEF3
BOOT_DEF4
BOOT_DEF5
BOOT_DEF6
BOOT_DEF7
15:8
BOOT_DEF1 Mode/Options
BOOT_DEF2 Mode/Options
BOOT_DEF3 Mode/Options
BOOT_DEF4 Mode/Options
BOOT_DEF5 Mode/Options
BOOT_DEF6 Mode/Options
BOOT_DEF7 Mode/Options
23:16
31:24
39:32
47:40
55:48
63:56
Refer to BOOT_DEF0 description
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8.10.2 GPIO Assignments
This section details the GPIOs and boot option values used for boot mode set in the BOOT_DEF memory
location located at Z1-OTP-BOOTDEF-LOW/ Z2-OTP-BOOTDEF-LOW and Z1-OTP-BOOTDEF-HIGH/ Z2-OTP-
BOOTDEF-HIGH. Refer to Configuring Boot Mode Table Options on how to configure BOOT_DEF. When
selecting a boot mode option, make sure to verify that the necessary pins are available in the pin mux options for
the specific device package being used.
表8-11. SCI Boot Options
OPTION
BOOTDEF VALUE
SCITXDA GPIO
SCIRXDA GPIO
GPIO28
GPIO17
GPIO9
0 (default)
0x01
0x21
0x41
0x61
0x81
GPIO29
1
2
3
4
GPIO16
GPIO8
GPIO2
GPIO3
GPIO16
GPIO3
表8-12. CAN Boot Options
OPTION
BOOTDEF VALUE
CANTXA GPIO
CANRXA GPIO
GPIO5
0 (default)
0x02
0x22
0x42
GPIO4
1
2
GPIO32
GPIO33
GPIO2
GPIO3
表8-13. I2C Boot Options
OPTION
BOOTDEF VALUE
SDAA GPIO
GPIO32
GPIO0
SCLA GPIO
GPIO33
GPIO1
0
1
2
0x07
0x27
0x47
GPIO10
GPIO8
表8-14. RAM Boot Options
RAM ENTRY POINT
(ADDRESS)
OPTION
BOOTDEF VALUE
0
0x05
0x0000 0000
表8-15. Flash Boot Options
FLASH ENTRY POINT
OPTION
BOOTDEF VALUE
FLASH SECTOR
(ADDRESS)
0x0008 0000
0x0008 4000
0x0008 8000
0x0008 EFF0
0 (default)
0x03
0x23
0x43
0x63
Bank0 Sector 0
Bank 0 Sector 4
1
2
3
Bank 0 Sector 8
Bank 0, End of Sector 14
表8-16. Wait Boot Options
OPTION
BOOTDEF VALUE
WATCHDOG
Enabled
0
1
0x04
0x24
Disabled
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TMS320F280025, TMS320F280025-Q1
TMS320F280025C, TMS320F280025C-Q1, TMS320F280023, TMS320F280023-Q1
TMS320F280023C, TMS320F280021, TMS320F280021-Q1
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表8-17. SPI Boot Options
OPTION
BOOTDEF VALUE
SPISIMOA
SPISOMIA
SPICLKA
GPIO3
GPIO3
GPIO9
GPIO9
SPISTEA
GPIO5
0
1
2
3
0x06
0x26
0x46
0x66
GPIO2
GPIO1
GPIO16
GPIO8
GPIO1
GPIO0
GPIO10
GPIO17
GPIO11
GPIO11
GPIO8
表8-18. Parallel Boot Options
28x(DSP) CONTROL
GPIO
OPTION
0 (default)
BOOTDEF VALUE
0x00
D0-D7 GPIO
HOST CONTROL GPIO
D0 - GPIO28
D1 - GPIO1
D2 - GPIO2
D3 - GPIO3
D4 - GPIO4
D5 - GPIO5
D6 - GPIO6
D7 - GPIO7
D0 - GPIO0
D1 - GPIO1
D2 - GPIO2
D3 - GPIO3
D4 - GPIO4
D5 - GPIO5
D6 - GPIO6
D7 - GPIO7
GPIO16
GPIO29
1
0x20
GPIO16
GPIO11
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TMS320F280025, TMS320F280025-Q1
TMS320F280025C, TMS320F280025C-Q1, TMS320F280023, TMS320F280023-Q1
TMS320F280023C, TMS320F280021, TMS320F280021-Q1
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8.11 Dual Code Security Module
The dual code security module (DCSM) prevents access to on-chip secure memories. The term “secure”
means access to secure memories and resources is blocked. The term “unsecure” means access is allowed;
for example, through a debugging tool such as Code Composer Studio™ (CCS).
The code security mechanism offers protection for two zones, Zone 1 (Z1) and Zone 2 (Z2). The security
implementation for both the zones is identical. Each zone has its own dedicated secure resource (OTP memory
and secure ROM) and allocated secure resource (LSx RAM and flash sectors).
The security of each zone is ensured by its own 128-bit password (CSM password). The password for each zone
is stored in an OTP memory location based on a zone-specific link pointer. The link pointer value can be
changed to program a different set of security settings (including passwords) in OTP.
Code Security Module Disclaimer
THE CODE SECURITY MODULE (CSM) INCLUDED ON THIS DEVICE WAS DESIGNED TO
PASSWORD PROTECT THE DATA STORED IN THE ASSOCIATED MEMORY AND IS
WARRANTED BY TEXAS INSTRUMENTS (TI), IN ACCORDANCE WITH ITS STANDARD TERMS
AND CONDITIONS, TO CONFORM TO TI'S PUBLISHED SPECIFICATIONS FOR THE WARRANTY
PERIOD APPLICABLE FOR THIS DEVICE.
TI DOES NOT, HOWEVER, WARRANT OR REPRESENT THAT THE CSM CANNOT BE
COMPROMISED OR BREACHED OR THAT THE DATA STORED IN THE ASSOCIATED MEMORY
CANNOT BE ACCESSED THROUGH OTHER MEANS. MOREOVER, EXCEPT AS SET FORTH
ABOVE, TI MAKES NO WARRANTIES OR REPRESENTATIONS CONCERNING THE CSM OR
OPERATION OF THIS DEVICE, INCLUDING ANY IMPLIED WARRANTIES OF MERCHANTABILITY
OR FITNESS FOR A PARTICULAR PURPOSE.
IN NO EVENT SHALL TI BE LIABLE FOR ANY CONSEQUENTIAL, SPECIAL, INDIRECT,
INCIDENTAL, OR PUNITIVE DAMAGES, HOWEVER CAUSED, ARISING IN ANY WAY OUT OF
YOUR USE OF THE CSM OR THIS DEVICE, WHETHER OR NOT TI HAS BEEN ADVISED OF THE
POSSIBILITY OF SUCH DAMAGES. EXCLUDED DAMAGES INCLUDE, BUT ARE NOT LIMITED
TO LOSS OF DATA, LOSS OF GOODWILL, LOSS OF USE OR INTERRUPTION OF BUSINESS OR
OTHER ECONOMIC LOSS.
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TMS320F280025, TMS320F280025-Q1
TMS320F280025C, TMS320F280025C-Q1, TMS320F280023, TMS320F280023-Q1
TMS320F280023C, TMS320F280021, TMS320F280021-Q1
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8.12 Watchdog
The watchdog module is the same as the one on previous TMS320C2000 devices, but with an optional lower
limit on the time between software resets of the counter. This windowed countdown is disabled by default, so the
watchdog is fully backward-compatible.
The watchdog generates either a reset or an interrupt. It is clocked from the internal oscillator with a selectable
frequency divider.
图8-3 shows the various functional blocks within the watchdog module.
WDCR.WDPRECLKDIV
WDCR.WDPS
WDCR.WDDIS
WDCNTR
WDCLK
(INTOSC1)
Overflow
1-count
delay
8-bit
Watchdog
Counter
WDCLK
Divider
Watchdog
Prescaler
SYSRSn
Clear
Count
WDWCR.MIN
WDKEY (7:0)
Watchdog
Window
Detector
Out of Window
Good Key
Watchdog
Key Detector
55 + AA
WDCR(WDCHK(2:0))
Bad Key
WDRSTn
WDINTn
Generate
512-WDCLK
Output Pulse
1
0
1
Watchdog Time-out
SCSR.WDENINT
图8-3. Windowed Watchdog
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TMS320F280025, TMS320F280025-Q1
TMS320F280025C, TMS320F280025C-Q1, TMS320F280023, TMS320F280023-Q1
TMS320F280023C, TMS320F280021, TMS320F280021-Q1
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8.13 C28x Timers
CPU-Timers 0, 1, and 2 are identical 32-bit timers with presettable periods and with 16-bit clock prescaling. The
timers have a 32-bit count-down register that generates an interrupt when the counter reaches zero. The counter
is decremented at the CPU clock speed divided by the prescale value setting. When the counter reaches zero, it
is automatically reloaded with a 32-bit period value.
CPU-Timer 0 is for general use and is connected to the PIE block. CPU-Timer 1 is also for general use and is
connected to INT13 of the CPU. CPU-Timer 2 is reserved for TI-RTOS. It is connected to INT14 of the CPU. If
TI-RTOS is not being used, CPU-Timer 2 is available for general use.
CPU-Timer 2 can be clocked by any one of the following:
• SYSCLK (default)
• Internal zero-pin oscillator 1 (INTOSC1)
• Internal zero-pin oscillator 2 (INTOSC2)
• X1 (XTAL)
8.14 Dual-Clock Comparator (DCC)
There are three Dual-Clock Comparators (DCC0 and DCC1) on the device. All three DCCs are only accessible
through CPU1. The DCC module is used for evaluating and monitoring the clock input based on a second clock,
which can be a more accurate and reliable version. This instrumentation is used to detect faults in clock source
or clock structures, thereby enhancing the system's safety metrics.
8.14.1 特性
DCC 具有以下特性:
• 允许应用确保两个时钟信号的频率之间保持固定的比率。
• 支持根据参考时钟周期数定义可编程公差窗口。
• 支持连续监视,而无需应用干预。
• 支持单序列模式进行点测量。
• 允许为每个计数器选择一个时钟源,从而产生几种特定的用例。
8.14.2 Mapping of DCCx (DCC0 and DCC1) Clock Source Inputs
表8-19. DCCx Clock Source0 Table
DCCxCLKSRC0[3:0]
CLOCK NAME
XTAL/X1
0x0
0x1
INTOSC1
0x2
INTOSC2
0x5
CPU1.SYSCLK
INPUT XBAR (Output16 of input-xbar)
Reserved
0xC
others
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TMS320F280025, TMS320F280025-Q1
TMS320F280025C, TMS320F280025C-Q1, TMS320F280023, TMS320F280023-Q1
TMS320F280023C, TMS320F280021, TMS320F280021-Q1
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表8-20. DCCx Clock Source1 Table
DCCxCLKSRC1[4:0]
CLOCK NAME
PLLRAWCLK
INTOSC1
0x0
0x2
0x3
0x6
INTOSC2
CPU1.SYSCLK
0x9
0xB
Input XBAR (Output15 of the input-xbar)
EPWMCLK
LSPCLK
0xC
0xD
0xE
ADCCLK
WDCLK
0xF
CAN0BITCLK
Reserved
others
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TMS320F280025, TMS320F280025-Q1
TMS320F280025C, TMS320F280025C-Q1, TMS320F280023, TMS320F280023-Q1
TMS320F280023C, TMS320F280021, TMS320F280021-Q1
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8.15 Configurable Logic Block (CLB)
The C2000 configurable logic block (CLB) is a collection of blocks that can be interconnected using software to
implement custom digital logic functions or enhance existing on-chip peripherals. The CLB is able to enhance
existing peripherals through a set of crossbar interconnections, which provide a high level of connectivity to
existing control peripherals such as enhanced pulse width modulators (ePWM), enhanced capture modules
(eCAP), and enhanced quadrature encoder pulse modules (eQEP). The crossbars also allow the CLB to be
connected to external GPIO pins. In this way, the CLB can be configured to interact with device peripherals to
perform small logical functions such as comparators, or to implement custom serial data exchange protocols.
Through the CLB, functions that would otherwise be accomplished using external logic devices can now be
implemented inside the MCU.
The CLB peripheral is configured through the CLB tool. For more information on the CLB tool, available
examples, application reports and users guide, please refer to the following location in your C2000Ware package
(C2000Ware_2_00_00_03 and higher):
C2000WARE_INSTALL_LOCATION\utilities\clb_tool\clb_syscfg\doc
CLB Tool User Guide
How to Design with the C2000™ CLB Application Report
How to Migrate Custom Logic From an FPGA/CPLD to C2000™ CLB Application Report
The CLB module and its interconnections are shown in 图8-4.
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TMS320F280025, TMS320F280025-Q1
TMS320F280025C, TMS320F280025C-Q1, TMS320F280023, TMS320F280023-Q1
TMS320F280023C, TMS320F280021, TMS320F280021-Q1
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图8-4. CLB Overview
Absolute encoder protocol interfaces are now provided as Position Manager solutions in the C2000Ware
MotorControl SDK. Configuration files, application programmer interface (API), and use examples for such
solutions are provided with C2000Ware MotorControl SDK. In some solutions, the TI-configured CLB is used
with other on-chip resources, such as the SPI port or the C28x CPU, to perform more complex functionality.
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TMS320F280025, TMS320F280025-Q1
TMS320F280025C, TMS320F280025C-Q1, TMS320F280023, TMS320F280023-Q1
TMS320F280023C, TMS320F280021, TMS320F280021-Q1
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9 Applications, Implementation, and Layout
Note
Information in the following applications sections is not part of the TI component specification, and TI
does not warrant its accuracy or completeness. TI’s customers are responsible for determining
suitability of components for their purposes, as well as validating and testing their design
implementation to confirm system functionality.
9.1 TI 参考设计
TI 参考设计库是一个涵盖模拟、嵌入式处理器和连接等内容的强大的参考设计资源库。所有参考设计均由 TI 专家
构建,旨在帮助您着手进行系统设计,其中包括原理图或方框图、BOM 和设计文件,助您加快产品上市步伐。
查看我们面向数字电源应用并基于 F28002x 的最新参考设计:使用 C2000™ MCU 的两相交错式 LLC 谐振转换
器参考设计。
在精选TI 参考设计中搜索并下载其他TI 参考设计。
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TMS320F280025, TMS320F280025-Q1
TMS320F280025C, TMS320F280025C-Q1, TMS320F280023, TMS320F280023-Q1
TMS320F280023C, TMS320F280021, TMS320F280021-Q1
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10 Device and Documentation Support
10.1 Getting Started and Next Steps
For a quick overview of the device, features, roadmap, comparisons to other devices, and package details, see
Texas Instruments C2000™ F28002x Real-Time Controller Series.
10.2 Device and Development Support Tool Nomenclature
To designate the stages in the product development cycle, TI assigns prefixes to the part numbers of all TMS320
MCU devices and support tools. Each TMS320™ MCU commercial family member has one of three prefixes:
TMX, TMP, or TMS (for example, TMS320F280025C). Texas Instruments recommends two of three possible
prefix designators for its support tools: TMDX and TMDS. These prefixes represent evolutionary stages of
product development from engineering prototypes (with TMX for devices and TMDX for tools) through fully
qualified production devices and tools (with TMS for devices and TMDS for tools).
Device development evolutionary flow:
TMX Experimental device that is not necessarily representative of the final device's electrical specifications and
may not use production assembly flow.
TMP Prototype device that is not necessarily the final silicon die and may not necessarily meet final electrical
specifications.
TMS Production version of the silicon die that is fully qualified.
Support tool development evolutionary flow:
TMDX Development-support product that has not yet completed Texas Instruments internal qualification testing.
TMDS Fully-qualified development-support product.
TMX and TMP devices and TMDX development-support tools are shipped against the following disclaimer:
"Developmental product is intended for internal evaluation purposes."
Production devices and TMDS development-support tools have been characterized fully, and the quality and
reliability of the device have been demonstrated fully. TI's standard warranty applies.
Predictions show that prototype devices (X or P) have a greater failure rate than the standard production
devices. Texas Instruments recommends that these devices not be used in any production system because their
expected end-use failure rate still is undefined. Only qualified production devices are to be used.
TI device nomenclature also includes a suffix with the device family name. This suffix indicates the package type
(for example, PN) and temperature range (for example, S).
For device part numbers and further ordering information, see the TI website (www.ti.com) or contact your TI
sales representative.
For additional description of the device nomenclature markings on the die, see the TMS320F28002x Real-Time
MCUs Silicon Errata.
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TMS320F280025, TMS320F280025-Q1
TMS320F280025C, TMS320F280025C-Q1, TMS320F280023, TMS320F280023-Q1
TMS320F280023C, TMS320F280021, TMS320F280021-Q1
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-Q1
Q
Generic Part Number: TMS 320
Orderable Part Number: (blank)
PREFIX(A)
F
F
280025C
R
X
280025C PN
SHIPPING OPTIONS
experimental device
TMX (X)
TMS (blank)
=
=
Tray
Tape and Reel
(blank)
R
=
=
qualified device
QUALIFICATION (in Generic Part Number)
Non-Automotive
Q1 refers to Automotive AEC Q100 Grade 1 qualification.
blank
-Q1
=
=
DEVICE FAMILY
320 = TMS320 MCU Family
TEMPERATURE RANGE (in Orderable Part Number)
−40°C to 125°C (TJ)
S
=
=
TECHNOLOGY
Q
−40°C to 125°C (TA)
F = Flash
PACKAGE TYPE
80-Pin PN Low-Profile Quad Flatpack (LQFP)
64-Pin PM LQFP
48-Pin PT LQFP
DEVICE
280025
280023
280021
280025C
280023C
A. Prefix X is used in orderable part numbers.
图10-1. Device Nomenclature
10.3 Markings
图10-2 and 图10-3 show the package symbolization. 表10-1 lists the silicon revision codes.
F280025CPMS
$$#−YMLLLLS
G4
F280025CPNS
$$#−YMLLLLS
G4
Package
Pin 1
Package
Pin 1
YMLLLLS
Lot Trace Code
=
YM
LLLL
S
2-Digit Year/Month Code
Assembly Lot
Assembly Site Code
Wafer Fab Code (one or two characters) as applicable
Silicon Revision Code
=
=
=
=
=
$$
#
G4
Green (Low Halogen and RoHS-compliant)
=
图10-2. Package Symbolization for PM and PN Packages
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TMS320F280025, TMS320F280025-Q1
TMS320F280025C, TMS320F280025C-Q1, TMS320F280023, TMS320F280023-Q1
TMS320F280023C, TMS320F280021, TMS320F280021-Q1
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YMLLLLS
Lot Trace Code
=
980 PTS
F280025C
YMLLLLS
YM
LLLL
S
980
$$
2-Digit Year/Month Code
Assembly Lot
Assembly Site Code
TI E.I.A. Code
Wafer Fab Code (one or two characters) as applicable
Silicon Revision Code
=
=
=
=
=
=
#
$$#
G4
G4
Green (Low Halogen and RoHS-compliant)
=
Package
Pin 1
图10-3. Package Symbolization for PT Package
表10-1. Revision Identification
REVID(1)
ADDRESS: 0x5D00C
SILICON REVISION CODE
SILICON REVISION
COMMENTS
Blank
A
0
0x0000 0000
0x0000 0001
This silicon revision is available as TMX.
This silicon revision is available as TMX and
TMS.
A
(1) Silicon Revision ID
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TMS320F280025, TMS320F280025-Q1
TMS320F280025C, TMS320F280025C-Q1, TMS320F280023, TMS320F280023-Q1
TMS320F280023C, TMS320F280021, TMS320F280021-Q1
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10.4 Tools and Software
TI offers an extensive line of development tools. Some of the tools and software to evaluate the performance of
the device, generate code, and develop solutions follow. To view all available tools and software for C2000™
real-time control MCUs, visit the C2000 real-time control MCUs –Design & development page.
Development Tools
LAUNCHXL-F280025C
LAUNCHXL-F280025C is a low-cost development board for TI C2000™ Real-Time Controllers series of F28002x
devices. Ideal for initial evaluation and prototyping, it provides a standardized and easy-to-use platform to
develop your next application. This extended version LaunchPad™ development kit offers extra pins for
evaluation and supports the connection of two BoosterPack™ plug-in modules.
F280025 controlCARD
The F280025 controlCARD is an HSEC180 controlCARD based evaluation and development tool for the C2000
™ F28002x series of microcontroller products. controlCARDs are ideal to use for initial evaluation and system
prototyping. controlCARDs are complete board-level modules that utilize one of two standard form factors (100-
pin DIMM or 180-pin HSEC ) to provide a low-profile single-board controller solution. For first evaluation
controlCARDs are typically purchased bundled with a baseboard or bundled in an application kit.
TI Resource Explorer
To enhance your experience, be sure to check out the TI Resource Explorer to browse examples, libraries, and
documentation for your applications.
Software Tools
C2000Ware for C2000 MCUs
C2000Ware for C2000™ MCUs is a cohesive set of software and documentation created to minimize
development time. It includes device-specific drivers, libraries, and peripheral examples.
Digital Power SDK
Digital Power SDK is a cohesive set of software infrastructure, tools, and documentation designed to minimize
C2000 MCU-based digital power system development time targeted for various AC-DC, DC-DC and DC-AC
power supply applications. The software includes firmware that runs on C2000 digital power evaluation modules
(EVMs) and TI designs (TIDs), which are targeted for solar, telecom, server, electric vehicle chargers and
industrial power delivery applications. Digital Power SDK provides all the needed resources at every stage of
development and evaluation in a digital power applications.
Motor Control SDK
Motor Control SDK is a cohesive set of software infrastructure, tools, and documentation designed to minimize
C2000 MCU-based motor control system development time targeted for various three-phase motor control
applications. The software includes firmware that runs on C2000 motor control evaluation modules (EVMs) and
TI designs (TIDs), which are targeted for industrial drive and other motor control, Motor Control SDK provides all
the needed resources at every stage of development and evaluation for high-performance motor control
applications.
Code Composer Studio™ (CCS) Integrated Development Environment (IDE) for C2000 microcontrollers
Code Composer Studio is an integrated development environment (IDE) that supports TI's Microcontroller and
Embedded Processors portfolio. Code Composer Studio comprises a suite of tools used to develop and debug
embedded applications. It includes an optimizing C/C++ compiler, source code editor, project build environment,
debugger, profiler, and many other features. The intuitive IDE provides a single user interface taking the user
through each step of the application development flow. Familiar tools and interfaces allow users to get started
faster than ever before. Code Composer Studio combines the advantages of the Eclipse software framework
with advanced embedded debug capabilities from TI resulting in a compelling feature-rich development
environment for embedded developers.
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TMS320F280025, TMS320F280025-Q1
TMS320F280025C, TMS320F280025C-Q1, TMS320F280023, TMS320F280023-Q1
TMS320F280023C, TMS320F280021, TMS320F280021-Q1
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SysConfig System configuration tool
SysConfig is a comprehensive collection of graphical utilities for configuring pins, peripherals, radios,
subsystems, and other components. SysConfig helps you manage, expose and resolve conflicts visually so that
you have more time to create differentiated applications. The tool's output includes C header and code files that
can be used with software development kit (SDK) examples or used to configure custom software. The
SysConfig tool automatically selects the pinmux settings that satisfy the entered requirements. The SysConfig
tool is delivered integrated in CCS, as a standalone installer, or can be used via the dev.ti.com cloud tools portal.
For more information about the SysConfig system configuration tool, visit the System configuation tool page.
Models
Various models are available for download from the product Design & development pages. These models
include I/O Buffer Information Specification (IBIS) Models and Boundary-Scan Description Language (BSDL)
Models. To view all available models, visit the Design tools & simulation section of the Design & development
page for each device.
Training
To help assist design engineers in taking full advantage of the C2000 microcontroller features and performance,
TI has developed a variety of training resources. Utilizing the online training materials and downloadable hands-
on workshops provides an easy means for gaining a complete working knowledge of the C2000 microcontroller
family. These training resources have been designed to decrease the learning curve, while reducing
development time, and accelerating product time to market. For more information on the various training
resources, visit the C2000™ real-time control MCUs –Support & training site.
The architecture and many of the peripherals of the F28002x are similar to those of the F28004x. The following
Workshop material and the Migration Between TMS320F28004x and TMS320F28002x Application Report will
cover the technical details of the TMS320F28004x architecture and highlight the device differences, which will be
helpful to users of the F28002x device.
Specific TMS320F28004x hands-on training resources can be found at C2000™ MCU Device Workshops.
Technical Introduction to the New C2000 TMS320F28004x Device Family
Many of the peripherals and architecture of the F28002x are similar to the F28004x. This presentation will cover
the technical details of the TMS320F28004x architecture and highlight the new improvements to various key
peripherals which will be helpful to users of the F28002x device.
10.5 Documentation Support
To receive notification of documentation updates, navigate to the device product folder on ti.com. Click on
Subscribe to updates to register and receive a weekly digest of any product information that has changed. For
change details, review the revision history included in any revised document.
The current documentation that describes the processor, related peripherals, and other technical collateral
follows.
Errata
TMS320F28002x Real-Time MCUs Silicon Errata describes known advisories on silicon and provides
workarounds.
Technical Reference Manual
TMS320F28002x Real-Time Microcontrollers Technical Reference Manual details the integration, the
environment, the functional description, and the programming models for each peripheral and subsystem in the
F28002x real-time microcontrollers.
Copyright © 2021 Texas Instruments Incorporated
188 Submit Document Feedback
Product Folder Links: TMS320F280025 TMS320F280025-Q1 TMS320F280025C TMS320F280025C-Q1
TMS320F280023 TMS320F280023-Q1 TMS320F280023C TMS320F280021 TMS320F280021-Q1
TMS320F280025, TMS320F280025-Q1
TMS320F280025C, TMS320F280025C-Q1, TMS320F280023, TMS320F280023-Q1
TMS320F280023C, TMS320F280021, TMS320F280021-Q1
www.ti.com.cn
ZHCSL01B –MARCH 2020 –REVISED DECEMBER 2020
CPU User's Guides
TMS320C28x CPU and Instruction Set Reference Guide describes the central processing unit (CPU) and the
assembly language instructions of the TMS320C28x fixed-point digital signal processors (DSPs). This Reference
Guide also describes emulation features available on these DSPs.
TMS320C28x Extended Instruction Sets Technical Reference Manual describes the architecture, pipeline, and
instruction set of the TMU, VCU-II, and FPU accelerators.
Peripheral Guides
C2000 Real-Time Control Peripherals Reference Guide describes the peripheral reference guides of the 28x
DSPs.
Tools Guides
TMS320C28x Assembly Language Tools v20.8.0.STS User's Guide describes the assembly language tools
(assembler and other tools used to develop assembly language code), assembler directives, macros, common
object file format, and symbolic debugging directives for the TMS320C28x device.
TMS320C28x Optimizing C/C++ Compiler v20.8.0.STS User's Guide describes the TMS320C28x C/C++
compiler. This compiler accepts ANSI standard C/C++ source code and produces TMS320 DSP assembly
language source code for the TMS320C28x device.
Application Reports
The SMT & packaging application notes website lists documentation on TI’s surface mount technology (SMT)
and application notes on a variety of packaging-related topics.
Semiconductor Packing Methodology describes the packing methodologies employed to prepare semiconductor
devices for shipment to end users.
Calculating Useful Lifetimes of Embedded Processors provides a methodology for calculating the useful lifetime
of TI embedded processors (EPs) under power when used in electronic systems. It is aimed at general
engineers who wish to determine if the reliability of the TI EP meets the end system reliability requirement.
An Introduction to IBIS (I/O Buffer Information Specification) Modeling discusses various aspects of IBIS
including its history, advantages, compatibility, model generation flow, data requirements in modeling the input/
output structures, and future trends.
Serial Flash Programming of C2000™ Microcontrollers discusses using a flash kernel and ROM loaders for
serial programming a device.
Fast Integer Division – A Differentiated Offering From C2000™ Product Family provides an overview of the
different division and modulo (remainder) functions and its associated properties.
C2000™ Key Technology Guide provides a deeper look into the components that differentiate the C2000
Microcontroller Unit (MCU) as it pertains to Real-Time Control Systems.
Migration Between TMS320F28004x and TMS320F28002x describes the hardware and software differences to
be aware of when moving between F28004x and F28002x C2000™ MCUs.
TMS320F2802x/TMS320F2803x to TMS320F28002x Migration Overview describes the differences between the
Texas Instruments TMS320F2802x/TMS320F2803x and the TMS320F28002x microcontrollers for the purpose
of assisting with application migration.
10.6 支持资源
TI E2E™ 支持论坛是工程师的重要参考资料,可直接从专家获得快速、经过验证的解答和设计帮助。搜索现有解
答或提出自己的问题可获得所需的快速设计帮助。
链接的内容由各个贡献者“按原样”提供。这些内容并不构成 TI 技术规范,并且不一定反映 TI 的观点;请参阅
TI 的《使用条款》。
Copyright © 2021 Texas Instruments Incorporated
Submit Document Feedback 189
Product Folder Links: TMS320F280025 TMS320F280025-Q1 TMS320F280025C TMS320F280025C-Q1
TMS320F280023 TMS320F280023-Q1 TMS320F280023C TMS320F280021 TMS320F280021-Q1
TMS320F280025, TMS320F280025-Q1
TMS320F280025C, TMS320F280025C-Q1, TMS320F280023, TMS320F280023-Q1
TMS320F280023C, TMS320F280021, TMS320F280021-Q1
ZHCSL01B –MARCH 2020 –REVISED DECEMBER 2020
www.ti.com.cn
10.7 Trademarks
C2000™, TMS320C2000™, InstaSPIN-FOC™, Code Composer Studio™, TMS320™, LaunchPad™, BoosterPack
™, TI E2E™ are trademarks of Texas Instruments.
Bosch® is a registered trademark of Robert Bosch GmbH Corporation.
所有商标均为其各自所有者的财产。
10.8 静电放电警告
静电放电(ESD) 会损坏这个集成电路。德州仪器(TI) 建议通过适当的预防措施处理所有集成电路。如果不遵守正确的处理
和安装程序,可能会损坏集成电路。
ESD 的损坏小至导致微小的性能降级,大至整个器件故障。精密的集成电路可能更容易受到损坏,这是因为非常细微的参
数更改都可能会导致器件与其发布的规格不相符。
10.9 术语表
TI 术语表
本术语表列出并解释了术语、首字母缩略词和定义。
Copyright © 2021 Texas Instruments Incorporated
190 Submit Document Feedback
Product Folder Links: TMS320F280025 TMS320F280025-Q1 TMS320F280025C TMS320F280025C-Q1
TMS320F280023 TMS320F280023-Q1 TMS320F280023C TMS320F280021 TMS320F280021-Q1
TMS320F280025, TMS320F280025-Q1
TMS320F280025C, TMS320F280025C-Q1, TMS320F280023, TMS320F280023-Q1
TMS320F280023C, TMS320F280021, TMS320F280021-Q1
www.ti.com.cn
ZHCSL01B –MARCH 2020 –REVISED DECEMBER 2020
11 Mechanical, Packaging, and Orderable Information
11.1 Packaging Information
The following pages include mechanical, packaging, and orderable information. This information is the most
current data available for the designated devices. This data is subject to change without notice and revision of
this document. For browser-based versions of this data sheet, refer to the left-hand navigation.
To learn more about TI packaging, visit the Packaging information website.
Copyright © 2021 Texas Instruments Incorporated
Submit Document Feedback 191
Product Folder Links: TMS320F280025 TMS320F280025-Q1 TMS320F280025C TMS320F280025C-Q1
TMS320F280023 TMS320F280023-Q1 TMS320F280023C TMS320F280021 TMS320F280021-Q1
PACKAGE OPTION ADDENDUM
www.ti.com
29-Jan-2021
PACKAGING INFORMATION
Orderable Device
Status Package Type Package Pins Package
Eco Plan
Lead finish/
Ball material
MSL Peak Temp
Op Temp (°C)
Device Marking
Samples
Drawing
Qty
(1)
(2)
(3)
(4/5)
(6)
F280021PTQR
F280021PTSR
ACTIVE
LQFP
LQFP
PT
48
48
1000 RoHS & Green
1000 RoHS & Green
NIPDAU
Level-3-260C-168 HR
Level-3-260C-168 HR
-40 to 125
-40 to 125
F280021
PTQ
ACTIVE
PT
NIPDAU
F280021
PTS
F280023CPMSR
F280023CPNSR
F280023CPTSR
ACTIVE
ACTIVE
ACTIVE
LQFP
LQFP
LQFP
PM
PN
PT
64
80
48
1000 RoHS & Green
1000 RoHS & Green
1000 RoHS & Green
NIPDAU
NIPDAU
NIPDAU
Level-3-260C-168 HR
Level-3-260C-168 HR
Level-3-260C-168 HR
-40 to 125
-40 to 125
-40 to 125
F280023CPMS
F280023CPNS
F280023C
PTS
F280023PMQR
F280023PMSR
F280023PNQR
F280023PNSR
F280023PTQR
ACTIVE
ACTIVE
ACTIVE
ACTIVE
ACTIVE
LQFP
LQFP
LQFP
LQFP
LQFP
PM
PM
PN
PN
PT
64
64
80
80
48
1000 RoHS & Green
1000 RoHS & Green
1000 RoHS & Green
1000 RoHS & Green
1000 RoHS & Green
NIPDAU
NIPDAU
NIPDAU
NIPDAU
NIPDAU
Level-3-260C-168 HR
Level-3-260C-168 HR
Level-3-260C-168 HR
Level-3-260C-168 HR
Level-3-260C-168 HR
-40 to 125
-40 to 125
-40 to 125
-40 to 125
-40 to 125
F280023PMQ
F280023PMS
F280023PNQ
F280023PNS
F280023
PTQ
F280023PTSR
ACTIVE
LQFP
PT
48
1000 RoHS & Green
1000 RoHS & Green
NIPDAU
Level-3-260C-168 HR
-40 to 125
F280023
PTS
F280025CPMQR
F280025CPMS
F280025CPMSR
F280025CPNQR
F280025CPNSR
F280025CPTQR
ACTIVE
ACTIVE
ACTIVE
ACTIVE
ACTIVE
ACTIVE
LQFP
LQFP
LQFP
LQFP
LQFP
LQFP
PM
PM
PM
PN
PN
PT
64
64
64
80
80
48
NIPDAU
NIPDAU
NIPDAU
NIPDAU
NIPDAU
NIPDAU
Level-3-260C-168 HR
Level-3-260C-168 HR
Level-3-260C-168 HR
Level-3-260C-168 HR
Level-3-260C-168 HR
Level-3-260C-168 HR
-40 to 125
-40 to 125
-40 to 125
-40 to 125
-40 to 125
-40 to 125
F280025CPMQ
F280025CPMS
F280025CPMS
F280025CPNQ
F280025CPNS
160
RoHS & Green
1000 RoHS & Green
1000 RoHS & Green
1000 RoHS & Green
1000 RoHS & Green
F280025C
PTQ
F280025CPTSR
ACTIVE
LQFP
PT
48
1000 RoHS & Green
NIPDAU
Level-3-260C-168 HR
-40 to 125
F280025C
PTS
Addendum-Page 1
PACKAGE OPTION ADDENDUM
www.ti.com
29-Jan-2021
Orderable Device
Status Package Type Package Pins Package
Eco Plan
Lead finish/
Ball material
MSL Peak Temp
Op Temp (°C)
Device Marking
Samples
Drawing
Qty
(1)
(2)
(3)
(4/5)
(6)
F280025PMQR
F280025PMS
F280025PMSR
F280025PNQR
F280025PNS
F280025PNSR
F280025PTQR
ACTIVE
ACTIVE
ACTIVE
ACTIVE
ACTIVE
ACTIVE
ACTIVE
LQFP
LQFP
LQFP
LQFP
LQFP
LQFP
LQFP
PM
PM
PM
PN
PN
PN
PT
64
64
64
80
80
80
48
1000 RoHS & Green
160 RoHS & Green
NIPDAU
Level-3-260C-168 HR
Level-3-260C-168 HR
Level-3-260C-168 HR
Level-3-260C-168 HR
Level-3-260C-168 HR
Level-3-260C-168 HR
Level-3-260C-168 HR
-40 to 125
-40 to 125
-40 to 125
-40 to 125
-40 to 125
-40 to 125
-40 to 125
F280025PMQ
NIPDAU
NIPDAU
NIPDAU
NIPDAU
NIPDAU
NIPDAU
F280025PMS
F280025PMS
F280025PNQ
F280025PNS
F280025PNS
1000 RoHS & Green
1000 RoHS & Green
119
RoHS & Green
1000 RoHS & Green
1000 RoHS & Green
F280025
PTQ
F280025PTS
ACTIVE
ACTIVE
LQFP
LQFP
PT
PT
48
48
250
RoHS & Green
NIPDAU
NIPDAU
Level-3-260C-168 HR
Level-3-260C-168 HR
-40 to 125
-40 to 125
F280025
PTS
F280025PTSR
1000 RoHS & Green
F280025
PTS
(1) The marketing status values are defined as follows:
ACTIVE: Product device recommended for new designs.
LIFEBUY: TI has announced that the device will be discontinued, and a lifetime-buy period is in effect.
NRND: Not recommended for new designs. Device is in production to support existing customers, but TI does not recommend using this part in a new design.
PREVIEW: Device has been announced but is not in production. Samples may or may not be available.
OBSOLETE: TI has discontinued the production of the device.
(2) RoHS: TI defines "RoHS" to mean semiconductor products that are compliant with the current EU RoHS requirements for all 10 RoHS substances, including the requirement that RoHS substance
do not exceed 0.1% by weight in homogeneous materials. Where designed to be soldered at high temperatures, "RoHS" products are suitable for use in specified lead-free processes. TI may
reference these types of products as "Pb-Free".
RoHS Exempt: TI defines "RoHS Exempt" to mean products that contain lead but are compliant with EU RoHS pursuant to a specific EU RoHS exemption.
Green: TI defines "Green" to mean the content of Chlorine (Cl) and Bromine (Br) based flame retardants meet JS709B low halogen requirements of <=1000ppm threshold. Antimony trioxide based
flame retardants must also meet the <=1000ppm threshold requirement.
(3) MSL, Peak Temp. - The Moisture Sensitivity Level rating according to the JEDEC industry standard classifications, and peak solder temperature.
(4) There may be additional marking, which relates to the logo, the lot trace code information, or the environmental category on the device.
Addendum-Page 2
PACKAGE OPTION ADDENDUM
www.ti.com
29-Jan-2021
(5) Multiple Device Markings will be inside parentheses. Only one Device Marking contained in parentheses and separated by a "~" will appear on a device. If a line is indented then it is a continuation
of the previous line and the two combined represent the entire Device Marking for that device.
(6)
Lead finish/Ball material - Orderable Devices may have multiple material finish options. Finish options are separated by a vertical ruled line. Lead finish/Ball material values may wrap to two
lines if the finish value exceeds the maximum column width.
Important Information and Disclaimer:The information provided on this page represents TI's knowledge and belief as of the date that it is provided. TI bases its knowledge and belief on information
provided by third parties, and makes no representation or warranty as to the accuracy of such information. Efforts are underway to better integrate information from third parties. TI has taken and
continues to take reasonable steps to provide representative and accurate information but may not have conducted destructive testing or chemical analysis on incoming materials and chemicals.
TI and TI suppliers consider certain information to be proprietary, and thus CAS numbers and other limited information may not be available for release.
In no event shall TI's liability arising out of such information exceed the total purchase price of the TI part(s) at issue in this document sold by TI to Customer on an annual basis.
Addendum-Page 3
PACKAGE MATERIALS INFORMATION
www.ti.com
4-Jan-2022
TAPE AND REEL INFORMATION
*All dimensions are nominal
Device
Package Package Pins
Type Drawing
SPQ
Reel
Reel
A0
B0
K0
P1
W
Pin1
Diameter Width (mm) (mm) (mm) (mm) (mm) Quadrant
(mm) W1 (mm)
F280021PTQR
F280021PTSR
F280023CPMSR
F280023CPNSR
F280023CPTSR
F280023PMQR
F280023PMSR
F280023PNQR
F280023PNSR
F280023PTQR
F280023PTSR
F280025CPMQR
F280025CPMSR
F280025CPNQR
F280025CPNSR
F280025CPTQR
F280025CPTSR
F280025PMQR
LQFP
LQFP
LQFP
LQFP
LQFP
LQFP
LQFP
LQFP
LQFP
LQFP
LQFP
LQFP
LQFP
LQFP
LQFP
LQFP
LQFP
LQFP
PT
PT
PM
PN
PT
PM
PM
PN
PN
PT
PT
PM
PM
PN
PN
PT
PT
PM
48
48
64
80
48
64
64
80
80
48
48
64
64
80
80
48
48
64
1000
1000
1000
1000
1000
1000
1000
1000
1000
1000
1000
1000
1000
1000
1000
1000
1000
1000
330.0
330.0
330.0
330.0
330.0
330.0
330.0
330.0
330.0
330.0
330.0
330.0
330.0
330.0
330.0
330.0
330.0
330.0
16.4
16.4
24.4
24.4
16.4
24.4
24.4
24.4
24.4
16.4
16.4
24.4
24.4
24.4
24.4
16.4
16.4
24.4
9.6
9.6
9.6
9.6
1.9
1.9
2.1
2.0
1.9
2.1
2.1
2.0
2.0
1.9
1.9
2.1
2.1
2.0
2.0
1.9
1.9
2.1
12.0
12.0
16.0
24.0
12.0
16.0
16.0
24.0
24.0
12.0
12.0
16.0
16.0
24.0
24.0
12.0
12.0
16.0
16.0
16.0
24.0
24.0
16.0
24.0
24.0
24.0
24.0
16.0
16.0
24.0
24.0
24.0
24.0
16.0
16.0
24.0
Q2
Q2
Q2
Q2
Q2
Q2
Q2
Q2
Q2
Q2
Q2
Q2
Q2
Q2
Q2
Q2
Q2
Q2
13.0
16.0
9.6
13.0
16.0
9.6
13.0
13.0
16.0
16.0
9.6
13.0
13.0
16.0
16.0
9.6
9.6
9.6
13.0
13.0
16.0
16.0
9.6
13.0
13.0
16.0
16.0
9.6
9.6
9.6
13.0
13.0
Pack Materials-Page 1
PACKAGE MATERIALS INFORMATION
www.ti.com
4-Jan-2022
Device
Package Package Pins
Type Drawing
SPQ
Reel
Reel
A0
B0
K0
P1
W
Pin1
Diameter Width (mm) (mm) (mm) (mm) (mm) Quadrant
(mm) W1 (mm)
F280025PMSR
F280025PNQR
F280025PNSR
F280025PTQR
F280025PTSR
LQFP
LQFP
LQFP
LQFP
LQFP
PM
PN
PN
PT
PT
64
80
80
48
48
1000
1000
1000
1000
1000
330.0
330.0
330.0
330.0
330.0
24.4
24.4
24.4
16.4
16.4
13.0
16.0
16.0
9.6
13.0
16.0
16.0
9.6
2.1
2.0
2.0
1.9
1.9
16.0
24.0
24.0
12.0
12.0
24.0
24.0
24.0
16.0
16.0
Q2
Q2
Q2
Q2
Q2
9.6
9.6
*All dimensions are nominal
Device
Package Type Package Drawing Pins
SPQ
Length (mm) Width (mm) Height (mm)
F280021PTQR
F280021PTSR
F280023CPMSR
F280023CPNSR
F280023CPTSR
F280023PMQR
F280023PMSR
F280023PNQR
F280023PNSR
F280023PTQR
F280023PTSR
F280025CPMQR
LQFP
LQFP
LQFP
LQFP
LQFP
LQFP
LQFP
LQFP
LQFP
LQFP
LQFP
LQFP
PT
PT
PM
PN
PT
PM
PM
PN
PN
PT
PT
PM
48
48
64
80
48
64
64
80
80
48
48
64
1000
1000
1000
1000
1000
1000
1000
1000
1000
1000
1000
1000
336.6
336.6
336.6
367.0
336.6
336.6
336.6
367.0
367.0
336.6
336.6
336.6
336.6
336.6
336.6
367.0
336.6
336.6
336.6
367.0
367.0
336.6
336.6
336.6
31.8
31.8
41.3
55.0
31.8
41.3
41.3
55.0
55.0
31.8
31.8
41.3
Pack Materials-Page 2
PACKAGE MATERIALS INFORMATION
www.ti.com
4-Jan-2022
Device
Package Type Package Drawing Pins
SPQ
Length (mm) Width (mm) Height (mm)
F280025CPMSR
F280025CPNQR
F280025CPNSR
F280025CPTQR
F280025CPTSR
F280025PMQR
F280025PMSR
F280025PNQR
F280025PNSR
F280025PTQR
F280025PTSR
LQFP
LQFP
LQFP
LQFP
LQFP
LQFP
LQFP
LQFP
LQFP
LQFP
LQFP
PM
PN
PN
PT
PT
PM
PM
PN
PN
PT
PT
64
80
80
48
48
64
64
80
80
48
48
1000
1000
1000
1000
1000
1000
1000
1000
1000
1000
1000
336.6
367.0
367.0
336.6
336.6
336.6
336.6
367.0
367.0
336.6
336.6
336.6
367.0
367.0
336.6
336.6
336.6
336.6
367.0
367.0
336.6
336.6
41.3
55.0
55.0
31.8
31.8
41.3
41.3
55.0
55.0
31.8
31.8
Pack Materials-Page 3
PACKAGE MATERIALS INFORMATION
www.ti.com
4-Jan-2022
TRAY
Chamfer on Tray corner indicates Pin 1 orientation of packed units.
*All dimensions are nominal
Device
Package Package Pins SPQ Unit array
Max
matrix temperature
(°C)
L (mm)
W
K0
P1
CL
CW
Name
Type
(mm) (µm) (mm) (mm) (mm)
F280025CPMS
F280025PMS
F280025PNS
F280025PTS
PM
PM
PN
PT
LQFP
LQFP
LQFP
LQFP
64
64
80
48
160
160
119
250
8 X 20
8 X 20
7 X 17
10 x 25
150
150
150
150
315 135.9 7620 15.2
315 135.9 7620 15.2
315 135.9 7620 17.9
315 135.9 7620 12.2
13.1
13.1
13
13
14.3 13.95
11.1 11.25
Pack Materials-Page 4
PACKAGE OUTLINE
PM0064A
LQFP - 1.6 mm max height
SCALE 1.400
PLASTIC QUAD FLATPACK
10.2
9.8
B
NOTE 3
64
49
PIN 1 ID
1
48
10.2
9.8
12.2
TYP
11.8
NOTE 3
33
16
32
17
A
0.27
0.17
64X
60X 0.5
4X 7.5
0.08
C A B
C
(0.13) TYP
SEATING PLANE
0.08
SEE DETAIL A
0.25
GAGE PLANE
(1.4)
1.6 MAX
0.05 MIN
0.75
0.45
0 -7
DETAIL
SCALE: 14
A
DETAIL A
TYPICAL
4215162/A 03/2017
NOTES:
1. All linear dimensions are in millimeters. Any dimensions in parenthesis are for reference only. Dimensioning and tolerancing
per ASME Y14.5M.
2. This drawing is subject to change without notice.
3. This dimension does not include mold flash, protrusions, or gate burrs. Mold flash, protrusions, or gate burrs shall not
exceed 0.15 mm per side.
4. Reference JEDEC registration MS-026.
www.ti.com
EXAMPLE BOARD LAYOUT
PM0064A
LQFP - 1.6 mm max height
PLASTIC QUAD FLATPACK
SYMM
49
64
64X (1.5)
1
48
64X (0.3)
SYMM
(11.4)
60X (0.5)
(R0.05) TYP
33
16
17
32
(11.4)
LAND PATTERN EXAMPLE
EXPOSED METAL SHOWN
SCALE:8X
0.05 MAX
ALL AROUND
EXPOSED METAL
METAL
0.05 MIN
ALL AROUND
EXPOSED METAL
SOLDER MASK
OPENING
METAL UNDER
SOLDER MASK
SOLDER MASK
NON SOLDER MASK
DEFINED
SOLDER MASK
DEFINED
SOLDER MASK DETAILS
4215162/A 03/2017
NOTES: (continued)
5. Publication IPC-7351 may have alternate designs.
6. Solder mask tolerances between and around signal pads can vary based on board fabrication site.
7. For more information, see Texas Instruments literature number SLMA004 (www.ti.com/lit/slma004).
www.ti.com
EXAMPLE STENCIL DESIGN
PM0064A
LQFP - 1.6 mm max height
PLASTIC QUAD FLATPACK
SYMM
64
49
64X (1.5)
1
48
64X (0.3)
SYMM
(11.4)
60X (0.5)
(R0.05) TYP
16
33
17
32
(11.4)
SOLDER PASTE EXAMPLE
BASED ON 0.125 mm THICK STENCIL
SCALE:8X
4215162/A 03/2017
NOTES: (continued)
8. Laser cutting apertures with trapezoidal walls and rounded corners may offer better paste release. IPC-7525 may have alternate
design recommendations.
9. Board assembly site may have different recommendations for stencil design.
www.ti.com
PACKAGE OUTLINE
PT0048A
LQFP - 1.6 mm max height
S
C
A
L
E
2
.
0
0
0
LOW PROFILE QUAD FLATPACK
9.2
8.8
7.2
6.8
B
A
9.2
8.8
7.2
6.8
0.27
48X
0.17
0.08
C A B
44X 0.5
4X 5.5
SEE DETAIL A
1.6 MAX
C
SEATING PLANE
0.1 C
1.45
1.35
0.25
GAGE PLANE
0.75
0.45
0.5 MIN
0 -7
A15.000
DETAIL A
4215159/A 12/2021
NOTES:
1. All linear dimensions are in millimeters. Any dimensions in parenthesis are for reference only. Dimensioning and tolerancing
per ASME Y14.5M.
2. This drawing is subject to change without notice.
3. Reference JEDEC registration MS-026.
4. This may also be a thermally enhanced plastic package with leads conected to the die pads.
www.ti.com
EXAMPLE BOARD LAYOUT
PT0048A
LQFP - 1.6 mm max height
LOW PROFILE QUAD FLATPACK
PKG
SYMM
48
37
SEE SOLDER MASK
DETAILS
48X (1.6)
1
36
48X (0.3)
44X (0.5)
PKG SYMM
(8.2)
(R0.05) TYP
12
25
13
24
(8.2)
LAND PATTERN EXAMPLE
EXPOSED METAL SHOWN
SCALE 10.000
0.05 MAX
ALLAROUND
0.05 MIN
ALL AROUND
EXPOSED METAL
EXPOSED METAL
METAL EDGE
SOLDER MASK
OPENING
METAL UNDER
SOLDER MASK
SOLDER MASK
OPENING
SOLDER MASK
DEFINED
NON SOLDER MASK
DEFINED
SOLDER MASK DETAILS
4215159/A 12/2021
NOTES: (continued)
5. Publication IPC-7351 may have alternate designs.
6. Solder mask tolerances between and around signal pads can vary based on board fabrication site.
www.ti.com
EXAMPLE STENCIL DESIGN
PT0048A
LQFP - 1.6 mm max height
LOW PROFILE QUAD FLATPACK
PKG
SYMM
48
37
48X (1.6)
1
36
48X (0.3)
44X (0.5)
PKG SYMM
(8.2)
(R0.05) TYP
12
25
13
24
(8.2)
SOLDER PASTE EXAMPLE
BASED ON 0.1 mm THICK STENCIL
SCALE: 10X
4215159/A 12/2021
NOTES: (continued)
7. Laser cutting apertures with trapezoidal walls and rounded corners may offer better paste release. IPC-7525 may have alternate
design recommendations.
8. Board assembly site may have different recommendations for stencil design.
www.ti.com
PACKAGE OUTLINE
PN0080A
LQFP - 1.6 mm max height
SCALE 1.250
PLASTIC QUAD FLATPACK
12.2
11.8
B
PIN 1 ID
A
80
61
1
60
12.2
11.8
14.2
TYP
13.8
20
41
40
21
76X 0.5
0.27
80X
0.17
4X 9.5
0.08
C A B
1.6 MAX
C
(0.13) TYP
SEATING PLANE
0.08
SEE DETAIL A
0.25
GAGE PLANE
(1.4)
0.05 MIN
0.75
0.45
0 -7
DETAIL
SCALE: 14
A
DETAIL A
TYPICAL
4215166/A 08/2022
NOTES:
1. All linear dimensions are in millimeters. Any dimensions in parenthesis are for reference only. Dimensioning and tolerancing
per ASME Y14.5M.
2. This drawing is subject to change without notice.
3. Reference JEDEC registration MS-026.
www.ti.com
EXAMPLE BOARD LAYOUT
PN0080A
LQFP - 1.6 mm max height
PLASTIC QUAD FLATPACK
SYMM
80
61
80X (1.5)
1
60
80X (0.3)
SYMM
(13.4)
76X (0.5)
(R0.05) TYP
20
41
21
40
(13.4)
LAND PATTERN EXAMPLE
EXPOSED METAL SHOWN
SCALE:6X
0.05 MAX
ALL AROUND
EXPOSED METAL
METAL
0.05 MIN
ALL AROUND
EXPOSED METAL
SOLDER MASK
SOLDER MASK
OPENING
METAL UNDER
SOLDER MASK
NON SOLDER MASK
DEFINED
SOLDER MASK
DEFINED
SOLDER MASK DETAILS
4215166/A 08/2022
NOTES: (continued)
4. Publication IPC-7351 may have alternate designs.
5. Solder mask tolerances between and around signal pads can vary based on board fabrication site.
6. For more information, see Texas Instruments literature number SLMA004 (www.ti.com/lit/slma004).
www.ti.com
EXAMPLE STENCIL DESIGN
PN0080A
LQFP - 1.6 mm max height
PLASTIC QUAD FLATPACK
SYMM
80
61
80X (1.5)
1
60
80X (0.3)
SYMM
(13.4)
76X (0.5)
(R0.05) TYP
20
41
21
40
(13.4)
SOLDER PASTE EXAMPLE
BASED ON 0.1 mm THICK STENCIL
SCALE:6X
4215166/A 08/2022
NOTES: (continued)
7. Laser cutting apertures with trapezoidal walls and rounded corners may offer better paste release. IPC-7525 may have alternate
design recommendations.
8. Board assembly site may have different recommendations for stencil design.
www.ti.com
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