The TPS36-Q1 offers high accuracy under voltage supervisor function at very low quiescent current. The voltage supervisor function is always active. After the device powers up from VDD < VPOR, the RESET and WDO outputs will be actively driven when VDD is greater than VPOR. The device starts monitoring the supply level when the VDD voltage is greater than 1.04 V. The device will hold the RESET pin asserted for tSTRT + tD time after the VDD > VIT+ (VIT- + VHYS). Refer
TPS36-Q1 具有可编程窗口看门狗计时器的精密电压监控器
TPS36-Q1 具有精密窗口看门狗计时器的汽车类毫微级 IQ 精密电压监控器
TPS36-Q1 具有精密窗口看门狗计时器的汽车类毫微级 IQ 精密电压监控器
特性
特性
应用
应用
说明
说明
Table of Contents
Table of Contents
Revision History
Revision History
器件比较
器件比较
Pin Configuration and Functions
Pin Configuration and Functions
Specifications
Specifications
Absolute Maximum Ratings
Absolute Maximum Ratings
ESD Ratings
ESD Ratings
Recommended Operating Conditions
Recommended Operating Conditions
Thermal Information
Thermal Information
Electrical Characteristics
Electrical Characteristics
Timing Requirements
Timing Requirements
Switching Characteristics
Switching Characteristics
Timing Diagrams
Timing Diagrams
Typical Characteristics
Typical Characteristics
Detailed Description
Detailed Description
Overview
Overview
Functional Block Diagrams
Functional Block Diagrams
Feature Description
Feature Description
Voltage Supervisor
Voltage Supervisor
Window Watchdog Timer
Window Watchdog Timer
tWC (Close Window) Timer
tWC (Close Window) Timer
tWO (Open Window) Timer
tWO (Open Window) Timer
Watchdog Enable Disable Operation
Watchdog Enable Disable Operation
tSD Watchdog Start Up Delay
tSD Watchdog Start Up Delay
SET Pin Behavior
SET Pin Behavior
Manual RESET
Manual RESET
RESET and WDO Output
RESET and WDO Output
Device Functional Modes
Device Functional Modes
Application and Implementation
Application and Implementation
Application Information
Application Information
CRST Delay
CRST Delay
Factory-Programmed Reset Delay Timing
Factory-Programmed Reset Delay Timing
Adjustable Capacitor Timing
Adjustable Capacitor Timing
Watchdog Window Functionality
Watchdog Window Functionality
Factory-Programmed watchdog Timing
Factory-Programmed watchdog Timing
Adjustable Capacitor Timing
Adjustable Capacitor Timing
Typical Applications
Typical Applications
Design 1: Monitoring Microcontroller Supply and Watchdog During Operational and Sleep Modes
Design 1: Monitoring Microcontroller Supply and Watchdog During Operational and Sleep Modes
Design Requirements
Design Requirements
Detailed Design Procedure
Detailed Design Procedure
Setting Voltage Threshold
Setting Voltage Threshold
Determining Window Timings During Operation and Sleep Modes
Determining Window Timings During Operation and Sleep Modes
Meeting the Minimum Reset Delay
Meeting the Minimum Reset Delay
Setting the Watchdog Window
Setting the Watchdog Window
Calculating the RESET Pullup Resistor
Calculating the RESET Pullup Resistor
Power Supply Recommendations
Power Supply Recommendations
Layout
Layout
Layout Guidelines
Layout Guidelines
Layout Example
Layout Example
Device and Documentation Support
Device and Documentation Support
接收文档更新通知
接收文档更新通知
支持资源
支持资源
Trademarks
Trademarks
静电放电警告
静电放电警告
术语表
术语表
Mechanical, Packaging, and Orderable Information
Mechanical, Packaging, and Orderable Information
重要声明和免责声明
重要声明和免责声明
TPS36-Q1 具有精密窗口看门狗计时器的汽车类毫微级 IQ 精密电压监控器
TPS36-Q1 具有精密窗口看门狗计时器的汽车类毫微级 IQ 精密电压监控器
TPS36-Q1窗口汽车类精密电压监控器
特性
A
20221210
将“预告信息”更改为“量产数据发布”
yes
具有符合 AEC-Q100 标准的下列特性:
器件温度等级 1:-40°C 至 125°C的环境工作温度范围
出厂编程或用户可编程的看门狗超时
±10% 精确计时器(最大值)
出厂编程的关闭窗口:1 毫秒至 100 秒
出厂编程或用户可编程的复位延迟
±10% 精确计时器(最大值)
出厂编程选项:2 毫秒至 10 秒
输入电压范围:VDD = 1.04 V 至 6.0 V
固定阈值电压 (VIT-):1.05 V 至 5.4 V
步长为 50mV 的阈值电压
1.2% 电压阈值精度(最大值)
内置迟滞 (VHYS):5%(典型值)
超低电源电流:IDD = 250nA(典型值)
开漏、推挽;低电平有效输出
各种可编程选项:
看门狗启用/禁用
看门狗启动延迟:无延迟至 10 秒
打开窗口与关闭窗口比率选项:1X 至 511X
锁存输出选项
MR 功能支持
特性
A
20221210
将“预告信息”更改为“量产数据发布”
yes
A
20221210
将“预告信息”更改为“量产数据发布”
yes
A
20221210
将“预告信息”更改为“量产数据发布”
yes
A20221210将“预告信息”更改为“量产数据发布”yes
具有符合 AEC-Q100 标准的下列特性:
器件温度等级 1:-40°C 至 125°C的环境工作温度范围
出厂编程或用户可编程的看门狗超时
±10% 精确计时器(最大值)
出厂编程的关闭窗口:1 毫秒至 100 秒
出厂编程或用户可编程的复位延迟
±10% 精确计时器(最大值)
出厂编程选项:2 毫秒至 10 秒
输入电压范围:VDD = 1.04 V 至 6.0 V
固定阈值电压 (VIT-):1.05 V 至 5.4 V
步长为 50mV 的阈值电压
1.2% 电压阈值精度(最大值)
内置迟滞 (VHYS):5%(典型值)
超低电源电流:IDD = 250nA(典型值)
开漏、推挽;低电平有效输出
各种可编程选项:
看门狗启用/禁用
看门狗启动延迟:无延迟至 10 秒
打开窗口与关闭窗口比率选项:1X 至 511X
锁存输出选项
MR 功能支持
具有符合 AEC-Q100 标准的下列特性:
器件温度等级 1:-40°C 至 125°C的环境工作温度范围
出厂编程或用户可编程的看门狗超时
±10% 精确计时器(最大值)
出厂编程的关闭窗口:1 毫秒至 100 秒
出厂编程或用户可编程的复位延迟
±10% 精确计时器(最大值)
出厂编程选项:2 毫秒至 10 秒
输入电压范围:VDD = 1.04 V 至 6.0 V
固定阈值电压 (VIT-):1.05 V 至 5.4 V
步长为 50mV 的阈值电压
1.2% 电压阈值精度(最大值)
内置迟滞 (VHYS):5%(典型值)
超低电源电流:IDD = 250nA(典型值)
开漏、推挽;低电平有效输出
各种可编程选项:
看门狗启用/禁用
看门狗启动延迟:无延迟至 10 秒
打开窗口与关闭窗口比率选项:1X 至 511X
锁存输出选项
MR 功能支持
具有符合 AEC-Q100 标准的下列特性:
器件温度等级 1:-40°C 至 125°C的环境工作温度范围
出厂编程或用户可编程的看门狗超时
±10% 精确计时器(最大值)
出厂编程的关闭窗口:1 毫秒至 100 秒
出厂编程或用户可编程的复位延迟
±10% 精确计时器(最大值)
出厂编程选项:2 毫秒至 10 秒
输入电压范围:VDD = 1.04 V 至 6.0 V
固定阈值电压 (VIT-):1.05 V 至 5.4 V
步长为 50mV 的阈值电压
1.2% 电压阈值精度(最大值)
内置迟滞 (VHYS):5%(典型值)
超低电源电流:IDD = 250nA(典型值)
开漏、推挽;低电平有效输出
各种可编程选项:
看门狗启用/禁用
看门狗启动延迟:无延迟至 10 秒
打开窗口与关闭窗口比率选项:1X 至 511X
锁存输出选项
MR 功能支持
具有符合 AEC-Q100 标准的下列特性:
器件温度等级 1:-40°C 至 125°C的环境工作温度范围
器件温度等级 1:-40°C 至 125°C的环境工作温度范围
器件温度等级 1:-40°C 至 125°C的环境工作温度范围出厂编程或用户可编程的看门狗超时
±10% 精确计时器(最大值)
出厂编程的关闭窗口:1 毫秒至 100 秒
±10% 精确计时器(最大值)
出厂编程的关闭窗口:1 毫秒至 100 秒
±10% 精确计时器(最大值)出厂编程的关闭窗口:1 毫秒至 100 秒出厂编程或用户可编程的复位延迟
±10% 精确计时器(最大值)
出厂编程选项:2 毫秒至 10 秒
±10% 精确计时器(最大值)
出厂编程选项:2 毫秒至 10 秒
±10% 精确计时器(最大值)出厂编程选项:2 毫秒至 10 秒输入电压范围:VDD = 1.04 V 至 6.0 VDD固定阈值电压 (VIT-):1.05 V 至 5.4 V
步长为 50mV 的阈值电压
1.2% 电压阈值精度(最大值)
内置迟滞 (VHYS):5%(典型值)
IT-
步长为 50mV 的阈值电压
1.2% 电压阈值精度(最大值)
内置迟滞 (VHYS):5%(典型值)
步长为 50mV 的阈值电压1.2% 电压阈值精度(最大值)内置迟滞 (VHYS):5%(典型值)HYS超低电源电流:IDD = 250nA(典型值)DD开漏、推挽;低电平有效输出各种可编程选项:
看门狗启用/禁用
看门狗启动延迟:无延迟至 10 秒
打开窗口与关闭窗口比率选项:1X 至 511X
锁存输出选项
看门狗启用/禁用
看门狗启动延迟:无延迟至 10 秒
打开窗口与关闭窗口比率选项:1X 至 511X
锁存输出选项
看门狗启用/禁用看门狗启动延迟:无延迟至 10 秒打开窗口与关闭窗口比率选项:1X 至 511X锁存输出选项
MR 功能支持MR
应用
车载充电器 (OBC) 和无线充电器
驾驶员监控
电池管理系统 (BMS)
前置摄像头
环视系统 ECU
应用
车载充电器 (OBC) 和无线充电器
驾驶员监控
电池管理系统 (BMS)
前置摄像头
环视系统 ECU
车载充电器 (OBC) 和无线充电器
驾驶员监控
电池管理系统 (BMS)
前置摄像头
环视系统 ECU
车载充电器 (OBC) 和无线充电器
驾驶员监控
电池管理系统 (BMS)
前置摄像头
环视系统 ECU
车载充电器 (OBC) 和无线充电器
车载充电器 (OBC) 和无线充电器
驾驶员监控
驾驶员监控
电池管理系统 (BMS)
电池管理系统 (BMS)
前置摄像头
前置摄像头
环视系统 ECU
环视系统 ECU
说明
TPS36-Q1 是一款超低功耗(典型值为 250nA)器件,可提供具有可编程窗口看门狗计时器的精密电压监控器。
TPS36-Q1 支持用于欠压监控的宽阈值电平,在额定温度范围内的精度为 1.2%。
TPS36-Q1 可提供具有多种功能的高精度窗口看门狗计时器,广泛适用于各种应用。关闭窗口计时器可以由工厂编程或用户使用外部电容器进行编程。可以使用逻辑引脚的组合来动态更改打开窗口与关闭窗口的比率。看门狗还提供独特的功能,例如启用/禁用、启动延迟、独立的 WDO 引脚选项。
RESET 或
WDO 延迟可设定为出厂编程的默认延迟设置或通过外部电容器进行编程。该器件还提供锁存输出操作,监控器或看门狗故障清除之前会锁存输出。
TPS36-Q1 提供了
TPS3852-Q1
器件系列的性能升级替代米6体育平台手机版_好二三四。TPS36-Q1 采用小型 8 引脚 SOT-23 封装。
器件信息
器件型号
封装
#GUID-A90FCBEA-9211-41EC-A530-F55740F95637/DEVINFONOTE
封装尺寸(标称值)
TPS36-Q1
DDF (8)
2.90mm × 1.60mm
如需了解所有可用封装,请参阅数据表末尾的可订购米6体育平台手机版_好二三四附录。
典型应用电路
说明
TPS36-Q1 是一款超低功耗(典型值为 250nA)器件,可提供具有可编程窗口看门狗计时器的精密电压监控器。
TPS36-Q1 支持用于欠压监控的宽阈值电平,在额定温度范围内的精度为 1.2%。
TPS36-Q1 可提供具有多种功能的高精度窗口看门狗计时器,广泛适用于各种应用。关闭窗口计时器可以由工厂编程或用户使用外部电容器进行编程。可以使用逻辑引脚的组合来动态更改打开窗口与关闭窗口的比率。看门狗还提供独特的功能,例如启用/禁用、启动延迟、独立的 WDO 引脚选项。
RESET 或
WDO 延迟可设定为出厂编程的默认延迟设置或通过外部电容器进行编程。该器件还提供锁存输出操作,监控器或看门狗故障清除之前会锁存输出。
TPS36-Q1 提供了
TPS3852-Q1
器件系列的性能升级替代米6体育平台手机版_好二三四。TPS36-Q1 采用小型 8 引脚 SOT-23 封装。
器件信息
器件型号
封装
#GUID-A90FCBEA-9211-41EC-A530-F55740F95637/DEVINFONOTE
封装尺寸(标称值)
TPS36-Q1
DDF (8)
2.90mm × 1.60mm
如需了解所有可用封装,请参阅数据表末尾的可订购米6体育平台手机版_好二三四附录。
典型应用电路
TPS36-Q1 是一款超低功耗(典型值为 250nA)器件,可提供具有可编程窗口看门狗计时器的精密电压监控器。
TPS36-Q1 支持用于欠压监控的宽阈值电平,在额定温度范围内的精度为 1.2%。
TPS36-Q1 可提供具有多种功能的高精度窗口看门狗计时器,广泛适用于各种应用。关闭窗口计时器可以由工厂编程或用户使用外部电容器进行编程。可以使用逻辑引脚的组合来动态更改打开窗口与关闭窗口的比率。看门狗还提供独特的功能,例如启用/禁用、启动延迟、独立的 WDO 引脚选项。
RESET 或
WDO 延迟可设定为出厂编程的默认延迟设置或通过外部电容器进行编程。该器件还提供锁存输出操作,监控器或看门狗故障清除之前会锁存输出。
TPS36-Q1 提供了
TPS3852-Q1
器件系列的性能升级替代米6体育平台手机版_好二三四。TPS36-Q1 采用小型 8 引脚 SOT-23 封装。
器件信息
器件型号
封装
#GUID-A90FCBEA-9211-41EC-A530-F55740F95637/DEVINFONOTE
封装尺寸(标称值)
TPS36-Q1
DDF (8)
2.90mm × 1.60mm
如需了解所有可用封装,请参阅数据表末尾的可订购米6体育平台手机版_好二三四附录。
TPS36-Q1 是一款超低功耗(典型值为 250nA)器件,可提供具有可编程窗口看门狗计时器的精密电压监控器。
TPS36-Q1 支持用于欠压监控的宽阈值电平,在额定温度范围内的精度为 1.2%。
TPS36-Q1窗口精密电压监控器
TPS36-Q1 支持用于欠压监控的宽阈值电平,在额定温度范围内的精度为 1.2%。TPS36-Q1
TPS36-Q1 可提供具有多种功能的高精度窗口看门狗计时器,广泛适用于各种应用。关闭窗口计时器可以由工厂编程或用户使用外部电容器进行编程。可以使用逻辑引脚的组合来动态更改打开窗口与关闭窗口的比率。看门狗还提供独特的功能,例如启用/禁用、启动延迟、独立的 WDO 引脚选项。TPS36-Q1
RESET 或
WDO 延迟可设定为出厂编程的默认延迟设置或通过外部电容器进行编程。该器件还提供锁存输出操作,监控器或看门狗故障清除之前会锁存输出。
RESET 或 RESETWDO监控器或
TPS36-Q1 提供了
TPS3852-Q1
器件系列的性能升级替代米6体育平台手机版_好二三四。TPS36-Q1 采用小型 8 引脚 SOT-23 封装。TPS36-Q1
TPS3852-Q1
TPS3852-Q1TPS36-Q1
器件信息
器件型号
封装
#GUID-A90FCBEA-9211-41EC-A530-F55740F95637/DEVINFONOTE
封装尺寸(标称值)
TPS36-Q1
DDF (8)
2.90mm × 1.60mm
器件信息
器件型号
封装
#GUID-A90FCBEA-9211-41EC-A530-F55740F95637/DEVINFONOTE
封装尺寸(标称值)
TPS36-Q1
DDF (8)
2.90mm × 1.60mm
器件型号
封装
#GUID-A90FCBEA-9211-41EC-A530-F55740F95637/DEVINFONOTE
封装尺寸(标称值)
器件型号
封装
#GUID-A90FCBEA-9211-41EC-A530-F55740F95637/DEVINFONOTE
封装尺寸(标称值)
器件型号封装
#GUID-A90FCBEA-9211-41EC-A530-F55740F95637/DEVINFONOTE
#GUID-A90FCBEA-9211-41EC-A530-F55740F95637/DEVINFONOTE
#GUID-A90FCBEA-9211-41EC-A530-F55740F95637/DEVINFONOTE封装尺寸(标称值)
TPS36-Q1
DDF (8)
2.90mm × 1.60mm
TPS36-Q1
DDF (8)
2.90mm × 1.60mm
TPS36-Q1
TPS36-Q1DDF (8)2.90mm × 1.60mm
如需了解所有可用封装,请参阅数据表末尾的可订购米6体育平台手机版_好二三四附录。
如需了解所有可用封装,请参阅数据表末尾的可订购米6体育平台手机版_好二三四附录。
典型应用电路
典型应用电路
典型应用电路
典型应用电路
Table of Contents
yes
Table of Contents
yes
yes
yes
Revision History
yes
November 2022
December 2022
*
A
Revision History
yes
November 2022
December 2022
*
A
yes
November 2022
December 2022
*
A
yesNovember 2022December 2022*A
器件比较
显示了 TPS36-Q1 的器件命名规则。对于所有可能的输出类型、阈值电压选项、看门狗时间选项和输出断言延迟选项,请参阅了解更多详细信息。有关其他选项的详细信息和可用性,请联系 TI 销售代码或访问 TI 的 E2E 论坛。
器件命名规则
TPS36-Q1 属于引脚兼容的器件系列,提供了不同的功能集,详见。
引脚兼容的器件系列
器件
电压监控器
看门狗类型
TPS35-Q1
是
Timeout
TPS36-Q1
是
窗口
TPS3435-Q1
否
Timeout
TPS3436-Q1
否
窗口
器件比较
显示了 TPS36-Q1 的器件命名规则。对于所有可能的输出类型、阈值电压选项、看门狗时间选项和输出断言延迟选项,请参阅了解更多详细信息。有关其他选项的详细信息和可用性,请联系 TI 销售代码或访问 TI 的 E2E 论坛。
器件命名规则
TPS36-Q1 属于引脚兼容的器件系列,提供了不同的功能集,详见。
引脚兼容的器件系列
器件
电压监控器
看门狗类型
TPS35-Q1
是
Timeout
TPS36-Q1
是
窗口
TPS3435-Q1
否
Timeout
TPS3436-Q1
否
窗口
显示了 TPS36-Q1 的器件命名规则。对于所有可能的输出类型、阈值电压选项、看门狗时间选项和输出断言延迟选项,请参阅了解更多详细信息。有关其他选项的详细信息和可用性,请联系 TI 销售代码或访问 TI 的 E2E 论坛。
器件命名规则
TPS36-Q1 属于引脚兼容的器件系列,提供了不同的功能集,详见。
引脚兼容的器件系列
器件
电压监控器
看门狗类型
TPS35-Q1
是
Timeout
TPS36-Q1
是
窗口
TPS3435-Q1
否
Timeout
TPS3436-Q1
否
窗口
显示了 TPS36-Q1 的器件命名规则。对于所有可能的输出类型、阈值电压选项、看门狗时间选项和输出断言延迟选项,请参阅了解更多详细信息。有关其他选项的详细信息和可用性,请联系 TI 销售代码或访问 TI 的 E2E 论坛。TPS36-Q1阈值电压选项、E2E 论坛
器件命名规则
器件命名规则
TPS36-Q1 属于引脚兼容的器件系列,提供了不同的功能集,详见。TPS36-Q1
引脚兼容的器件系列
器件
电压监控器
看门狗类型
TPS35-Q1
是
Timeout
TPS36-Q1
是
窗口
TPS3435-Q1
否
Timeout
TPS3436-Q1
否
窗口
引脚兼容的器件系列
器件
电压监控器
看门狗类型
TPS35-Q1
是
Timeout
TPS36-Q1
是
窗口
TPS3435-Q1
否
Timeout
TPS3436-Q1
否
窗口
器件
电压监控器
看门狗类型
器件
电压监控器
看门狗类型
器件电压监控器看门狗类型
TPS35-Q1
是
Timeout
TPS36-Q1
是
窗口
TPS3435-Q1
否
Timeout
TPS3436-Q1
否
窗口
TPS35-Q1
是
Timeout
TPS35-Q1
-Q1是Timeout
TPS36-Q1
是
窗口
TPS36-Q1
-Q1是窗口
TPS3435-Q1
否
Timeout
TPS3435-Q1
-Q1否Timeout
TPS3436-Q1
否
窗口
TPS3436-Q1
-Q1否窗口
Pin Configuration and Functions
Pin Configuration Option
A
DDF Package,
8-Pin SOT-23,
TPS36-Q1 Top View
Pin Configuration Option
B
DDF Package,
8-Pin SOT-23,
TPS36-Q1 Top View
Pin Configuration Option
C
DDF Package,
8-Pin SOT-23,
TPS36-Q1 Top View
Pin Configuration Option
D
DDF Package,
8-Pin SOT-23,
TPS36-Q1 Top View
Pin Functions
PIN NAME
PIN NUMBER
I/O
DESCRIPTION
PINOUT A
PINOUT B
PINOUT C
PINOUT D
CRST
3
3
—
—
I
Programmable reset timeout pin.
Connect a capacitor between this pin and GND to program the reset
timeout period. See
for
more details.
CWD
2
2
—
—
I
Programmable watchdog timeout
input. Watchdog close time is set by
connecting a capacitor between this pin and ground. See
for
more details.
GND
4
4
4
4
—
Ground pin
MR
1
—
2
—
I
Manual reset pin. A logic low
on this pin asserts the RESET. See
for
more details.
RESET
7
7
7
7
O
Reset output. Connect
RESET to VDD using a pull up resistance
when using open drain output. RESET is asserted
when the voltage at the VDD pin goes below the undervoltage
threshold (VIT-) or MR pin is driven
LOW. For pinout options which do not support independent
WDO pin, RESET is also
asserted for watchdog error. See
for
more details.
SET0
5
1
1
1
I
Logic input. SET0, SET1, and
WD-EN pins select the watchdog window
ratios and enable-disable the watchdog; see
for
more details.
SET1
—
5
5
5
I
Logic input. SET0, SET1, and
WD-EN pins select the watchdog window
ratios and enable-disable the watchdog; see
for
more details.
VDD
8
8
8
8
I
Supply voltage pin. For noisy
systems, connecting a 0.1-µF bypass capacitor is
recommended.
WD-EN
—
—
6
2
I
Logic input. Logic high input
enables the watchdog monitoring feature. See
for
more details.
WDI
6
6
3
3
I
Watchdog input. A falling
transition (edge) must occur at this pin during the open window in
order for RESET / WDO to
not assert. See
for
more details.
WDO
—
—
—
6
O
Watchdog output. Connect
WDO to VDD using pull up resistance when
using open drain output. WDO asserts when a
watchdog error occurs. WDO only asserts when
RESET is high. When a watchdog error
occurs, WDO asserts for the set
RESET timeout delay (tD). When
RESET is asserted, WDO
is deasserted and watchdog functionality is disabled. See
for
more details.
Pin Configuration and Functions
Pin Configuration Option
A
DDF Package,
8-Pin SOT-23,
TPS36-Q1 Top View
Pin Configuration Option
B
DDF Package,
8-Pin SOT-23,
TPS36-Q1 Top View
Pin Configuration Option
C
DDF Package,
8-Pin SOT-23,
TPS36-Q1 Top View
Pin Configuration Option
D
DDF Package,
8-Pin SOT-23,
TPS36-Q1 Top View
Pin Functions
PIN NAME
PIN NUMBER
I/O
DESCRIPTION
PINOUT A
PINOUT B
PINOUT C
PINOUT D
CRST
3
3
—
—
I
Programmable reset timeout pin.
Connect a capacitor between this pin and GND to program the reset
timeout period. See
for
more details.
CWD
2
2
—
—
I
Programmable watchdog timeout
input. Watchdog close time is set by
connecting a capacitor between this pin and ground. See
for
more details.
GND
4
4
4
4
—
Ground pin
MR
1
—
2
—
I
Manual reset pin. A logic low
on this pin asserts the RESET. See
for
more details.
RESET
7
7
7
7
O
Reset output. Connect
RESET to VDD using a pull up resistance
when using open drain output. RESET is asserted
when the voltage at the VDD pin goes below the undervoltage
threshold (VIT-) or MR pin is driven
LOW. For pinout options which do not support independent
WDO pin, RESET is also
asserted for watchdog error. See
for
more details.
SET0
5
1
1
1
I
Logic input. SET0, SET1, and
WD-EN pins select the watchdog window
ratios and enable-disable the watchdog; see
for
more details.
SET1
—
5
5
5
I
Logic input. SET0, SET1, and
WD-EN pins select the watchdog window
ratios and enable-disable the watchdog; see
for
more details.
VDD
8
8
8
8
I
Supply voltage pin. For noisy
systems, connecting a 0.1-µF bypass capacitor is
recommended.
WD-EN
—
—
6
2
I
Logic input. Logic high input
enables the watchdog monitoring feature. See
for
more details.
WDI
6
6
3
3
I
Watchdog input. A falling
transition (edge) must occur at this pin during the open window in
order for RESET / WDO to
not assert. See
for
more details.
WDO
—
—
—
6
O
Watchdog output. Connect
WDO to VDD using pull up resistance when
using open drain output. WDO asserts when a
watchdog error occurs. WDO only asserts when
RESET is high. When a watchdog error
occurs, WDO asserts for the set
RESET timeout delay (tD). When
RESET is asserted, WDO
is deasserted and watchdog functionality is disabled. See
for
more details.
Pin Configuration Option
A
DDF Package,
8-Pin SOT-23,
TPS36-Q1 Top View
Pin Configuration Option
B
DDF Package,
8-Pin SOT-23,
TPS36-Q1 Top View
Pin Configuration Option
C
DDF Package,
8-Pin SOT-23,
TPS36-Q1 Top View
Pin Configuration Option
D
DDF Package,
8-Pin SOT-23,
TPS36-Q1 Top View
Pin Functions
PIN NAME
PIN NUMBER
I/O
DESCRIPTION
PINOUT A
PINOUT B
PINOUT C
PINOUT D
CRST
3
3
—
—
I
Programmable reset timeout pin.
Connect a capacitor between this pin and GND to program the reset
timeout period. See
for
more details.
CWD
2
2
—
—
I
Programmable watchdog timeout
input. Watchdog close time is set by
connecting a capacitor between this pin and ground. See
for
more details.
GND
4
4
4
4
—
Ground pin
MR
1
—
2
—
I
Manual reset pin. A logic low
on this pin asserts the RESET. See
for
more details.
RESET
7
7
7
7
O
Reset output. Connect
RESET to VDD using a pull up resistance
when using open drain output. RESET is asserted
when the voltage at the VDD pin goes below the undervoltage
threshold (VIT-) or MR pin is driven
LOW. For pinout options which do not support independent
WDO pin, RESET is also
asserted for watchdog error. See
for
more details.
SET0
5
1
1
1
I
Logic input. SET0, SET1, and
WD-EN pins select the watchdog window
ratios and enable-disable the watchdog; see
for
more details.
SET1
—
5
5
5
I
Logic input. SET0, SET1, and
WD-EN pins select the watchdog window
ratios and enable-disable the watchdog; see
for
more details.
VDD
8
8
8
8
I
Supply voltage pin. For noisy
systems, connecting a 0.1-µF bypass capacitor is
recommended.
WD-EN
—
—
6
2
I
Logic input. Logic high input
enables the watchdog monitoring feature. See
for
more details.
WDI
6
6
3
3
I
Watchdog input. A falling
transition (edge) must occur at this pin during the open window in
order for RESET / WDO to
not assert. See
for
more details.
WDO
—
—
—
6
O
Watchdog output. Connect
WDO to VDD using pull up resistance when
using open drain output. WDO asserts when a
watchdog error occurs. WDO only asserts when
RESET is high. When a watchdog error
occurs, WDO asserts for the set
RESET timeout delay (tD). When
RESET is asserted, WDO
is deasserted and watchdog functionality is disabled. See
for
more details.
Pin Configuration Option
A
DDF Package,
8-Pin SOT-23,
TPS36-Q1 Top View
Pin Configuration Option
B
DDF Package,
8-Pin SOT-23,
TPS36-Q1 Top View
Pin Configuration Option
C
DDF Package,
8-Pin SOT-23,
TPS36-Q1 Top View
Pin Configuration Option
D
DDF Package,
8-Pin SOT-23,
TPS36-Q1 Top View
Pin Configuration Option
A
DDF Package,
8-Pin SOT-23,
TPS36-Q1 Top View
Pin Configuration Option
A
DDF Package,
8-Pin SOT-23,
TPS36-Q1 Top View
DDF Package,
8-Pin SOT-23,
TPS36-Q1 Top ViewTPS36-Q1
Pin Configuration Option
B
DDF Package,
8-Pin SOT-23,
TPS36-Q1 Top View
Pin Configuration Option
B
DDF Package,
8-Pin SOT-23,
TPS36-Q1 Top View
DDF Package,
8-Pin SOT-23,
TPS36-Q1 Top ViewTPS36-Q1
Pin Configuration Option
C
DDF Package,
8-Pin SOT-23,
TPS36-Q1 Top View
Pin Configuration Option
C
DDF Package,
8-Pin SOT-23,
TPS36-Q1 Top View
DDF Package,
8-Pin SOT-23,
TPS36-Q1 Top ViewTPS36-Q1
Pin Configuration Option
D
DDF Package,
8-Pin SOT-23,
TPS36-Q1 Top View
Pin Configuration Option
D
DDF Package,
8-Pin SOT-23,
TPS36-Q1 Top View
DDF Package,
8-Pin SOT-23,
TPS36-Q1 Top ViewTPS36-Q1
Pin Functions
PIN NAME
PIN NUMBER
I/O
DESCRIPTION
PINOUT A
PINOUT B
PINOUT C
PINOUT D
CRST
3
3
—
—
I
Programmable reset timeout pin.
Connect a capacitor between this pin and GND to program the reset
timeout period. See
for
more details.
CWD
2
2
—
—
I
Programmable watchdog timeout
input. Watchdog close time is set by
connecting a capacitor between this pin and ground. See
for
more details.
GND
4
4
4
4
—
Ground pin
MR
1
—
2
—
I
Manual reset pin. A logic low
on this pin asserts the RESET. See
for
more details.
RESET
7
7
7
7
O
Reset output. Connect
RESET to VDD using a pull up resistance
when using open drain output. RESET is asserted
when the voltage at the VDD pin goes below the undervoltage
threshold (VIT-) or MR pin is driven
LOW. For pinout options which do not support independent
WDO pin, RESET is also
asserted for watchdog error. See
for
more details.
SET0
5
1
1
1
I
Logic input. SET0, SET1, and
WD-EN pins select the watchdog window
ratios and enable-disable the watchdog; see
for
more details.
SET1
—
5
5
5
I
Logic input. SET0, SET1, and
WD-EN pins select the watchdog window
ratios and enable-disable the watchdog; see
for
more details.
VDD
8
8
8
8
I
Supply voltage pin. For noisy
systems, connecting a 0.1-µF bypass capacitor is
recommended.
WD-EN
—
—
6
2
I
Logic input. Logic high input
enables the watchdog monitoring feature. See
for
more details.
WDI
6
6
3
3
I
Watchdog input. A falling
transition (edge) must occur at this pin during the open window in
order for RESET / WDO to
not assert. See
for
more details.
WDO
—
—
—
6
O
Watchdog output. Connect
WDO to VDD using pull up resistance when
using open drain output. WDO asserts when a
watchdog error occurs. WDO only asserts when
RESET is high. When a watchdog error
occurs, WDO asserts for the set
RESET timeout delay (tD). When
RESET is asserted, WDO
is deasserted and watchdog functionality is disabled. See
for
more details.
Pin Functions
PIN NAME
PIN NUMBER
I/O
DESCRIPTION
PINOUT A
PINOUT B
PINOUT C
PINOUT D
CRST
3
3
—
—
I
Programmable reset timeout pin.
Connect a capacitor between this pin and GND to program the reset
timeout period. See
for
more details.
CWD
2
2
—
—
I
Programmable watchdog timeout
input. Watchdog close time is set by
connecting a capacitor between this pin and ground. See
for
more details.
GND
4
4
4
4
—
Ground pin
MR
1
—
2
—
I
Manual reset pin. A logic low
on this pin asserts the RESET. See
for
more details.
RESET
7
7
7
7
O
Reset output. Connect
RESET to VDD using a pull up resistance
when using open drain output. RESET is asserted
when the voltage at the VDD pin goes below the undervoltage
threshold (VIT-) or MR pin is driven
LOW. For pinout options which do not support independent
WDO pin, RESET is also
asserted for watchdog error. See
for
more details.
SET0
5
1
1
1
I
Logic input. SET0, SET1, and
WD-EN pins select the watchdog window
ratios and enable-disable the watchdog; see
for
more details.
SET1
—
5
5
5
I
Logic input. SET0, SET1, and
WD-EN pins select the watchdog window
ratios and enable-disable the watchdog; see
for
more details.
VDD
8
8
8
8
I
Supply voltage pin. For noisy
systems, connecting a 0.1-µF bypass capacitor is
recommended.
WD-EN
—
—
6
2
I
Logic input. Logic high input
enables the watchdog monitoring feature. See
for
more details.
WDI
6
6
3
3
I
Watchdog input. A falling
transition (edge) must occur at this pin during the open window in
order for RESET / WDO to
not assert. See
for
more details.
WDO
—
—
—
6
O
Watchdog output. Connect
WDO to VDD using pull up resistance when
using open drain output. WDO asserts when a
watchdog error occurs. WDO only asserts when
RESET is high. When a watchdog error
occurs, WDO asserts for the set
RESET timeout delay (tD). When
RESET is asserted, WDO
is deasserted and watchdog functionality is disabled. See
for
more details.
PIN NAME
PIN NUMBER
I/O
DESCRIPTION
PINOUT A
PINOUT B
PINOUT C
PINOUT D
PIN NAME
PIN NUMBER
I/O
DESCRIPTION
PIN NAMEPIN NUMBERI/ODESCRIPTION
PINOUT A
PINOUT B
PINOUT C
PINOUT D
PINOUT APINOUT BPINOUT CPINOUT D
CRST
3
3
—
—
I
Programmable reset timeout pin.
Connect a capacitor between this pin and GND to program the reset
timeout period. See
for
more details.
CWD
2
2
—
—
I
Programmable watchdog timeout
input. Watchdog close time is set by
connecting a capacitor between this pin and ground. See
for
more details.
GND
4
4
4
4
—
Ground pin
MR
1
—
2
—
I
Manual reset pin. A logic low
on this pin asserts the RESET. See
for
more details.
RESET
7
7
7
7
O
Reset output. Connect
RESET to VDD using a pull up resistance
when using open drain output. RESET is asserted
when the voltage at the VDD pin goes below the undervoltage
threshold (VIT-) or MR pin is driven
LOW. For pinout options which do not support independent
WDO pin, RESET is also
asserted for watchdog error. See
for
more details.
SET0
5
1
1
1
I
Logic input. SET0, SET1, and
WD-EN pins select the watchdog window
ratios and enable-disable the watchdog; see
for
more details.
SET1
—
5
5
5
I
Logic input. SET0, SET1, and
WD-EN pins select the watchdog window
ratios and enable-disable the watchdog; see
for
more details.
VDD
8
8
8
8
I
Supply voltage pin. For noisy
systems, connecting a 0.1-µF bypass capacitor is
recommended.
WD-EN
—
—
6
2
I
Logic input. Logic high input
enables the watchdog monitoring feature. See
for
more details.
WDI
6
6
3
3
I
Watchdog input. A falling
transition (edge) must occur at this pin during the open window in
order for RESET / WDO to
not assert. See
for
more details.
WDO
—
—
—
6
O
Watchdog output. Connect
WDO to VDD using pull up resistance when
using open drain output. WDO asserts when a
watchdog error occurs. WDO only asserts when
RESET is high. When a watchdog error
occurs, WDO asserts for the set
RESET timeout delay (tD). When
RESET is asserted, WDO
is deasserted and watchdog functionality is disabled. See
for
more details.
CRST
3
3
—
—
I
Programmable reset timeout pin.
Connect a capacitor between this pin and GND to program the reset
timeout period. See
for
more details.
CRST33——IProgrammable reset timeout pin.
Connect a capacitor between this pin and GND to program the reset
timeout period. See
for
more details.
CWD
2
2
—
—
I
Programmable watchdog timeout
input. Watchdog close time is set by
connecting a capacitor between this pin and ground. See
for
more details.
CWD22——IProgrammable watchdog timeout
input. Watchdog close time is set by
connecting a capacitor between this pin and ground. See
for
more details.close time
GND
4
4
4
4
—
Ground pin
GND4444—Ground pin
MR
1
—
2
—
I
Manual reset pin. A logic low
on this pin asserts the RESET. See
for
more details.
MR
MR1—2—IManual reset pin. A logic low
on this pin asserts the RESET. See
for
more details.RESET
RESET
7
7
7
7
O
Reset output. Connect
RESET to VDD using a pull up resistance
when using open drain output. RESET is asserted
when the voltage at the VDD pin goes below the undervoltage
threshold (VIT-) or MR pin is driven
LOW. For pinout options which do not support independent
WDO pin, RESET is also
asserted for watchdog error. See
for
more details.
RESET
RESET7777OReset output. Connect
RESET to VDD using a pull up resistance
when using open drain output. RESET is asserted
when the voltage at the VDD pin goes below the undervoltage
threshold (VIT-) or MR pin is driven
LOW. For pinout options which do not support independent
WDO pin, RESET is also
asserted for watchdog error. See
for
more details.RESETRESETIT-MRWDORESET
SET0
5
1
1
1
I
Logic input. SET0, SET1, and
WD-EN pins select the watchdog window
ratios and enable-disable the watchdog; see
for
more details.
SET05111ILogic input. SET0, SET1, and
WD-EN pins select the watchdog window
ratios and enable-disable the watchdog; see
for
more details.window
ratios
SET1
—
5
5
5
I
Logic input. SET0, SET1, and
WD-EN pins select the watchdog window
ratios and enable-disable the watchdog; see
for
more details.
SET1—555ILogic input. SET0, SET1, and
WD-EN pins select the watchdog window
ratios and enable-disable the watchdog; see
for
more details.window
ratios
VDD
8
8
8
8
I
Supply voltage pin. For noisy
systems, connecting a 0.1-µF bypass capacitor is
recommended.
VDD8888ISupply voltage pin. For noisy
systems, connecting a 0.1-µF bypass capacitor is
recommended.
WD-EN
—
—
6
2
I
Logic input. Logic high input
enables the watchdog monitoring feature. See
for
more details.
WD-EN——62ILogic input. Logic high input
enables the watchdog monitoring feature. See
for
more details.
WDI
6
6
3
3
I
Watchdog input. A falling
transition (edge) must occur at this pin during the open window in
order for RESET / WDO to
not assert. See
for
more details.
WDI6633IWatchdog input. A falling
transition (edge) must occur at this pin during the open window in
order for RESET / WDO to
not assert. See
for
more details.during the open windowRESETWDO
WDO
—
—
—
6
O
Watchdog output. Connect
WDO to VDD using pull up resistance when
using open drain output. WDO asserts when a
watchdog error occurs. WDO only asserts when
RESET is high. When a watchdog error
occurs, WDO asserts for the set
RESET timeout delay (tD). When
RESET is asserted, WDO
is deasserted and watchdog functionality is disabled. See
for
more details.
WDO
WDO———6OWatchdog output. Connect
WDO to VDD using pull up resistance when
using open drain output. WDO asserts when a
watchdog error occurs. WDO only asserts when
RESET is high. When a watchdog error
occurs, WDO asserts for the set
RESET timeout delay (tD). When
RESET is asserted, WDO
is deasserted and watchdog functionality is disabled. See
for
more details.WDOWDOWDORESETWDORESETDRESETWDO
Specifications
Absolute Maximum Ratings
over operating free-air temperature range, unless otherwise noted#GUID-XXXXXXXX-SF0T-XXXX-XXXX-000000244046/A_SUPERVISOR_VVCM_1_ABSMAX_FOOTER1
MIN
MAX
UNIT
Voltage
VDD
–0.3
6.5
V
Voltage
CWD, CRST, WD–EN, SETx, WDI, MR
(2), RESET (Push Pull),
WDO (Push Pull)
–0.3
VDD+0.3 #GUID-XXXXXXXX-SF0T-XXXX-XXXX-000000244046/SF_WMY9TRSL1
V
RESET (Open Drain),
WDO (Open Drain)
–0.3
6.5
Current
RESET,
WDO pin
–20
20
mA
Temperature #GUID-XXXXXXXX-SF0T-XXXX-XXXX-000000244046/A_SUPERVISOR_VVCM_1_ABSMAX_FOOTER2
Operating ambient temperature, TA
–40
125
℃
Temperature
Storage, Tstg
–65
150
Stresses beyond those listed under Absolute Maximum Rating may cause permanent damage to the device. These are stress ratings only, which do not imply functional operation of the device at these or any other conditions beyond those indicated under Recommended Operating Condition. Exposure to absolute-maximum-rated conditions for extended periods may affect device reliability.
If the logic signal driving MR is less than VDD, then additional current flows into VDD and out of MR.
The absolute maximum rating is (VDD + 0.3) V or 6.5 V, whichever is smaller
As a result of the low dissipated power in this device, it is assumed that TJ = TA.
ESD Ratings
VALUE
UNIT
V(ESD)
Electrostatic discharge
Human body model (HBM), per AEC Q100-002#GUID-XXXXXXXX-SF0T-XXXX-XXXX-000000244048/A_SUPERVISOR_VVCM_3_ESD_RATINGS_AUTOMOTIVE_FOOTER1
±2000
V
Charged device model (CDM), per AEC Q100-011
±750
AEC Q100-002 indicates that HBM stressing shall be in accordance with the ANSI/ESDA/JEDEC JS-001 specification.
Recommended Operating Conditions
over operating free-air temperature range (unless otherwise noted)
MIN
NOM
MAX
UNIT
Voltage
VDD (Active Low output)
0.9
6
V
CWD, CRST, WD–EN, SETx, WDI, MR
(1)
0
VDD
RESET
(Open Drain) ,
WDO (Open Drain)
0
6
RESET
(Open Drain) ,
WDO (Push Pull)
0
VDD
Current
RESET,
WDO pin current
–5
5
mA
CRST
CRST pin capacitor range
1.5
1800
nF
CWD
CWD pin capacitor range
1.5
1000
nF
TA
Operating ambient temperature
–40
125
℃
If the logic signal driving MR is less than VDD, then additional current flows into VDD and out of MR. VMR should not be higher than VDD.
Thermal Information
THERMAL METRIC#GUID-XXXXXXXX-SF0T-XXXX-XXXX-000000244050/A_SUPERVISOR_VVCM_5_THERMAL_FOOTER1
TPS36-Q1
UNIT
DDF (SOT23-8)
8 PINS
RθJA
Junction-to-ambient thermal resistance
175.3
°C/W
RθJC(top)
Junction-to-case (top) thermal resistance
94.7
°C/W
RθJB
Junction-to-board thermal resistance
92.4
°C/W
ψJT
Junction-to-top characterization parameter
8.4
°C/W
ψJB
Junction-to-board characterization parameter
91.9
°C/W
RθJC(bot)
Junction-to-case (bottom) thermal resistance
N/A
°C/W
For more information about traditional and new thermal metrics, see the Semiconductor and IC Package Thermal Metrics application report.
Electrical Characteristics
At 1.04 V ≤ VDD ≤ 6 V, MR = Open, RESET pull-up resistor (Rpull-up) = 100 kΩ to VDD, WDO pull-up resistor (Rpull-up) = 100 kΩ to VDD, output load (CLOAD) = 10 pF and over operating free-air temperature range –40℃ to 125℃, unless otherwise noted. VDD ramp rate ≤ 1 V/µs. Typical values are at TA = 25℃
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
COMMON PARAMETERS
VDD
Input supply voltage
Active LOW output
1.04
6
V
VIT–
Negative-going input threshold accuracy #GUID-XXXXXXXX-SF0T-XXXX-XXXX-000000244580/A_SUPERVISOR_VVCM_6_ELECTCHAR_FOOTER1_SF1
VIT– = 1.05 V to 1.95 V
–1.4
±0.5
1.4
%
VIT– = 2.0 V to 5.4 V
–1.2
±0.5
1.2
VHYS
Hysteresis VIT– pin
VIT– = 1.05 V to 5.4 V
3
5
7
%
IDD
Supply current into VDD pin #GUID-XXXXXXXX-SF0T-XXXX-XXXX-000000244580/A_SUPERVISOR_VVCM_6_ELECTCHAR_FOOTER5_SF1
VDD = 2 VVIT– = 1.05 V to 1.95 V
TA = –40℃ to 85℃
0.25
0.8
µA
0.25
3
VDD = 6 VVIT– = 1.05 V to 5.4 V
TA = –40℃ to 85℃
0.25
0.8
0.25
3
VIL
Low level input voltage WD–EN, WDI, SETx, MR
(3)
0.3VDD
V
VIH
High level input voltage WD–EN, WDI, SETx, MR
(3)
0.7VDD
V
R
MR
Manual reset internal pull-up resistance
100
kΩ
RESET / WDO (Open-drain active-low)
VOL
Low level output voltage
VDD =1.5 V, 1.55 V ≤ VIT– ≤ 3.35 VIOUT(Sink) = 500 µA
300
mV
VDD = 3.3 V, 3.4 V ≤ VIT– ≤ 5.4 VIOUT(Sink) = 2 mA
300
Ilkg(OD)
Open-Drain output leakage current
VDD = VPULLUP = 6VTA = –40℃ to 85℃
10
30
nA
VDD = VPULLUP = 6V
10
120
nA
RESET / WDO (Push-pull active-low)
VPOR
Power on RESET voltage (5)
VOL(max) = 300 mVIOUT(Sink) = 15 µA
900
mV
VOL
Low level output voltage
VDD = 0.9 V, 1.05 V ≤ VIT– ≤ 1.5 VIOUT(Sink) = 15 µA
300
mV
VDD = 1.5 V, 1.55 V ≤ VIT– ≤ 3.35 VIOUT(Sink) = 500 µA
300
VDD = 3.3 V, 3.4 V ≤ VIT– ≤ 5.4 VIOUT(Sink) = 2 mA
300
VOH
High level output voltage
VDD = 1.8 V, 1.05 V ≤ VIT– ≤ 1.4 VIOUT(Source) = 500 µA
0.8VDD
V
VDD = 3.3 V, 1.45 V ≤ VIT– ≤ 3.0 VIOUT(Source) = 500 µA
0.8VDD
VDD = 6 V, 3.05 V ≤ VIT– ≤ 5.4 VIOUT(Source) = 2 mA
0.8VDD
VIT– threshold voltage range from 1.05 V to 5.4 V in 50 mV steps.
If the logic signal driving MR is less than VDD, then additional current flows into VDD and out of MR.
VPOR is the minimum VDD voltage level for a controlled output state
Timing Requirements
At 1.04 V ≤ VDD ≤ 6 V, MR = Open, RESET pull-up resistor (Rpull-up) = 100 kΩ to VDD, WDO pull-up resistor (Rpull-up) = 100 kΩ to VDD, output RESET / WDO load (CLOAD) = 10 pF and over operating free-air temperature range –40℃ to 125℃, unless otherwise noted. VDD ramp rate ≤ 1 V/µs. Typical values are at TA = 25℃
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
tGI_VIT–
Glitch immunity VIT–
5% VIT– overdrive#GUID-XXXXXXXX-SF0T-XXXX-XXXX-000000244581/A_SUPERVISOR_VVCM_7_TIMINGREQ_FOOTER2_SF2
15
µs
t
MR_PW
MR pin pulse duration to assert reset
100
ns
tP-WD
WDI pulse duration to start next frame #GUID-XXXXXXXX-SF0T-XXXX-XXXX-000000244581/SFSEP1E0POOS
VDD > VIT–
500
ns
tHD-WDEN
WD-EN hold time to enable or disable WD operation #GUID-XXXXXXXX-SF0T-XXXX-XXXX-000000244581/SFSEP1E0POOS
VDD > VIT–
200
µs
tHD-SETx
SETx hold time to change WD timer setting #GUID-XXXXXXXX-SF0T-XXXX-XXXX-000000244581/SFSEP1E0POOS
VDD > VIT–
150
µs
tWC
Watchdog close window time period
Orderable Option TPS36xxxxB
0.8
1
1.2
ms
Orderable Option TPS36xxxxC
4
5
6
Orderable Option TPS36xxxxD
9
10
11
Orderable Option TPS36xxxxE
18
20
22
Orderable Option TPS36xxxxF
45
50
55
Orderable Option TPS36xxxxG
90
100
110
Orderable Option TPS36xxxxH
180
200
220
Orderable Option TPS36xxxxI
0.9
1
1.1
s
Orderable Option TPS36xxxxJ
1.26
1.4
1.54
Orderable Option TPS36xxxxK
1.44
1.6
1.76
Orderable Option TPS36xxxxL
9
10
11
Orderable Option TPS36xxxxM
45
50
55
Orderable Option TPS36xxxxN
90
100
110
tWO
Watchdog open window time period
SETx pin decide multipler n
(n-1) X tWC
ms
Overdrive % = [(VDD/ VIT–) – 1] × 100%
Not production tested
Switching Characteristics
At 1.04 V ≤ VDD ≤ 6 V, MR = Open, RESET pull-up resistor (Rpull-up) = 100 kΩ to VDD, WDO pull-up resistor (Rpull-up) = 100 kΩ to VDD, output RESET / WDO load (CLOAD) = 10 pF and over operating free-air temperature range –40℃ to 125℃, unless otherwise noted. VDD ramp rate ≤ 1 V/µs. Typical values are at TA = 25℃
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
tSTRT
Startup delay(4)
500
µs
tP_HL
RESET detect delay for VDD falling below VIT–
VDD : (VIT+ + 10%) to (VIT– – 10%)#GUID-XXXXXXXX-SF0T-XXXX-XXXX-000000244582/A_SUPERVISOR_VVCM_7_TIMINGREQ_FOOTER4_SF1_SF1
30
50
µs
tSD
Watchdog startup delay
Orderable part number TPS36xA, TPS36xG
0
ms
Orderable part number TPS36xB, TPS36xH
180
200
220
Orderable part number TPS36xC, TPS36xI
450
500
550
Orderable part number TPS36xD, TPS36xJ
0.9
1
1.1
s
Orderable part number TPS36xE, TPS36xK
4.5
5
5.5
Orderable part number TPS36xF, TPS36xL
9
10
11
tD
Reset time delay #GUID-XXXXXXXX-SF0T-XXXX-XXXX-000000244582/A_SUPERVISOR_VVCM_7_TIMINGREQ_FOOTER3_SF1_SF1
Orderable part number TPS36xxxxxxB
1.6
2
2.4
ms
Orderable part number TPS36xxxxxxC
9
10
11
ms
Orderable part number TPS36xxxxxxD
22.5
25
27.5
ms
Orderable part number TPS36xxxxxxE
45
50
55
ms
Orderable part number TPS36xxxxxxF
90
100
110
ms
Orderable part number TPS36xxxxxxG
180
200
220
ms
Orderable part number TPS36xxxxxxH
0.9
1
1.1
s
Orderable part number TPS36xxxxxxI
9
10
11
s
tWDO
Watchdog timeout delay
tD
s
t
MR_RES
Propagation delay from MR low to reset assertion
VDD ≥ VIT– + 0.2 V,
MR = V
MR_H to V
MR_L
100
ns
t
MR_tD
Delay from MR release to reset deassert
VDD = 3.3 V,
MR = V
MR_L to V
MR_H
tD
s
tP_HL measured from threshold trip point (VIT–) to RESET assert. VIT+ = VIT– + VHYS
Specified by design parameter. When VDD starts from less than the specified minimum VDD and then exceeds VIT+, reset is deasserted after the startup delay (tSTRT) + tD delay.
VDD voltage transitions from (VIT– - 10%) to (VIT– + 10%)
Timing Diagrams
*
Added a footnote to for tINIT
no
Functional Timing Diagram
Typical Characteristics
all curves are taken at TA = 25°C
(unless otherwise noted)
VIT- Accuracy vs Temperature
VIT- Accuracy
Histogram
VIT- Hysteresis Vs Temperature
Supply Glitch Immunity vs Overdrive
Timer Accuracy vs
Temperature
Timer Accuracy Histogram
tWC vs Capacitance
tD vs Capacitance
RESET VOL vs I
sink, VDD = 1.5 V
WDO VOL vs I
sink, VDD = 1.5 V
RESET VOL vs I sink, VDD = 3.3 V
WDO VOL vs I sink, VDD = 3.3 V
RESET VOH vs I source, VDD = 2.0 V
WDO VOH vs I source, VDD = 2.0 V
RESET VOH vs I source, VDD = 6.0 V
WDO VOH vs I source, VDD = 6.0 V
Supply Current
vs Power-Supply Voltage
Specifications
Absolute Maximum Ratings
over operating free-air temperature range, unless otherwise noted#GUID-XXXXXXXX-SF0T-XXXX-XXXX-000000244046/A_SUPERVISOR_VVCM_1_ABSMAX_FOOTER1
MIN
MAX
UNIT
Voltage
VDD
–0.3
6.5
V
Voltage
CWD, CRST, WD–EN, SETx, WDI, MR
(2), RESET (Push Pull),
WDO (Push Pull)
–0.3
VDD+0.3 #GUID-XXXXXXXX-SF0T-XXXX-XXXX-000000244046/SF_WMY9TRSL1
V
RESET (Open Drain),
WDO (Open Drain)
–0.3
6.5
Current
RESET,
WDO pin
–20
20
mA
Temperature #GUID-XXXXXXXX-SF0T-XXXX-XXXX-000000244046/A_SUPERVISOR_VVCM_1_ABSMAX_FOOTER2
Operating ambient temperature, TA
–40
125
℃
Temperature
Storage, Tstg
–65
150
Stresses beyond those listed under Absolute Maximum Rating may cause permanent damage to the device. These are stress ratings only, which do not imply functional operation of the device at these or any other conditions beyond those indicated under Recommended Operating Condition. Exposure to absolute-maximum-rated conditions for extended periods may affect device reliability.
If the logic signal driving MR is less than VDD, then additional current flows into VDD and out of MR.
The absolute maximum rating is (VDD + 0.3) V or 6.5 V, whichever is smaller
As a result of the low dissipated power in this device, it is assumed that TJ = TA.
Absolute Maximum Ratings
over operating free-air temperature range, unless otherwise noted#GUID-XXXXXXXX-SF0T-XXXX-XXXX-000000244046/A_SUPERVISOR_VVCM_1_ABSMAX_FOOTER1
MIN
MAX
UNIT
Voltage
VDD
–0.3
6.5
V
Voltage
CWD, CRST, WD–EN, SETx, WDI, MR
(2), RESET (Push Pull),
WDO (Push Pull)
–0.3
VDD+0.3 #GUID-XXXXXXXX-SF0T-XXXX-XXXX-000000244046/SF_WMY9TRSL1
V
RESET (Open Drain),
WDO (Open Drain)
–0.3
6.5
Current
RESET,
WDO pin
–20
20
mA
Temperature #GUID-XXXXXXXX-SF0T-XXXX-XXXX-000000244046/A_SUPERVISOR_VVCM_1_ABSMAX_FOOTER2
Operating ambient temperature, TA
–40
125
℃
Temperature
Storage, Tstg
–65
150
Stresses beyond those listed under Absolute Maximum Rating may cause permanent damage to the device. These are stress ratings only, which do not imply functional operation of the device at these or any other conditions beyond those indicated under Recommended Operating Condition. Exposure to absolute-maximum-rated conditions for extended periods may affect device reliability.
If the logic signal driving MR is less than VDD, then additional current flows into VDD and out of MR.
The absolute maximum rating is (VDD + 0.3) V or 6.5 V, whichever is smaller
As a result of the low dissipated power in this device, it is assumed that TJ = TA.
over operating free-air temperature range, unless otherwise noted#GUID-XXXXXXXX-SF0T-XXXX-XXXX-000000244046/A_SUPERVISOR_VVCM_1_ABSMAX_FOOTER1
MIN
MAX
UNIT
Voltage
VDD
–0.3
6.5
V
Voltage
CWD, CRST, WD–EN, SETx, WDI, MR
(2), RESET (Push Pull),
WDO (Push Pull)
–0.3
VDD+0.3 #GUID-XXXXXXXX-SF0T-XXXX-XXXX-000000244046/SF_WMY9TRSL1
V
RESET (Open Drain),
WDO (Open Drain)
–0.3
6.5
Current
RESET,
WDO pin
–20
20
mA
Temperature #GUID-XXXXXXXX-SF0T-XXXX-XXXX-000000244046/A_SUPERVISOR_VVCM_1_ABSMAX_FOOTER2
Operating ambient temperature, TA
–40
125
℃
Temperature
Storage, Tstg
–65
150
over operating free-air temperature range, unless otherwise noted#GUID-XXXXXXXX-SF0T-XXXX-XXXX-000000244046/A_SUPERVISOR_VVCM_1_ABSMAX_FOOTER1
#GUID-XXXXXXXX-SF0T-XXXX-XXXX-000000244046/A_SUPERVISOR_VVCM_1_ABSMAX_FOOTER1
MIN
MAX
UNIT
Voltage
VDD
–0.3
6.5
V
Voltage
CWD, CRST, WD–EN, SETx, WDI, MR
(2), RESET (Push Pull),
WDO (Push Pull)
–0.3
VDD+0.3 #GUID-XXXXXXXX-SF0T-XXXX-XXXX-000000244046/SF_WMY9TRSL1
V
RESET (Open Drain),
WDO (Open Drain)
–0.3
6.5
Current
RESET,
WDO pin
–20
20
mA
Temperature #GUID-XXXXXXXX-SF0T-XXXX-XXXX-000000244046/A_SUPERVISOR_VVCM_1_ABSMAX_FOOTER2
Operating ambient temperature, TA
–40
125
℃
Temperature
Storage, Tstg
–65
150
MIN
MAX
UNIT
MIN
MAX
UNIT
MINMAXUNIT
Voltage
VDD
–0.3
6.5
V
Voltage
CWD, CRST, WD–EN, SETx, WDI, MR
(2), RESET (Push Pull),
WDO (Push Pull)
–0.3
VDD+0.3 #GUID-XXXXXXXX-SF0T-XXXX-XXXX-000000244046/SF_WMY9TRSL1
V
RESET (Open Drain),
WDO (Open Drain)
–0.3
6.5
Current
RESET,
WDO pin
–20
20
mA
Temperature #GUID-XXXXXXXX-SF0T-XXXX-XXXX-000000244046/A_SUPERVISOR_VVCM_1_ABSMAX_FOOTER2
Operating ambient temperature, TA
–40
125
℃
Temperature
Storage, Tstg
–65
150
Voltage
VDD
–0.3
6.5
V
VoltageVDD–0.36.5V
Voltage
CWD, CRST, WD–EN, SETx, WDI, MR
(2), RESET (Push Pull),
WDO (Push Pull)
–0.3
VDD+0.3 #GUID-XXXXXXXX-SF0T-XXXX-XXXX-000000244046/SF_WMY9TRSL1
V
VoltageCWD, CRST, WD–EN, SETx, WDI, MR
(2), RESET (Push Pull),
WDO (Push Pull)WDRSTMR(2) RESET (Push Pull),RESETWDO–0.3VDD+0.3 #GUID-XXXXXXXX-SF0T-XXXX-XXXX-000000244046/SF_WMY9TRSL1
DD#GUID-XXXXXXXX-SF0T-XXXX-XXXX-000000244046/SF_WMY9TRSL1V
RESET (Open Drain),
WDO (Open Drain)
–0.3
6.5
RESET (Open Drain),
WDO (Open Drain)
RESET (Open Drain), RESET
WDO (Open Drain)WDO–0.36.5
Current
RESET,
WDO pin
–20
20
mA
Current
RESET,
WDO pin
RESET,
RESET,WDO–2020mA
Temperature #GUID-XXXXXXXX-SF0T-XXXX-XXXX-000000244046/A_SUPERVISOR_VVCM_1_ABSMAX_FOOTER2
Operating ambient temperature, TA
–40
125
℃
Temperature #GUID-XXXXXXXX-SF0T-XXXX-XXXX-000000244046/A_SUPERVISOR_VVCM_1_ABSMAX_FOOTER2
#GUID-XXXXXXXX-SF0T-XXXX-XXXX-000000244046/A_SUPERVISOR_VVCM_1_ABSMAX_FOOTER2Operating ambient temperature, TA
A–40125℃
Temperature
Storage, Tstg
–65
150
TemperatureStorage, Tstg
stg–65150
Stresses beyond those listed under Absolute Maximum Rating may cause permanent damage to the device. These are stress ratings only, which do not imply functional operation of the device at these or any other conditions beyond those indicated under Recommended Operating Condition. Exposure to absolute-maximum-rated conditions for extended periods may affect device reliability.
If the logic signal driving MR is less than VDD, then additional current flows into VDD and out of MR.
The absolute maximum rating is (VDD + 0.3) V or 6.5 V, whichever is smaller
As a result of the low dissipated power in this device, it is assumed that TJ = TA.
Stresses beyond those listed under Absolute Maximum Rating may cause permanent damage to the device. These are stress ratings only, which do not imply functional operation of the device at these or any other conditions beyond those indicated under Recommended Operating Condition. Exposure to absolute-maximum-rated conditions for extended periods may affect device reliability.Absolute Maximum RatingRecommended Operating ConditionIf the logic signal driving MR is less than VDD, then additional current flows into VDD and out of MR. MRDDDDMRThe absolute maximum rating is (VDD + 0.3) V or 6.5 V, whichever is smallerAs a result of the low dissipated power in this device, it is assumed that TJ = TA.JA
ESD Ratings
VALUE
UNIT
V(ESD)
Electrostatic discharge
Human body model (HBM), per AEC Q100-002#GUID-XXXXXXXX-SF0T-XXXX-XXXX-000000244048/A_SUPERVISOR_VVCM_3_ESD_RATINGS_AUTOMOTIVE_FOOTER1
±2000
V
Charged device model (CDM), per AEC Q100-011
±750
AEC Q100-002 indicates that HBM stressing shall be in accordance with the ANSI/ESDA/JEDEC JS-001 specification.
ESD Ratings
VALUE
UNIT
V(ESD)
Electrostatic discharge
Human body model (HBM), per AEC Q100-002#GUID-XXXXXXXX-SF0T-XXXX-XXXX-000000244048/A_SUPERVISOR_VVCM_3_ESD_RATINGS_AUTOMOTIVE_FOOTER1
±2000
V
Charged device model (CDM), per AEC Q100-011
±750
AEC Q100-002 indicates that HBM stressing shall be in accordance with the ANSI/ESDA/JEDEC JS-001 specification.
VALUE
UNIT
V(ESD)
Electrostatic discharge
Human body model (HBM), per AEC Q100-002#GUID-XXXXXXXX-SF0T-XXXX-XXXX-000000244048/A_SUPERVISOR_VVCM_3_ESD_RATINGS_AUTOMOTIVE_FOOTER1
±2000
V
Charged device model (CDM), per AEC Q100-011
±750
VALUE
UNIT
V(ESD)
Electrostatic discharge
Human body model (HBM), per AEC Q100-002#GUID-XXXXXXXX-SF0T-XXXX-XXXX-000000244048/A_SUPERVISOR_VVCM_3_ESD_RATINGS_AUTOMOTIVE_FOOTER1
±2000
V
Charged device model (CDM), per AEC Q100-011
±750
VALUE
UNIT
VALUE
UNIT
VALUEUNIT
V(ESD)
Electrostatic discharge
Human body model (HBM), per AEC Q100-002#GUID-XXXXXXXX-SF0T-XXXX-XXXX-000000244048/A_SUPERVISOR_VVCM_3_ESD_RATINGS_AUTOMOTIVE_FOOTER1
±2000
V
Charged device model (CDM), per AEC Q100-011
±750
V(ESD)
Electrostatic discharge
Human body model (HBM), per AEC Q100-002#GUID-XXXXXXXX-SF0T-XXXX-XXXX-000000244048/A_SUPERVISOR_VVCM_3_ESD_RATINGS_AUTOMOTIVE_FOOTER1
±2000
V
V(ESD)
(ESD)Electrostatic dischargeHuman body model (HBM), per AEC Q100-002#GUID-XXXXXXXX-SF0T-XXXX-XXXX-000000244048/A_SUPERVISOR_VVCM_3_ESD_RATINGS_AUTOMOTIVE_FOOTER1
#GUID-XXXXXXXX-SF0T-XXXX-XXXX-000000244048/A_SUPERVISOR_VVCM_3_ESD_RATINGS_AUTOMOTIVE_FOOTER1±2000V
Charged device model (CDM), per AEC Q100-011
±750
Charged device model (CDM), per AEC Q100-011±750
AEC Q100-002 indicates that HBM stressing shall be in accordance with the ANSI/ESDA/JEDEC JS-001 specification.
AEC Q100-002 indicates that HBM stressing shall be in accordance with the ANSI/ESDA/JEDEC JS-001 specification.
Recommended Operating Conditions
over operating free-air temperature range (unless otherwise noted)
MIN
NOM
MAX
UNIT
Voltage
VDD (Active Low output)
0.9
6
V
CWD, CRST, WD–EN, SETx, WDI, MR
(1)
0
VDD
RESET
(Open Drain) ,
WDO (Open Drain)
0
6
RESET
(Open Drain) ,
WDO (Push Pull)
0
VDD
Current
RESET,
WDO pin current
–5
5
mA
CRST
CRST pin capacitor range
1.5
1800
nF
CWD
CWD pin capacitor range
1.5
1000
nF
TA
Operating ambient temperature
–40
125
℃
If the logic signal driving MR is less than VDD, then additional current flows into VDD and out of MR. VMR should not be higher than VDD.
Recommended Operating Conditions
over operating free-air temperature range (unless otherwise noted)
MIN
NOM
MAX
UNIT
Voltage
VDD (Active Low output)
0.9
6
V
CWD, CRST, WD–EN, SETx, WDI, MR
(1)
0
VDD
RESET
(Open Drain) ,
WDO (Open Drain)
0
6
RESET
(Open Drain) ,
WDO (Push Pull)
0
VDD
Current
RESET,
WDO pin current
–5
5
mA
CRST
CRST pin capacitor range
1.5
1800
nF
CWD
CWD pin capacitor range
1.5
1000
nF
TA
Operating ambient temperature
–40
125
℃
If the logic signal driving MR is less than VDD, then additional current flows into VDD and out of MR. VMR should not be higher than VDD.
over operating free-air temperature range (unless otherwise noted)
MIN
NOM
MAX
UNIT
Voltage
VDD (Active Low output)
0.9
6
V
CWD, CRST, WD–EN, SETx, WDI, MR
(1)
0
VDD
RESET
(Open Drain) ,
WDO (Open Drain)
0
6
RESET
(Open Drain) ,
WDO (Push Pull)
0
VDD
Current
RESET,
WDO pin current
–5
5
mA
CRST
CRST pin capacitor range
1.5
1800
nF
CWD
CWD pin capacitor range
1.5
1000
nF
TA
Operating ambient temperature
–40
125
℃
over operating free-air temperature range (unless otherwise noted)
MIN
NOM
MAX
UNIT
Voltage
VDD (Active Low output)
0.9
6
V
CWD, CRST, WD–EN, SETx, WDI, MR
(1)
0
VDD
RESET
(Open Drain) ,
WDO (Open Drain)
0
6
RESET
(Open Drain) ,
WDO (Push Pull)
0
VDD
Current
RESET,
WDO pin current
–5
5
mA
CRST
CRST pin capacitor range
1.5
1800
nF
CWD
CWD pin capacitor range
1.5
1000
nF
TA
Operating ambient temperature
–40
125
℃
MIN
NOM
MAX
UNIT
MIN
NOM
MAX
UNIT
MINNOMMAXUNIT
Voltage
VDD (Active Low output)
0.9
6
V
CWD, CRST, WD–EN, SETx, WDI, MR
(1)
0
VDD
RESET
(Open Drain) ,
WDO (Open Drain)
0
6
RESET
(Open Drain) ,
WDO (Push Pull)
0
VDD
Current
RESET,
WDO pin current
–5
5
mA
CRST
CRST pin capacitor range
1.5
1800
nF
CWD
CWD pin capacitor range
1.5
1000
nF
TA
Operating ambient temperature
–40
125
℃
Voltage
VDD (Active Low output)
0.9
6
V
VoltageVDD (Active Low output)0.96V
CWD, CRST, WD–EN, SETx, WDI, MR
(1)
0
VDD
CWD, CRST, WD–EN, SETx, WDI, MR
(1)
WDRSTMR(1)0VDD
RESET
(Open Drain) ,
WDO (Open Drain)
0
6
RESET
(Open Drain) ,
WDO (Open Drain)
RESET
RESET (Open Drain) ,WDO06
RESET
(Open Drain) ,
WDO (Push Pull)
0
VDD
RESET
(Open Drain) ,
WDO (Push Pull)
RESET
RESET(Open Drain) ,WDO0VDD
Current
RESET,
WDO pin current
–5
5
mA
Current
RESET,
WDO pin current
RESET,RESETWDO–55mA
CRST
CRST pin capacitor range
1.5
1800
nF
CRST
RSTCRST pin capacitor rangeRST1.51800nF
CWD
CWD pin capacitor range
1.5
1000
nF
CWD
WDCWD pin capacitor rangeWD1.51000nF
TA
Operating ambient temperature
–40
125
℃
TA
AOperating ambient temperature–40125℃
If the logic signal driving MR is less than VDD, then additional current flows into VDD and out of MR. VMR should not be higher than VDD.
If the logic signal driving MR is less than VDD, then additional current flows into VDD and out of MR. VMR should not be higher than VDD.
MRDDDDMRMRDD.
Thermal Information
THERMAL METRIC#GUID-XXXXXXXX-SF0T-XXXX-XXXX-000000244050/A_SUPERVISOR_VVCM_5_THERMAL_FOOTER1
TPS36-Q1
UNIT
DDF (SOT23-8)
8 PINS
RθJA
Junction-to-ambient thermal resistance
175.3
°C/W
RθJC(top)
Junction-to-case (top) thermal resistance
94.7
°C/W
RθJB
Junction-to-board thermal resistance
92.4
°C/W
ψJT
Junction-to-top characterization parameter
8.4
°C/W
ψJB
Junction-to-board characterization parameter
91.9
°C/W
RθJC(bot)
Junction-to-case (bottom) thermal resistance
N/A
°C/W
For more information about traditional and new thermal metrics, see the Semiconductor and IC Package Thermal Metrics application report.
Thermal Information
THERMAL METRIC#GUID-XXXXXXXX-SF0T-XXXX-XXXX-000000244050/A_SUPERVISOR_VVCM_5_THERMAL_FOOTER1
TPS36-Q1
UNIT
DDF (SOT23-8)
8 PINS
RθJA
Junction-to-ambient thermal resistance
175.3
°C/W
RθJC(top)
Junction-to-case (top) thermal resistance
94.7
°C/W
RθJB
Junction-to-board thermal resistance
92.4
°C/W
ψJT
Junction-to-top characterization parameter
8.4
°C/W
ψJB
Junction-to-board characterization parameter
91.9
°C/W
RθJC(bot)
Junction-to-case (bottom) thermal resistance
N/A
°C/W
For more information about traditional and new thermal metrics, see the Semiconductor and IC Package Thermal Metrics application report.
THERMAL METRIC#GUID-XXXXXXXX-SF0T-XXXX-XXXX-000000244050/A_SUPERVISOR_VVCM_5_THERMAL_FOOTER1
TPS36-Q1
UNIT
DDF (SOT23-8)
8 PINS
RθJA
Junction-to-ambient thermal resistance
175.3
°C/W
RθJC(top)
Junction-to-case (top) thermal resistance
94.7
°C/W
RθJB
Junction-to-board thermal resistance
92.4
°C/W
ψJT
Junction-to-top characterization parameter
8.4
°C/W
ψJB
Junction-to-board characterization parameter
91.9
°C/W
RθJC(bot)
Junction-to-case (bottom) thermal resistance
N/A
°C/W
THERMAL METRIC#GUID-XXXXXXXX-SF0T-XXXX-XXXX-000000244050/A_SUPERVISOR_VVCM_5_THERMAL_FOOTER1
TPS36-Q1
UNIT
DDF (SOT23-8)
8 PINS
RθJA
Junction-to-ambient thermal resistance
175.3
°C/W
RθJC(top)
Junction-to-case (top) thermal resistance
94.7
°C/W
RθJB
Junction-to-board thermal resistance
92.4
°C/W
ψJT
Junction-to-top characterization parameter
8.4
°C/W
ψJB
Junction-to-board characterization parameter
91.9
°C/W
RθJC(bot)
Junction-to-case (bottom) thermal resistance
N/A
°C/W
THERMAL METRIC#GUID-XXXXXXXX-SF0T-XXXX-XXXX-000000244050/A_SUPERVISOR_VVCM_5_THERMAL_FOOTER1
TPS36-Q1
UNIT
DDF (SOT23-8)
8 PINS
THERMAL METRIC#GUID-XXXXXXXX-SF0T-XXXX-XXXX-000000244050/A_SUPERVISOR_VVCM_5_THERMAL_FOOTER1
TPS36-Q1
UNIT
THERMAL METRIC#GUID-XXXXXXXX-SF0T-XXXX-XXXX-000000244050/A_SUPERVISOR_VVCM_5_THERMAL_FOOTER1
#GUID-XXXXXXXX-SF0T-XXXX-XXXX-000000244050/A_SUPERVISOR_VVCM_5_THERMAL_FOOTER1
TPS36-Q1
TPS36-Q1UNIT
DDF (SOT23-8)
DDF (SOT23-8)
8 PINS
8 PINS
RθJA
Junction-to-ambient thermal resistance
175.3
°C/W
RθJC(top)
Junction-to-case (top) thermal resistance
94.7
°C/W
RθJB
Junction-to-board thermal resistance
92.4
°C/W
ψJT
Junction-to-top characterization parameter
8.4
°C/W
ψJB
Junction-to-board characterization parameter
91.9
°C/W
RθJC(bot)
Junction-to-case (bottom) thermal resistance
N/A
°C/W
RθJA
Junction-to-ambient thermal resistance
175.3
°C/W
RθJA
θJAJunction-to-ambient thermal resistance175.3°C/W
RθJC(top)
Junction-to-case (top) thermal resistance
94.7
°C/W
RθJC(top)
θJC(top)Junction-to-case (top) thermal resistance94.7°C/W
RθJB
Junction-to-board thermal resistance
92.4
°C/W
RθJB
θJBJunction-to-board thermal resistance92.4°C/W
ψJT
Junction-to-top characterization parameter
8.4
°C/W
ψJT
JTJunction-to-top characterization parameter8.4°C/W
ψJB
Junction-to-board characterization parameter
91.9
°C/W
ψJB
JBJunction-to-board characterization parameter91.9°C/W
RθJC(bot)
Junction-to-case (bottom) thermal resistance
N/A
°C/W
RθJC(bot)
θJC(bot)Junction-to-case (bottom) thermal resistanceN/A°C/W
For more information about traditional and new thermal metrics, see the Semiconductor and IC Package Thermal Metrics application report.
For more information about traditional and new thermal metrics, see the Semiconductor and IC Package Thermal Metrics application report.Semiconductor and IC Package Thermal Metrics
Electrical Characteristics
At 1.04 V ≤ VDD ≤ 6 V, MR = Open, RESET pull-up resistor (Rpull-up) = 100 kΩ to VDD, WDO pull-up resistor (Rpull-up) = 100 kΩ to VDD, output load (CLOAD) = 10 pF and over operating free-air temperature range –40℃ to 125℃, unless otherwise noted. VDD ramp rate ≤ 1 V/µs. Typical values are at TA = 25℃
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
COMMON PARAMETERS
VDD
Input supply voltage
Active LOW output
1.04
6
V
VIT–
Negative-going input threshold accuracy #GUID-XXXXXXXX-SF0T-XXXX-XXXX-000000244580/A_SUPERVISOR_VVCM_6_ELECTCHAR_FOOTER1_SF1
VIT– = 1.05 V to 1.95 V
–1.4
±0.5
1.4
%
VIT– = 2.0 V to 5.4 V
–1.2
±0.5
1.2
VHYS
Hysteresis VIT– pin
VIT– = 1.05 V to 5.4 V
3
5
7
%
IDD
Supply current into VDD pin #GUID-XXXXXXXX-SF0T-XXXX-XXXX-000000244580/A_SUPERVISOR_VVCM_6_ELECTCHAR_FOOTER5_SF1
VDD = 2 VVIT– = 1.05 V to 1.95 V
TA = –40℃ to 85℃
0.25
0.8
µA
0.25
3
VDD = 6 VVIT– = 1.05 V to 5.4 V
TA = –40℃ to 85℃
0.25
0.8
0.25
3
VIL
Low level input voltage WD–EN, WDI, SETx, MR
(3)
0.3VDD
V
VIH
High level input voltage WD–EN, WDI, SETx, MR
(3)
0.7VDD
V
R
MR
Manual reset internal pull-up resistance
100
kΩ
RESET / WDO (Open-drain active-low)
VOL
Low level output voltage
VDD =1.5 V, 1.55 V ≤ VIT– ≤ 3.35 VIOUT(Sink) = 500 µA
300
mV
VDD = 3.3 V, 3.4 V ≤ VIT– ≤ 5.4 VIOUT(Sink) = 2 mA
300
Ilkg(OD)
Open-Drain output leakage current
VDD = VPULLUP = 6VTA = –40℃ to 85℃
10
30
nA
VDD = VPULLUP = 6V
10
120
nA
RESET / WDO (Push-pull active-low)
VPOR
Power on RESET voltage (5)
VOL(max) = 300 mVIOUT(Sink) = 15 µA
900
mV
VOL
Low level output voltage
VDD = 0.9 V, 1.05 V ≤ VIT– ≤ 1.5 VIOUT(Sink) = 15 µA
300
mV
VDD = 1.5 V, 1.55 V ≤ VIT– ≤ 3.35 VIOUT(Sink) = 500 µA
300
VDD = 3.3 V, 3.4 V ≤ VIT– ≤ 5.4 VIOUT(Sink) = 2 mA
300
VOH
High level output voltage
VDD = 1.8 V, 1.05 V ≤ VIT– ≤ 1.4 VIOUT(Source) = 500 µA
0.8VDD
V
VDD = 3.3 V, 1.45 V ≤ VIT– ≤ 3.0 VIOUT(Source) = 500 µA
0.8VDD
VDD = 6 V, 3.05 V ≤ VIT– ≤ 5.4 VIOUT(Source) = 2 mA
0.8VDD
VIT– threshold voltage range from 1.05 V to 5.4 V in 50 mV steps.
If the logic signal driving MR is less than VDD, then additional current flows into VDD and out of MR.
VPOR is the minimum VDD voltage level for a controlled output state
Electrical Characteristics
At 1.04 V ≤ VDD ≤ 6 V, MR = Open, RESET pull-up resistor (Rpull-up) = 100 kΩ to VDD, WDO pull-up resistor (Rpull-up) = 100 kΩ to VDD, output load (CLOAD) = 10 pF and over operating free-air temperature range –40℃ to 125℃, unless otherwise noted. VDD ramp rate ≤ 1 V/µs. Typical values are at TA = 25℃
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
COMMON PARAMETERS
VDD
Input supply voltage
Active LOW output
1.04
6
V
VIT–
Negative-going input threshold accuracy #GUID-XXXXXXXX-SF0T-XXXX-XXXX-000000244580/A_SUPERVISOR_VVCM_6_ELECTCHAR_FOOTER1_SF1
VIT– = 1.05 V to 1.95 V
–1.4
±0.5
1.4
%
VIT– = 2.0 V to 5.4 V
–1.2
±0.5
1.2
VHYS
Hysteresis VIT– pin
VIT– = 1.05 V to 5.4 V
3
5
7
%
IDD
Supply current into VDD pin #GUID-XXXXXXXX-SF0T-XXXX-XXXX-000000244580/A_SUPERVISOR_VVCM_6_ELECTCHAR_FOOTER5_SF1
VDD = 2 VVIT– = 1.05 V to 1.95 V
TA = –40℃ to 85℃
0.25
0.8
µA
0.25
3
VDD = 6 VVIT– = 1.05 V to 5.4 V
TA = –40℃ to 85℃
0.25
0.8
0.25
3
VIL
Low level input voltage WD–EN, WDI, SETx, MR
(3)
0.3VDD
V
VIH
High level input voltage WD–EN, WDI, SETx, MR
(3)
0.7VDD
V
R
MR
Manual reset internal pull-up resistance
100
kΩ
RESET / WDO (Open-drain active-low)
VOL
Low level output voltage
VDD =1.5 V, 1.55 V ≤ VIT– ≤ 3.35 VIOUT(Sink) = 500 µA
300
mV
VDD = 3.3 V, 3.4 V ≤ VIT– ≤ 5.4 VIOUT(Sink) = 2 mA
300
Ilkg(OD)
Open-Drain output leakage current
VDD = VPULLUP = 6VTA = –40℃ to 85℃
10
30
nA
VDD = VPULLUP = 6V
10
120
nA
RESET / WDO (Push-pull active-low)
VPOR
Power on RESET voltage (5)
VOL(max) = 300 mVIOUT(Sink) = 15 µA
900
mV
VOL
Low level output voltage
VDD = 0.9 V, 1.05 V ≤ VIT– ≤ 1.5 VIOUT(Sink) = 15 µA
300
mV
VDD = 1.5 V, 1.55 V ≤ VIT– ≤ 3.35 VIOUT(Sink) = 500 µA
300
VDD = 3.3 V, 3.4 V ≤ VIT– ≤ 5.4 VIOUT(Sink) = 2 mA
300
VOH
High level output voltage
VDD = 1.8 V, 1.05 V ≤ VIT– ≤ 1.4 VIOUT(Source) = 500 µA
0.8VDD
V
VDD = 3.3 V, 1.45 V ≤ VIT– ≤ 3.0 VIOUT(Source) = 500 µA
0.8VDD
VDD = 6 V, 3.05 V ≤ VIT– ≤ 5.4 VIOUT(Source) = 2 mA
0.8VDD
VIT– threshold voltage range from 1.05 V to 5.4 V in 50 mV steps.
If the logic signal driving MR is less than VDD, then additional current flows into VDD and out of MR.
VPOR is the minimum VDD voltage level for a controlled output state
At 1.04 V ≤ VDD ≤ 6 V, MR = Open, RESET pull-up resistor (Rpull-up) = 100 kΩ to VDD, WDO pull-up resistor (Rpull-up) = 100 kΩ to VDD, output load (CLOAD) = 10 pF and over operating free-air temperature range –40℃ to 125℃, unless otherwise noted. VDD ramp rate ≤ 1 V/µs. Typical values are at TA = 25℃
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
COMMON PARAMETERS
VDD
Input supply voltage
Active LOW output
1.04
6
V
VIT–
Negative-going input threshold accuracy #GUID-XXXXXXXX-SF0T-XXXX-XXXX-000000244580/A_SUPERVISOR_VVCM_6_ELECTCHAR_FOOTER1_SF1
VIT– = 1.05 V to 1.95 V
–1.4
±0.5
1.4
%
VIT– = 2.0 V to 5.4 V
–1.2
±0.5
1.2
VHYS
Hysteresis VIT– pin
VIT– = 1.05 V to 5.4 V
3
5
7
%
IDD
Supply current into VDD pin #GUID-XXXXXXXX-SF0T-XXXX-XXXX-000000244580/A_SUPERVISOR_VVCM_6_ELECTCHAR_FOOTER5_SF1
VDD = 2 VVIT– = 1.05 V to 1.95 V
TA = –40℃ to 85℃
0.25
0.8
µA
0.25
3
VDD = 6 VVIT– = 1.05 V to 5.4 V
TA = –40℃ to 85℃
0.25
0.8
0.25
3
VIL
Low level input voltage WD–EN, WDI, SETx, MR
(3)
0.3VDD
V
VIH
High level input voltage WD–EN, WDI, SETx, MR
(3)
0.7VDD
V
R
MR
Manual reset internal pull-up resistance
100
kΩ
RESET / WDO (Open-drain active-low)
VOL
Low level output voltage
VDD =1.5 V, 1.55 V ≤ VIT– ≤ 3.35 VIOUT(Sink) = 500 µA
300
mV
VDD = 3.3 V, 3.4 V ≤ VIT– ≤ 5.4 VIOUT(Sink) = 2 mA
300
Ilkg(OD)
Open-Drain output leakage current
VDD = VPULLUP = 6VTA = –40℃ to 85℃
10
30
nA
VDD = VPULLUP = 6V
10
120
nA
RESET / WDO (Push-pull active-low)
VPOR
Power on RESET voltage (5)
VOL(max) = 300 mVIOUT(Sink) = 15 µA
900
mV
VOL
Low level output voltage
VDD = 0.9 V, 1.05 V ≤ VIT– ≤ 1.5 VIOUT(Sink) = 15 µA
300
mV
VDD = 1.5 V, 1.55 V ≤ VIT– ≤ 3.35 VIOUT(Sink) = 500 µA
300
VDD = 3.3 V, 3.4 V ≤ VIT– ≤ 5.4 VIOUT(Sink) = 2 mA
300
VOH
High level output voltage
VDD = 1.8 V, 1.05 V ≤ VIT– ≤ 1.4 VIOUT(Source) = 500 µA
0.8VDD
V
VDD = 3.3 V, 1.45 V ≤ VIT– ≤ 3.0 VIOUT(Source) = 500 µA
0.8VDD
VDD = 6 V, 3.05 V ≤ VIT– ≤ 5.4 VIOUT(Source) = 2 mA
0.8VDD
At 1.04 V ≤ VDD ≤ 6 V, MR = Open, RESET pull-up resistor (Rpull-up) = 100 kΩ to VDD, WDO pull-up resistor (Rpull-up) = 100 kΩ to VDD, output load (CLOAD) = 10 pF and over operating free-air temperature range –40℃ to 125℃, unless otherwise noted. VDD ramp rate ≤ 1 V/µs. Typical values are at TA = 25℃DDMR RESETpull-upWDOpull-upLOADA
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
COMMON PARAMETERS
VDD
Input supply voltage
Active LOW output
1.04
6
V
VIT–
Negative-going input threshold accuracy #GUID-XXXXXXXX-SF0T-XXXX-XXXX-000000244580/A_SUPERVISOR_VVCM_6_ELECTCHAR_FOOTER1_SF1
VIT– = 1.05 V to 1.95 V
–1.4
±0.5
1.4
%
VIT– = 2.0 V to 5.4 V
–1.2
±0.5
1.2
VHYS
Hysteresis VIT– pin
VIT– = 1.05 V to 5.4 V
3
5
7
%
IDD
Supply current into VDD pin #GUID-XXXXXXXX-SF0T-XXXX-XXXX-000000244580/A_SUPERVISOR_VVCM_6_ELECTCHAR_FOOTER5_SF1
VDD = 2 VVIT– = 1.05 V to 1.95 V
TA = –40℃ to 85℃
0.25
0.8
µA
0.25
3
VDD = 6 VVIT– = 1.05 V to 5.4 V
TA = –40℃ to 85℃
0.25
0.8
0.25
3
VIL
Low level input voltage WD–EN, WDI, SETx, MR
(3)
0.3VDD
V
VIH
High level input voltage WD–EN, WDI, SETx, MR
(3)
0.7VDD
V
R
MR
Manual reset internal pull-up resistance
100
kΩ
RESET / WDO (Open-drain active-low)
VOL
Low level output voltage
VDD =1.5 V, 1.55 V ≤ VIT– ≤ 3.35 VIOUT(Sink) = 500 µA
300
mV
VDD = 3.3 V, 3.4 V ≤ VIT– ≤ 5.4 VIOUT(Sink) = 2 mA
300
Ilkg(OD)
Open-Drain output leakage current
VDD = VPULLUP = 6VTA = –40℃ to 85℃
10
30
nA
VDD = VPULLUP = 6V
10
120
nA
RESET / WDO (Push-pull active-low)
VPOR
Power on RESET voltage (5)
VOL(max) = 300 mVIOUT(Sink) = 15 µA
900
mV
VOL
Low level output voltage
VDD = 0.9 V, 1.05 V ≤ VIT– ≤ 1.5 VIOUT(Sink) = 15 µA
300
mV
VDD = 1.5 V, 1.55 V ≤ VIT– ≤ 3.35 VIOUT(Sink) = 500 µA
300
VDD = 3.3 V, 3.4 V ≤ VIT– ≤ 5.4 VIOUT(Sink) = 2 mA
300
VOH
High level output voltage
VDD = 1.8 V, 1.05 V ≤ VIT– ≤ 1.4 VIOUT(Source) = 500 µA
0.8VDD
V
VDD = 3.3 V, 1.45 V ≤ VIT– ≤ 3.0 VIOUT(Source) = 500 µA
0.8VDD
VDD = 6 V, 3.05 V ≤ VIT– ≤ 5.4 VIOUT(Source) = 2 mA
0.8VDD
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
PARAMETERTEST CONDITIONSMINTYPMAXUNIT
COMMON PARAMETERS
VDD
Input supply voltage
Active LOW output
1.04
6
V
VIT–
Negative-going input threshold accuracy #GUID-XXXXXXXX-SF0T-XXXX-XXXX-000000244580/A_SUPERVISOR_VVCM_6_ELECTCHAR_FOOTER1_SF1
VIT– = 1.05 V to 1.95 V
–1.4
±0.5
1.4
%
VIT– = 2.0 V to 5.4 V
–1.2
±0.5
1.2
VHYS
Hysteresis VIT– pin
VIT– = 1.05 V to 5.4 V
3
5
7
%
IDD
Supply current into VDD pin #GUID-XXXXXXXX-SF0T-XXXX-XXXX-000000244580/A_SUPERVISOR_VVCM_6_ELECTCHAR_FOOTER5_SF1
VDD = 2 VVIT– = 1.05 V to 1.95 V
TA = –40℃ to 85℃
0.25
0.8
µA
0.25
3
VDD = 6 VVIT– = 1.05 V to 5.4 V
TA = –40℃ to 85℃
0.25
0.8
0.25
3
VIL
Low level input voltage WD–EN, WDI, SETx, MR
(3)
0.3VDD
V
VIH
High level input voltage WD–EN, WDI, SETx, MR
(3)
0.7VDD
V
R
MR
Manual reset internal pull-up resistance
100
kΩ
RESET / WDO (Open-drain active-low)
VOL
Low level output voltage
VDD =1.5 V, 1.55 V ≤ VIT– ≤ 3.35 VIOUT(Sink) = 500 µA
300
mV
VDD = 3.3 V, 3.4 V ≤ VIT– ≤ 5.4 VIOUT(Sink) = 2 mA
300
Ilkg(OD)
Open-Drain output leakage current
VDD = VPULLUP = 6VTA = –40℃ to 85℃
10
30
nA
VDD = VPULLUP = 6V
10
120
nA
RESET / WDO (Push-pull active-low)
VPOR
Power on RESET voltage (5)
VOL(max) = 300 mVIOUT(Sink) = 15 µA
900
mV
VOL
Low level output voltage
VDD = 0.9 V, 1.05 V ≤ VIT– ≤ 1.5 VIOUT(Sink) = 15 µA
300
mV
VDD = 1.5 V, 1.55 V ≤ VIT– ≤ 3.35 VIOUT(Sink) = 500 µA
300
VDD = 3.3 V, 3.4 V ≤ VIT– ≤ 5.4 VIOUT(Sink) = 2 mA
300
VOH
High level output voltage
VDD = 1.8 V, 1.05 V ≤ VIT– ≤ 1.4 VIOUT(Source) = 500 µA
0.8VDD
V
VDD = 3.3 V, 1.45 V ≤ VIT– ≤ 3.0 VIOUT(Source) = 500 µA
0.8VDD
VDD = 6 V, 3.05 V ≤ VIT– ≤ 5.4 VIOUT(Source) = 2 mA
0.8VDD
COMMON PARAMETERS
COMMON PARAMETERS
VDD
Input supply voltage
Active LOW output
1.04
6
V
VDD
DDInput supply voltageActive LOW output1.046V
VIT–
Negative-going input threshold accuracy #GUID-XXXXXXXX-SF0T-XXXX-XXXX-000000244580/A_SUPERVISOR_VVCM_6_ELECTCHAR_FOOTER1_SF1
VIT– = 1.05 V to 1.95 V
–1.4
±0.5
1.4
%
VIT–
IT–Negative-going input threshold accuracy #GUID-XXXXXXXX-SF0T-XXXX-XXXX-000000244580/A_SUPERVISOR_VVCM_6_ELECTCHAR_FOOTER1_SF1
#GUID-XXXXXXXX-SF0T-XXXX-XXXX-000000244580/A_SUPERVISOR_VVCM_6_ELECTCHAR_FOOTER1_SF1VIT– = 1.05 V to 1.95 VIT––1.4±0.51.4%
VIT– = 2.0 V to 5.4 V
–1.2
±0.5
1.2
VIT– = 2.0 V to 5.4 VIT––1.2±0.51.2
VHYS
Hysteresis VIT– pin
VIT– = 1.05 V to 5.4 V
3
5
7
%
VHYS
HYSHysteresis VIT– pinIT–VIT– = 1.05 V to 5.4 VIT–357%
IDD
Supply current into VDD pin #GUID-XXXXXXXX-SF0T-XXXX-XXXX-000000244580/A_SUPERVISOR_VVCM_6_ELECTCHAR_FOOTER5_SF1
VDD = 2 VVIT– = 1.05 V to 1.95 V
TA = –40℃ to 85℃
0.25
0.8
µA
IDD
DDSupply current into VDD pin #GUID-XXXXXXXX-SF0T-XXXX-XXXX-000000244580/A_SUPERVISOR_VVCM_6_ELECTCHAR_FOOTER5_SF1
#GUID-XXXXXXXX-SF0T-XXXX-XXXX-000000244580/A_SUPERVISOR_VVCM_6_ELECTCHAR_FOOTER5_SF1VDD = 2 VVIT– = 1.05 V to 1.95 VDDIT–TA = –40℃ to 85℃ A0.250.8µA
0.25
3
0.253
VDD = 6 VVIT– = 1.05 V to 5.4 V
TA = –40℃ to 85℃
0.25
0.8
VDD = 6 VVIT– = 1.05 V to 5.4 VDDIT–TA = –40℃ to 85℃ A0.250.8
0.25
3
0.253
VIL
Low level input voltage WD–EN, WDI, SETx, MR
(3)
0.3VDD
V
VIL
ILLow level input voltage WD–EN, WDI, SETx, MR
(3)
MR(3)0.3VDD
DDV
VIH
High level input voltage WD–EN, WDI, SETx, MR
(3)
0.7VDD
V
VIH
IHHigh level input voltage WD–EN, WDI, SETx, MR
(3)
MR(3)0.7VDD
DDV
R
MR
Manual reset internal pull-up resistance
100
kΩ
R
MR
MR
MRManual reset internal pull-up resistance100kΩ
RESET / WDO (Open-drain active-low)
RESET / WDO (Open-drain active-low)RESETWDO
VOL
Low level output voltage
VDD =1.5 V, 1.55 V ≤ VIT– ≤ 3.35 VIOUT(Sink) = 500 µA
300
mV
VOL
OLLow level output voltage VDD =1.5 V, 1.55 V ≤ VIT– ≤ 3.35 VIOUT(Sink) = 500 µADDIT–OUT(Sink)300mV
VDD = 3.3 V, 3.4 V ≤ VIT– ≤ 5.4 VIOUT(Sink) = 2 mA
300
VDD = 3.3 V, 3.4 V ≤ VIT– ≤ 5.4 VIOUT(Sink) = 2 mADDIT–OUT(Sink)300
Ilkg(OD)
Open-Drain output leakage current
VDD = VPULLUP = 6VTA = –40℃ to 85℃
10
30
nA
Ilkg(OD)
lkg(OD)Open-Drain output leakage currentVDD = VPULLUP = 6VTA = –40℃ to 85℃DDPULLUPA1030nA
VDD = VPULLUP = 6V
10
120
nA
VDD = VPULLUP = 6VDDPULLUP10120nA
RESET / WDO (Push-pull active-low)
RESET / WDO (Push-pull active-low)RESETWDO
VPOR
Power on RESET voltage (5)
VOL(max) = 300 mVIOUT(Sink) = 15 µA
900
mV
VPOR
PORPower on RESET voltage (5)
RESET(5)VOL(max) = 300 mVIOUT(Sink) = 15 µAOL(max)OUT(Sink)900mV
VOL
Low level output voltage
VDD = 0.9 V, 1.05 V ≤ VIT– ≤ 1.5 VIOUT(Sink) = 15 µA
300
mV
VOL
OLLow level output voltage VDD = 0.9 V, 1.05 V ≤ VIT– ≤ 1.5 VIOUT(Sink) = 15 µADDIT–OUT(Sink)300mV
VDD = 1.5 V, 1.55 V ≤ VIT– ≤ 3.35 VIOUT(Sink) = 500 µA
300
VDD = 1.5 V, 1.55 V ≤ VIT– ≤ 3.35 VIOUT(Sink) = 500 µADDIT–OUT(Sink)300
VDD = 3.3 V, 3.4 V ≤ VIT– ≤ 5.4 VIOUT(Sink) = 2 mA
300
VDD = 3.3 V, 3.4 V ≤ VIT– ≤ 5.4 VIOUT(Sink) = 2 mADDIT–OUT(Sink)300
VOH
High level output voltage
VDD = 1.8 V, 1.05 V ≤ VIT– ≤ 1.4 VIOUT(Source) = 500 µA
0.8VDD
V
VOH
OHHigh level output voltage VDD = 1.8 V, 1.05 V ≤ VIT– ≤ 1.4 VIOUT(Source) = 500 µADD IT–OUT(Source)0.8VDD
DDV
VDD = 3.3 V, 1.45 V ≤ VIT– ≤ 3.0 VIOUT(Source) = 500 µA
0.8VDD
VDD = 3.3 V, 1.45 V ≤ VIT– ≤ 3.0 VIOUT(Source) = 500 µADD IT–OUT(Source)0.8VDD
DD
VDD = 6 V, 3.05 V ≤ VIT– ≤ 5.4 VIOUT(Source) = 2 mA
0.8VDD
VDD = 6 V, 3.05 V ≤ VIT– ≤ 5.4 VIOUT(Source) = 2 mADD IT–OUT(Source)0.8VDD
DD
VIT– threshold voltage range from 1.05 V to 5.4 V in 50 mV steps.
If the logic signal driving MR is less than VDD, then additional current flows into VDD and out of MR.
VPOR is the minimum VDD voltage level for a controlled output state
VIT– threshold voltage range from 1.05 V to 5.4 V in 50 mV steps.IT–If the logic signal driving MR is less than VDD, then additional current flows into VDD and out of MR.MRDDDD MRVPOR is the minimum VDD voltage level for a controlled output statePORDD
Timing Requirements
At 1.04 V ≤ VDD ≤ 6 V, MR = Open, RESET pull-up resistor (Rpull-up) = 100 kΩ to VDD, WDO pull-up resistor (Rpull-up) = 100 kΩ to VDD, output RESET / WDO load (CLOAD) = 10 pF and over operating free-air temperature range –40℃ to 125℃, unless otherwise noted. VDD ramp rate ≤ 1 V/µs. Typical values are at TA = 25℃
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
tGI_VIT–
Glitch immunity VIT–
5% VIT– overdrive#GUID-XXXXXXXX-SF0T-XXXX-XXXX-000000244581/A_SUPERVISOR_VVCM_7_TIMINGREQ_FOOTER2_SF2
15
µs
t
MR_PW
MR pin pulse duration to assert reset
100
ns
tP-WD
WDI pulse duration to start next frame #GUID-XXXXXXXX-SF0T-XXXX-XXXX-000000244581/SFSEP1E0POOS
VDD > VIT–
500
ns
tHD-WDEN
WD-EN hold time to enable or disable WD operation #GUID-XXXXXXXX-SF0T-XXXX-XXXX-000000244581/SFSEP1E0POOS
VDD > VIT–
200
µs
tHD-SETx
SETx hold time to change WD timer setting #GUID-XXXXXXXX-SF0T-XXXX-XXXX-000000244581/SFSEP1E0POOS
VDD > VIT–
150
µs
tWC
Watchdog close window time period
Orderable Option TPS36xxxxB
0.8
1
1.2
ms
Orderable Option TPS36xxxxC
4
5
6
Orderable Option TPS36xxxxD
9
10
11
Orderable Option TPS36xxxxE
18
20
22
Orderable Option TPS36xxxxF
45
50
55
Orderable Option TPS36xxxxG
90
100
110
Orderable Option TPS36xxxxH
180
200
220
Orderable Option TPS36xxxxI
0.9
1
1.1
s
Orderable Option TPS36xxxxJ
1.26
1.4
1.54
Orderable Option TPS36xxxxK
1.44
1.6
1.76
Orderable Option TPS36xxxxL
9
10
11
Orderable Option TPS36xxxxM
45
50
55
Orderable Option TPS36xxxxN
90
100
110
tWO
Watchdog open window time period
SETx pin decide multipler n
(n-1) X tWC
ms
Overdrive % = [(VDD/ VIT–) – 1] × 100%
Not production tested
Timing Requirements
At 1.04 V ≤ VDD ≤ 6 V, MR = Open, RESET pull-up resistor (Rpull-up) = 100 kΩ to VDD, WDO pull-up resistor (Rpull-up) = 100 kΩ to VDD, output RESET / WDO load (CLOAD) = 10 pF and over operating free-air temperature range –40℃ to 125℃, unless otherwise noted. VDD ramp rate ≤ 1 V/µs. Typical values are at TA = 25℃
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
tGI_VIT–
Glitch immunity VIT–
5% VIT– overdrive#GUID-XXXXXXXX-SF0T-XXXX-XXXX-000000244581/A_SUPERVISOR_VVCM_7_TIMINGREQ_FOOTER2_SF2
15
µs
t
MR_PW
MR pin pulse duration to assert reset
100
ns
tP-WD
WDI pulse duration to start next frame #GUID-XXXXXXXX-SF0T-XXXX-XXXX-000000244581/SFSEP1E0POOS
VDD > VIT–
500
ns
tHD-WDEN
WD-EN hold time to enable or disable WD operation #GUID-XXXXXXXX-SF0T-XXXX-XXXX-000000244581/SFSEP1E0POOS
VDD > VIT–
200
µs
tHD-SETx
SETx hold time to change WD timer setting #GUID-XXXXXXXX-SF0T-XXXX-XXXX-000000244581/SFSEP1E0POOS
VDD > VIT–
150
µs
tWC
Watchdog close window time period
Orderable Option TPS36xxxxB
0.8
1
1.2
ms
Orderable Option TPS36xxxxC
4
5
6
Orderable Option TPS36xxxxD
9
10
11
Orderable Option TPS36xxxxE
18
20
22
Orderable Option TPS36xxxxF
45
50
55
Orderable Option TPS36xxxxG
90
100
110
Orderable Option TPS36xxxxH
180
200
220
Orderable Option TPS36xxxxI
0.9
1
1.1
s
Orderable Option TPS36xxxxJ
1.26
1.4
1.54
Orderable Option TPS36xxxxK
1.44
1.6
1.76
Orderable Option TPS36xxxxL
9
10
11
Orderable Option TPS36xxxxM
45
50
55
Orderable Option TPS36xxxxN
90
100
110
tWO
Watchdog open window time period
SETx pin decide multipler n
(n-1) X tWC
ms
Overdrive % = [(VDD/ VIT–) – 1] × 100%
Not production tested
At 1.04 V ≤ VDD ≤ 6 V, MR = Open, RESET pull-up resistor (Rpull-up) = 100 kΩ to VDD, WDO pull-up resistor (Rpull-up) = 100 kΩ to VDD, output RESET / WDO load (CLOAD) = 10 pF and over operating free-air temperature range –40℃ to 125℃, unless otherwise noted. VDD ramp rate ≤ 1 V/µs. Typical values are at TA = 25℃
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
tGI_VIT–
Glitch immunity VIT–
5% VIT– overdrive#GUID-XXXXXXXX-SF0T-XXXX-XXXX-000000244581/A_SUPERVISOR_VVCM_7_TIMINGREQ_FOOTER2_SF2
15
µs
t
MR_PW
MR pin pulse duration to assert reset
100
ns
tP-WD
WDI pulse duration to start next frame #GUID-XXXXXXXX-SF0T-XXXX-XXXX-000000244581/SFSEP1E0POOS
VDD > VIT–
500
ns
tHD-WDEN
WD-EN hold time to enable or disable WD operation #GUID-XXXXXXXX-SF0T-XXXX-XXXX-000000244581/SFSEP1E0POOS
VDD > VIT–
200
µs
tHD-SETx
SETx hold time to change WD timer setting #GUID-XXXXXXXX-SF0T-XXXX-XXXX-000000244581/SFSEP1E0POOS
VDD > VIT–
150
µs
tWC
Watchdog close window time period
Orderable Option TPS36xxxxB
0.8
1
1.2
ms
Orderable Option TPS36xxxxC
4
5
6
Orderable Option TPS36xxxxD
9
10
11
Orderable Option TPS36xxxxE
18
20
22
Orderable Option TPS36xxxxF
45
50
55
Orderable Option TPS36xxxxG
90
100
110
Orderable Option TPS36xxxxH
180
200
220
Orderable Option TPS36xxxxI
0.9
1
1.1
s
Orderable Option TPS36xxxxJ
1.26
1.4
1.54
Orderable Option TPS36xxxxK
1.44
1.6
1.76
Orderable Option TPS36xxxxL
9
10
11
Orderable Option TPS36xxxxM
45
50
55
Orderable Option TPS36xxxxN
90
100
110
tWO
Watchdog open window time period
SETx pin decide multipler n
(n-1) X tWC
ms
At 1.04 V ≤ VDD ≤ 6 V, MR = Open, RESET pull-up resistor (Rpull-up) = 100 kΩ to VDD, WDO pull-up resistor (Rpull-up) = 100 kΩ to VDD, output RESET / WDO load (CLOAD) = 10 pF and over operating free-air temperature range –40℃ to 125℃, unless otherwise noted. VDD ramp rate ≤ 1 V/µs. Typical values are at TA = 25℃DDMR RESETpull-upWDOpull-upLOADA
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
tGI_VIT–
Glitch immunity VIT–
5% VIT– overdrive#GUID-XXXXXXXX-SF0T-XXXX-XXXX-000000244581/A_SUPERVISOR_VVCM_7_TIMINGREQ_FOOTER2_SF2
15
µs
t
MR_PW
MR pin pulse duration to assert reset
100
ns
tP-WD
WDI pulse duration to start next frame #GUID-XXXXXXXX-SF0T-XXXX-XXXX-000000244581/SFSEP1E0POOS
VDD > VIT–
500
ns
tHD-WDEN
WD-EN hold time to enable or disable WD operation #GUID-XXXXXXXX-SF0T-XXXX-XXXX-000000244581/SFSEP1E0POOS
VDD > VIT–
200
µs
tHD-SETx
SETx hold time to change WD timer setting #GUID-XXXXXXXX-SF0T-XXXX-XXXX-000000244581/SFSEP1E0POOS
VDD > VIT–
150
µs
tWC
Watchdog close window time period
Orderable Option TPS36xxxxB
0.8
1
1.2
ms
Orderable Option TPS36xxxxC
4
5
6
Orderable Option TPS36xxxxD
9
10
11
Orderable Option TPS36xxxxE
18
20
22
Orderable Option TPS36xxxxF
45
50
55
Orderable Option TPS36xxxxG
90
100
110
Orderable Option TPS36xxxxH
180
200
220
Orderable Option TPS36xxxxI
0.9
1
1.1
s
Orderable Option TPS36xxxxJ
1.26
1.4
1.54
Orderable Option TPS36xxxxK
1.44
1.6
1.76
Orderable Option TPS36xxxxL
9
10
11
Orderable Option TPS36xxxxM
45
50
55
Orderable Option TPS36xxxxN
90
100
110
tWO
Watchdog open window time period
SETx pin decide multipler n
(n-1) X tWC
ms
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
PARAMETERTEST CONDITIONSMINTYPMAXUNIT
tGI_VIT–
Glitch immunity VIT–
5% VIT– overdrive#GUID-XXXXXXXX-SF0T-XXXX-XXXX-000000244581/A_SUPERVISOR_VVCM_7_TIMINGREQ_FOOTER2_SF2
15
µs
t
MR_PW
MR pin pulse duration to assert reset
100
ns
tP-WD
WDI pulse duration to start next frame #GUID-XXXXXXXX-SF0T-XXXX-XXXX-000000244581/SFSEP1E0POOS
VDD > VIT–
500
ns
tHD-WDEN
WD-EN hold time to enable or disable WD operation #GUID-XXXXXXXX-SF0T-XXXX-XXXX-000000244581/SFSEP1E0POOS
VDD > VIT–
200
µs
tHD-SETx
SETx hold time to change WD timer setting #GUID-XXXXXXXX-SF0T-XXXX-XXXX-000000244581/SFSEP1E0POOS
VDD > VIT–
150
µs
tWC
Watchdog close window time period
Orderable Option TPS36xxxxB
0.8
1
1.2
ms
Orderable Option TPS36xxxxC
4
5
6
Orderable Option TPS36xxxxD
9
10
11
Orderable Option TPS36xxxxE
18
20
22
Orderable Option TPS36xxxxF
45
50
55
Orderable Option TPS36xxxxG
90
100
110
Orderable Option TPS36xxxxH
180
200
220
Orderable Option TPS36xxxxI
0.9
1
1.1
s
Orderable Option TPS36xxxxJ
1.26
1.4
1.54
Orderable Option TPS36xxxxK
1.44
1.6
1.76
Orderable Option TPS36xxxxL
9
10
11
Orderable Option TPS36xxxxM
45
50
55
Orderable Option TPS36xxxxN
90
100
110
tWO
Watchdog open window time period
SETx pin decide multipler n
(n-1) X tWC
ms
tGI_VIT–
Glitch immunity VIT–
5% VIT– overdrive#GUID-XXXXXXXX-SF0T-XXXX-XXXX-000000244581/A_SUPERVISOR_VVCM_7_TIMINGREQ_FOOTER2_SF2
15
µs
tGI_VIT–
GI_VIT– Glitch immunity VIT–
IT–
5% VIT– overdrive#GUID-XXXXXXXX-SF0T-XXXX-XXXX-000000244581/A_SUPERVISOR_VVCM_7_TIMINGREQ_FOOTER2_SF2
IT–#GUID-XXXXXXXX-SF0T-XXXX-XXXX-000000244581/A_SUPERVISOR_VVCM_7_TIMINGREQ_FOOTER2_SF215µs
t
MR_PW
MR pin pulse duration to assert reset
100
ns
t
MR_PW
MR_PWMR
MR pin pulse duration to assert resetMR100ns
tP-WD
WDI pulse duration to start next frame #GUID-XXXXXXXX-SF0T-XXXX-XXXX-000000244581/SFSEP1E0POOS
VDD > VIT–
500
ns
tP-WD
P-WDWDI pulse duration to start next frame #GUID-XXXXXXXX-SF0T-XXXX-XXXX-000000244581/SFSEP1E0POOS
#GUID-XXXXXXXX-SF0T-XXXX-XXXX-000000244581/SFSEP1E0POOSVDD > VIT–
DDIT–500ns
tHD-WDEN
WD-EN hold time to enable or disable WD operation #GUID-XXXXXXXX-SF0T-XXXX-XXXX-000000244581/SFSEP1E0POOS
VDD > VIT–
200
µs
tHD-WDEN
HD-WDENWD-EN hold time to enable or disable WD operation #GUID-XXXXXXXX-SF0T-XXXX-XXXX-000000244581/SFSEP1E0POOS
#GUID-XXXXXXXX-SF0T-XXXX-XXXX-000000244581/SFSEP1E0POOSVDD > VIT–
DDIT–200µs
tHD-SETx
SETx hold time to change WD timer setting #GUID-XXXXXXXX-SF0T-XXXX-XXXX-000000244581/SFSEP1E0POOS
VDD > VIT–
150
µs
tHD-SETx
HD-SETxSETx hold time to change WD timer setting #GUID-XXXXXXXX-SF0T-XXXX-XXXX-000000244581/SFSEP1E0POOS
#GUID-XXXXXXXX-SF0T-XXXX-XXXX-000000244581/SFSEP1E0POOSVDD > VIT–
DDIT–150µs
tWC
Watchdog close window time period
Orderable Option TPS36xxxxB
0.8
1
1.2
ms
tWC
WCWatchdog close window time periodOrderable Option TPS36xxxxB0.811.2ms
Orderable Option TPS36xxxxC
4
5
6
Orderable Option TPS36xxxxC456
Orderable Option TPS36xxxxD
9
10
11
Orderable Option TPS36xxxxD91011
Orderable Option TPS36xxxxE
18
20
22
Orderable Option TPS36xxxxE182022
Orderable Option TPS36xxxxF
45
50
55
Orderable Option TPS36xxxxF455055
Orderable Option TPS36xxxxG
90
100
110
Orderable Option TPS36xxxxG90100110
Orderable Option TPS36xxxxH
180
200
220
Orderable Option TPS36xxxxH180200220
Orderable Option TPS36xxxxI
0.9
1
1.1
s
Orderable Option TPS36xxxxI0.911.1s
Orderable Option TPS36xxxxJ
1.26
1.4
1.54
Orderable Option TPS36xxxxJ1.261.41.54
Orderable Option TPS36xxxxK
1.44
1.6
1.76
Orderable Option TPS36xxxxK1.441.61.76
Orderable Option TPS36xxxxL
9
10
11
Orderable Option TPS36xxxxL91011
Orderable Option TPS36xxxxM
45
50
55
Orderable Option TPS36xxxxM455055
Orderable Option TPS36xxxxN
90
100
110
Orderable Option TPS36xxxxN90100110
tWO
Watchdog open window time period
SETx pin decide multipler n
(n-1) X tWC
ms
tWO
WOWatchdog open window time periodSETx pin decide multipler n
n
(n-1) X tWC
(n-1)WCms
Overdrive % = [(VDD/ VIT–) – 1] × 100%
Not production tested
Overdrive % = [(VDD/ VIT–) – 1] × 100%DDIT–Not production tested
Switching Characteristics
At 1.04 V ≤ VDD ≤ 6 V, MR = Open, RESET pull-up resistor (Rpull-up) = 100 kΩ to VDD, WDO pull-up resistor (Rpull-up) = 100 kΩ to VDD, output RESET / WDO load (CLOAD) = 10 pF and over operating free-air temperature range –40℃ to 125℃, unless otherwise noted. VDD ramp rate ≤ 1 V/µs. Typical values are at TA = 25℃
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
tSTRT
Startup delay(4)
500
µs
tP_HL
RESET detect delay for VDD falling below VIT–
VDD : (VIT+ + 10%) to (VIT– – 10%)#GUID-XXXXXXXX-SF0T-XXXX-XXXX-000000244582/A_SUPERVISOR_VVCM_7_TIMINGREQ_FOOTER4_SF1_SF1
30
50
µs
tSD
Watchdog startup delay
Orderable part number TPS36xA, TPS36xG
0
ms
Orderable part number TPS36xB, TPS36xH
180
200
220
Orderable part number TPS36xC, TPS36xI
450
500
550
Orderable part number TPS36xD, TPS36xJ
0.9
1
1.1
s
Orderable part number TPS36xE, TPS36xK
4.5
5
5.5
Orderable part number TPS36xF, TPS36xL
9
10
11
tD
Reset time delay #GUID-XXXXXXXX-SF0T-XXXX-XXXX-000000244582/A_SUPERVISOR_VVCM_7_TIMINGREQ_FOOTER3_SF1_SF1
Orderable part number TPS36xxxxxxB
1.6
2
2.4
ms
Orderable part number TPS36xxxxxxC
9
10
11
ms
Orderable part number TPS36xxxxxxD
22.5
25
27.5
ms
Orderable part number TPS36xxxxxxE
45
50
55
ms
Orderable part number TPS36xxxxxxF
90
100
110
ms
Orderable part number TPS36xxxxxxG
180
200
220
ms
Orderable part number TPS36xxxxxxH
0.9
1
1.1
s
Orderable part number TPS36xxxxxxI
9
10
11
s
tWDO
Watchdog timeout delay
tD
s
t
MR_RES
Propagation delay from MR low to reset assertion
VDD ≥ VIT– + 0.2 V,
MR = V
MR_H to V
MR_L
100
ns
t
MR_tD
Delay from MR release to reset deassert
VDD = 3.3 V,
MR = V
MR_L to V
MR_H
tD
s
tP_HL measured from threshold trip point (VIT–) to RESET assert. VIT+ = VIT– + VHYS
Specified by design parameter. When VDD starts from less than the specified minimum VDD and then exceeds VIT+, reset is deasserted after the startup delay (tSTRT) + tD delay.
VDD voltage transitions from (VIT– - 10%) to (VIT– + 10%)
Switching Characteristics
At 1.04 V ≤ VDD ≤ 6 V, MR = Open, RESET pull-up resistor (Rpull-up) = 100 kΩ to VDD, WDO pull-up resistor (Rpull-up) = 100 kΩ to VDD, output RESET / WDO load (CLOAD) = 10 pF and over operating free-air temperature range –40℃ to 125℃, unless otherwise noted. VDD ramp rate ≤ 1 V/µs. Typical values are at TA = 25℃
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
tSTRT
Startup delay(4)
500
µs
tP_HL
RESET detect delay for VDD falling below VIT–
VDD : (VIT+ + 10%) to (VIT– – 10%)#GUID-XXXXXXXX-SF0T-XXXX-XXXX-000000244582/A_SUPERVISOR_VVCM_7_TIMINGREQ_FOOTER4_SF1_SF1
30
50
µs
tSD
Watchdog startup delay
Orderable part number TPS36xA, TPS36xG
0
ms
Orderable part number TPS36xB, TPS36xH
180
200
220
Orderable part number TPS36xC, TPS36xI
450
500
550
Orderable part number TPS36xD, TPS36xJ
0.9
1
1.1
s
Orderable part number TPS36xE, TPS36xK
4.5
5
5.5
Orderable part number TPS36xF, TPS36xL
9
10
11
tD
Reset time delay #GUID-XXXXXXXX-SF0T-XXXX-XXXX-000000244582/A_SUPERVISOR_VVCM_7_TIMINGREQ_FOOTER3_SF1_SF1
Orderable part number TPS36xxxxxxB
1.6
2
2.4
ms
Orderable part number TPS36xxxxxxC
9
10
11
ms
Orderable part number TPS36xxxxxxD
22.5
25
27.5
ms
Orderable part number TPS36xxxxxxE
45
50
55
ms
Orderable part number TPS36xxxxxxF
90
100
110
ms
Orderable part number TPS36xxxxxxG
180
200
220
ms
Orderable part number TPS36xxxxxxH
0.9
1
1.1
s
Orderable part number TPS36xxxxxxI
9
10
11
s
tWDO
Watchdog timeout delay
tD
s
t
MR_RES
Propagation delay from MR low to reset assertion
VDD ≥ VIT– + 0.2 V,
MR = V
MR_H to V
MR_L
100
ns
t
MR_tD
Delay from MR release to reset deassert
VDD = 3.3 V,
MR = V
MR_L to V
MR_H
tD
s
tP_HL measured from threshold trip point (VIT–) to RESET assert. VIT+ = VIT– + VHYS
Specified by design parameter. When VDD starts from less than the specified minimum VDD and then exceeds VIT+, reset is deasserted after the startup delay (tSTRT) + tD delay.
VDD voltage transitions from (VIT– - 10%) to (VIT– + 10%)
At 1.04 V ≤ VDD ≤ 6 V, MR = Open, RESET pull-up resistor (Rpull-up) = 100 kΩ to VDD, WDO pull-up resistor (Rpull-up) = 100 kΩ to VDD, output RESET / WDO load (CLOAD) = 10 pF and over operating free-air temperature range –40℃ to 125℃, unless otherwise noted. VDD ramp rate ≤ 1 V/µs. Typical values are at TA = 25℃
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
tSTRT
Startup delay(4)
500
µs
tP_HL
RESET detect delay for VDD falling below VIT–
VDD : (VIT+ + 10%) to (VIT– – 10%)#GUID-XXXXXXXX-SF0T-XXXX-XXXX-000000244582/A_SUPERVISOR_VVCM_7_TIMINGREQ_FOOTER4_SF1_SF1
30
50
µs
tSD
Watchdog startup delay
Orderable part number TPS36xA, TPS36xG
0
ms
Orderable part number TPS36xB, TPS36xH
180
200
220
Orderable part number TPS36xC, TPS36xI
450
500
550
Orderable part number TPS36xD, TPS36xJ
0.9
1
1.1
s
Orderable part number TPS36xE, TPS36xK
4.5
5
5.5
Orderable part number TPS36xF, TPS36xL
9
10
11
tD
Reset time delay #GUID-XXXXXXXX-SF0T-XXXX-XXXX-000000244582/A_SUPERVISOR_VVCM_7_TIMINGREQ_FOOTER3_SF1_SF1
Orderable part number TPS36xxxxxxB
1.6
2
2.4
ms
Orderable part number TPS36xxxxxxC
9
10
11
ms
Orderable part number TPS36xxxxxxD
22.5
25
27.5
ms
Orderable part number TPS36xxxxxxE
45
50
55
ms
Orderable part number TPS36xxxxxxF
90
100
110
ms
Orderable part number TPS36xxxxxxG
180
200
220
ms
Orderable part number TPS36xxxxxxH
0.9
1
1.1
s
Orderable part number TPS36xxxxxxI
9
10
11
s
tWDO
Watchdog timeout delay
tD
s
t
MR_RES
Propagation delay from MR low to reset assertion
VDD ≥ VIT– + 0.2 V,
MR = V
MR_H to V
MR_L
100
ns
t
MR_tD
Delay from MR release to reset deassert
VDD = 3.3 V,
MR = V
MR_L to V
MR_H
tD
s
At 1.04 V ≤ VDD ≤ 6 V, MR = Open, RESET pull-up resistor (Rpull-up) = 100 kΩ to VDD, WDO pull-up resistor (Rpull-up) = 100 kΩ to VDD, output RESET / WDO load (CLOAD) = 10 pF and over operating free-air temperature range –40℃ to 125℃, unless otherwise noted. VDD ramp rate ≤ 1 V/µs. Typical values are at TA = 25℃DDMR RESETpull-upWDOpull-upLOADA
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
tSTRT
Startup delay(4)
500
µs
tP_HL
RESET detect delay for VDD falling below VIT–
VDD : (VIT+ + 10%) to (VIT– – 10%)#GUID-XXXXXXXX-SF0T-XXXX-XXXX-000000244582/A_SUPERVISOR_VVCM_7_TIMINGREQ_FOOTER4_SF1_SF1
30
50
µs
tSD
Watchdog startup delay
Orderable part number TPS36xA, TPS36xG
0
ms
Orderable part number TPS36xB, TPS36xH
180
200
220
Orderable part number TPS36xC, TPS36xI
450
500
550
Orderable part number TPS36xD, TPS36xJ
0.9
1
1.1
s
Orderable part number TPS36xE, TPS36xK
4.5
5
5.5
Orderable part number TPS36xF, TPS36xL
9
10
11
tD
Reset time delay #GUID-XXXXXXXX-SF0T-XXXX-XXXX-000000244582/A_SUPERVISOR_VVCM_7_TIMINGREQ_FOOTER3_SF1_SF1
Orderable part number TPS36xxxxxxB
1.6
2
2.4
ms
Orderable part number TPS36xxxxxxC
9
10
11
ms
Orderable part number TPS36xxxxxxD
22.5
25
27.5
ms
Orderable part number TPS36xxxxxxE
45
50
55
ms
Orderable part number TPS36xxxxxxF
90
100
110
ms
Orderable part number TPS36xxxxxxG
180
200
220
ms
Orderable part number TPS36xxxxxxH
0.9
1
1.1
s
Orderable part number TPS36xxxxxxI
9
10
11
s
tWDO
Watchdog timeout delay
tD
s
t
MR_RES
Propagation delay from MR low to reset assertion
VDD ≥ VIT– + 0.2 V,
MR = V
MR_H to V
MR_L
100
ns
t
MR_tD
Delay from MR release to reset deassert
VDD = 3.3 V,
MR = V
MR_L to V
MR_H
tD
s
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
PARAMETERTEST CONDITIONSMINTYPMAXUNIT
tSTRT
Startup delay(4)
500
µs
tP_HL
RESET detect delay for VDD falling below VIT–
VDD : (VIT+ + 10%) to (VIT– – 10%)#GUID-XXXXXXXX-SF0T-XXXX-XXXX-000000244582/A_SUPERVISOR_VVCM_7_TIMINGREQ_FOOTER4_SF1_SF1
30
50
µs
tSD
Watchdog startup delay
Orderable part number TPS36xA, TPS36xG
0
ms
Orderable part number TPS36xB, TPS36xH
180
200
220
Orderable part number TPS36xC, TPS36xI
450
500
550
Orderable part number TPS36xD, TPS36xJ
0.9
1
1.1
s
Orderable part number TPS36xE, TPS36xK
4.5
5
5.5
Orderable part number TPS36xF, TPS36xL
9
10
11
tD
Reset time delay #GUID-XXXXXXXX-SF0T-XXXX-XXXX-000000244582/A_SUPERVISOR_VVCM_7_TIMINGREQ_FOOTER3_SF1_SF1
Orderable part number TPS36xxxxxxB
1.6
2
2.4
ms
Orderable part number TPS36xxxxxxC
9
10
11
ms
Orderable part number TPS36xxxxxxD
22.5
25
27.5
ms
Orderable part number TPS36xxxxxxE
45
50
55
ms
Orderable part number TPS36xxxxxxF
90
100
110
ms
Orderable part number TPS36xxxxxxG
180
200
220
ms
Orderable part number TPS36xxxxxxH
0.9
1
1.1
s
Orderable part number TPS36xxxxxxI
9
10
11
s
tWDO
Watchdog timeout delay
tD
s
t
MR_RES
Propagation delay from MR low to reset assertion
VDD ≥ VIT– + 0.2 V,
MR = V
MR_H to V
MR_L
100
ns
t
MR_tD
Delay from MR release to reset deassert
VDD = 3.3 V,
MR = V
MR_L to V
MR_H
tD
s
tSTRT
Startup delay(4)
500
µs
tSTRT
STRTStartup delay(4)
(4)
500µs
tP_HL
RESET detect delay for VDD falling below VIT–
VDD : (VIT+ + 10%) to (VIT– – 10%)#GUID-XXXXXXXX-SF0T-XXXX-XXXX-000000244582/A_SUPERVISOR_VVCM_7_TIMINGREQ_FOOTER4_SF1_SF1
30
50
µs
tP_HL
P_HLRESET detect delay for VDD falling below VIT–
IT–VDD : (VIT+ + 10%) to (VIT– – 10%)#GUID-XXXXXXXX-SF0T-XXXX-XXXX-000000244582/A_SUPERVISOR_VVCM_7_TIMINGREQ_FOOTER4_SF1_SF1
DD IT+ IT–#GUID-XXXXXXXX-SF0T-XXXX-XXXX-000000244582/A_SUPERVISOR_VVCM_7_TIMINGREQ_FOOTER4_SF1_SF13050µs
tSD
Watchdog startup delay
Orderable part number TPS36xA, TPS36xG
0
ms
tSD
SDWatchdog startup delayOrderable part number TPS36xA, TPS36xG0ms
Orderable part number TPS36xB, TPS36xH
180
200
220
Orderable part number TPS36xB, TPS36xH180200220
Orderable part number TPS36xC, TPS36xI
450
500
550
Orderable part number TPS36xC, TPS36xI450500550
Orderable part number TPS36xD, TPS36xJ
0.9
1
1.1
s
Orderable part number TPS36xD, TPS36xJ0.911.1s
Orderable part number TPS36xE, TPS36xK
4.5
5
5.5
Orderable part number TPS36xE, TPS36xK4.555.5
Orderable part number TPS36xF, TPS36xL
9
10
11
Orderable part number TPS36xF, TPS36xL91011
tD
Reset time delay #GUID-XXXXXXXX-SF0T-XXXX-XXXX-000000244582/A_SUPERVISOR_VVCM_7_TIMINGREQ_FOOTER3_SF1_SF1
Orderable part number TPS36xxxxxxB
1.6
2
2.4
ms
tD
DReset time delay #GUID-XXXXXXXX-SF0T-XXXX-XXXX-000000244582/A_SUPERVISOR_VVCM_7_TIMINGREQ_FOOTER3_SF1_SF1
#GUID-XXXXXXXX-SF0T-XXXX-XXXX-000000244582/A_SUPERVISOR_VVCM_7_TIMINGREQ_FOOTER3_SF1_SF1Orderable part number TPS36xxxxxxB1.622.4ms
Orderable part number TPS36xxxxxxC
9
10
11
ms
Orderable part number TPS36xxxxxxC91011ms
Orderable part number TPS36xxxxxxD
22.5
25
27.5
ms
Orderable part number TPS36xxxxxxD22.52527.5ms
Orderable part number TPS36xxxxxxE
45
50
55
ms
Orderable part number TPS36xxxxxxE455055ms
Orderable part number TPS36xxxxxxF
90
100
110
ms
Orderable part number TPS36xxxxxxF90100110ms
Orderable part number TPS36xxxxxxG
180
200
220
ms
Orderable part number TPS36xxxxxxG180200220ms
Orderable part number TPS36xxxxxxH
0.9
1
1.1
s
Orderable part number TPS36xxxxxxH0.911.1s
Orderable part number TPS36xxxxxxI
9
10
11
s
Orderable part number TPS36xxxxxxI91011s
tWDO
Watchdog timeout delay
tD
s
tWDO
WDOWatchdog timeout delaytD
Ds
t
MR_RES
Propagation delay from MR low to reset assertion
VDD ≥ VIT– + 0.2 V,
MR = V
MR_H to V
MR_L
100
ns
t
MR_RES
MR_RESMRPropagation delay from MR low to reset assertionMRVDD ≥ VIT– + 0.2 V,
MR = V
MR_H to V
MR_L
DDIT–MR
MR_H MR
MR_LMR100ns
t
MR_tD
Delay from MR release to reset deassert
VDD = 3.3 V,
MR = V
MR_L to V
MR_H
tD
s
t
MR_tD
MR_tDMRDelay from MR release to reset deassertMR VDD = 3.3 V,
MR = V
MR_L to V
MR_H
DDMR
MR_L MR
MR_H MRtD
Ds
tP_HL measured from threshold trip point (VIT–) to RESET assert. VIT+ = VIT– + VHYS
Specified by design parameter. When VDD starts from less than the specified minimum VDD and then exceeds VIT+, reset is deasserted after the startup delay (tSTRT) + tD delay.
VDD voltage transitions from (VIT– - 10%) to (VIT– + 10%)
tP_HL measured from threshold trip point (VIT–) to RESET assert. VIT+ = VIT– + VHYS
P_HLIT–IT+IT–HYSSpecified by design parameter. When VDD starts from less than the specified minimum VDD and then exceeds VIT+, reset is deasserted after the startup delay (tSTRT) + tD delay.DDIT+STRTDVDD voltage transitions from (VIT– - 10%) to (VIT– + 10%)IT– IT–
Timing Diagrams
*
Added a footnote to for tINIT
no
Functional Timing Diagram
Timing Diagrams
*
Added a footnote to for tINIT
no
*
Added a footnote to for tINIT
no
*
Added a footnote to for tINIT
no
*Added a footnote to for tINIT
INITno
Functional Timing Diagram
Functional Timing Diagram
Functional Timing Diagram
Functional Timing Diagram
Typical Characteristics
all curves are taken at TA = 25°C
(unless otherwise noted)
VIT- Accuracy vs Temperature
VIT- Accuracy
Histogram
VIT- Hysteresis Vs Temperature
Supply Glitch Immunity vs Overdrive
Timer Accuracy vs
Temperature
Timer Accuracy Histogram
tWC vs Capacitance
tD vs Capacitance
RESET VOL vs I
sink, VDD = 1.5 V
WDO VOL vs I
sink, VDD = 1.5 V
RESET VOL vs I sink, VDD = 3.3 V
WDO VOL vs I sink, VDD = 3.3 V
RESET VOH vs I source, VDD = 2.0 V
WDO VOH vs I source, VDD = 2.0 V
RESET VOH vs I source, VDD = 6.0 V
WDO VOH vs I source, VDD = 6.0 V
Supply Current
vs Power-Supply Voltage
Typical Characteristics
all curves are taken at TA = 25°C
(unless otherwise noted)
VIT- Accuracy vs Temperature
VIT- Accuracy
Histogram
VIT- Hysteresis Vs Temperature
Supply Glitch Immunity vs Overdrive
Timer Accuracy vs
Temperature
Timer Accuracy Histogram
tWC vs Capacitance
tD vs Capacitance
RESET VOL vs I
sink, VDD = 1.5 V
WDO VOL vs I
sink, VDD = 1.5 V
RESET VOL vs I sink, VDD = 3.3 V
WDO VOL vs I sink, VDD = 3.3 V
RESET VOH vs I source, VDD = 2.0 V
WDO VOH vs I source, VDD = 2.0 V
RESET VOH vs I source, VDD = 6.0 V
WDO VOH vs I source, VDD = 6.0 V
Supply Current
vs Power-Supply Voltage
all curves are taken at TA = 25°C
(unless otherwise noted)
VIT- Accuracy vs Temperature
VIT- Accuracy
Histogram
VIT- Hysteresis Vs Temperature
Supply Glitch Immunity vs Overdrive
Timer Accuracy vs
Temperature
Timer Accuracy Histogram
tWC vs Capacitance
tD vs Capacitance
RESET VOL vs I
sink, VDD = 1.5 V
WDO VOL vs I
sink, VDD = 1.5 V
RESET VOL vs I sink, VDD = 3.3 V
WDO VOL vs I sink, VDD = 3.3 V
RESET VOH vs I source, VDD = 2.0 V
WDO VOH vs I source, VDD = 2.0 V
RESET VOH vs I source, VDD = 6.0 V
WDO VOH vs I source, VDD = 6.0 V
Supply Current
vs Power-Supply Voltage
all curves are taken at TA = 25°C
(unless otherwise noted)A
VIT- Accuracy vs Temperature
VIT- Accuracy
Histogram
VIT- Hysteresis Vs Temperature
Supply Glitch Immunity vs Overdrive
Timer Accuracy vs
Temperature
Timer Accuracy Histogram
tWC vs Capacitance
tD vs Capacitance
RESET VOL vs I
sink, VDD = 1.5 V
WDO VOL vs I
sink, VDD = 1.5 V
RESET VOL vs I sink, VDD = 3.3 V
WDO VOL vs I sink, VDD = 3.3 V
RESET VOH vs I source, VDD = 2.0 V
WDO VOH vs I source, VDD = 2.0 V
RESET VOH vs I source, VDD = 6.0 V
WDO VOH vs I source, VDD = 6.0 V
Supply Current
vs Power-Supply Voltage
VIT- Accuracy vs Temperature
VIT- Accuracy vs TemperatureIT-
VIT- Accuracy
Histogram
VIT- Accuracy
HistogramIT-
VIT- Hysteresis Vs Temperature
VIT- Hysteresis Vs TemperatureIT-
Supply Glitch Immunity vs Overdrive
Supply Glitch Immunity vs Overdrive
Timer Accuracy vs
Temperature
Timer Accuracy vs
Temperature
Timer Accuracy Histogram
Timer Accuracy Histogram
tWC vs Capacitance
tWC vs CapacitanceWC
tD vs Capacitance
tD vs CapacitanceD
RESET VOL vs I
sink, VDD = 1.5 V
RESET VOL vs I
sink, VDD = 1.5 VOLsinkDD
WDO VOL vs I
sink, VDD = 1.5 V
WDO VOL vs I
sink, VDD = 1.5 VOLsinkDD
RESET VOL vs I sink, VDD = 3.3 V
RESET VOL vs I sink, VDD = 3.3 VOLsinkDD
WDO VOL vs I sink, VDD = 3.3 V
WDO VOL vs I sink, VDD = 3.3 VOLsinkDD
RESET VOH vs I source, VDD = 2.0 V
RESET VOH vs I source, VDD = 2.0 VOHsourceDD
WDO VOH vs I source, VDD = 2.0 V
WDO VOH vs I source, VDD = 2.0 VOHsourceDD
RESET VOH vs I source, VDD = 6.0 V
RESET VOH vs I source, VDD = 6.0 VOHsourceDD
WDO VOH vs I source, VDD = 6.0 V
WDO VOH vs I source, VDD = 6.0 VOHsourceDD
Supply Current
vs Power-Supply Voltage
Supply Current
vs Power-Supply Voltage
Detailed Description
Overview
The TPS36-Q1 is a high-accuracy
under voltage supervisor with an integrated
window watchdog timer device. The device
family supports multiple features related to watchdog operation in a compact 8 pin SOT23 package. The devices are
available in 4 different
pinout configurations. Each pinout offers access to different features to meet the various
application requirements. The device family is rated for
-Q100 applications.
Functional Block Diagrams
Pinout Option A
Pinout Option B
Pinout Option C
Pinout Option D
Feature Description
Voltage Supervisor
The TPS36-Q1 offers high accuracy under voltage supervisor function at very low quiescent current. The voltage supervisor function is always active. After the device powers up from VDD < VPOR, the RESET and WDO outputs will be actively driven when VDD is greater than VPOR. The device starts monitoring the supply level when the VDD voltage is greater than 1.04 V. The device will hold the RESET pin asserted for tSTRT + tD time after the VDD > VIT+ (VIT- + VHYS). Refer
for the tD value computation. For a capacitor based tD delay option, the RESET will be asserted for tSTRT + 2 msec time if the CRST pin is open.
Device pinout options A to C offer only RESET output. In these devices the internal RESET output from supervisor and WDO output from watchdog timer are ANDed together to drive the external RESET output.
The supervisor offers wide range of fixed
monitoring thresholds (VIT-) from 1.05 V to 5.40 V in steps of 50 mV. The
device asserts the RESET output when the VDD signal falls below VIT-
threshold. The device offers hysteresis functionality for voltage supervision. This
ensures the supply has recovered above the monitoring threshold before the RESET
output is deasserted. The TPS36-Q1 typical voltage hysteresis
(VHYS) is 5%. Along with the voltage hysteresis, the device keeps the
RESET output asserted for time duration tD after the supply has risen
above VIT+. The RESET output assert duration changes from tD
to tSTRT + tD if the VDD signal is ramping from voltage <
VPOR. The tD time duration can be programmable using an
external capacitor or fixed time options offered by the device.
The typical timing behavior for a voltage
supervisor and the RESET output is showcased in . The voltage
supervisor monitoring output has higher priority over watchdog functionality. If the
device voltage supervisor output is asserted, the watchdog functionality will be
disabled including WDO assert control. The device resumes watchdog related
functionality only after the supply is stable and the tD time duration
has elapsed.
Voltage Supervisor Timing Diagram
Window Watchdog Timer
The TPS36-Q1 offers high precision window watchdog timer monitoring. The device is available in multiple pinout options A to D which support multiple features to meet ever expanding needs of various applications. Ensure a correct pinout is selected to meet the application needs.
The window watchdog is active when the VDD voltage is higher than the VIT- + VHYS and the RESET is deasserted after the tD time. The watchdog stays active as long as VDD > VIT- and watchdog is enabled.
TPS36-Q1 family offers various startup time delay options to ensure enough time is available for the host to complete boot operation. Please refer
section for additional details.
The window watchdog timer frame consists of two
windows namely close window (tWC) followed by open window
(tWO). The device monitors the WDI pin for falling edge. User is expected
to provide a valid falling edge on WDI pin in the open window. Refer
to
arrive at the relevant close window and open window values needed for application.
The timer value is reset when a valid falling edge is detected on WDI pin in the
tWO time duration. An early fault is reported if a WDI falling edge
is detected in close window. A late fault is reported if WDI falling edge is not
detected in both close and open window. The device
asserts RESET output for pinout options A, B and C or WDO output for pinout
D for time tD
in event of watchdog fault. Refer
to
arrive at the relevant tD
value needed for application.
shows the basic operation for window watchdog timer operation. The TPS36-Q1 watchdog functionality supports multiple features. Details are available in following sub sections.
Window Watchdog Timer Operation
tWC (Close Window) Timer
The window watchdog frame consists of two sub
frames tWC followed by tWO. The host is not expected to drive
valid WDI transition during tWC time. A valid WDI transition during
tWC frame results in early fault condition and the WDO output is
asserted. RESET output is asserted if pinout does
not offer independent WDO output. The tWC timer for TPS36-Q1 can be set using an external capacitor connected between
CWD pin and GND pin. This feature is available with pinout options A or B.
Applications which are space constrained or need timer values which meet offered
timer options, can benefit when using pinout options C or D. The TPS36-Q1 offers multiple fixed timer options ranging from 1 msec
up-to 100 sec.
The TPS36-Q1 when using
capacitance based timer, senses the capacitance value during the power up or after a RESET event. The capacitor is
charged and discharged with known internal current source for one cycle to sense the
capacitance value. The sensed value is used to arrive at tWC timer for
the watchdog operation. This unique implementation helps reduce the continuous
charge and discharge current for the capacitor, thus reducing overall current
consumption. Continuous charge and discharge of capacitance creates wider dead time
(no watchdog monitor functionality) when capacitor is discharging. The dead time is
higher for high value of capacitance. The unique implementation of TPS36-Q1 helps avoid the dead time as the capacitance is not
continuously charging or discharging under normal operation. Ensure CCWD
is < 200 x CCRST for accurate calibration of capacitance. The close
time window is decided based on SETx pin combination and the CWD capacitance. #GUID-D3B3A4B6-F3FF-43A2-9270-9617951C20C1/TABLE_EPC_QP1_DVB to #GUID-D3B3A4B6-F3FF-43A2-9270-9617951C20C1/TABLE_MHQ_NQ1_DVB highlights the relationship between tWC in second and CWD capacitance
in farad. The tWC timer is 20% accurate for an ideal capacitor. Accuracy
of the capacitance will have additional impact on the tWC time. Ensure
the capacitance meets the recommended operating range. Capacitance outside the
recommended range can lead to incorrect operation of the device.
tWC Equation 1 SET Pin (Pin
Configuration A)
SET pin value
Equation
0
tWC (sec) = 79.2 x 106 x CCWD (F)
1
tWC (sec) = 39.6 x 106 x CCWD (F)
tWC Equation 2 SET Pin, WD-EN = 1
(Pin Configuration C, D)
SET Pin Value
Equation
00
tWC (sec) = 79.2 x 106 x CCWD (F)
01
tWC (sec) = 79.2 x 106 x CCWD (F)
10
tWC (sec) = 39.6 x 106 x CCWD (F)
11
tWC (sec) = 9.9 x 106 x CCWD (F)
tWC Equation 2 SET
Pin, WD-EN Not Available (Pin Configuration B)
SET Pin Value
Equation
00
tWC (sec) = 79.2 x 106 x CCWD
(F)
01
Watchdog disabled
10
tWC (sec) = 39.6 x 106 x CCWD
(F)
11
tWC (sec) = 9.9 x 106 x CCWD
(F)
The TPS36-Q1 also offers wide
selection of high accuracy fixed tWC timer options starting from 1 msec
to 100 sec including various industry standard values. The TPS36-Q1
fixed time options are ±10% accurate for tWC ≥ 10 msec. For
tWC < 10 msec, the accuracy is ±20%. tWC value relevant
to application can be identified from the orderable part number. Refer
to
identify mapping of orderable part number to tWC value.
tWO (Open Window) Timer
The window watchdog frame consists of
two sub frames tWC followed by tWO. The host is expected to
drive valid WDI transition during tWO time. A valid WDI transition before
beginning of tWO frame causes early fault condition. Failure to offer
valid WDI transition during tWC and tWO frames results in late
fault condition. When a fault condition is detected the WDO output is asserted. RESET output is asserted if pinout does not offer
independent WDO output.
The tWO value is derived
using tWC value and the window open time ratio value n. Equation highlights the relationship between tWO and
tWC. Refer to select available ratio
options.
tWO =
(n - 1) x tWC
Each orderable can offer up to 3 ratio
options based on the available SET pins. Refer to identify mapping of ratio
value to SET pin control. The maximum tWO value is limited to 640 second.
Ensure selected tWC and ratio combination does not lead to tWO
value greater than 640 second.
Watchdog Enable Disable Operation
The TPS36-Q1 supports
watchdog enable or disable functionality. This functionality is critical for
different use cases as listed below.
Disable watchdog during firmware update to avoid host RESET.
Disable watchdog during software step-by-step debug operation.
Disable watchdog when performing critical task to avoid watchdog error
interrupt.
Keep watchdog disabled until host boots up.
The TPS36-Q1 supports
watchdog enable or disable functionality through either WD-EN pin (pin configuration
C,D) or SET[1:0] = 0b'01 (pin configuration B) logic combination. For a given pinout only one of these two methods is
available for the user to disable watchdog operation.
For a pinout which offers a WD-EN pin,
the watchdog enable disable functionality is controlled by the logic state of WD-EN
pin. Drive WD-EN = 1 to enable the watchdog operation or drive WD-EN = 0 to disable
the watchdog operation. The WD-EN pin can be toggled any time during the device
operation. The diagram
shows timing behavior with WD-EN pin control.
Watchdog Enable: WD-EN Pin
Control
SET[1:0] = 0b'01 combination can be
used to disable watchdog operation with a pinout which offers SET1 and SET0 pins,
but does not include WD-EN pin. The SET pin logic states can be changed at any time
during watchdog operation. Refer
section for additional details regarding SET[1:0] pin behavior.
Pinout options A, B offer watchdog timer control using a
capacitance connected between CWD and GND pin. A capacitance value higher than
recommended or connect to GND leads to watchdog functionality getting disabled.
Capacitance based disable operation overrides the other two options mentioned above.
Changing capacitance on the fly does not enable or disable watchdog operation. A
power supply recycle
or device recovery after UV fault, MR low event is needed
to detect change in capacitance.
Ongoing watchdog frame is terminated
when watchdog is disabled. WDO stays deasserted when watchdog operation is disabled.
For a pinout with only RESET output, the RESET can
assert if supply supervisor error occurs. When
enabled the device immediately enters tWC
frame and start watchdog
monitoring operation.
tSD Watchdog Start Up Delay
The TPS36-Q1 supports watchdog
startup delay feature. This feature is activated after power up or after a RESET assert event or after WDO
assert event. When tSD frame is active, the device monitors the WDI pin
but the WDO output is not asserted. This feature allows time for the host complete
boot process before watchdog monitoring can take over. The start up delay helps
avoid unexpected WDO or RESET assert events
during boot. The tSD time is predetermined based on the device part
number selected. Refer
section
for details to map the part number to tSD time. Pinout option A, B are available only in no delay or 10 sec
start up delay options.
The tSD frame is complete when the time
duration selected for tSD is over or host provides a valid transition on
the WDI pin. The host must provide a valid transition on the WDI pin during
tSD time. The device exits the tSD frame and enters
watchdog monitoring phase after valid WDI transition. Failure to provide valid
transition on WDI pin triggers the watchdog error by asserting the WDO output
pin. For devices with
only RESET output, the RESET pin is asserted.
The tSD frame is not initiated when the watchdog functionality is enabled using WD-EN pin or SET[1:0] pin or WDI float functionality as described in
section.
shows the
operation for tSD time frame.
tSD Frame
Behavior
SET Pin Behavior
The TPS36-Q1 offers one or two
SET pins based on the pinout option selected. SET
pins offer flexibility to the user to program the
tWO timer on the fly to meet various
application requirements. Typical use cases where
SET pin can be used are
Use wide open window timer when host is in sleep mode, change to small timeout operation when host is operational. Watchdog can be used to wake up the host after long duration to perform the application related activities before going back to sleep.
Change to wide open window timer when performing system critical tasks to ensure watchdog does not interrupt the critical task. Change timer to application specified interval after the critical task is complete.
The tWO timer value for the device is
combination of tWC timer selection based on the CWD pin or fixed timer
value along with SET pin logic level. The tWC timer value is decided
based on the Watchdog Close Time selector in the
section.
The SET pin logic level is decoded during the device power up. The SET pin value can
be changed any time during the operation. SETx pin change which leads to change of
watchdog timer value or enable disable state, terminates the ongoing watchdog frame
immediately. SETx pins can be updated when WDO or RESET output is
asserted as well. The updated tWO timer value will be applied after
output is deasserted and the tSD timer is over or terminated.
For a pinout which offers only SET0 pin to the user, the tWO ratio value is decided based on the Watchdog Open Time Ratio selector field in the orderable part number. Refer
for available options. showcases an example of the tWO values for different SET0 logic levels when using Watchdog Close Time setting as option D = 10 msec.
tWO Values with SET0 Pin Only (Pin
Configuration A)
Watchdog Open Time Ratio Selection
tWO
SET0 =
0
SET0 =
1
A
10 msec
30 msec
B
30 msec
70 msec
C
70 msec
150 msec
D
150 msec
310 msec
E
310 msec
630 msec
F
630 msec
1270 msec
Pinout which offer both SET0 & SET1 pins to the user, the tWO ratio value is decided based on the Watchdog Open Time Ratio selector field in the orderable part number. Refer
for available options. Two SETx pins offer 3 different time scaling options. The SET[1:0] = 0b'01 combination disables the watchdog operation. showcases an example of the tWO values for different SET[1:0] logic levels when using Watchdog Close Time setting as option G = 100 msec. The package pin out selected does not offer WD-EN pin.
tWO Values with SET0 & SET1
Pins, WD-EN Pin Not Available (Pin Configuration
B)
Watchdog Open Time Ratio selection
tWO
SET[1:0]
= 0b'00
SET[1:0]
= 0b'01
SET[1:0]
= 0b'10
SET[1:0]
= 0b'11
A
100 msec
Watchdog disable
300 msec
1500 msec
B
300 msec
Watchdog disable
700 msec
3100 msec
C
700 msec
Watchdog disable
1500 msec
6300 msec
D
1500 msec
Watchdog disable
3100 msec
12700 msec
E
3100 msec
Watchdog disable
6300 msec
25500 msec
F
6300 msec
Watchdog disable
12700 msec
51100 msec
Example for Watchdog Close Time setting = 100 msec.
Selected pinout option can offer WD-EN pin along
with SET[1:0] pins (Pin Configuration C, D). With
this pinout, the WD-EN pin controls watchdog
enable and disable operation. The SET[1:0] = 0b'01
combination operates as SET[1:0] = 0b'00.
Ensure the tWO value with SETx ratio does not exceed 640 sec. If a selection of close window timer and ratio results in tWO > 640 sec, the timer value will be restricted to 640 sec.
to
show the timing behavior with respect to SETx
status changes.
Watchdog Behavior with SETx Pin Status
Watchdog Operation with 2 SET Pins
Watchdog Operation with 1 SET Pin
Manual RESET
The TPS36-Q1 supports manual reset functionality using MR pin. MR pin when driven with voltage lower than 0.3 x VDD, asserts the RESET output. The MR pin has 100 kΩ pull up to VDD. The MR pin can be left floating. The internal pull up will ensure the output is not asserted due to MR pin trigger.
The output is deasserted after MR pin voltage rises above 0.7 x VDD voltage and time tD is elapsed. Refer for more details.
MR Pin Response
RESET and WDO Output
The TPS36-Q1 device can offer RESET or
RESET with independent WDO output pin. The output configuration is dependent on the
pinout variant selected. For a pinout which has only RESET output, the RESET output
is asserted when VDD voltage is below the monitored threshold or
MR pin voltage is lower than threshold or watchdog timer
error is detected. For a pinout which has independent RESET and WDO output pins, the
RESET output is asserted when VDD voltage is below the monitored threshold or
MR pin voltage is lower than threshold. WDO output is
asserted only when watchdog timer error is detected. RESET error has higher priority
than WDO error. If RESET is asserted when WDO is asserted, the device deasserts the
WDO pin and watchdog is disabled until RESET pin is deasserted and startup delay
frame is terminated.
The output will be asserted for tD
time when any relevant events
described above are detected. The time tD
can be programmed by
connecting a capacitor between CRST pin and GND or device will assert tD
for fixed time duration as
selected by orderable part number. Refer
section for all
available options.
describes the relationship between capacitor value and the time tD
. Ensure the capacitance meets
the recommended operating range. Capacitance outside the recommended range can lead
to incorrect operation of the device.
t
D
(sec) = 4.95 x
106 x CCRST (F)
TPS36-Q1 also offers
a unique option of latched output. An orderable with latched output will hold the
output in asserted state indefinitely until the device is power cycled or the error
condition is addressed. If the output is latched due to
voltage supervisor undervoltage detection, the output latch will be released
when VDD voltage rises above the VIT- + VHYS level.
If the output is latched
due to MR pin low voltage, the output latch will be released
when MR pin voltage rises above 0.7 x VDD level. If
the output is latched due to watchdog timer error, the output latch will be released
when a WDI negative edge is detected or the device is shutdown and powered up again.
shows
timing behavior of the device with latched output configuration.
Output Latch Timing Behavior
Device Functional Modes
#GUID-B008A25A-278A-4B38-AFBB-A738DE66DE26/A_1467996961_SHEET1
summarizes the functional modes of the TPS36-Q1.
Device Functional
Modes
VDD
WATCHDOG STATUS
WDI
WDO
RESET
VDD <
VPOR
Not Applicable
—
Undefined
Undefined
VPOR ≤
VDD < VIT-
Not Applicable
Ignored
High
Low
VDD ≥ VIT+
Disabled
Ignored
High
High
Enabled
tWC(max) ≤
tpulse
1 ≤ tWC(max) + tWO(min)
High
High
Enabled
tWC(max) >
tpulse
1
Low
High
Enabled
tWC(max) +
tWO(max) < tpulse
1
Low
High
Where tpulse is the time between falling edges on
WDI.
Detailed Description
Overview
The TPS36-Q1 is a high-accuracy
under voltage supervisor with an integrated
window watchdog timer device. The device
family supports multiple features related to watchdog operation in a compact 8 pin SOT23 package. The devices are
available in 4 different
pinout configurations. Each pinout offers access to different features to meet the various
application requirements. The device family is rated for
-Q100 applications.
Overview
The TPS36-Q1 is a high-accuracy
under voltage supervisor with an integrated
window watchdog timer device. The device
family supports multiple features related to watchdog operation in a compact 8 pin SOT23 package. The devices are
available in 4 different
pinout configurations. Each pinout offers access to different features to meet the various
application requirements. The device family is rated for
-Q100 applications.
The TPS36-Q1 is a high-accuracy
under voltage supervisor with an integrated
window watchdog timer device. The device
family supports multiple features related to watchdog operation in a compact 8 pin SOT23 package. The devices are
available in 4 different
pinout configurations. Each pinout offers access to different features to meet the various
application requirements. The device family is rated for
-Q100 applications.
The TPS36-Q1 is a high-accuracy
under voltage supervisor with an integrated
window watchdog timer device. The device
family supports multiple features related to watchdog operation in a compact 8 pin SOT23 package. The devices are
available in 4 different
pinout configurations. Each pinout offers access to different features to meet the various
application requirements. The device family is rated for
-Q100 applications.
TPS36-Q1under voltage supervisor with an integrated window 4The device family is rated for
-Q100 applications.
Functional Block Diagrams
Pinout Option A
Pinout Option B
Pinout Option C
Pinout Option D
Functional Block Diagrams
Pinout Option A
Pinout Option B
Pinout Option C
Pinout Option D
Pinout Option A
Pinout Option B
Pinout Option C
Pinout Option D
Pinout Option A
Pinout Option A
Pinout Option B
Pinout Option B
Pinout Option C
Pinout Option C
Pinout Option D
Pinout Option D
Feature Description
Voltage Supervisor
The TPS36-Q1 offers high accuracy under voltage supervisor function at very low quiescent current. The voltage supervisor function is always active. After the device powers up from VDD < VPOR, the RESET and WDO outputs will be actively driven when VDD is greater than VPOR. The device starts monitoring the supply level when the VDD voltage is greater than 1.04 V. The device will hold the RESET pin asserted for tSTRT + tD time after the VDD > VIT+ (VIT- + VHYS). Refer
for the tD value computation. For a capacitor based tD delay option, the RESET will be asserted for tSTRT + 2 msec time if the CRST pin is open.
Device pinout options A to C offer only RESET output. In these devices the internal RESET output from supervisor and WDO output from watchdog timer are ANDed together to drive the external RESET output.
The supervisor offers wide range of fixed
monitoring thresholds (VIT-) from 1.05 V to 5.40 V in steps of 50 mV. The
device asserts the RESET output when the VDD signal falls below VIT-
threshold. The device offers hysteresis functionality for voltage supervision. This
ensures the supply has recovered above the monitoring threshold before the RESET
output is deasserted. The TPS36-Q1 typical voltage hysteresis
(VHYS) is 5%. Along with the voltage hysteresis, the device keeps the
RESET output asserted for time duration tD after the supply has risen
above VIT+. The RESET output assert duration changes from tD
to tSTRT + tD if the VDD signal is ramping from voltage <
VPOR. The tD time duration can be programmable using an
external capacitor or fixed time options offered by the device.
The typical timing behavior for a voltage
supervisor and the RESET output is showcased in . The voltage
supervisor monitoring output has higher priority over watchdog functionality. If the
device voltage supervisor output is asserted, the watchdog functionality will be
disabled including WDO assert control. The device resumes watchdog related
functionality only after the supply is stable and the tD time duration
has elapsed.
Voltage Supervisor Timing Diagram
Window Watchdog Timer
The TPS36-Q1 offers high precision window watchdog timer monitoring. The device is available in multiple pinout options A to D which support multiple features to meet ever expanding needs of various applications. Ensure a correct pinout is selected to meet the application needs.
The window watchdog is active when the VDD voltage is higher than the VIT- + VHYS and the RESET is deasserted after the tD time. The watchdog stays active as long as VDD > VIT- and watchdog is enabled.
TPS36-Q1 family offers various startup time delay options to ensure enough time is available for the host to complete boot operation. Please refer
section for additional details.
The window watchdog timer frame consists of two
windows namely close window (tWC) followed by open window
(tWO). The device monitors the WDI pin for falling edge. User is expected
to provide a valid falling edge on WDI pin in the open window. Refer
to
arrive at the relevant close window and open window values needed for application.
The timer value is reset when a valid falling edge is detected on WDI pin in the
tWO time duration. An early fault is reported if a WDI falling edge
is detected in close window. A late fault is reported if WDI falling edge is not
detected in both close and open window. The device
asserts RESET output for pinout options A, B and C or WDO output for pinout
D for time tD
in event of watchdog fault. Refer
to
arrive at the relevant tD
value needed for application.
shows the basic operation for window watchdog timer operation. The TPS36-Q1 watchdog functionality supports multiple features. Details are available in following sub sections.
Window Watchdog Timer Operation
tWC (Close Window) Timer
The window watchdog frame consists of two sub
frames tWC followed by tWO. The host is not expected to drive
valid WDI transition during tWC time. A valid WDI transition during
tWC frame results in early fault condition and the WDO output is
asserted. RESET output is asserted if pinout does
not offer independent WDO output. The tWC timer for TPS36-Q1 can be set using an external capacitor connected between
CWD pin and GND pin. This feature is available with pinout options A or B.
Applications which are space constrained or need timer values which meet offered
timer options, can benefit when using pinout options C or D. The TPS36-Q1 offers multiple fixed timer options ranging from 1 msec
up-to 100 sec.
The TPS36-Q1 when using
capacitance based timer, senses the capacitance value during the power up or after a RESET event. The capacitor is
charged and discharged with known internal current source for one cycle to sense the
capacitance value. The sensed value is used to arrive at tWC timer for
the watchdog operation. This unique implementation helps reduce the continuous
charge and discharge current for the capacitor, thus reducing overall current
consumption. Continuous charge and discharge of capacitance creates wider dead time
(no watchdog monitor functionality) when capacitor is discharging. The dead time is
higher for high value of capacitance. The unique implementation of TPS36-Q1 helps avoid the dead time as the capacitance is not
continuously charging or discharging under normal operation. Ensure CCWD
is < 200 x CCRST for accurate calibration of capacitance. The close
time window is decided based on SETx pin combination and the CWD capacitance. #GUID-D3B3A4B6-F3FF-43A2-9270-9617951C20C1/TABLE_EPC_QP1_DVB to #GUID-D3B3A4B6-F3FF-43A2-9270-9617951C20C1/TABLE_MHQ_NQ1_DVB highlights the relationship between tWC in second and CWD capacitance
in farad. The tWC timer is 20% accurate for an ideal capacitor. Accuracy
of the capacitance will have additional impact on the tWC time. Ensure
the capacitance meets the recommended operating range. Capacitance outside the
recommended range can lead to incorrect operation of the device.
tWC Equation 1 SET Pin (Pin
Configuration A)
SET pin value
Equation
0
tWC (sec) = 79.2 x 106 x CCWD (F)
1
tWC (sec) = 39.6 x 106 x CCWD (F)
tWC Equation 2 SET Pin, WD-EN = 1
(Pin Configuration C, D)
SET Pin Value
Equation
00
tWC (sec) = 79.2 x 106 x CCWD (F)
01
tWC (sec) = 79.2 x 106 x CCWD (F)
10
tWC (sec) = 39.6 x 106 x CCWD (F)
11
tWC (sec) = 9.9 x 106 x CCWD (F)
tWC Equation 2 SET
Pin, WD-EN Not Available (Pin Configuration B)
SET Pin Value
Equation
00
tWC (sec) = 79.2 x 106 x CCWD
(F)
01
Watchdog disabled
10
tWC (sec) = 39.6 x 106 x CCWD
(F)
11
tWC (sec) = 9.9 x 106 x CCWD
(F)
The TPS36-Q1 also offers wide
selection of high accuracy fixed tWC timer options starting from 1 msec
to 100 sec including various industry standard values. The TPS36-Q1
fixed time options are ±10% accurate for tWC ≥ 10 msec. For
tWC < 10 msec, the accuracy is ±20%. tWC value relevant
to application can be identified from the orderable part number. Refer
to
identify mapping of orderable part number to tWC value.
tWO (Open Window) Timer
The window watchdog frame consists of
two sub frames tWC followed by tWO. The host is expected to
drive valid WDI transition during tWO time. A valid WDI transition before
beginning of tWO frame causes early fault condition. Failure to offer
valid WDI transition during tWC and tWO frames results in late
fault condition. When a fault condition is detected the WDO output is asserted. RESET output is asserted if pinout does not offer
independent WDO output.
The tWO value is derived
using tWC value and the window open time ratio value n. Equation highlights the relationship between tWO and
tWC. Refer to select available ratio
options.
tWO =
(n - 1) x tWC
Each orderable can offer up to 3 ratio
options based on the available SET pins. Refer to identify mapping of ratio
value to SET pin control. The maximum tWO value is limited to 640 second.
Ensure selected tWC and ratio combination does not lead to tWO
value greater than 640 second.
Watchdog Enable Disable Operation
The TPS36-Q1 supports
watchdog enable or disable functionality. This functionality is critical for
different use cases as listed below.
Disable watchdog during firmware update to avoid host RESET.
Disable watchdog during software step-by-step debug operation.
Disable watchdog when performing critical task to avoid watchdog error
interrupt.
Keep watchdog disabled until host boots up.
The TPS36-Q1 supports
watchdog enable or disable functionality through either WD-EN pin (pin configuration
C,D) or SET[1:0] = 0b'01 (pin configuration B) logic combination. For a given pinout only one of these two methods is
available for the user to disable watchdog operation.
For a pinout which offers a WD-EN pin,
the watchdog enable disable functionality is controlled by the logic state of WD-EN
pin. Drive WD-EN = 1 to enable the watchdog operation or drive WD-EN = 0 to disable
the watchdog operation. The WD-EN pin can be toggled any time during the device
operation. The diagram
shows timing behavior with WD-EN pin control.
Watchdog Enable: WD-EN Pin
Control
SET[1:0] = 0b'01 combination can be
used to disable watchdog operation with a pinout which offers SET1 and SET0 pins,
but does not include WD-EN pin. The SET pin logic states can be changed at any time
during watchdog operation. Refer
section for additional details regarding SET[1:0] pin behavior.
Pinout options A, B offer watchdog timer control using a
capacitance connected between CWD and GND pin. A capacitance value higher than
recommended or connect to GND leads to watchdog functionality getting disabled.
Capacitance based disable operation overrides the other two options mentioned above.
Changing capacitance on the fly does not enable or disable watchdog operation. A
power supply recycle
or device recovery after UV fault, MR low event is needed
to detect change in capacitance.
Ongoing watchdog frame is terminated
when watchdog is disabled. WDO stays deasserted when watchdog operation is disabled.
For a pinout with only RESET output, the RESET can
assert if supply supervisor error occurs. When
enabled the device immediately enters tWC
frame and start watchdog
monitoring operation.
tSD Watchdog Start Up Delay
The TPS36-Q1 supports watchdog
startup delay feature. This feature is activated after power up or after a RESET assert event or after WDO
assert event. When tSD frame is active, the device monitors the WDI pin
but the WDO output is not asserted. This feature allows time for the host complete
boot process before watchdog monitoring can take over. The start up delay helps
avoid unexpected WDO or RESET assert events
during boot. The tSD time is predetermined based on the device part
number selected. Refer
section
for details to map the part number to tSD time. Pinout option A, B are available only in no delay or 10 sec
start up delay options.
The tSD frame is complete when the time
duration selected for tSD is over or host provides a valid transition on
the WDI pin. The host must provide a valid transition on the WDI pin during
tSD time. The device exits the tSD frame and enters
watchdog monitoring phase after valid WDI transition. Failure to provide valid
transition on WDI pin triggers the watchdog error by asserting the WDO output
pin. For devices with
only RESET output, the RESET pin is asserted.
The tSD frame is not initiated when the watchdog functionality is enabled using WD-EN pin or SET[1:0] pin or WDI float functionality as described in
section.
shows the
operation for tSD time frame.
tSD Frame
Behavior
SET Pin Behavior
The TPS36-Q1 offers one or two
SET pins based on the pinout option selected. SET
pins offer flexibility to the user to program the
tWO timer on the fly to meet various
application requirements. Typical use cases where
SET pin can be used are
Use wide open window timer when host is in sleep mode, change to small timeout operation when host is operational. Watchdog can be used to wake up the host after long duration to perform the application related activities before going back to sleep.
Change to wide open window timer when performing system critical tasks to ensure watchdog does not interrupt the critical task. Change timer to application specified interval after the critical task is complete.
The tWO timer value for the device is
combination of tWC timer selection based on the CWD pin or fixed timer
value along with SET pin logic level. The tWC timer value is decided
based on the Watchdog Close Time selector in the
section.
The SET pin logic level is decoded during the device power up. The SET pin value can
be changed any time during the operation. SETx pin change which leads to change of
watchdog timer value or enable disable state, terminates the ongoing watchdog frame
immediately. SETx pins can be updated when WDO or RESET output is
asserted as well. The updated tWO timer value will be applied after
output is deasserted and the tSD timer is over or terminated.
For a pinout which offers only SET0 pin to the user, the tWO ratio value is decided based on the Watchdog Open Time Ratio selector field in the orderable part number. Refer
for available options. showcases an example of the tWO values for different SET0 logic levels when using Watchdog Close Time setting as option D = 10 msec.
tWO Values with SET0 Pin Only (Pin
Configuration A)
Watchdog Open Time Ratio Selection
tWO
SET0 =
0
SET0 =
1
A
10 msec
30 msec
B
30 msec
70 msec
C
70 msec
150 msec
D
150 msec
310 msec
E
310 msec
630 msec
F
630 msec
1270 msec
Pinout which offer both SET0 & SET1 pins to the user, the tWO ratio value is decided based on the Watchdog Open Time Ratio selector field in the orderable part number. Refer
for available options. Two SETx pins offer 3 different time scaling options. The SET[1:0] = 0b'01 combination disables the watchdog operation. showcases an example of the tWO values for different SET[1:0] logic levels when using Watchdog Close Time setting as option G = 100 msec. The package pin out selected does not offer WD-EN pin.
tWO Values with SET0 & SET1
Pins, WD-EN Pin Not Available (Pin Configuration
B)
Watchdog Open Time Ratio selection
tWO
SET[1:0]
= 0b'00
SET[1:0]
= 0b'01
SET[1:0]
= 0b'10
SET[1:0]
= 0b'11
A
100 msec
Watchdog disable
300 msec
1500 msec
B
300 msec
Watchdog disable
700 msec
3100 msec
C
700 msec
Watchdog disable
1500 msec
6300 msec
D
1500 msec
Watchdog disable
3100 msec
12700 msec
E
3100 msec
Watchdog disable
6300 msec
25500 msec
F
6300 msec
Watchdog disable
12700 msec
51100 msec
Example for Watchdog Close Time setting = 100 msec.
Selected pinout option can offer WD-EN pin along
with SET[1:0] pins (Pin Configuration C, D). With
this pinout, the WD-EN pin controls watchdog
enable and disable operation. The SET[1:0] = 0b'01
combination operates as SET[1:0] = 0b'00.
Ensure the tWO value with SETx ratio does not exceed 640 sec. If a selection of close window timer and ratio results in tWO > 640 sec, the timer value will be restricted to 640 sec.
to
show the timing behavior with respect to SETx
status changes.
Watchdog Behavior with SETx Pin Status
Watchdog Operation with 2 SET Pins
Watchdog Operation with 1 SET Pin
Manual RESET
The TPS36-Q1 supports manual reset functionality using MR pin. MR pin when driven with voltage lower than 0.3 x VDD, asserts the RESET output. The MR pin has 100 kΩ pull up to VDD. The MR pin can be left floating. The internal pull up will ensure the output is not asserted due to MR pin trigger.
The output is deasserted after MR pin voltage rises above 0.7 x VDD voltage and time tD is elapsed. Refer for more details.
MR Pin Response
RESET and WDO Output
The TPS36-Q1 device can offer RESET or
RESET with independent WDO output pin. The output configuration is dependent on the
pinout variant selected. For a pinout which has only RESET output, the RESET output
is asserted when VDD voltage is below the monitored threshold or
MR pin voltage is lower than threshold or watchdog timer
error is detected. For a pinout which has independent RESET and WDO output pins, the
RESET output is asserted when VDD voltage is below the monitored threshold or
MR pin voltage is lower than threshold. WDO output is
asserted only when watchdog timer error is detected. RESET error has higher priority
than WDO error. If RESET is asserted when WDO is asserted, the device deasserts the
WDO pin and watchdog is disabled until RESET pin is deasserted and startup delay
frame is terminated.
The output will be asserted for tD
time when any relevant events
described above are detected. The time tD
can be programmed by
connecting a capacitor between CRST pin and GND or device will assert tD
for fixed time duration as
selected by orderable part number. Refer
section for all
available options.
describes the relationship between capacitor value and the time tD
. Ensure the capacitance meets
the recommended operating range. Capacitance outside the recommended range can lead
to incorrect operation of the device.
t
D
(sec) = 4.95 x
106 x CCRST (F)
TPS36-Q1 also offers
a unique option of latched output. An orderable with latched output will hold the
output in asserted state indefinitely until the device is power cycled or the error
condition is addressed. If the output is latched due to
voltage supervisor undervoltage detection, the output latch will be released
when VDD voltage rises above the VIT- + VHYS level.
If the output is latched
due to MR pin low voltage, the output latch will be released
when MR pin voltage rises above 0.7 x VDD level. If
the output is latched due to watchdog timer error, the output latch will be released
when a WDI negative edge is detected or the device is shutdown and powered up again.
shows
timing behavior of the device with latched output configuration.
Output Latch Timing Behavior
Feature Description
Voltage Supervisor
The TPS36-Q1 offers high accuracy under voltage supervisor function at very low quiescent current. The voltage supervisor function is always active. After the device powers up from VDD < VPOR, the RESET and WDO outputs will be actively driven when VDD is greater than VPOR. The device starts monitoring the supply level when the VDD voltage is greater than 1.04 V. The device will hold the RESET pin asserted for tSTRT + tD time after the VDD > VIT+ (VIT- + VHYS). Refer
for the tD value computation. For a capacitor based tD delay option, the RESET will be asserted for tSTRT + 2 msec time if the CRST pin is open.
Device pinout options A to C offer only RESET output. In these devices the internal RESET output from supervisor and WDO output from watchdog timer are ANDed together to drive the external RESET output.
The supervisor offers wide range of fixed
monitoring thresholds (VIT-) from 1.05 V to 5.40 V in steps of 50 mV. The
device asserts the RESET output when the VDD signal falls below VIT-
threshold. The device offers hysteresis functionality for voltage supervision. This
ensures the supply has recovered above the monitoring threshold before the RESET
output is deasserted. The TPS36-Q1 typical voltage hysteresis
(VHYS) is 5%. Along with the voltage hysteresis, the device keeps the
RESET output asserted for time duration tD after the supply has risen
above VIT+. The RESET output assert duration changes from tD
to tSTRT + tD if the VDD signal is ramping from voltage <
VPOR. The tD time duration can be programmable using an
external capacitor or fixed time options offered by the device.
The typical timing behavior for a voltage
supervisor and the RESET output is showcased in . The voltage
supervisor monitoring output has higher priority over watchdog functionality. If the
device voltage supervisor output is asserted, the watchdog functionality will be
disabled including WDO assert control. The device resumes watchdog related
functionality only after the supply is stable and the tD time duration
has elapsed.
Voltage Supervisor Timing Diagram
Voltage Supervisor
The TPS36-Q1 offers high accuracy under voltage supervisor function at very low quiescent current. The voltage supervisor function is always active. After the device powers up from VDD < VPOR, the RESET and WDO outputs will be actively driven when VDD is greater than VPOR. The device starts monitoring the supply level when the VDD voltage is greater than 1.04 V. The device will hold the RESET pin asserted for tSTRT + tD time after the VDD > VIT+ (VIT- + VHYS). Refer
for the tD value computation. For a capacitor based tD delay option, the RESET will be asserted for tSTRT + 2 msec time if the CRST pin is open.
Device pinout options A to C offer only RESET output. In these devices the internal RESET output from supervisor and WDO output from watchdog timer are ANDed together to drive the external RESET output.
The supervisor offers wide range of fixed
monitoring thresholds (VIT-) from 1.05 V to 5.40 V in steps of 50 mV. The
device asserts the RESET output when the VDD signal falls below VIT-
threshold. The device offers hysteresis functionality for voltage supervision. This
ensures the supply has recovered above the monitoring threshold before the RESET
output is deasserted. The TPS36-Q1 typical voltage hysteresis
(VHYS) is 5%. Along with the voltage hysteresis, the device keeps the
RESET output asserted for time duration tD after the supply has risen
above VIT+. The RESET output assert duration changes from tD
to tSTRT + tD if the VDD signal is ramping from voltage <
VPOR. The tD time duration can be programmable using an
external capacitor or fixed time options offered by the device.
The typical timing behavior for a voltage
supervisor and the RESET output is showcased in . The voltage
supervisor monitoring output has higher priority over watchdog functionality. If the
device voltage supervisor output is asserted, the watchdog functionality will be
disabled including WDO assert control. The device resumes watchdog related
functionality only after the supply is stable and the tD time duration
has elapsed.
Voltage Supervisor Timing Diagram
The TPS36-Q1 offers high accuracy under voltage supervisor function at very low quiescent current. The voltage supervisor function is always active. After the device powers up from VDD < VPOR, the RESET and WDO outputs will be actively driven when VDD is greater than VPOR. The device starts monitoring the supply level when the VDD voltage is greater than 1.04 V. The device will hold the RESET pin asserted for tSTRT + tD time after the VDD > VIT+ (VIT- + VHYS). Refer
for the tD value computation. For a capacitor based tD delay option, the RESET will be asserted for tSTRT + 2 msec time if the CRST pin is open.
Device pinout options A to C offer only RESET output. In these devices the internal RESET output from supervisor and WDO output from watchdog timer are ANDed together to drive the external RESET output.
The supervisor offers wide range of fixed
monitoring thresholds (VIT-) from 1.05 V to 5.40 V in steps of 50 mV. The
device asserts the RESET output when the VDD signal falls below VIT-
threshold. The device offers hysteresis functionality for voltage supervision. This
ensures the supply has recovered above the monitoring threshold before the RESET
output is deasserted. The TPS36-Q1 typical voltage hysteresis
(VHYS) is 5%. Along with the voltage hysteresis, the device keeps the
RESET output asserted for time duration tD after the supply has risen
above VIT+. The RESET output assert duration changes from tD
to tSTRT + tD if the VDD signal is ramping from voltage <
VPOR. The tD time duration can be programmable using an
external capacitor or fixed time options offered by the device.
The typical timing behavior for a voltage
supervisor and the RESET output is showcased in . The voltage
supervisor monitoring output has higher priority over watchdog functionality. If the
device voltage supervisor output is asserted, the watchdog functionality will be
disabled including WDO assert control. The device resumes watchdog related
functionality only after the supply is stable and the tD time duration
has elapsed.
Voltage Supervisor Timing Diagram
The TPS36-Q1 offers high accuracy under voltage supervisor function at very low quiescent current. The voltage supervisor function is always active. After the device powers up from VDD < VPOR, the RESET and WDO outputs will be actively driven when VDD is greater than VPOR. The device starts monitoring the supply level when the VDD voltage is greater than 1.04 V. The device will hold the RESET pin asserted for tSTRT + tD time after the VDD > VIT+ (VIT- + VHYS). Refer
for the tD value computation. For a capacitor based tD delay option, the RESET will be asserted for tSTRT + 2 msec time if the CRST pin is open. TPS36-Q1PORPORSTRTDIT+IT-HYS
DDSTRTDevice pinout options A to C offer only RESET output. In these devices the internal RESET output from supervisor and WDO output from watchdog timer are ANDed together to drive the external RESET output.The supervisor offers wide range of fixed
monitoring thresholds (VIT-) from 1.05 V to 5.40 V in steps of 50 mV. The
device asserts the RESET output when the VDD signal falls below VIT-
threshold. The device offers hysteresis functionality for voltage supervision. This
ensures the supply has recovered above the monitoring threshold before the RESET
output is deasserted. The TPS36-Q1 typical voltage hysteresis
(VHYS) is 5%. Along with the voltage hysteresis, the device keeps the
RESET output asserted for time duration tD after the supply has risen
above VIT+. The RESET output assert duration changes from tD
to tSTRT + tD if the VDD signal is ramping from voltage <
VPOR. The tD time duration can be programmable using an
external capacitor or fixed time options offered by the device.IT-IT-TPS36-Q1HYSDIT+DSTRTDPORDThe typical timing behavior for a voltage
supervisor and the RESET output is showcased in . The voltage
supervisor monitoring output has higher priority over watchdog functionality. If the
device voltage supervisor output is asserted, the watchdog functionality will be
disabled including WDO assert control. The device resumes watchdog related
functionality only after the supply is stable and the tD time duration
has elapsed.D
Voltage Supervisor Timing Diagram
Voltage Supervisor Timing Diagram
Window Watchdog Timer
The TPS36-Q1 offers high precision window watchdog timer monitoring. The device is available in multiple pinout options A to D which support multiple features to meet ever expanding needs of various applications. Ensure a correct pinout is selected to meet the application needs.
The window watchdog is active when the VDD voltage is higher than the VIT- + VHYS and the RESET is deasserted after the tD time. The watchdog stays active as long as VDD > VIT- and watchdog is enabled.
TPS36-Q1 family offers various startup time delay options to ensure enough time is available for the host to complete boot operation. Please refer
section for additional details.
The window watchdog timer frame consists of two
windows namely close window (tWC) followed by open window
(tWO). The device monitors the WDI pin for falling edge. User is expected
to provide a valid falling edge on WDI pin in the open window. Refer
to
arrive at the relevant close window and open window values needed for application.
The timer value is reset when a valid falling edge is detected on WDI pin in the
tWO time duration. An early fault is reported if a WDI falling edge
is detected in close window. A late fault is reported if WDI falling edge is not
detected in both close and open window. The device
asserts RESET output for pinout options A, B and C or WDO output for pinout
D for time tD
in event of watchdog fault. Refer
to
arrive at the relevant tD
value needed for application.
shows the basic operation for window watchdog timer operation. The TPS36-Q1 watchdog functionality supports multiple features. Details are available in following sub sections.
Window Watchdog Timer Operation
tWC (Close Window) Timer
The window watchdog frame consists of two sub
frames tWC followed by tWO. The host is not expected to drive
valid WDI transition during tWC time. A valid WDI transition during
tWC frame results in early fault condition and the WDO output is
asserted. RESET output is asserted if pinout does
not offer independent WDO output. The tWC timer for TPS36-Q1 can be set using an external capacitor connected between
CWD pin and GND pin. This feature is available with pinout options A or B.
Applications which are space constrained or need timer values which meet offered
timer options, can benefit when using pinout options C or D. The TPS36-Q1 offers multiple fixed timer options ranging from 1 msec
up-to 100 sec.
The TPS36-Q1 when using
capacitance based timer, senses the capacitance value during the power up or after a RESET event. The capacitor is
charged and discharged with known internal current source for one cycle to sense the
capacitance value. The sensed value is used to arrive at tWC timer for
the watchdog operation. This unique implementation helps reduce the continuous
charge and discharge current for the capacitor, thus reducing overall current
consumption. Continuous charge and discharge of capacitance creates wider dead time
(no watchdog monitor functionality) when capacitor is discharging. The dead time is
higher for high value of capacitance. The unique implementation of TPS36-Q1 helps avoid the dead time as the capacitance is not
continuously charging or discharging under normal operation. Ensure CCWD
is < 200 x CCRST for accurate calibration of capacitance. The close
time window is decided based on SETx pin combination and the CWD capacitance. #GUID-D3B3A4B6-F3FF-43A2-9270-9617951C20C1/TABLE_EPC_QP1_DVB to #GUID-D3B3A4B6-F3FF-43A2-9270-9617951C20C1/TABLE_MHQ_NQ1_DVB highlights the relationship between tWC in second and CWD capacitance
in farad. The tWC timer is 20% accurate for an ideal capacitor. Accuracy
of the capacitance will have additional impact on the tWC time. Ensure
the capacitance meets the recommended operating range. Capacitance outside the
recommended range can lead to incorrect operation of the device.
tWC Equation 1 SET Pin (Pin
Configuration A)
SET pin value
Equation
0
tWC (sec) = 79.2 x 106 x CCWD (F)
1
tWC (sec) = 39.6 x 106 x CCWD (F)
tWC Equation 2 SET Pin, WD-EN = 1
(Pin Configuration C, D)
SET Pin Value
Equation
00
tWC (sec) = 79.2 x 106 x CCWD (F)
01
tWC (sec) = 79.2 x 106 x CCWD (F)
10
tWC (sec) = 39.6 x 106 x CCWD (F)
11
tWC (sec) = 9.9 x 106 x CCWD (F)
tWC Equation 2 SET
Pin, WD-EN Not Available (Pin Configuration B)
SET Pin Value
Equation
00
tWC (sec) = 79.2 x 106 x CCWD
(F)
01
Watchdog disabled
10
tWC (sec) = 39.6 x 106 x CCWD
(F)
11
tWC (sec) = 9.9 x 106 x CCWD
(F)
The TPS36-Q1 also offers wide
selection of high accuracy fixed tWC timer options starting from 1 msec
to 100 sec including various industry standard values. The TPS36-Q1
fixed time options are ±10% accurate for tWC ≥ 10 msec. For
tWC < 10 msec, the accuracy is ±20%. tWC value relevant
to application can be identified from the orderable part number. Refer
to
identify mapping of orderable part number to tWC value.
tWO (Open Window) Timer
The window watchdog frame consists of
two sub frames tWC followed by tWO. The host is expected to
drive valid WDI transition during tWO time. A valid WDI transition before
beginning of tWO frame causes early fault condition. Failure to offer
valid WDI transition during tWC and tWO frames results in late
fault condition. When a fault condition is detected the WDO output is asserted. RESET output is asserted if pinout does not offer
independent WDO output.
The tWO value is derived
using tWC value and the window open time ratio value n. Equation highlights the relationship between tWO and
tWC. Refer to select available ratio
options.
tWO =
(n - 1) x tWC
Each orderable can offer up to 3 ratio
options based on the available SET pins. Refer to identify mapping of ratio
value to SET pin control. The maximum tWO value is limited to 640 second.
Ensure selected tWC and ratio combination does not lead to tWO
value greater than 640 second.
Watchdog Enable Disable Operation
The TPS36-Q1 supports
watchdog enable or disable functionality. This functionality is critical for
different use cases as listed below.
Disable watchdog during firmware update to avoid host RESET.
Disable watchdog during software step-by-step debug operation.
Disable watchdog when performing critical task to avoid watchdog error
interrupt.
Keep watchdog disabled until host boots up.
The TPS36-Q1 supports
watchdog enable or disable functionality through either WD-EN pin (pin configuration
C,D) or SET[1:0] = 0b'01 (pin configuration B) logic combination. For a given pinout only one of these two methods is
available for the user to disable watchdog operation.
For a pinout which offers a WD-EN pin,
the watchdog enable disable functionality is controlled by the logic state of WD-EN
pin. Drive WD-EN = 1 to enable the watchdog operation or drive WD-EN = 0 to disable
the watchdog operation. The WD-EN pin can be toggled any time during the device
operation. The diagram
shows timing behavior with WD-EN pin control.
Watchdog Enable: WD-EN Pin
Control
SET[1:0] = 0b'01 combination can be
used to disable watchdog operation with a pinout which offers SET1 and SET0 pins,
but does not include WD-EN pin. The SET pin logic states can be changed at any time
during watchdog operation. Refer
section for additional details regarding SET[1:0] pin behavior.
Pinout options A, B offer watchdog timer control using a
capacitance connected between CWD and GND pin. A capacitance value higher than
recommended or connect to GND leads to watchdog functionality getting disabled.
Capacitance based disable operation overrides the other two options mentioned above.
Changing capacitance on the fly does not enable or disable watchdog operation. A
power supply recycle
or device recovery after UV fault, MR low event is needed
to detect change in capacitance.
Ongoing watchdog frame is terminated
when watchdog is disabled. WDO stays deasserted when watchdog operation is disabled.
For a pinout with only RESET output, the RESET can
assert if supply supervisor error occurs. When
enabled the device immediately enters tWC
frame and start watchdog
monitoring operation.
tSD Watchdog Start Up Delay
The TPS36-Q1 supports watchdog
startup delay feature. This feature is activated after power up or after a RESET assert event or after WDO
assert event. When tSD frame is active, the device monitors the WDI pin
but the WDO output is not asserted. This feature allows time for the host complete
boot process before watchdog monitoring can take over. The start up delay helps
avoid unexpected WDO or RESET assert events
during boot. The tSD time is predetermined based on the device part
number selected. Refer
section
for details to map the part number to tSD time. Pinout option A, B are available only in no delay or 10 sec
start up delay options.
The tSD frame is complete when the time
duration selected for tSD is over or host provides a valid transition on
the WDI pin. The host must provide a valid transition on the WDI pin during
tSD time. The device exits the tSD frame and enters
watchdog monitoring phase after valid WDI transition. Failure to provide valid
transition on WDI pin triggers the watchdog error by asserting the WDO output
pin. For devices with
only RESET output, the RESET pin is asserted.
The tSD frame is not initiated when the watchdog functionality is enabled using WD-EN pin or SET[1:0] pin or WDI float functionality as described in
section.
shows the
operation for tSD time frame.
tSD Frame
Behavior
SET Pin Behavior
The TPS36-Q1 offers one or two
SET pins based on the pinout option selected. SET
pins offer flexibility to the user to program the
tWO timer on the fly to meet various
application requirements. Typical use cases where
SET pin can be used are
Use wide open window timer when host is in sleep mode, change to small timeout operation when host is operational. Watchdog can be used to wake up the host after long duration to perform the application related activities before going back to sleep.
Change to wide open window timer when performing system critical tasks to ensure watchdog does not interrupt the critical task. Change timer to application specified interval after the critical task is complete.
The tWO timer value for the device is
combination of tWC timer selection based on the CWD pin or fixed timer
value along with SET pin logic level. The tWC timer value is decided
based on the Watchdog Close Time selector in the
section.
The SET pin logic level is decoded during the device power up. The SET pin value can
be changed any time during the operation. SETx pin change which leads to change of
watchdog timer value or enable disable state, terminates the ongoing watchdog frame
immediately. SETx pins can be updated when WDO or RESET output is
asserted as well. The updated tWO timer value will be applied after
output is deasserted and the tSD timer is over or terminated.
For a pinout which offers only SET0 pin to the user, the tWO ratio value is decided based on the Watchdog Open Time Ratio selector field in the orderable part number. Refer
for available options. showcases an example of the tWO values for different SET0 logic levels when using Watchdog Close Time setting as option D = 10 msec.
tWO Values with SET0 Pin Only (Pin
Configuration A)
Watchdog Open Time Ratio Selection
tWO
SET0 =
0
SET0 =
1
A
10 msec
30 msec
B
30 msec
70 msec
C
70 msec
150 msec
D
150 msec
310 msec
E
310 msec
630 msec
F
630 msec
1270 msec
Pinout which offer both SET0 & SET1 pins to the user, the tWO ratio value is decided based on the Watchdog Open Time Ratio selector field in the orderable part number. Refer
for available options. Two SETx pins offer 3 different time scaling options. The SET[1:0] = 0b'01 combination disables the watchdog operation. showcases an example of the tWO values for different SET[1:0] logic levels when using Watchdog Close Time setting as option G = 100 msec. The package pin out selected does not offer WD-EN pin.
tWO Values with SET0 & SET1
Pins, WD-EN Pin Not Available (Pin Configuration
B)
Watchdog Open Time Ratio selection
tWO
SET[1:0]
= 0b'00
SET[1:0]
= 0b'01
SET[1:0]
= 0b'10
SET[1:0]
= 0b'11
A
100 msec
Watchdog disable
300 msec
1500 msec
B
300 msec
Watchdog disable
700 msec
3100 msec
C
700 msec
Watchdog disable
1500 msec
6300 msec
D
1500 msec
Watchdog disable
3100 msec
12700 msec
E
3100 msec
Watchdog disable
6300 msec
25500 msec
F
6300 msec
Watchdog disable
12700 msec
51100 msec
Example for Watchdog Close Time setting = 100 msec.
Selected pinout option can offer WD-EN pin along
with SET[1:0] pins (Pin Configuration C, D). With
this pinout, the WD-EN pin controls watchdog
enable and disable operation. The SET[1:0] = 0b'01
combination operates as SET[1:0] = 0b'00.
Ensure the tWO value with SETx ratio does not exceed 640 sec. If a selection of close window timer and ratio results in tWO > 640 sec, the timer value will be restricted to 640 sec.
to
show the timing behavior with respect to SETx
status changes.
Watchdog Behavior with SETx Pin Status
Watchdog Operation with 2 SET Pins
Watchdog Operation with 1 SET Pin
Window Watchdog Timer
The TPS36-Q1 offers high precision window watchdog timer monitoring. The device is available in multiple pinout options A to D which support multiple features to meet ever expanding needs of various applications. Ensure a correct pinout is selected to meet the application needs.
The window watchdog is active when the VDD voltage is higher than the VIT- + VHYS and the RESET is deasserted after the tD time. The watchdog stays active as long as VDD > VIT- and watchdog is enabled.
TPS36-Q1 family offers various startup time delay options to ensure enough time is available for the host to complete boot operation. Please refer
section for additional details.
The window watchdog timer frame consists of two
windows namely close window (tWC) followed by open window
(tWO). The device monitors the WDI pin for falling edge. User is expected
to provide a valid falling edge on WDI pin in the open window. Refer
to
arrive at the relevant close window and open window values needed for application.
The timer value is reset when a valid falling edge is detected on WDI pin in the
tWO time duration. An early fault is reported if a WDI falling edge
is detected in close window. A late fault is reported if WDI falling edge is not
detected in both close and open window. The device
asserts RESET output for pinout options A, B and C or WDO output for pinout
D for time tD
in event of watchdog fault. Refer
to
arrive at the relevant tD
value needed for application.
shows the basic operation for window watchdog timer operation. The TPS36-Q1 watchdog functionality supports multiple features. Details are available in following sub sections.
Window Watchdog Timer Operation
The TPS36-Q1 offers high precision window watchdog timer monitoring. The device is available in multiple pinout options A to D which support multiple features to meet ever expanding needs of various applications. Ensure a correct pinout is selected to meet the application needs.
The window watchdog is active when the VDD voltage is higher than the VIT- + VHYS and the RESET is deasserted after the tD time. The watchdog stays active as long as VDD > VIT- and watchdog is enabled.
TPS36-Q1 family offers various startup time delay options to ensure enough time is available for the host to complete boot operation. Please refer
section for additional details.
The window watchdog timer frame consists of two
windows namely close window (tWC) followed by open window
(tWO). The device monitors the WDI pin for falling edge. User is expected
to provide a valid falling edge on WDI pin in the open window. Refer
to
arrive at the relevant close window and open window values needed for application.
The timer value is reset when a valid falling edge is detected on WDI pin in the
tWO time duration. An early fault is reported if a WDI falling edge
is detected in close window. A late fault is reported if WDI falling edge is not
detected in both close and open window. The device
asserts RESET output for pinout options A, B and C or WDO output for pinout
D for time tD
in event of watchdog fault. Refer
to
arrive at the relevant tD
value needed for application.
shows the basic operation for window watchdog timer operation. The TPS36-Q1 watchdog functionality supports multiple features. Details are available in following sub sections.
Window Watchdog Timer Operation
The TPS36-Q1 offers high precision window watchdog timer monitoring. The device is available in multiple pinout options A to D which support multiple features to meet ever expanding needs of various applications. Ensure a correct pinout is selected to meet the application needs.TPS36-Q1D
The window watchdog is active when the VDD voltage is higher than the VIT- + VHYS and the RESET is deasserted after the tD time. The watchdog stays active as long as VDD > VIT- and watchdog is enabled.
TPS36-Q1 family offers various startup time delay options to ensure enough time is available for the host to complete boot operation. Please refer
section for additional details.The window watchdog is active when the VDD voltage is higher than the VIT- + VHYS and the RESET is deasserted after the tD time. The watchdog stays active as long as VDD > VIT- and watchdog is enabled.IT-HYSDIT-TPS36-Q1
The window watchdog timer frame consists of two
windows namely close window (tWC) followed by open window
(tWO). The device monitors the WDI pin for falling edge. User is expected
to provide a valid falling edge on WDI pin in the open window. Refer
to
arrive at the relevant close window and open window values needed for application.
The timer value is reset when a valid falling edge is detected on WDI pin in the
tWO time duration. An early fault is reported if a WDI falling edge
is detected in close window. A late fault is reported if WDI falling edge is not
detected in both close and open window. The device
asserts RESET output for pinout options A, B and C or WDO output for pinout
D for time tD
in event of watchdog fault. Refer
to
arrive at the relevant tD
value needed for application.WCWO
WOThe device
asserts RESET output for pinout options A, B and C or WDO output for pinout
DtD
D
tD
D
shows the basic operation for window watchdog timer operation. The TPS36-Q1 watchdog functionality supports multiple features. Details are available in following sub sections.TPS36-Q1
Window Watchdog Timer Operation
Window Watchdog Timer Operation
tWC (Close Window) Timer
The window watchdog frame consists of two sub
frames tWC followed by tWO. The host is not expected to drive
valid WDI transition during tWC time. A valid WDI transition during
tWC frame results in early fault condition and the WDO output is
asserted. RESET output is asserted if pinout does
not offer independent WDO output. The tWC timer for TPS36-Q1 can be set using an external capacitor connected between
CWD pin and GND pin. This feature is available with pinout options A or B.
Applications which are space constrained or need timer values which meet offered
timer options, can benefit when using pinout options C or D. The TPS36-Q1 offers multiple fixed timer options ranging from 1 msec
up-to 100 sec.
The TPS36-Q1 when using
capacitance based timer, senses the capacitance value during the power up or after a RESET event. The capacitor is
charged and discharged with known internal current source for one cycle to sense the
capacitance value. The sensed value is used to arrive at tWC timer for
the watchdog operation. This unique implementation helps reduce the continuous
charge and discharge current for the capacitor, thus reducing overall current
consumption. Continuous charge and discharge of capacitance creates wider dead time
(no watchdog monitor functionality) when capacitor is discharging. The dead time is
higher for high value of capacitance. The unique implementation of TPS36-Q1 helps avoid the dead time as the capacitance is not
continuously charging or discharging under normal operation. Ensure CCWD
is < 200 x CCRST for accurate calibration of capacitance. The close
time window is decided based on SETx pin combination and the CWD capacitance. #GUID-D3B3A4B6-F3FF-43A2-9270-9617951C20C1/TABLE_EPC_QP1_DVB to #GUID-D3B3A4B6-F3FF-43A2-9270-9617951C20C1/TABLE_MHQ_NQ1_DVB highlights the relationship between tWC in second and CWD capacitance
in farad. The tWC timer is 20% accurate for an ideal capacitor. Accuracy
of the capacitance will have additional impact on the tWC time. Ensure
the capacitance meets the recommended operating range. Capacitance outside the
recommended range can lead to incorrect operation of the device.
tWC Equation 1 SET Pin (Pin
Configuration A)
SET pin value
Equation
0
tWC (sec) = 79.2 x 106 x CCWD (F)
1
tWC (sec) = 39.6 x 106 x CCWD (F)
tWC Equation 2 SET Pin, WD-EN = 1
(Pin Configuration C, D)
SET Pin Value
Equation
00
tWC (sec) = 79.2 x 106 x CCWD (F)
01
tWC (sec) = 79.2 x 106 x CCWD (F)
10
tWC (sec) = 39.6 x 106 x CCWD (F)
11
tWC (sec) = 9.9 x 106 x CCWD (F)
tWC Equation 2 SET
Pin, WD-EN Not Available (Pin Configuration B)
SET Pin Value
Equation
00
tWC (sec) = 79.2 x 106 x CCWD
(F)
01
Watchdog disabled
10
tWC (sec) = 39.6 x 106 x CCWD
(F)
11
tWC (sec) = 9.9 x 106 x CCWD
(F)
The TPS36-Q1 also offers wide
selection of high accuracy fixed tWC timer options starting from 1 msec
to 100 sec including various industry standard values. The TPS36-Q1
fixed time options are ±10% accurate for tWC ≥ 10 msec. For
tWC < 10 msec, the accuracy is ±20%. tWC value relevant
to application can be identified from the orderable part number. Refer
to
identify mapping of orderable part number to tWC value.
tWC (Close Window) TimerWC
The window watchdog frame consists of two sub
frames tWC followed by tWO. The host is not expected to drive
valid WDI transition during tWC time. A valid WDI transition during
tWC frame results in early fault condition and the WDO output is
asserted. RESET output is asserted if pinout does
not offer independent WDO output. The tWC timer for TPS36-Q1 can be set using an external capacitor connected between
CWD pin and GND pin. This feature is available with pinout options A or B.
Applications which are space constrained or need timer values which meet offered
timer options, can benefit when using pinout options C or D. The TPS36-Q1 offers multiple fixed timer options ranging from 1 msec
up-to 100 sec.
The TPS36-Q1 when using
capacitance based timer, senses the capacitance value during the power up or after a RESET event. The capacitor is
charged and discharged with known internal current source for one cycle to sense the
capacitance value. The sensed value is used to arrive at tWC timer for
the watchdog operation. This unique implementation helps reduce the continuous
charge and discharge current for the capacitor, thus reducing overall current
consumption. Continuous charge and discharge of capacitance creates wider dead time
(no watchdog monitor functionality) when capacitor is discharging. The dead time is
higher for high value of capacitance. The unique implementation of TPS36-Q1 helps avoid the dead time as the capacitance is not
continuously charging or discharging under normal operation. Ensure CCWD
is < 200 x CCRST for accurate calibration of capacitance. The close
time window is decided based on SETx pin combination and the CWD capacitance. #GUID-D3B3A4B6-F3FF-43A2-9270-9617951C20C1/TABLE_EPC_QP1_DVB to #GUID-D3B3A4B6-F3FF-43A2-9270-9617951C20C1/TABLE_MHQ_NQ1_DVB highlights the relationship between tWC in second and CWD capacitance
in farad. The tWC timer is 20% accurate for an ideal capacitor. Accuracy
of the capacitance will have additional impact on the tWC time. Ensure
the capacitance meets the recommended operating range. Capacitance outside the
recommended range can lead to incorrect operation of the device.
tWC Equation 1 SET Pin (Pin
Configuration A)
SET pin value
Equation
0
tWC (sec) = 79.2 x 106 x CCWD (F)
1
tWC (sec) = 39.6 x 106 x CCWD (F)
tWC Equation 2 SET Pin, WD-EN = 1
(Pin Configuration C, D)
SET Pin Value
Equation
00
tWC (sec) = 79.2 x 106 x CCWD (F)
01
tWC (sec) = 79.2 x 106 x CCWD (F)
10
tWC (sec) = 39.6 x 106 x CCWD (F)
11
tWC (sec) = 9.9 x 106 x CCWD (F)
tWC Equation 2 SET
Pin, WD-EN Not Available (Pin Configuration B)
SET Pin Value
Equation
00
tWC (sec) = 79.2 x 106 x CCWD
(F)
01
Watchdog disabled
10
tWC (sec) = 39.6 x 106 x CCWD
(F)
11
tWC (sec) = 9.9 x 106 x CCWD
(F)
The TPS36-Q1 also offers wide
selection of high accuracy fixed tWC timer options starting from 1 msec
to 100 sec including various industry standard values. The TPS36-Q1
fixed time options are ±10% accurate for tWC ≥ 10 msec. For
tWC < 10 msec, the accuracy is ±20%. tWC value relevant
to application can be identified from the orderable part number. Refer
to
identify mapping of orderable part number to tWC value.
The window watchdog frame consists of two sub
frames tWC followed by tWO. The host is not expected to drive
valid WDI transition during tWC time. A valid WDI transition during
tWC frame results in early fault condition and the WDO output is
asserted. RESET output is asserted if pinout does
not offer independent WDO output. The tWC timer for TPS36-Q1 can be set using an external capacitor connected between
CWD pin and GND pin. This feature is available with pinout options A or B.
Applications which are space constrained or need timer values which meet offered
timer options, can benefit when using pinout options C or D. The TPS36-Q1 offers multiple fixed timer options ranging from 1 msec
up-to 100 sec.
The TPS36-Q1 when using
capacitance based timer, senses the capacitance value during the power up or after a RESET event. The capacitor is
charged and discharged with known internal current source for one cycle to sense the
capacitance value. The sensed value is used to arrive at tWC timer for
the watchdog operation. This unique implementation helps reduce the continuous
charge and discharge current for the capacitor, thus reducing overall current
consumption. Continuous charge and discharge of capacitance creates wider dead time
(no watchdog monitor functionality) when capacitor is discharging. The dead time is
higher for high value of capacitance. The unique implementation of TPS36-Q1 helps avoid the dead time as the capacitance is not
continuously charging or discharging under normal operation. Ensure CCWD
is < 200 x CCRST for accurate calibration of capacitance. The close
time window is decided based on SETx pin combination and the CWD capacitance. #GUID-D3B3A4B6-F3FF-43A2-9270-9617951C20C1/TABLE_EPC_QP1_DVB to #GUID-D3B3A4B6-F3FF-43A2-9270-9617951C20C1/TABLE_MHQ_NQ1_DVB highlights the relationship between tWC in second and CWD capacitance
in farad. The tWC timer is 20% accurate for an ideal capacitor. Accuracy
of the capacitance will have additional impact on the tWC time. Ensure
the capacitance meets the recommended operating range. Capacitance outside the
recommended range can lead to incorrect operation of the device.
tWC Equation 1 SET Pin (Pin
Configuration A)
SET pin value
Equation
0
tWC (sec) = 79.2 x 106 x CCWD (F)
1
tWC (sec) = 39.6 x 106 x CCWD (F)
tWC Equation 2 SET Pin, WD-EN = 1
(Pin Configuration C, D)
SET Pin Value
Equation
00
tWC (sec) = 79.2 x 106 x CCWD (F)
01
tWC (sec) = 79.2 x 106 x CCWD (F)
10
tWC (sec) = 39.6 x 106 x CCWD (F)
11
tWC (sec) = 9.9 x 106 x CCWD (F)
tWC Equation 2 SET
Pin, WD-EN Not Available (Pin Configuration B)
SET Pin Value
Equation
00
tWC (sec) = 79.2 x 106 x CCWD
(F)
01
Watchdog disabled
10
tWC (sec) = 39.6 x 106 x CCWD
(F)
11
tWC (sec) = 9.9 x 106 x CCWD
(F)
The TPS36-Q1 also offers wide
selection of high accuracy fixed tWC timer options starting from 1 msec
to 100 sec including various industry standard values. The TPS36-Q1
fixed time options are ±10% accurate for tWC ≥ 10 msec. For
tWC < 10 msec, the accuracy is ±20%. tWC value relevant
to application can be identified from the orderable part number. Refer
to
identify mapping of orderable part number to tWC value.
The window watchdog frame consists of two sub
frames tWC followed by tWO. The host is not expected to drive
valid WDI transition during tWC time. A valid WDI transition during
tWC frame results in early fault condition and the WDO output is
asserted. RESET output is asserted if pinout does
not offer independent WDO output. The tWC timer for TPS36-Q1 can be set using an external capacitor connected between
CWD pin and GND pin. This feature is available with pinout options A or B.
Applications which are space constrained or need timer values which meet offered
timer options, can benefit when using pinout options C or D. The TPS36-Q1 offers multiple fixed timer options ranging from 1 msec
up-to 100 sec.WCWOWCWCRESET output is asserted if pinout does
not offer independent WDO output.WCTPS36-Q1s or DTPS36-Q1The TPS36-Q1 when using
capacitance based timer, senses the capacitance value during the power up or after a RESET event. The capacitor is
charged and discharged with known internal current source for one cycle to sense the
capacitance value. The sensed value is used to arrive at tWC timer for
the watchdog operation. This unique implementation helps reduce the continuous
charge and discharge current for the capacitor, thus reducing overall current
consumption. Continuous charge and discharge of capacitance creates wider dead time
(no watchdog monitor functionality) when capacitor is discharging. The dead time is
higher for high value of capacitance. The unique implementation of TPS36-Q1 helps avoid the dead time as the capacitance is not
continuously charging or discharging under normal operation. Ensure CCWD
is < 200 x CCRST for accurate calibration of capacitance. The close
time window is decided based on SETx pin combination and the CWD capacitance. #GUID-D3B3A4B6-F3FF-43A2-9270-9617951C20C1/TABLE_EPC_QP1_DVB to #GUID-D3B3A4B6-F3FF-43A2-9270-9617951C20C1/TABLE_MHQ_NQ1_DVB highlights the relationship between tWC in second and CWD capacitance
in farad. The tWC timer is 20% accurate for an ideal capacitor. Accuracy
of the capacitance will have additional impact on the tWC time. Ensure
the capacitance meets the recommended operating range. Capacitance outside the
recommended range can lead to incorrect operation of the device.TPS36-Q1 or after a RESET eventWCTPS36-Q1CWDCRST#GUID-D3B3A4B6-F3FF-43A2-9270-9617951C20C1/TABLE_EPC_QP1_DVB#GUID-D3B3A4B6-F3FF-43A2-9270-9617951C20C1/TABLE_MHQ_NQ1_DVBWCWCWC
tWC Equation 1 SET Pin (Pin
Configuration A)
SET pin value
Equation
0
tWC (sec) = 79.2 x 106 x CCWD (F)
1
tWC (sec) = 39.6 x 106 x CCWD (F)
tWC Equation 1 SET Pin (Pin
Configuration A)WC
SET pin value
Equation
0
tWC (sec) = 79.2 x 106 x CCWD (F)
1
tWC (sec) = 39.6 x 106 x CCWD (F)
SET pin value
Equation
SET pin value
Equation
SET pin valueEquation
0
tWC (sec) = 79.2 x 106 x CCWD (F)
1
tWC (sec) = 39.6 x 106 x CCWD (F)
0
tWC (sec) = 79.2 x 106 x CCWD (F)
0tWC (sec) = 79.2 x 106 x CCWD (F)WC6CWD
1
tWC (sec) = 39.6 x 106 x CCWD (F)
1tWC (sec) = 39.6 x 106 x CCWD (F)WC6CWD
tWC Equation 2 SET Pin, WD-EN = 1
(Pin Configuration C, D)
SET Pin Value
Equation
00
tWC (sec) = 79.2 x 106 x CCWD (F)
01
tWC (sec) = 79.2 x 106 x CCWD (F)
10
tWC (sec) = 39.6 x 106 x CCWD (F)
11
tWC (sec) = 9.9 x 106 x CCWD (F)
tWC Equation 2 SET Pin, WD-EN = 1
(Pin Configuration C, D)WC
SET Pin Value
Equation
00
tWC (sec) = 79.2 x 106 x CCWD (F)
01
tWC (sec) = 79.2 x 106 x CCWD (F)
10
tWC (sec) = 39.6 x 106 x CCWD (F)
11
tWC (sec) = 9.9 x 106 x CCWD (F)
SET Pin Value
Equation
SET Pin Value
Equation
SET Pin ValueEquation
00
tWC (sec) = 79.2 x 106 x CCWD (F)
01
tWC (sec) = 79.2 x 106 x CCWD (F)
10
tWC (sec) = 39.6 x 106 x CCWD (F)
11
tWC (sec) = 9.9 x 106 x CCWD (F)
00
tWC (sec) = 79.2 x 106 x CCWD (F)
00tWC (sec) = 79.2 x 106 x CCWD (F)WC6CWD
01
tWC (sec) = 79.2 x 106 x CCWD (F)
01tWC (sec) = 79.2 x 106 x CCWD (F)WC6CWD
10
tWC (sec) = 39.6 x 106 x CCWD (F)
10tWC (sec) = 39.6 x 106 x CCWD (F)WC6CWD
11
tWC (sec) = 9.9 x 106 x CCWD (F)
11tWC (sec) = 9.9 x 106 x CCWD (F)WC6CWD
tWC Equation 2 SET
Pin, WD-EN Not Available (Pin Configuration B)
SET Pin Value
Equation
00
tWC (sec) = 79.2 x 106 x CCWD
(F)
01
Watchdog disabled
10
tWC (sec) = 39.6 x 106 x CCWD
(F)
11
tWC (sec) = 9.9 x 106 x CCWD
(F)
tWC Equation 2 SET
Pin, WD-EN Not Available (Pin Configuration B)WC
SET Pin Value
Equation
00
tWC (sec) = 79.2 x 106 x CCWD
(F)
01
Watchdog disabled
10
tWC (sec) = 39.6 x 106 x CCWD
(F)
11
tWC (sec) = 9.9 x 106 x CCWD
(F)
SET Pin Value
Equation
SET Pin Value
Equation
SET Pin ValueEquation
00
tWC (sec) = 79.2 x 106 x CCWD
(F)
01
Watchdog disabled
10
tWC (sec) = 39.6 x 106 x CCWD
(F)
11
tWC (sec) = 9.9 x 106 x CCWD
(F)
00
tWC (sec) = 79.2 x 106 x CCWD
(F)
00tWC (sec) = 79.2 x 106 x CCWD
(F)WC6CWD
01
Watchdog disabled
01Watchdog disabled
10
tWC (sec) = 39.6 x 106 x CCWD
(F)
10tWC (sec) = 39.6 x 106 x CCWD
(F)WC6CWD
11
tWC (sec) = 9.9 x 106 x CCWD
(F)
11tWC (sec) = 9.9 x 106 x CCWD
(F)WC6CWDThe TPS36-Q1 also offers wide
selection of high accuracy fixed tWC timer options starting from 1 msec
to 100 sec including various industry standard values. The TPS36-Q1
fixed time options are ±10% accurate for tWC ≥ 10 msec. For
tWC < 10 msec, the accuracy is ±20%. tWC value relevant
to application can be identified from the orderable part number. Refer
to
identify mapping of orderable part number to tWC value.TPS36-Q1WCTPS36-Q1WCWCWC
WC
tWO (Open Window) Timer
The window watchdog frame consists of
two sub frames tWC followed by tWO. The host is expected to
drive valid WDI transition during tWO time. A valid WDI transition before
beginning of tWO frame causes early fault condition. Failure to offer
valid WDI transition during tWC and tWO frames results in late
fault condition. When a fault condition is detected the WDO output is asserted. RESET output is asserted if pinout does not offer
independent WDO output.
The tWO value is derived
using tWC value and the window open time ratio value n. Equation highlights the relationship between tWO and
tWC. Refer to select available ratio
options.
tWO =
(n - 1) x tWC
Each orderable can offer up to 3 ratio
options based on the available SET pins. Refer to identify mapping of ratio
value to SET pin control. The maximum tWO value is limited to 640 second.
Ensure selected tWC and ratio combination does not lead to tWO
value greater than 640 second.
tWO (Open Window) TimerWO
The window watchdog frame consists of
two sub frames tWC followed by tWO. The host is expected to
drive valid WDI transition during tWO time. A valid WDI transition before
beginning of tWO frame causes early fault condition. Failure to offer
valid WDI transition during tWC and tWO frames results in late
fault condition. When a fault condition is detected the WDO output is asserted. RESET output is asserted if pinout does not offer
independent WDO output.
The tWO value is derived
using tWC value and the window open time ratio value n. Equation highlights the relationship between tWO and
tWC. Refer to select available ratio
options.
tWO =
(n - 1) x tWC
Each orderable can offer up to 3 ratio
options based on the available SET pins. Refer to identify mapping of ratio
value to SET pin control. The maximum tWO value is limited to 640 second.
Ensure selected tWC and ratio combination does not lead to tWO
value greater than 640 second.
The window watchdog frame consists of
two sub frames tWC followed by tWO. The host is expected to
drive valid WDI transition during tWO time. A valid WDI transition before
beginning of tWO frame causes early fault condition. Failure to offer
valid WDI transition during tWC and tWO frames results in late
fault condition. When a fault condition is detected the WDO output is asserted. RESET output is asserted if pinout does not offer
independent WDO output.
The tWO value is derived
using tWC value and the window open time ratio value n. Equation highlights the relationship between tWO and
tWC. Refer to select available ratio
options.
tWO =
(n - 1) x tWC
Each orderable can offer up to 3 ratio
options based on the available SET pins. Refer to identify mapping of ratio
value to SET pin control. The maximum tWO value is limited to 640 second.
Ensure selected tWC and ratio combination does not lead to tWO
value greater than 640 second.
The window watchdog frame consists of
two sub frames tWC followed by tWO. The host is expected to
drive valid WDI transition during tWO time. A valid WDI transition before
beginning of tWO frame causes early fault condition. Failure to offer
valid WDI transition during tWC and tWO frames results in late
fault condition. When a fault condition is detected the WDO output is asserted. RESET output is asserted if pinout does not offer
independent WDO output.
WCWOWOWOWCWORESET output is asserted if pinout does not offer
independent WDO output.The tWO value is derived
using tWC value and the window open time ratio value n. Equation highlights the relationship between tWO and
tWC. Refer to select available ratio
options.WOWCnEquationWOWCtWO =
(n - 1) x tWC
WOnWCEach orderable can offer up to 3 ratio
options based on the available SET pins. Refer to identify mapping of ratio
value to SET pin control. The maximum tWO value is limited to 640 second.
Ensure selected tWC and ratio combination does not lead to tWO
value greater than 640 second.WOWCWO
Watchdog Enable Disable Operation
The TPS36-Q1 supports
watchdog enable or disable functionality. This functionality is critical for
different use cases as listed below.
Disable watchdog during firmware update to avoid host RESET.
Disable watchdog during software step-by-step debug operation.
Disable watchdog when performing critical task to avoid watchdog error
interrupt.
Keep watchdog disabled until host boots up.
The TPS36-Q1 supports
watchdog enable or disable functionality through either WD-EN pin (pin configuration
C,D) or SET[1:0] = 0b'01 (pin configuration B) logic combination. For a given pinout only one of these two methods is
available for the user to disable watchdog operation.
For a pinout which offers a WD-EN pin,
the watchdog enable disable functionality is controlled by the logic state of WD-EN
pin. Drive WD-EN = 1 to enable the watchdog operation or drive WD-EN = 0 to disable
the watchdog operation. The WD-EN pin can be toggled any time during the device
operation. The diagram
shows timing behavior with WD-EN pin control.
Watchdog Enable: WD-EN Pin
Control
SET[1:0] = 0b'01 combination can be
used to disable watchdog operation with a pinout which offers SET1 and SET0 pins,
but does not include WD-EN pin. The SET pin logic states can be changed at any time
during watchdog operation. Refer
section for additional details regarding SET[1:0] pin behavior.
Pinout options A, B offer watchdog timer control using a
capacitance connected between CWD and GND pin. A capacitance value higher than
recommended or connect to GND leads to watchdog functionality getting disabled.
Capacitance based disable operation overrides the other two options mentioned above.
Changing capacitance on the fly does not enable or disable watchdog operation. A
power supply recycle
or device recovery after UV fault, MR low event is needed
to detect change in capacitance.
Ongoing watchdog frame is terminated
when watchdog is disabled. WDO stays deasserted when watchdog operation is disabled.
For a pinout with only RESET output, the RESET can
assert if supply supervisor error occurs. When
enabled the device immediately enters tWC
frame and start watchdog
monitoring operation.
Watchdog Enable Disable Operation
The TPS36-Q1 supports
watchdog enable or disable functionality. This functionality is critical for
different use cases as listed below.
Disable watchdog during firmware update to avoid host RESET.
Disable watchdog during software step-by-step debug operation.
Disable watchdog when performing critical task to avoid watchdog error
interrupt.
Keep watchdog disabled until host boots up.
The TPS36-Q1 supports
watchdog enable or disable functionality through either WD-EN pin (pin configuration
C,D) or SET[1:0] = 0b'01 (pin configuration B) logic combination. For a given pinout only one of these two methods is
available for the user to disable watchdog operation.
For a pinout which offers a WD-EN pin,
the watchdog enable disable functionality is controlled by the logic state of WD-EN
pin. Drive WD-EN = 1 to enable the watchdog operation or drive WD-EN = 0 to disable
the watchdog operation. The WD-EN pin can be toggled any time during the device
operation. The diagram
shows timing behavior with WD-EN pin control.
Watchdog Enable: WD-EN Pin
Control
SET[1:0] = 0b'01 combination can be
used to disable watchdog operation with a pinout which offers SET1 and SET0 pins,
but does not include WD-EN pin. The SET pin logic states can be changed at any time
during watchdog operation. Refer
section for additional details regarding SET[1:0] pin behavior.
Pinout options A, B offer watchdog timer control using a
capacitance connected between CWD and GND pin. A capacitance value higher than
recommended or connect to GND leads to watchdog functionality getting disabled.
Capacitance based disable operation overrides the other two options mentioned above.
Changing capacitance on the fly does not enable or disable watchdog operation. A
power supply recycle
or device recovery after UV fault, MR low event is needed
to detect change in capacitance.
Ongoing watchdog frame is terminated
when watchdog is disabled. WDO stays deasserted when watchdog operation is disabled.
For a pinout with only RESET output, the RESET can
assert if supply supervisor error occurs. When
enabled the device immediately enters tWC
frame and start watchdog
monitoring operation.
The TPS36-Q1 supports
watchdog enable or disable functionality. This functionality is critical for
different use cases as listed below.
Disable watchdog during firmware update to avoid host RESET.
Disable watchdog during software step-by-step debug operation.
Disable watchdog when performing critical task to avoid watchdog error
interrupt.
Keep watchdog disabled until host boots up.
The TPS36-Q1 supports
watchdog enable or disable functionality through either WD-EN pin (pin configuration
C,D) or SET[1:0] = 0b'01 (pin configuration B) logic combination. For a given pinout only one of these two methods is
available for the user to disable watchdog operation.
For a pinout which offers a WD-EN pin,
the watchdog enable disable functionality is controlled by the logic state of WD-EN
pin. Drive WD-EN = 1 to enable the watchdog operation or drive WD-EN = 0 to disable
the watchdog operation. The WD-EN pin can be toggled any time during the device
operation. The diagram
shows timing behavior with WD-EN pin control.
Watchdog Enable: WD-EN Pin
Control
SET[1:0] = 0b'01 combination can be
used to disable watchdog operation with a pinout which offers SET1 and SET0 pins,
but does not include WD-EN pin. The SET pin logic states can be changed at any time
during watchdog operation. Refer
section for additional details regarding SET[1:0] pin behavior.
Pinout options A, B offer watchdog timer control using a
capacitance connected between CWD and GND pin. A capacitance value higher than
recommended or connect to GND leads to watchdog functionality getting disabled.
Capacitance based disable operation overrides the other two options mentioned above.
Changing capacitance on the fly does not enable or disable watchdog operation. A
power supply recycle
or device recovery after UV fault, MR low event is needed
to detect change in capacitance.
Ongoing watchdog frame is terminated
when watchdog is disabled. WDO stays deasserted when watchdog operation is disabled.
For a pinout with only RESET output, the RESET can
assert if supply supervisor error occurs. When
enabled the device immediately enters tWC
frame and start watchdog
monitoring operation.
The TPS36-Q1 supports
watchdog enable or disable functionality. This functionality is critical for
different use cases as listed below.TPS36-Q1
Disable watchdog during firmware update to avoid host RESET.
Disable watchdog during software step-by-step debug operation.
Disable watchdog when performing critical task to avoid watchdog error
interrupt.
Keep watchdog disabled until host boots up.
Disable watchdog during firmware update to avoid host RESET.Disable watchdog during software step-by-step debug operation.Disable watchdog when performing critical task to avoid watchdog error
interrupt.Keep watchdog disabled until host boots up.The TPS36-Q1 supports
watchdog enable or disable functionality through either WD-EN pin (pin configuration
C,D) or SET[1:0] = 0b'01 (pin configuration B) logic combination. For a given pinout only one of these two methods is
available for the user to disable watchdog operation.TPS36-Q1For a pinout which offers a WD-EN pin,
the watchdog enable disable functionality is controlled by the logic state of WD-EN
pin. Drive WD-EN = 1 to enable the watchdog operation or drive WD-EN = 0 to disable
the watchdog operation. The WD-EN pin can be toggled any time during the device
operation. The diagram
shows timing behavior with WD-EN pin control.
Watchdog Enable: WD-EN Pin
Control
Watchdog Enable: WD-EN Pin
ControlSET[1:0] = 0b'01 combination can be
used to disable watchdog operation with a pinout which offers SET1 and SET0 pins,
but does not include WD-EN pin. The SET pin logic states can be changed at any time
during watchdog operation. Refer
section for additional details regarding SET[1:0] pin behavior.
Pinout options A, B offer watchdog timer control using a
capacitance connected between CWD and GND pin. A capacitance value higher than
recommended or connect to GND leads to watchdog functionality getting disabled.
Capacitance based disable operation overrides the other two options mentioned above.
Changing capacitance on the fly does not enable or disable watchdog operation. A
power supply recycle
or device recovery after UV fault, MR low event is needed
to detect change in capacitance.
or device recovery after UV fault, MR low eventMROngoing watchdog frame is terminated
when watchdog is disabled. WDO stays deasserted when watchdog operation is disabled.
For a pinout with only RESET output, the RESET can
assert if supply supervisor error occurs. When
enabled the device immediately enters tWC
frame and start watchdog
monitoring operation.For a pinout with only RESET output, the RESET can
assert if supply supervisor error occurs. tWC
WC
tSD Watchdog Start Up Delay
The TPS36-Q1 supports watchdog
startup delay feature. This feature is activated after power up or after a RESET assert event or after WDO
assert event. When tSD frame is active, the device monitors the WDI pin
but the WDO output is not asserted. This feature allows time for the host complete
boot process before watchdog monitoring can take over. The start up delay helps
avoid unexpected WDO or RESET assert events
during boot. The tSD time is predetermined based on the device part
number selected. Refer
section
for details to map the part number to tSD time. Pinout option A, B are available only in no delay or 10 sec
start up delay options.
The tSD frame is complete when the time
duration selected for tSD is over or host provides a valid transition on
the WDI pin. The host must provide a valid transition on the WDI pin during
tSD time. The device exits the tSD frame and enters
watchdog monitoring phase after valid WDI transition. Failure to provide valid
transition on WDI pin triggers the watchdog error by asserting the WDO output
pin. For devices with
only RESET output, the RESET pin is asserted.
The tSD frame is not initiated when the watchdog functionality is enabled using WD-EN pin or SET[1:0] pin or WDI float functionality as described in
section.
shows the
operation for tSD time frame.
tSD Frame
Behavior
tSD Watchdog Start Up DelaySD
The TPS36-Q1 supports watchdog
startup delay feature. This feature is activated after power up or after a RESET assert event or after WDO
assert event. When tSD frame is active, the device monitors the WDI pin
but the WDO output is not asserted. This feature allows time for the host complete
boot process before watchdog monitoring can take over. The start up delay helps
avoid unexpected WDO or RESET assert events
during boot. The tSD time is predetermined based on the device part
number selected. Refer
section
for details to map the part number to tSD time. Pinout option A, B are available only in no delay or 10 sec
start up delay options.
The tSD frame is complete when the time
duration selected for tSD is over or host provides a valid transition on
the WDI pin. The host must provide a valid transition on the WDI pin during
tSD time. The device exits the tSD frame and enters
watchdog monitoring phase after valid WDI transition. Failure to provide valid
transition on WDI pin triggers the watchdog error by asserting the WDO output
pin. For devices with
only RESET output, the RESET pin is asserted.
The tSD frame is not initiated when the watchdog functionality is enabled using WD-EN pin or SET[1:0] pin or WDI float functionality as described in
section.
shows the
operation for tSD time frame.
tSD Frame
Behavior
The TPS36-Q1 supports watchdog
startup delay feature. This feature is activated after power up or after a RESET assert event or after WDO
assert event. When tSD frame is active, the device monitors the WDI pin
but the WDO output is not asserted. This feature allows time for the host complete
boot process before watchdog monitoring can take over. The start up delay helps
avoid unexpected WDO or RESET assert events
during boot. The tSD time is predetermined based on the device part
number selected. Refer
section
for details to map the part number to tSD time. Pinout option A, B are available only in no delay or 10 sec
start up delay options.
The tSD frame is complete when the time
duration selected for tSD is over or host provides a valid transition on
the WDI pin. The host must provide a valid transition on the WDI pin during
tSD time. The device exits the tSD frame and enters
watchdog monitoring phase after valid WDI transition. Failure to provide valid
transition on WDI pin triggers the watchdog error by asserting the WDO output
pin. For devices with
only RESET output, the RESET pin is asserted.
The tSD frame is not initiated when the watchdog functionality is enabled using WD-EN pin or SET[1:0] pin or WDI float functionality as described in
section.
shows the
operation for tSD time frame.
tSD Frame
Behavior
The TPS36-Q1 supports watchdog
startup delay feature. This feature is activated after power up or after a RESET assert event or after WDO
assert event. When tSD frame is active, the device monitors the WDI pin
but the WDO output is not asserted. This feature allows time for the host complete
boot process before watchdog monitoring can take over. The start up delay helps
avoid unexpected WDO or RESET assert events
during boot. The tSD time is predetermined based on the device part
number selected. Refer
section
for details to map the part number to tSD time. Pinout option A, B are available only in no delay or 10 sec
start up delay options.TPS36-Q1or after a RESET assert event SD or RESETSD
SDThe tSD frame is complete when the time
duration selected for tSD is over or host provides a valid transition on
the WDI pin. The host must provide a valid transition on the WDI pin during
tSD time. The device exits the tSD frame and enters
watchdog monitoring phase after valid WDI transition. Failure to provide valid
transition on WDI pin triggers the watchdog error by asserting the WDO output
pin. For devices with
only RESET output, the RESET pin is asserted.
SDSDSDSD For devices with
only RESET output, the RESET pin is asserted.The tSD frame is not initiated when the watchdog functionality is enabled using WD-EN pin or SET[1:0] pin or WDI float functionality as described in
section.SD
shows the
operation for tSD time frame.SD
tSD Frame
Behavior
tSD Frame
BehaviorSD
SET Pin Behavior
The TPS36-Q1 offers one or two
SET pins based on the pinout option selected. SET
pins offer flexibility to the user to program the
tWO timer on the fly to meet various
application requirements. Typical use cases where
SET pin can be used are
Use wide open window timer when host is in sleep mode, change to small timeout operation when host is operational. Watchdog can be used to wake up the host after long duration to perform the application related activities before going back to sleep.
Change to wide open window timer when performing system critical tasks to ensure watchdog does not interrupt the critical task. Change timer to application specified interval after the critical task is complete.
The tWO timer value for the device is
combination of tWC timer selection based on the CWD pin or fixed timer
value along with SET pin logic level. The tWC timer value is decided
based on the Watchdog Close Time selector in the
section.
The SET pin logic level is decoded during the device power up. The SET pin value can
be changed any time during the operation. SETx pin change which leads to change of
watchdog timer value or enable disable state, terminates the ongoing watchdog frame
immediately. SETx pins can be updated when WDO or RESET output is
asserted as well. The updated tWO timer value will be applied after
output is deasserted and the tSD timer is over or terminated.
For a pinout which offers only SET0 pin to the user, the tWO ratio value is decided based on the Watchdog Open Time Ratio selector field in the orderable part number. Refer
for available options. showcases an example of the tWO values for different SET0 logic levels when using Watchdog Close Time setting as option D = 10 msec.
tWO Values with SET0 Pin Only (Pin
Configuration A)
Watchdog Open Time Ratio Selection
tWO
SET0 =
0
SET0 =
1
A
10 msec
30 msec
B
30 msec
70 msec
C
70 msec
150 msec
D
150 msec
310 msec
E
310 msec
630 msec
F
630 msec
1270 msec
Pinout which offer both SET0 & SET1 pins to the user, the tWO ratio value is decided based on the Watchdog Open Time Ratio selector field in the orderable part number. Refer
for available options. Two SETx pins offer 3 different time scaling options. The SET[1:0] = 0b'01 combination disables the watchdog operation. showcases an example of the tWO values for different SET[1:0] logic levels when using Watchdog Close Time setting as option G = 100 msec. The package pin out selected does not offer WD-EN pin.
tWO Values with SET0 & SET1
Pins, WD-EN Pin Not Available (Pin Configuration
B)
Watchdog Open Time Ratio selection
tWO
SET[1:0]
= 0b'00
SET[1:0]
= 0b'01
SET[1:0]
= 0b'10
SET[1:0]
= 0b'11
A
100 msec
Watchdog disable
300 msec
1500 msec
B
300 msec
Watchdog disable
700 msec
3100 msec
C
700 msec
Watchdog disable
1500 msec
6300 msec
D
1500 msec
Watchdog disable
3100 msec
12700 msec
E
3100 msec
Watchdog disable
6300 msec
25500 msec
F
6300 msec
Watchdog disable
12700 msec
51100 msec
Example for Watchdog Close Time setting = 100 msec.
Selected pinout option can offer WD-EN pin along
with SET[1:0] pins (Pin Configuration C, D). With
this pinout, the WD-EN pin controls watchdog
enable and disable operation. The SET[1:0] = 0b'01
combination operates as SET[1:0] = 0b'00.
Ensure the tWO value with SETx ratio does not exceed 640 sec. If a selection of close window timer and ratio results in tWO > 640 sec, the timer value will be restricted to 640 sec.
to
show the timing behavior with respect to SETx
status changes.
Watchdog Behavior with SETx Pin Status
Watchdog Operation with 2 SET Pins
Watchdog Operation with 1 SET Pin
SET Pin Behavior
The TPS36-Q1 offers one or two
SET pins based on the pinout option selected. SET
pins offer flexibility to the user to program the
tWO timer on the fly to meet various
application requirements. Typical use cases where
SET pin can be used are
Use wide open window timer when host is in sleep mode, change to small timeout operation when host is operational. Watchdog can be used to wake up the host after long duration to perform the application related activities before going back to sleep.
Change to wide open window timer when performing system critical tasks to ensure watchdog does not interrupt the critical task. Change timer to application specified interval after the critical task is complete.
The tWO timer value for the device is
combination of tWC timer selection based on the CWD pin or fixed timer
value along with SET pin logic level. The tWC timer value is decided
based on the Watchdog Close Time selector in the
section.
The SET pin logic level is decoded during the device power up. The SET pin value can
be changed any time during the operation. SETx pin change which leads to change of
watchdog timer value or enable disable state, terminates the ongoing watchdog frame
immediately. SETx pins can be updated when WDO or RESET output is
asserted as well. The updated tWO timer value will be applied after
output is deasserted and the tSD timer is over or terminated.
For a pinout which offers only SET0 pin to the user, the tWO ratio value is decided based on the Watchdog Open Time Ratio selector field in the orderable part number. Refer
for available options. showcases an example of the tWO values for different SET0 logic levels when using Watchdog Close Time setting as option D = 10 msec.
tWO Values with SET0 Pin Only (Pin
Configuration A)
Watchdog Open Time Ratio Selection
tWO
SET0 =
0
SET0 =
1
A
10 msec
30 msec
B
30 msec
70 msec
C
70 msec
150 msec
D
150 msec
310 msec
E
310 msec
630 msec
F
630 msec
1270 msec
Pinout which offer both SET0 & SET1 pins to the user, the tWO ratio value is decided based on the Watchdog Open Time Ratio selector field in the orderable part number. Refer
for available options. Two SETx pins offer 3 different time scaling options. The SET[1:0] = 0b'01 combination disables the watchdog operation. showcases an example of the tWO values for different SET[1:0] logic levels when using Watchdog Close Time setting as option G = 100 msec. The package pin out selected does not offer WD-EN pin.
tWO Values with SET0 & SET1
Pins, WD-EN Pin Not Available (Pin Configuration
B)
Watchdog Open Time Ratio selection
tWO
SET[1:0]
= 0b'00
SET[1:0]
= 0b'01
SET[1:0]
= 0b'10
SET[1:0]
= 0b'11
A
100 msec
Watchdog disable
300 msec
1500 msec
B
300 msec
Watchdog disable
700 msec
3100 msec
C
700 msec
Watchdog disable
1500 msec
6300 msec
D
1500 msec
Watchdog disable
3100 msec
12700 msec
E
3100 msec
Watchdog disable
6300 msec
25500 msec
F
6300 msec
Watchdog disable
12700 msec
51100 msec
Example for Watchdog Close Time setting = 100 msec.
Selected pinout option can offer WD-EN pin along
with SET[1:0] pins (Pin Configuration C, D). With
this pinout, the WD-EN pin controls watchdog
enable and disable operation. The SET[1:0] = 0b'01
combination operates as SET[1:0] = 0b'00.
Ensure the tWO value with SETx ratio does not exceed 640 sec. If a selection of close window timer and ratio results in tWO > 640 sec, the timer value will be restricted to 640 sec.
to
show the timing behavior with respect to SETx
status changes.
Watchdog Behavior with SETx Pin Status
Watchdog Operation with 2 SET Pins
Watchdog Operation with 1 SET Pin
The TPS36-Q1 offers one or two
SET pins based on the pinout option selected. SET
pins offer flexibility to the user to program the
tWO timer on the fly to meet various
application requirements. Typical use cases where
SET pin can be used are
Use wide open window timer when host is in sleep mode, change to small timeout operation when host is operational. Watchdog can be used to wake up the host after long duration to perform the application related activities before going back to sleep.
Change to wide open window timer when performing system critical tasks to ensure watchdog does not interrupt the critical task. Change timer to application specified interval after the critical task is complete.
The tWO timer value for the device is
combination of tWC timer selection based on the CWD pin or fixed timer
value along with SET pin logic level. The tWC timer value is decided
based on the Watchdog Close Time selector in the
section.
The SET pin logic level is decoded during the device power up. The SET pin value can
be changed any time during the operation. SETx pin change which leads to change of
watchdog timer value or enable disable state, terminates the ongoing watchdog frame
immediately. SETx pins can be updated when WDO or RESET output is
asserted as well. The updated tWO timer value will be applied after
output is deasserted and the tSD timer is over or terminated.
For a pinout which offers only SET0 pin to the user, the tWO ratio value is decided based on the Watchdog Open Time Ratio selector field in the orderable part number. Refer
for available options. showcases an example of the tWO values for different SET0 logic levels when using Watchdog Close Time setting as option D = 10 msec.
tWO Values with SET0 Pin Only (Pin
Configuration A)
Watchdog Open Time Ratio Selection
tWO
SET0 =
0
SET0 =
1
A
10 msec
30 msec
B
30 msec
70 msec
C
70 msec
150 msec
D
150 msec
310 msec
E
310 msec
630 msec
F
630 msec
1270 msec
Pinout which offer both SET0 & SET1 pins to the user, the tWO ratio value is decided based on the Watchdog Open Time Ratio selector field in the orderable part number. Refer
for available options. Two SETx pins offer 3 different time scaling options. The SET[1:0] = 0b'01 combination disables the watchdog operation. showcases an example of the tWO values for different SET[1:0] logic levels when using Watchdog Close Time setting as option G = 100 msec. The package pin out selected does not offer WD-EN pin.
tWO Values with SET0 & SET1
Pins, WD-EN Pin Not Available (Pin Configuration
B)
Watchdog Open Time Ratio selection
tWO
SET[1:0]
= 0b'00
SET[1:0]
= 0b'01
SET[1:0]
= 0b'10
SET[1:0]
= 0b'11
A
100 msec
Watchdog disable
300 msec
1500 msec
B
300 msec
Watchdog disable
700 msec
3100 msec
C
700 msec
Watchdog disable
1500 msec
6300 msec
D
1500 msec
Watchdog disable
3100 msec
12700 msec
E
3100 msec
Watchdog disable
6300 msec
25500 msec
F
6300 msec
Watchdog disable
12700 msec
51100 msec
Example for Watchdog Close Time setting = 100 msec.
Selected pinout option can offer WD-EN pin along
with SET[1:0] pins (Pin Configuration C, D). With
this pinout, the WD-EN pin controls watchdog
enable and disable operation. The SET[1:0] = 0b'01
combination operates as SET[1:0] = 0b'00.
Ensure the tWO value with SETx ratio does not exceed 640 sec. If a selection of close window timer and ratio results in tWO > 640 sec, the timer value will be restricted to 640 sec.
to
show the timing behavior with respect to SETx
status changes.
Watchdog Behavior with SETx Pin Status
Watchdog Operation with 2 SET Pins
Watchdog Operation with 1 SET Pin
The TPS36-Q1 offers one or two
SET pins based on the pinout option selected. SET
pins offer flexibility to the user to program the
tWO timer on the fly to meet various
application requirements. Typical use cases where
SET pin can be used areTPS36-Q1WO
Use wide open window timer when host is in sleep mode, change to small timeout operation when host is operational. Watchdog can be used to wake up the host after long duration to perform the application related activities before going back to sleep.
Change to wide open window timer when performing system critical tasks to ensure watchdog does not interrupt the critical task. Change timer to application specified interval after the critical task is complete.
Use wide open window timer when host is in sleep mode, change to small timeout operation when host is operational. Watchdog can be used to wake up the host after long duration to perform the application related activities before going back to sleep.Change to wide open window timer when performing system critical tasks to ensure watchdog does not interrupt the critical task. Change timer to application specified interval after the critical task is complete.The tWO timer value for the device is
combination of tWC timer selection based on the CWD pin or fixed timer
value along with SET pin logic level. The tWC timer value is decided
based on the Watchdog Close Time selector in the
section.
The SET pin logic level is decoded during the device power up. The SET pin value can
be changed any time during the operation. SETx pin change which leads to change of
watchdog timer value or enable disable state, terminates the ongoing watchdog frame
immediately. SETx pins can be updated when WDO or RESET output is
asserted as well. The updated tWO timer value will be applied after
output is deasserted and the tSD timer is over or terminated.WOWCWC
or RESETWOSDFor a pinout which offers only SET0 pin to the user, the tWO ratio value is decided based on the Watchdog Open Time Ratio selector field in the orderable part number. Refer
for available options. showcases an example of the tWO values for different SET0 logic levels when using Watchdog Close Time setting as option D = 10 msec.WO
WO
tWO Values with SET0 Pin Only (Pin
Configuration A)
Watchdog Open Time Ratio Selection
tWO
SET0 =
0
SET0 =
1
A
10 msec
30 msec
B
30 msec
70 msec
C
70 msec
150 msec
D
150 msec
310 msec
E
310 msec
630 msec
F
630 msec
1270 msec
tWO Values with SET0 Pin Only (Pin
Configuration A)WO
Watchdog Open Time Ratio Selection
tWO
SET0 =
0
SET0 =
1
A
10 msec
30 msec
B
30 msec
70 msec
C
70 msec
150 msec
D
150 msec
310 msec
E
310 msec
630 msec
F
630 msec
1270 msec
Watchdog Open Time Ratio Selection
tWO
SET0 =
0
SET0 =
1
Watchdog Open Time Ratio Selection
tWO
Watchdog Open Time Ratio Selection
Watchdog Open Time Ratio Selection
tWO
tWO
WO
SET0 =
0
SET0 =
1
SET0 =
0
SET0 =
0
SET0 =
1
SET0 =
1
A
10 msec
30 msec
B
30 msec
70 msec
C
70 msec
150 msec
D
150 msec
310 msec
E
310 msec
630 msec
F
630 msec
1270 msec
A
10 msec
30 msec
A10 msec30 msec
B
30 msec
70 msec
B30 msec70 msec
C
70 msec
150 msec
C70 msec150 msec
D
150 msec
310 msec
D150 msec310 msec
E
310 msec
630 msec
E310 msec630 msec
F
630 msec
1270 msec
F630 msec1270 msecPinout which offer both SET0 & SET1 pins to the user, the tWO ratio value is decided based on the Watchdog Open Time Ratio selector field in the orderable part number. Refer
for available options. Two SETx pins offer 3 different time scaling options. The SET[1:0] = 0b'01 combination disables the watchdog operation. showcases an example of the tWO values for different SET[1:0] logic levels when using Watchdog Close Time setting as option G = 100 msec. The package pin out selected does not offer WD-EN pin.WO
WO
tWO Values with SET0 & SET1
Pins, WD-EN Pin Not Available (Pin Configuration
B)
Watchdog Open Time Ratio selection
tWO
SET[1:0]
= 0b'00
SET[1:0]
= 0b'01
SET[1:0]
= 0b'10
SET[1:0]
= 0b'11
A
100 msec
Watchdog disable
300 msec
1500 msec
B
300 msec
Watchdog disable
700 msec
3100 msec
C
700 msec
Watchdog disable
1500 msec
6300 msec
D
1500 msec
Watchdog disable
3100 msec
12700 msec
E
3100 msec
Watchdog disable
6300 msec
25500 msec
F
6300 msec
Watchdog disable
12700 msec
51100 msec
tWO Values with SET0 & SET1
Pins, WD-EN Pin Not Available (Pin Configuration
B)WO
Watchdog Open Time Ratio selection
tWO
SET[1:0]
= 0b'00
SET[1:0]
= 0b'01
SET[1:0]
= 0b'10
SET[1:0]
= 0b'11
A
100 msec
Watchdog disable
300 msec
1500 msec
B
300 msec
Watchdog disable
700 msec
3100 msec
C
700 msec
Watchdog disable
1500 msec
6300 msec
D
1500 msec
Watchdog disable
3100 msec
12700 msec
E
3100 msec
Watchdog disable
6300 msec
25500 msec
F
6300 msec
Watchdog disable
12700 msec
51100 msec
Watchdog Open Time Ratio selection
tWO
SET[1:0]
= 0b'00
SET[1:0]
= 0b'01
SET[1:0]
= 0b'10
SET[1:0]
= 0b'11
Watchdog Open Time Ratio selection
tWO
Watchdog Open Time Ratio selection
Watchdog Open Time Ratio selection
tWO
tWO
WO
SET[1:0]
= 0b'00
SET[1:0]
= 0b'01
SET[1:0]
= 0b'10
SET[1:0]
= 0b'11
SET[1:0]
= 0b'00
SET[1:0]
= 0b'00
SET[1:0]
= 0b'01
SET[1:0]
= 0b'01
SET[1:0]
= 0b'10
SET[1:0]
= 0b'10
SET[1:0]
= 0b'11
SET[1:0]
= 0b'11
A
100 msec
Watchdog disable
300 msec
1500 msec
B
300 msec
Watchdog disable
700 msec
3100 msec
C
700 msec
Watchdog disable
1500 msec
6300 msec
D
1500 msec
Watchdog disable
3100 msec
12700 msec
E
3100 msec
Watchdog disable
6300 msec
25500 msec
F
6300 msec
Watchdog disable
12700 msec
51100 msec
A
100 msec
Watchdog disable
300 msec
1500 msec
A100 msecWatchdog disable300 msec1500 msec
B
300 msec
Watchdog disable
700 msec
3100 msec
B300 msecWatchdog disable700 msec3100 msec
C
700 msec
Watchdog disable
1500 msec
6300 msec
C700 msecWatchdog disable1500 msec6300 msec
D
1500 msec
Watchdog disable
3100 msec
12700 msec
D1500 msecWatchdog disable3100 msec12700 msec
E
3100 msec
Watchdog disable
6300 msec
25500 msec
E3100 msecWatchdog disable6300 msec25500 msec
F
6300 msec
Watchdog disable
12700 msec
51100 msec
F6300 msecWatchdog disable12700 msec51100 msec
Example for Watchdog Close Time setting = 100 msec.
Example for Watchdog Close Time setting = 100 msec.Selected pinout option can offer WD-EN pin along
with SET[1:0] pins (Pin Configuration C, D). With
this pinout, the WD-EN pin controls watchdog
enable and disable operation. The SET[1:0] = 0b'01
combination operates as SET[1:0] = 0b'00. Ensure the tWO value with SETx ratio does not exceed 640 sec. If a selection of close window timer and ratio results in tWO > 640 sec, the timer value will be restricted to 640 sec.WOWO
to
show the timing behavior with respect to SETx
status changes.
Watchdog Behavior with SETx Pin Status
Watchdog Behavior with SETx Pin Status
Watchdog Operation with 2 SET Pins
Watchdog Operation with 2 SET Pins
Watchdog Operation with 1 SET Pin
Watchdog Operation with 1 SET Pin
Manual RESET
The TPS36-Q1 supports manual reset functionality using MR pin. MR pin when driven with voltage lower than 0.3 x VDD, asserts the RESET output. The MR pin has 100 kΩ pull up to VDD. The MR pin can be left floating. The internal pull up will ensure the output is not asserted due to MR pin trigger.
The output is deasserted after MR pin voltage rises above 0.7 x VDD voltage and time tD is elapsed. Refer for more details.
MR Pin Response
Manual RESET
The TPS36-Q1 supports manual reset functionality using MR pin. MR pin when driven with voltage lower than 0.3 x VDD, asserts the RESET output. The MR pin has 100 kΩ pull up to VDD. The MR pin can be left floating. The internal pull up will ensure the output is not asserted due to MR pin trigger.
The output is deasserted after MR pin voltage rises above 0.7 x VDD voltage and time tD is elapsed. Refer for more details.
MR Pin Response
The TPS36-Q1 supports manual reset functionality using MR pin. MR pin when driven with voltage lower than 0.3 x VDD, asserts the RESET output. The MR pin has 100 kΩ pull up to VDD. The MR pin can be left floating. The internal pull up will ensure the output is not asserted due to MR pin trigger.
The output is deasserted after MR pin voltage rises above 0.7 x VDD voltage and time tD is elapsed. Refer for more details.
MR Pin Response
The TPS36-Q1 supports manual reset functionality using MR pin. MR pin when driven with voltage lower than 0.3 x VDD, asserts the RESET output. The MR pin has 100 kΩ pull up to VDD. The MR pin can be left floating. The internal pull up will ensure the output is not asserted due to MR pin trigger.TPS36-Q1MRMRRESETMRMRMRThe output is deasserted after MR pin voltage rises above 0.7 x VDD voltage and time tD is elapsed. Refer for more details.MR and time tD is elapsedD
MR Pin Response
MR Pin ResponseMR
RESET and WDO Output
The TPS36-Q1 device can offer RESET or
RESET with independent WDO output pin. The output configuration is dependent on the
pinout variant selected. For a pinout which has only RESET output, the RESET output
is asserted when VDD voltage is below the monitored threshold or
MR pin voltage is lower than threshold or watchdog timer
error is detected. For a pinout which has independent RESET and WDO output pins, the
RESET output is asserted when VDD voltage is below the monitored threshold or
MR pin voltage is lower than threshold. WDO output is
asserted only when watchdog timer error is detected. RESET error has higher priority
than WDO error. If RESET is asserted when WDO is asserted, the device deasserts the
WDO pin and watchdog is disabled until RESET pin is deasserted and startup delay
frame is terminated.
The output will be asserted for tD
time when any relevant events
described above are detected. The time tD
can be programmed by
connecting a capacitor between CRST pin and GND or device will assert tD
for fixed time duration as
selected by orderable part number. Refer
section for all
available options.
describes the relationship between capacitor value and the time tD
. Ensure the capacitance meets
the recommended operating range. Capacitance outside the recommended range can lead
to incorrect operation of the device.
t
D
(sec) = 4.95 x
106 x CCRST (F)
TPS36-Q1 also offers
a unique option of latched output. An orderable with latched output will hold the
output in asserted state indefinitely until the device is power cycled or the error
condition is addressed. If the output is latched due to
voltage supervisor undervoltage detection, the output latch will be released
when VDD voltage rises above the VIT- + VHYS level.
If the output is latched
due to MR pin low voltage, the output latch will be released
when MR pin voltage rises above 0.7 x VDD level. If
the output is latched due to watchdog timer error, the output latch will be released
when a WDI negative edge is detected or the device is shutdown and powered up again.
shows
timing behavior of the device with latched output configuration.
Output Latch Timing Behavior
RESET and WDO OutputRESET and
The TPS36-Q1 device can offer RESET or
RESET with independent WDO output pin. The output configuration is dependent on the
pinout variant selected. For a pinout which has only RESET output, the RESET output
is asserted when VDD voltage is below the monitored threshold or
MR pin voltage is lower than threshold or watchdog timer
error is detected. For a pinout which has independent RESET and WDO output pins, the
RESET output is asserted when VDD voltage is below the monitored threshold or
MR pin voltage is lower than threshold. WDO output is
asserted only when watchdog timer error is detected. RESET error has higher priority
than WDO error. If RESET is asserted when WDO is asserted, the device deasserts the
WDO pin and watchdog is disabled until RESET pin is deasserted and startup delay
frame is terminated.
The output will be asserted for tD
time when any relevant events
described above are detected. The time tD
can be programmed by
connecting a capacitor between CRST pin and GND or device will assert tD
for fixed time duration as
selected by orderable part number. Refer
section for all
available options.
describes the relationship between capacitor value and the time tD
. Ensure the capacitance meets
the recommended operating range. Capacitance outside the recommended range can lead
to incorrect operation of the device.
t
D
(sec) = 4.95 x
106 x CCRST (F)
TPS36-Q1 also offers
a unique option of latched output. An orderable with latched output will hold the
output in asserted state indefinitely until the device is power cycled or the error
condition is addressed. If the output is latched due to
voltage supervisor undervoltage detection, the output latch will be released
when VDD voltage rises above the VIT- + VHYS level.
If the output is latched
due to MR pin low voltage, the output latch will be released
when MR pin voltage rises above 0.7 x VDD level. If
the output is latched due to watchdog timer error, the output latch will be released
when a WDI negative edge is detected or the device is shutdown and powered up again.
shows
timing behavior of the device with latched output configuration.
Output Latch Timing Behavior
The TPS36-Q1 device can offer RESET or
RESET with independent WDO output pin. The output configuration is dependent on the
pinout variant selected. For a pinout which has only RESET output, the RESET output
is asserted when VDD voltage is below the monitored threshold or
MR pin voltage is lower than threshold or watchdog timer
error is detected. For a pinout which has independent RESET and WDO output pins, the
RESET output is asserted when VDD voltage is below the monitored threshold or
MR pin voltage is lower than threshold. WDO output is
asserted only when watchdog timer error is detected. RESET error has higher priority
than WDO error. If RESET is asserted when WDO is asserted, the device deasserts the
WDO pin and watchdog is disabled until RESET pin is deasserted and startup delay
frame is terminated.
The output will be asserted for tD
time when any relevant events
described above are detected. The time tD
can be programmed by
connecting a capacitor between CRST pin and GND or device will assert tD
for fixed time duration as
selected by orderable part number. Refer
section for all
available options.
describes the relationship between capacitor value and the time tD
. Ensure the capacitance meets
the recommended operating range. Capacitance outside the recommended range can lead
to incorrect operation of the device.
t
D
(sec) = 4.95 x
106 x CCRST (F)
TPS36-Q1 also offers
a unique option of latched output. An orderable with latched output will hold the
output in asserted state indefinitely until the device is power cycled or the error
condition is addressed. If the output is latched due to
voltage supervisor undervoltage detection, the output latch will be released
when VDD voltage rises above the VIT- + VHYS level.
If the output is latched
due to MR pin low voltage, the output latch will be released
when MR pin voltage rises above 0.7 x VDD level. If
the output is latched due to watchdog timer error, the output latch will be released
when a WDI negative edge is detected or the device is shutdown and powered up again.
shows
timing behavior of the device with latched output configuration.
Output Latch Timing Behavior
The TPS36-Q1 device can offer RESET or
RESET with independent WDO output pin. The output configuration is dependent on the
pinout variant selected. For a pinout which has only RESET output, the RESET output
is asserted when VDD voltage is below the monitored threshold or
MR pin voltage is lower than threshold or watchdog timer
error is detected. For a pinout which has independent RESET and WDO output pins, the
RESET output is asserted when VDD voltage is below the monitored threshold or
MR pin voltage is lower than threshold. WDO output is
asserted only when watchdog timer error is detected. RESET error has higher priority
than WDO error. If RESET is asserted when WDO is asserted, the device deasserts the
WDO pin and watchdog is disabled until RESET pin is deasserted and startup delay
frame is terminated.TPS36-Q1MRMRThe output will be asserted for tD
time when any relevant events
described above are detected. The time tD
can be programmed by
connecting a capacitor between CRST pin and GND or device will assert tD
for fixed time duration as
selected by orderable part number. Refer
section for all
available options.tD
DtD
DtD
D
describes the relationship between capacitor value and the time tD
. Ensure the capacitance meets
the recommended operating range. Capacitance outside the recommended range can lead
to incorrect operation of the device.tD
D
t
D
(sec) = 4.95 x
106 x CCRST (F)
t
D
(sec) = 4.95 x
106 x CCRST (F)
D
D6CRST
TPS36-Q1 also offers
a unique option of latched output. An orderable with latched output will hold the
output in asserted state indefinitely until the device is power cycled or the error
condition is addressed. If the output is latched due to
voltage supervisor undervoltage detection, the output latch will be released
when VDD voltage rises above the VIT- + VHYS level.
If the output is latched
due to MR pin low voltage, the output latch will be released
when MR pin voltage rises above 0.7 x VDD level. If
the output is latched due to watchdog timer error, the output latch will be released
when a WDI negative edge is detected or the device is shutdown and powered up again.
shows
timing behavior of the device with latched output configuration.TPS36-Q1If the output is latched due to
voltage supervisor undervoltage detection, the output latch will be released
when VDD voltage rises above the VIT- + VHYS level.
IT-HYSMRMRDD
Output Latch Timing Behavior
Output Latch Timing Behavior
Device Functional Modes
#GUID-B008A25A-278A-4B38-AFBB-A738DE66DE26/A_1467996961_SHEET1
summarizes the functional modes of the TPS36-Q1.
Device Functional
Modes
VDD
WATCHDOG STATUS
WDI
WDO
RESET
VDD <
VPOR
Not Applicable
—
Undefined
Undefined
VPOR ≤
VDD < VIT-
Not Applicable
Ignored
High
Low
VDD ≥ VIT+
Disabled
Ignored
High
High
Enabled
tWC(max) ≤
tpulse
1 ≤ tWC(max) + tWO(min)
High
High
Enabled
tWC(max) >
tpulse
1
Low
High
Enabled
tWC(max) +
tWO(max) < tpulse
1
Low
High
Where tpulse is the time between falling edges on
WDI.
Device Functional Modes
#GUID-B008A25A-278A-4B38-AFBB-A738DE66DE26/A_1467996961_SHEET1
summarizes the functional modes of the TPS36-Q1.
Device Functional
Modes
VDD
WATCHDOG STATUS
WDI
WDO
RESET
VDD <
VPOR
Not Applicable
—
Undefined
Undefined
VPOR ≤
VDD < VIT-
Not Applicable
Ignored
High
Low
VDD ≥ VIT+
Disabled
Ignored
High
High
Enabled
tWC(max) ≤
tpulse
1 ≤ tWC(max) + tWO(min)
High
High
Enabled
tWC(max) >
tpulse
1
Low
High
Enabled
tWC(max) +
tWO(max) < tpulse
1
Low
High
Where tpulse is the time between falling edges on
WDI.
#GUID-B008A25A-278A-4B38-AFBB-A738DE66DE26/A_1467996961_SHEET1
summarizes the functional modes of the TPS36-Q1.
Device Functional
Modes
VDD
WATCHDOG STATUS
WDI
WDO
RESET
VDD <
VPOR
Not Applicable
—
Undefined
Undefined
VPOR ≤
VDD < VIT-
Not Applicable
Ignored
High
Low
VDD ≥ VIT+
Disabled
Ignored
High
High
Enabled
tWC(max) ≤
tpulse
1 ≤ tWC(max) + tWO(min)
High
High
Enabled
tWC(max) >
tpulse
1
Low
High
Enabled
tWC(max) +
tWO(max) < tpulse
1
Low
High
Where tpulse is the time between falling edges on
WDI.
#GUID-B008A25A-278A-4B38-AFBB-A738DE66DE26/A_1467996961_SHEET1
summarizes the functional modes of the TPS36-Q1.
#GUID-B008A25A-278A-4B38-AFBB-A738DE66DE26/A_1467996961_SHEET1
#GUID-B008A25A-278A-4B38-AFBB-A738DE66DE26/A_1467996961_SHEET1TPS36-Q1
Device Functional
Modes
VDD
WATCHDOG STATUS
WDI
WDO
RESET
VDD <
VPOR
Not Applicable
—
Undefined
Undefined
VPOR ≤
VDD < VIT-
Not Applicable
Ignored
High
Low
VDD ≥ VIT+
Disabled
Ignored
High
High
Enabled
tWC(max) ≤
tpulse
1 ≤ tWC(max) + tWO(min)
High
High
Enabled
tWC(max) >
tpulse
1
Low
High
Enabled
tWC(max) +
tWO(max) < tpulse
1
Low
High
Device Functional
Modes
VDD
WATCHDOG STATUS
WDI
WDO
RESET
VDD <
VPOR
Not Applicable
—
Undefined
Undefined
VPOR ≤
VDD < VIT-
Not Applicable
Ignored
High
Low
VDD ≥ VIT+
Disabled
Ignored
High
High
Enabled
tWC(max) ≤
tpulse
1 ≤ tWC(max) + tWO(min)
High
High
Enabled
tWC(max) >
tpulse
1
Low
High
Enabled
tWC(max) +
tWO(max) < tpulse
1
Low
High
VDD
WATCHDOG STATUS
WDI
WDO
RESET
VDD
WATCHDOG STATUS
WDI
WDO
RESET
VDDWATCHDOG STATUSWDI
WDO
WDO
RESET
RESET
VDD <
VPOR
Not Applicable
—
Undefined
Undefined
VPOR ≤
VDD < VIT-
Not Applicable
Ignored
High
Low
VDD ≥ VIT+
Disabled
Ignored
High
High
Enabled
tWC(max) ≤
tpulse
1 ≤ tWC(max) + tWO(min)
High
High
Enabled
tWC(max) >
tpulse
1
Low
High
Enabled
tWC(max) +
tWO(max) < tpulse
1
Low
High
VDD <
VPOR
Not Applicable
—
Undefined
Undefined
VDD <
VPOR
DDPORNot Applicable—UndefinedUndefined
VPOR ≤
VDD < VIT-
Not Applicable
Ignored
High
Low
VPOR ≤
VDD < VIT-
PORDDIT-Not ApplicableIgnoredHighLow
VDD ≥ VIT+
Disabled
Ignored
High
High
VDD ≥ VIT+
DDIT+DisabledIgnoredHighHigh
Enabled
tWC(max) ≤
tpulse
1 ≤ tWC(max) + tWO(min)
High
High
EnabledtWC(max) ≤
tpulse
1 ≤ tWC(max) + tWO(min)
WC(max)pulse1WC(max)WO(min)HighHigh
Enabled
tWC(max) >
tpulse
1
Low
High
EnabledtWC(max) >
tpulse
1
WC(max)pulse1LowHigh
Enabled
tWC(max) +
tWO(max) < tpulse
1
Low
High
EnabledtWC(max) +
tWO(max) < tpulse
1
WC(max)WO(max)pulse1LowHigh
Where tpulse is the time between falling edges on
WDI.
Where tpulse is the time between falling edges on
WDI.pulse
Application and Implementation
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.
Application Information
The following sections describe in detail proper device implementation, depending on the final application requirements.
CRST Delay
The TPS36-Q1 features two options
for setting the reset delay
(tD): using a fixed timing and programming the timing through
an external capacitor.
Factory-Programmed Reset Delay Timing
Fixed reset delay timings are available using pinouts C and D. Using these timings enables a high-precision, 10% accurate reset delay timing.
Adjustable Capacitor Timing
The TPS36-Q1 also offers
programmable reset delay option when using pinout A and B. The TPS36-Q1 can be programmed to have a desired reset delay by
connecting a capacitor between CRST pin and GND. The typical delay time resulting
from a given external capacitance on the CRST pin can be calculated by #GUID-7710661D-BC6A-40DC-BDC1-A7B294C2058B/T4523365-12 , where tD is the reset delay time in seconds and CCRST is
the capacitance in farads.
tD (sec) = 4.95 ×
106 × CCRST (F)
To minimize the difference between the calculated
reset delay time and the actual reset delay time, use a use a high-quality ceramic
dielectric COG capacitor and minimize parasitic board capacitance around this pin.
#GUID-7710661D-BC6A-40DC-BDC1-A7B294C2058B/SBVS3011026
lists the reset delay time ideal capacitor values for CCRST.
Reset Delay Time for Common Ideal Capacitor Values
CCRST
RESETDELAY TIME (tD)
UNIT
MIN #GUID-7710661D-BC6A-40DC-BDC1-A7B294C2058B/T4523365-39
TYP
MAX #GUID-7710661D-BC6A-40DC-BDC1-A7B294C2058B/T4523365-39
10 nF
39.6
49.5
59.4
ms
100 nF
396
495
594
ms
1 μF
3960
4950
5940
ms
Minimum and maximum values are calculated using ideal capacitors.
Watchdog Window Functionality
The TPS36-Q1 features two options
for setting the close window watchdog timer (tWC
): using a fixed timing and
programming the timing through an external capacitor.
Factory-Programmed watchdog Timing
Fixed watchdog window close timings are available using
pinout C and D. Using these timings enables a high-precision, 10% accurate watchdog timer
tWC.
Adjustable Capacitor Timing
Pinout options A and B support adjustable
tWC timing. This is achievable by connecting a capacitor between CWD
and GND pin. Consult , , and for calculating
typical tWC values using ideal capacitors. Capacitor tolerances will
cause additional deviation. For the most accurate timing, use ceramic capacitors
with COG dielectric material.
Typical Applications
Design 1: Monitoring Microcontroller Supply and Watchdog During Operational and Sleep Modes
The TPS36-Q1 can utilize high-accuracy voltage monitoring and on-the-fly SETx assigning to monitor a microcontroller that has both an operational and sleep mode.
Monitoring Microcontroller
Supply and Watchdog During Operation and Sleep
Design Requirements
Design Parameters
PARAMETER
DESIGN REQUIREMENT
DESIGN RESULT
Voltage Threshold
Typical Voltage Threshold of 1.65 V
Typical Voltage Threshold of 1.65 V
Window Close Time During Operation
Typical tWC of 50 ms during opertation
Typical tWC of 50 ms
Window Open Time During Operation
Typical tWO of 1.4 s during
operation
Typical tWO of 1.55 s
Window Close Time During Sleep
Typical tWC of 50 ms during sleep
Typical tWC of 50 ms
Window Open Time During Sleep
Typical tWO of 12 s during operation
Typical tWO of 12.75
s
RESET Delay
200 ms
200 ms
Output Logic
Open-drain
Open-drain
Maximum Device Current Consumption
20 μA
250 nA typical, 3 μA maximum
Detailed Design Procedure
Setting Voltage Threshold
The negative-going threshold voltage, VIT-, is set by the device variant. #GUID-6C90B256-3A47-4AA0-878A-A3AC84C87BCA/EQUATION-BLOCK_XV1_5Z1_YTB shows how to calculate the "Threshold Voltage" section of the orderable part number.
OPN "Threshold
Voltage" number = (VIT- - 1) /
0.05
In this example, the nominal supply voltage for
the microcontroller is 1.8 V. The minimum supply voltage is 10% lower than the
nominal supply voltage, or 1.62 V. Setting a 1.65 V threshold ensures that the
device is reset just before the supply voltage reaches the minimum allowed. Thus a
1.65 V threshold is chosen and, using #GUID-6C90B256-3A47-4AA0-878A-A3AC84C87BCA/EQUATION-BLOCK_XV1_5Z1_YTB, the part number
is reduced to TPS36xx13xxxxxxxQ1. The hysteresis is 5% typical, resulting in a
positive-going threshold voltage, VIT+, of 1.73 V.
Determining Window Timings During Operation and Sleep Modes
The TPS36-Q1 allows for precise
10% accurate watchdog timings. This application requires two different window
timings in order to maximize power efficiency: one for the microcontroller's
operational state and one for its sleep state. To achieve this, the host can
reassign the SETx pins when it transitions between states. A window close time,
tWC, of 50 ms typical is chosen because of the application's 50 ms
typical tWC requirement. The application requires a minimum watchdog open
time, tWO, of 1.4 s during operation and a tWO of 12 s during
sleep. Thus, the possible variant options are narrowed to TPS36xx13FExDDFRQ1.
Meeting the Minimum Reset Delay
The TPS36-Q1 features two options for selecting reset delays: fixed delays and capacitor-programmable delays. The TPS36-Q1 supports only fixed watchdog timings and fixed reset delays or programmable watchdog timings and programmable reset delays. The application requires a 200 ms minimum reset delay, thus reset delay option G is used. Because of these requirements and no need for a startup delay, the TPS36CA13FEGDDFRQ1 is used.
Setting the Watchdog Window
In this application, the watchdog timing options
are based on the WDI signal that is provided to the TPS36-Q1. A
watchdog WDI setting must be chosen such that a transition must always occur within
the open watchdog window. There are several ways to achieve these window parameters.
An external capacitor can be placed on the CWD pin and calculated to have a
sufficient window close time. Another option is to use one of the factory-programmed
timing options. An additional advantage of choosing one of the factory-programmed
options is the ability to reduce the number of components required, thus reducing
overall BOM cost.
Calculating the RESET Pullup Resistor
The TPS36-Q1 uses an open-drain configuration for the RESET output, as shown in .When the FET is off, the resistor pulls the drain of the transistor to VDD and when the FET is turned on, the FET pulls the output to ground, thus creating an effective resistor divider. The resistors in this divider must be chosen to ensure that VOL is below its maximum value. To choose the proper pullup resistor, there are three key specifications to keep in mind: the pullup voltage (VPU), the recommended maximum RESET pin current (IRST), and VOL. The maximum VOL is 0.3 V, meaning that the effective resistor divider created must be able to bring the voltage on the reset pin below 0.3 V with IRST kept below 2 mA for VDD ≥ 3 V and 500 μA for VDD = 1.5 V. For this example, with a VPU =VDD = 1.5 V, a resistor must be chosen to keep IRST below 500 μA because this value is the maximum consumption current allowed. To ensure this specification is met, a pullup resistor value of 10 kΩ was selected, which sinks a maximum of 180 μA when RESET is asserted.
Open-Drain RESET Configuration
Power Supply Recommendations
This device is designed to operate from
an input supply with a voltage range between 1.04 V and 6 V. An input supply capacitor is
not required for this device; however, if the input supply is noisy, then good analog
practice is to place a 0.1-µF capacitor between the VDD pin and the GND pin.
Layout
Layout Guidelines
Make sure that the connection to the VDD pin is
low impedance. Good analog design practice recommends placing a 0.1-µF ceramic
capacitor as near as possible to the VDD pin. If a capacitor is not connected to the
CRST pin, then minimize parasitic capacitance on this pin so the
RESET
delay time is not adversely affected.
Make sure that the connection
to the VDD pin is low impedance. Good analog design practice is to place a
0.1-µF ceramic capacitor as near as possible to the VDD pin.
Place CCRST
capacitor as close as possible to the CRST pin.
Place CCWD
capacitor as close as possible to the CWD pin.
Place the pullup resistor on
the
RESET
pin as close to the pin as
possible.
Layout Example
Typical
Layout for the pinout C of TPS36-Q1
Application and Implementation
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.
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.
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.
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.
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.
Application Information
The following sections describe in detail proper device implementation, depending on the final application requirements.
CRST Delay
The TPS36-Q1 features two options
for setting the reset delay
(tD): using a fixed timing and programming the timing through
an external capacitor.
Factory-Programmed Reset Delay Timing
Fixed reset delay timings are available using pinouts C and D. Using these timings enables a high-precision, 10% accurate reset delay timing.
Adjustable Capacitor Timing
The TPS36-Q1 also offers
programmable reset delay option when using pinout A and B. The TPS36-Q1 can be programmed to have a desired reset delay by
connecting a capacitor between CRST pin and GND. The typical delay time resulting
from a given external capacitance on the CRST pin can be calculated by #GUID-7710661D-BC6A-40DC-BDC1-A7B294C2058B/T4523365-12 , where tD is the reset delay time in seconds and CCRST is
the capacitance in farads.
tD (sec) = 4.95 ×
106 × CCRST (F)
To minimize the difference between the calculated
reset delay time and the actual reset delay time, use a use a high-quality ceramic
dielectric COG capacitor and minimize parasitic board capacitance around this pin.
#GUID-7710661D-BC6A-40DC-BDC1-A7B294C2058B/SBVS3011026
lists the reset delay time ideal capacitor values for CCRST.
Reset Delay Time for Common Ideal Capacitor Values
CCRST
RESETDELAY TIME (tD)
UNIT
MIN #GUID-7710661D-BC6A-40DC-BDC1-A7B294C2058B/T4523365-39
TYP
MAX #GUID-7710661D-BC6A-40DC-BDC1-A7B294C2058B/T4523365-39
10 nF
39.6
49.5
59.4
ms
100 nF
396
495
594
ms
1 μF
3960
4950
5940
ms
Minimum and maximum values are calculated using ideal capacitors.
Watchdog Window Functionality
The TPS36-Q1 features two options
for setting the close window watchdog timer (tWC
): using a fixed timing and
programming the timing through an external capacitor.
Factory-Programmed watchdog Timing
Fixed watchdog window close timings are available using
pinout C and D. Using these timings enables a high-precision, 10% accurate watchdog timer
tWC.
Adjustable Capacitor Timing
Pinout options A and B support adjustable
tWC timing. This is achievable by connecting a capacitor between CWD
and GND pin. Consult , , and for calculating
typical tWC values using ideal capacitors. Capacitor tolerances will
cause additional deviation. For the most accurate timing, use ceramic capacitors
with COG dielectric material.
Application Information
The following sections describe in detail proper device implementation, depending on the final application requirements.
The following sections describe in detail proper device implementation, depending on the final application requirements.
The following sections describe in detail proper device implementation, depending on the final application requirements.
CRST Delay
The TPS36-Q1 features two options
for setting the reset delay
(tD): using a fixed timing and programming the timing through
an external capacitor.
Factory-Programmed Reset Delay Timing
Fixed reset delay timings are available using pinouts C and D. Using these timings enables a high-precision, 10% accurate reset delay timing.
Adjustable Capacitor Timing
The TPS36-Q1 also offers
programmable reset delay option when using pinout A and B. The TPS36-Q1 can be programmed to have a desired reset delay by
connecting a capacitor between CRST pin and GND. The typical delay time resulting
from a given external capacitance on the CRST pin can be calculated by #GUID-7710661D-BC6A-40DC-BDC1-A7B294C2058B/T4523365-12 , where tD is the reset delay time in seconds and CCRST is
the capacitance in farads.
tD (sec) = 4.95 ×
106 × CCRST (F)
To minimize the difference between the calculated
reset delay time and the actual reset delay time, use a use a high-quality ceramic
dielectric COG capacitor and minimize parasitic board capacitance around this pin.
#GUID-7710661D-BC6A-40DC-BDC1-A7B294C2058B/SBVS3011026
lists the reset delay time ideal capacitor values for CCRST.
Reset Delay Time for Common Ideal Capacitor Values
CCRST
RESETDELAY TIME (tD)
UNIT
MIN #GUID-7710661D-BC6A-40DC-BDC1-A7B294C2058B/T4523365-39
TYP
MAX #GUID-7710661D-BC6A-40DC-BDC1-A7B294C2058B/T4523365-39
10 nF
39.6
49.5
59.4
ms
100 nF
396
495
594
ms
1 μF
3960
4950
5940
ms
Minimum and maximum values are calculated using ideal capacitors.
CRST Delay
The TPS36-Q1 features two options
for setting the reset delay
(tD): using a fixed timing and programming the timing through
an external capacitor.
The TPS36-Q1 features two options
for setting the reset delay
(tD): using a fixed timing and programming the timing through
an external capacitor.
The TPS36-Q1 features two options
for setting the reset delay
(tD): using a fixed timing and programming the timing through
an external capacitor.TPS36-Q1 (tD)D
Factory-Programmed Reset Delay Timing
Fixed reset delay timings are available using pinouts C and D. Using these timings enables a high-precision, 10% accurate reset delay timing.
Factory-Programmed Reset Delay Timing
Fixed reset delay timings are available using pinouts C and D. Using these timings enables a high-precision, 10% accurate reset delay timing.
Fixed reset delay timings are available using pinouts C and D. Using these timings enables a high-precision, 10% accurate reset delay timing.
Fixed reset delay timings are available using pinouts C and D. Using these timings enables a high-precision, 10% accurate reset delay timing.
Adjustable Capacitor Timing
The TPS36-Q1 also offers
programmable reset delay option when using pinout A and B. The TPS36-Q1 can be programmed to have a desired reset delay by
connecting a capacitor between CRST pin and GND. The typical delay time resulting
from a given external capacitance on the CRST pin can be calculated by #GUID-7710661D-BC6A-40DC-BDC1-A7B294C2058B/T4523365-12 , where tD is the reset delay time in seconds and CCRST is
the capacitance in farads.
tD (sec) = 4.95 ×
106 × CCRST (F)
To minimize the difference between the calculated
reset delay time and the actual reset delay time, use a use a high-quality ceramic
dielectric COG capacitor and minimize parasitic board capacitance around this pin.
#GUID-7710661D-BC6A-40DC-BDC1-A7B294C2058B/SBVS3011026
lists the reset delay time ideal capacitor values for CCRST.
Reset Delay Time for Common Ideal Capacitor Values
CCRST
RESETDELAY TIME (tD)
UNIT
MIN #GUID-7710661D-BC6A-40DC-BDC1-A7B294C2058B/T4523365-39
TYP
MAX #GUID-7710661D-BC6A-40DC-BDC1-A7B294C2058B/T4523365-39
10 nF
39.6
49.5
59.4
ms
100 nF
396
495
594
ms
1 μF
3960
4950
5940
ms
Minimum and maximum values are calculated using ideal capacitors.
Adjustable Capacitor Timing
The TPS36-Q1 also offers
programmable reset delay option when using pinout A and B. The TPS36-Q1 can be programmed to have a desired reset delay by
connecting a capacitor between CRST pin and GND. The typical delay time resulting
from a given external capacitance on the CRST pin can be calculated by #GUID-7710661D-BC6A-40DC-BDC1-A7B294C2058B/T4523365-12 , where tD is the reset delay time in seconds and CCRST is
the capacitance in farads.
tD (sec) = 4.95 ×
106 × CCRST (F)
To minimize the difference between the calculated
reset delay time and the actual reset delay time, use a use a high-quality ceramic
dielectric COG capacitor and minimize parasitic board capacitance around this pin.
#GUID-7710661D-BC6A-40DC-BDC1-A7B294C2058B/SBVS3011026
lists the reset delay time ideal capacitor values for CCRST.
Reset Delay Time for Common Ideal Capacitor Values
CCRST
RESETDELAY TIME (tD)
UNIT
MIN #GUID-7710661D-BC6A-40DC-BDC1-A7B294C2058B/T4523365-39
TYP
MAX #GUID-7710661D-BC6A-40DC-BDC1-A7B294C2058B/T4523365-39
10 nF
39.6
49.5
59.4
ms
100 nF
396
495
594
ms
1 μF
3960
4950
5940
ms
Minimum and maximum values are calculated using ideal capacitors.
The TPS36-Q1 also offers
programmable reset delay option when using pinout A and B. The TPS36-Q1 can be programmed to have a desired reset delay by
connecting a capacitor between CRST pin and GND. The typical delay time resulting
from a given external capacitance on the CRST pin can be calculated by #GUID-7710661D-BC6A-40DC-BDC1-A7B294C2058B/T4523365-12 , where tD is the reset delay time in seconds and CCRST is
the capacitance in farads.
tD (sec) = 4.95 ×
106 × CCRST (F)
To minimize the difference between the calculated
reset delay time and the actual reset delay time, use a use a high-quality ceramic
dielectric COG capacitor and minimize parasitic board capacitance around this pin.
#GUID-7710661D-BC6A-40DC-BDC1-A7B294C2058B/SBVS3011026
lists the reset delay time ideal capacitor values for CCRST.
Reset Delay Time for Common Ideal Capacitor Values
CCRST
RESETDELAY TIME (tD)
UNIT
MIN #GUID-7710661D-BC6A-40DC-BDC1-A7B294C2058B/T4523365-39
TYP
MAX #GUID-7710661D-BC6A-40DC-BDC1-A7B294C2058B/T4523365-39
10 nF
39.6
49.5
59.4
ms
100 nF
396
495
594
ms
1 μF
3960
4950
5940
ms
Minimum and maximum values are calculated using ideal capacitors.
The TPS36-Q1 also offers
programmable reset delay option when using pinout A and B. The TPS36-Q1 can be programmed to have a desired reset delay by
connecting a capacitor between CRST pin and GND. The typical delay time resulting
from a given external capacitance on the CRST pin can be calculated by #GUID-7710661D-BC6A-40DC-BDC1-A7B294C2058B/T4523365-12 , where tD is the reset delay time in seconds and CCRST is
the capacitance in farads.TPS36-Q1TPS36-Q1#GUID-7710661D-BC6A-40DC-BDC1-A7B294C2058B/T4523365-12DCRSTtD (sec) = 4.95 ×
106 × CCRST (F)D6CRSTTo minimize the difference between the calculated
reset delay time and the actual reset delay time, use a use a high-quality ceramic
dielectric COG capacitor and minimize parasitic board capacitance around this pin.
#GUID-7710661D-BC6A-40DC-BDC1-A7B294C2058B/SBVS3011026
lists the reset delay time ideal capacitor values for CCRST.#GUID-7710661D-BC6A-40DC-BDC1-A7B294C2058B/SBVS3011026CRST
Reset Delay Time for Common Ideal Capacitor Values
CCRST
RESETDELAY TIME (tD)
UNIT
MIN #GUID-7710661D-BC6A-40DC-BDC1-A7B294C2058B/T4523365-39
TYP
MAX #GUID-7710661D-BC6A-40DC-BDC1-A7B294C2058B/T4523365-39
10 nF
39.6
49.5
59.4
ms
100 nF
396
495
594
ms
1 μF
3960
4950
5940
ms
Reset Delay Time for Common Ideal Capacitor Values
CCRST
RESETDELAY TIME (tD)
UNIT
MIN #GUID-7710661D-BC6A-40DC-BDC1-A7B294C2058B/T4523365-39
TYP
MAX #GUID-7710661D-BC6A-40DC-BDC1-A7B294C2058B/T4523365-39
10 nF
39.6
49.5
59.4
ms
100 nF
396
495
594
ms
1 μF
3960
4950
5940
ms
CCRST
RESETDELAY TIME (tD)
UNIT
MIN #GUID-7710661D-BC6A-40DC-BDC1-A7B294C2058B/T4523365-39
TYP
MAX #GUID-7710661D-BC6A-40DC-BDC1-A7B294C2058B/T4523365-39
CCRST
RESETDELAY TIME (tD)
UNIT
CCRST
CRST
RESETDELAY TIME (tD)RESETDUNIT
MIN #GUID-7710661D-BC6A-40DC-BDC1-A7B294C2058B/T4523365-39
TYP
MAX #GUID-7710661D-BC6A-40DC-BDC1-A7B294C2058B/T4523365-39
MIN #GUID-7710661D-BC6A-40DC-BDC1-A7B294C2058B/T4523365-39
#GUID-7710661D-BC6A-40DC-BDC1-A7B294C2058B/T4523365-39TYPMAX #GUID-7710661D-BC6A-40DC-BDC1-A7B294C2058B/T4523365-39
#GUID-7710661D-BC6A-40DC-BDC1-A7B294C2058B/T4523365-39
10 nF
39.6
49.5
59.4
ms
100 nF
396
495
594
ms
1 μF
3960
4950
5940
ms
10 nF
39.6
49.5
59.4
ms
10 nF39.649.559.4ms
100 nF
396
495
594
ms
100 nF396495594ms
1 μF
3960
4950
5940
ms
1 μF396049505940ms
Minimum and maximum values are calculated using ideal capacitors.
Minimum and maximum values are calculated using ideal capacitors.
Watchdog Window Functionality
The TPS36-Q1 features two options
for setting the close window watchdog timer (tWC
): using a fixed timing and
programming the timing through an external capacitor.
Factory-Programmed watchdog Timing
Fixed watchdog window close timings are available using
pinout C and D. Using these timings enables a high-precision, 10% accurate watchdog timer
tWC.
Adjustable Capacitor Timing
Pinout options A and B support adjustable
tWC timing. This is achievable by connecting a capacitor between CWD
and GND pin. Consult , , and for calculating
typical tWC values using ideal capacitors. Capacitor tolerances will
cause additional deviation. For the most accurate timing, use ceramic capacitors
with COG dielectric material.
Watchdog Window FunctionalityWindow
The TPS36-Q1 features two options
for setting the close window watchdog timer (tWC
): using a fixed timing and
programming the timing through an external capacitor.
The TPS36-Q1 features two options
for setting the close window watchdog timer (tWC
): using a fixed timing and
programming the timing through an external capacitor.
The TPS36-Q1 features two options
for setting the close window watchdog timer (tWC
): using a fixed timing and
programming the timing through an external capacitor.TPS36-Q1close window tWC
WC
Factory-Programmed watchdog Timing
Fixed watchdog window close timings are available using
pinout C and D. Using these timings enables a high-precision, 10% accurate watchdog timer
tWC.
Factory-Programmed watchdog Timing
Fixed watchdog window close timings are available using
pinout C and D. Using these timings enables a high-precision, 10% accurate watchdog timer
tWC.
Fixed watchdog window close timings are available using
pinout C and D. Using these timings enables a high-precision, 10% accurate watchdog timer
tWC.
Fixed watchdog window close timings are available using
pinout C and D. Using these timings enables a high-precision, 10% accurate watchdog timer
tWC.WC
Adjustable Capacitor Timing
Pinout options A and B support adjustable
tWC timing. This is achievable by connecting a capacitor between CWD
and GND pin. Consult , , and for calculating
typical tWC values using ideal capacitors. Capacitor tolerances will
cause additional deviation. For the most accurate timing, use ceramic capacitors
with COG dielectric material.
Adjustable Capacitor Timing
Pinout options A and B support adjustable
tWC timing. This is achievable by connecting a capacitor between CWD
and GND pin. Consult , , and for calculating
typical tWC values using ideal capacitors. Capacitor tolerances will
cause additional deviation. For the most accurate timing, use ceramic capacitors
with COG dielectric material.
Pinout options A and B support adjustable
tWC timing. This is achievable by connecting a capacitor between CWD
and GND pin. Consult , , and for calculating
typical tWC values using ideal capacitors. Capacitor tolerances will
cause additional deviation. For the most accurate timing, use ceramic capacitors
with COG dielectric material.
Pinout options A and B support adjustable
tWC timing. This is achievable by connecting a capacitor between CWD
and GND pin. Consult , , and for calculating
typical tWC values using ideal capacitors. Capacitor tolerances will
cause additional deviation. For the most accurate timing, use ceramic capacitors
with COG dielectric material.WCWC
Typical Applications
Design 1: Monitoring Microcontroller Supply and Watchdog During Operational and Sleep Modes
The TPS36-Q1 can utilize high-accuracy voltage monitoring and on-the-fly SETx assigning to monitor a microcontroller that has both an operational and sleep mode.
Monitoring Microcontroller
Supply and Watchdog During Operation and Sleep
Design Requirements
Design Parameters
PARAMETER
DESIGN REQUIREMENT
DESIGN RESULT
Voltage Threshold
Typical Voltage Threshold of 1.65 V
Typical Voltage Threshold of 1.65 V
Window Close Time During Operation
Typical tWC of 50 ms during opertation
Typical tWC of 50 ms
Window Open Time During Operation
Typical tWO of 1.4 s during
operation
Typical tWO of 1.55 s
Window Close Time During Sleep
Typical tWC of 50 ms during sleep
Typical tWC of 50 ms
Window Open Time During Sleep
Typical tWO of 12 s during operation
Typical tWO of 12.75
s
RESET Delay
200 ms
200 ms
Output Logic
Open-drain
Open-drain
Maximum Device Current Consumption
20 μA
250 nA typical, 3 μA maximum
Detailed Design Procedure
Setting Voltage Threshold
The negative-going threshold voltage, VIT-, is set by the device variant. #GUID-6C90B256-3A47-4AA0-878A-A3AC84C87BCA/EQUATION-BLOCK_XV1_5Z1_YTB shows how to calculate the "Threshold Voltage" section of the orderable part number.
OPN "Threshold
Voltage" number = (VIT- - 1) /
0.05
In this example, the nominal supply voltage for
the microcontroller is 1.8 V. The minimum supply voltage is 10% lower than the
nominal supply voltage, or 1.62 V. Setting a 1.65 V threshold ensures that the
device is reset just before the supply voltage reaches the minimum allowed. Thus a
1.65 V threshold is chosen and, using #GUID-6C90B256-3A47-4AA0-878A-A3AC84C87BCA/EQUATION-BLOCK_XV1_5Z1_YTB, the part number
is reduced to TPS36xx13xxxxxxxQ1. The hysteresis is 5% typical, resulting in a
positive-going threshold voltage, VIT+, of 1.73 V.
Determining Window Timings During Operation and Sleep Modes
The TPS36-Q1 allows for precise
10% accurate watchdog timings. This application requires two different window
timings in order to maximize power efficiency: one for the microcontroller's
operational state and one for its sleep state. To achieve this, the host can
reassign the SETx pins when it transitions between states. A window close time,
tWC, of 50 ms typical is chosen because of the application's 50 ms
typical tWC requirement. The application requires a minimum watchdog open
time, tWO, of 1.4 s during operation and a tWO of 12 s during
sleep. Thus, the possible variant options are narrowed to TPS36xx13FExDDFRQ1.
Meeting the Minimum Reset Delay
The TPS36-Q1 features two options for selecting reset delays: fixed delays and capacitor-programmable delays. The TPS36-Q1 supports only fixed watchdog timings and fixed reset delays or programmable watchdog timings and programmable reset delays. The application requires a 200 ms minimum reset delay, thus reset delay option G is used. Because of these requirements and no need for a startup delay, the TPS36CA13FEGDDFRQ1 is used.
Setting the Watchdog Window
In this application, the watchdog timing options
are based on the WDI signal that is provided to the TPS36-Q1. A
watchdog WDI setting must be chosen such that a transition must always occur within
the open watchdog window. There are several ways to achieve these window parameters.
An external capacitor can be placed on the CWD pin and calculated to have a
sufficient window close time. Another option is to use one of the factory-programmed
timing options. An additional advantage of choosing one of the factory-programmed
options is the ability to reduce the number of components required, thus reducing
overall BOM cost.
Calculating the RESET Pullup Resistor
The TPS36-Q1 uses an open-drain configuration for the RESET output, as shown in .When the FET is off, the resistor pulls the drain of the transistor to VDD and when the FET is turned on, the FET pulls the output to ground, thus creating an effective resistor divider. The resistors in this divider must be chosen to ensure that VOL is below its maximum value. To choose the proper pullup resistor, there are three key specifications to keep in mind: the pullup voltage (VPU), the recommended maximum RESET pin current (IRST), and VOL. The maximum VOL is 0.3 V, meaning that the effective resistor divider created must be able to bring the voltage on the reset pin below 0.3 V with IRST kept below 2 mA for VDD ≥ 3 V and 500 μA for VDD = 1.5 V. For this example, with a VPU =VDD = 1.5 V, a resistor must be chosen to keep IRST below 500 μA because this value is the maximum consumption current allowed. To ensure this specification is met, a pullup resistor value of 10 kΩ was selected, which sinks a maximum of 180 μA when RESET is asserted.
Open-Drain RESET Configuration
Typical Applications
Design 1: Monitoring Microcontroller Supply and Watchdog During Operational and Sleep Modes
The TPS36-Q1 can utilize high-accuracy voltage monitoring and on-the-fly SETx assigning to monitor a microcontroller that has both an operational and sleep mode.
Monitoring Microcontroller
Supply and Watchdog During Operation and Sleep
Design Requirements
Design Parameters
PARAMETER
DESIGN REQUIREMENT
DESIGN RESULT
Voltage Threshold
Typical Voltage Threshold of 1.65 V
Typical Voltage Threshold of 1.65 V
Window Close Time During Operation
Typical tWC of 50 ms during opertation
Typical tWC of 50 ms
Window Open Time During Operation
Typical tWO of 1.4 s during
operation
Typical tWO of 1.55 s
Window Close Time During Sleep
Typical tWC of 50 ms during sleep
Typical tWC of 50 ms
Window Open Time During Sleep
Typical tWO of 12 s during operation
Typical tWO of 12.75
s
RESET Delay
200 ms
200 ms
Output Logic
Open-drain
Open-drain
Maximum Device Current Consumption
20 μA
250 nA typical, 3 μA maximum
Detailed Design Procedure
Setting Voltage Threshold
The negative-going threshold voltage, VIT-, is set by the device variant. #GUID-6C90B256-3A47-4AA0-878A-A3AC84C87BCA/EQUATION-BLOCK_XV1_5Z1_YTB shows how to calculate the "Threshold Voltage" section of the orderable part number.
OPN "Threshold
Voltage" number = (VIT- - 1) /
0.05
In this example, the nominal supply voltage for
the microcontroller is 1.8 V. The minimum supply voltage is 10% lower than the
nominal supply voltage, or 1.62 V. Setting a 1.65 V threshold ensures that the
device is reset just before the supply voltage reaches the minimum allowed. Thus a
1.65 V threshold is chosen and, using #GUID-6C90B256-3A47-4AA0-878A-A3AC84C87BCA/EQUATION-BLOCK_XV1_5Z1_YTB, the part number
is reduced to TPS36xx13xxxxxxxQ1. The hysteresis is 5% typical, resulting in a
positive-going threshold voltage, VIT+, of 1.73 V.
Determining Window Timings During Operation and Sleep Modes
The TPS36-Q1 allows for precise
10% accurate watchdog timings. This application requires two different window
timings in order to maximize power efficiency: one for the microcontroller's
operational state and one for its sleep state. To achieve this, the host can
reassign the SETx pins when it transitions between states. A window close time,
tWC, of 50 ms typical is chosen because of the application's 50 ms
typical tWC requirement. The application requires a minimum watchdog open
time, tWO, of 1.4 s during operation and a tWO of 12 s during
sleep. Thus, the possible variant options are narrowed to TPS36xx13FExDDFRQ1.
Meeting the Minimum Reset Delay
The TPS36-Q1 features two options for selecting reset delays: fixed delays and capacitor-programmable delays. The TPS36-Q1 supports only fixed watchdog timings and fixed reset delays or programmable watchdog timings and programmable reset delays. The application requires a 200 ms minimum reset delay, thus reset delay option G is used. Because of these requirements and no need for a startup delay, the TPS36CA13FEGDDFRQ1 is used.
Setting the Watchdog Window
In this application, the watchdog timing options
are based on the WDI signal that is provided to the TPS36-Q1. A
watchdog WDI setting must be chosen such that a transition must always occur within
the open watchdog window. There are several ways to achieve these window parameters.
An external capacitor can be placed on the CWD pin and calculated to have a
sufficient window close time. Another option is to use one of the factory-programmed
timing options. An additional advantage of choosing one of the factory-programmed
options is the ability to reduce the number of components required, thus reducing
overall BOM cost.
Calculating the RESET Pullup Resistor
The TPS36-Q1 uses an open-drain configuration for the RESET output, as shown in .When the FET is off, the resistor pulls the drain of the transistor to VDD and when the FET is turned on, the FET pulls the output to ground, thus creating an effective resistor divider. The resistors in this divider must be chosen to ensure that VOL is below its maximum value. To choose the proper pullup resistor, there are three key specifications to keep in mind: the pullup voltage (VPU), the recommended maximum RESET pin current (IRST), and VOL. The maximum VOL is 0.3 V, meaning that the effective resistor divider created must be able to bring the voltage on the reset pin below 0.3 V with IRST kept below 2 mA for VDD ≥ 3 V and 500 μA for VDD = 1.5 V. For this example, with a VPU =VDD = 1.5 V, a resistor must be chosen to keep IRST below 500 μA because this value is the maximum consumption current allowed. To ensure this specification is met, a pullup resistor value of 10 kΩ was selected, which sinks a maximum of 180 μA when RESET is asserted.
Open-Drain RESET Configuration
Design 1: Monitoring Microcontroller Supply and Watchdog During Operational and Sleep Modes
The TPS36-Q1 can utilize high-accuracy voltage monitoring and on-the-fly SETx assigning to monitor a microcontroller that has both an operational and sleep mode.
Monitoring Microcontroller
Supply and Watchdog During Operation and Sleep
The TPS36-Q1 can utilize high-accuracy voltage monitoring and on-the-fly SETx assigning to monitor a microcontroller that has both an operational and sleep mode.
Monitoring Microcontroller
Supply and Watchdog During Operation and Sleep
The TPS36-Q1 can utilize high-accuracy voltage monitoring and on-the-fly SETx assigning to monitor a microcontroller that has both an operational and sleep mode.
Monitoring Microcontroller
Supply and Watchdog During Operation and Sleep
Monitoring Microcontroller
Supply and Watchdog During Operation and Sleep
Design Requirements
Design Parameters
PARAMETER
DESIGN REQUIREMENT
DESIGN RESULT
Voltage Threshold
Typical Voltage Threshold of 1.65 V
Typical Voltage Threshold of 1.65 V
Window Close Time During Operation
Typical tWC of 50 ms during opertation
Typical tWC of 50 ms
Window Open Time During Operation
Typical tWO of 1.4 s during
operation
Typical tWO of 1.55 s
Window Close Time During Sleep
Typical tWC of 50 ms during sleep
Typical tWC of 50 ms
Window Open Time During Sleep
Typical tWO of 12 s during operation
Typical tWO of 12.75
s
RESET Delay
200 ms
200 ms
Output Logic
Open-drain
Open-drain
Maximum Device Current Consumption
20 μA
250 nA typical, 3 μA maximum
Design Requirements
Design Parameters
PARAMETER
DESIGN REQUIREMENT
DESIGN RESULT
Voltage Threshold
Typical Voltage Threshold of 1.65 V
Typical Voltage Threshold of 1.65 V
Window Close Time During Operation
Typical tWC of 50 ms during opertation
Typical tWC of 50 ms
Window Open Time During Operation
Typical tWO of 1.4 s during
operation
Typical tWO of 1.55 s
Window Close Time During Sleep
Typical tWC of 50 ms during sleep
Typical tWC of 50 ms
Window Open Time During Sleep
Typical tWO of 12 s during operation
Typical tWO of 12.75
s
RESET Delay
200 ms
200 ms
Output Logic
Open-drain
Open-drain
Maximum Device Current Consumption
20 μA
250 nA typical, 3 μA maximum
Design Parameters
PARAMETER
DESIGN REQUIREMENT
DESIGN RESULT
Voltage Threshold
Typical Voltage Threshold of 1.65 V
Typical Voltage Threshold of 1.65 V
Window Close Time During Operation
Typical tWC of 50 ms during opertation
Typical tWC of 50 ms
Window Open Time During Operation
Typical tWO of 1.4 s during
operation
Typical tWO of 1.55 s
Window Close Time During Sleep
Typical tWC of 50 ms during sleep
Typical tWC of 50 ms
Window Open Time During Sleep
Typical tWO of 12 s during operation
Typical tWO of 12.75
s
RESET Delay
200 ms
200 ms
Output Logic
Open-drain
Open-drain
Maximum Device Current Consumption
20 μA
250 nA typical, 3 μA maximum
Design Parameters
PARAMETER
DESIGN REQUIREMENT
DESIGN RESULT
Voltage Threshold
Typical Voltage Threshold of 1.65 V
Typical Voltage Threshold of 1.65 V
Window Close Time During Operation
Typical tWC of 50 ms during opertation
Typical tWC of 50 ms
Window Open Time During Operation
Typical tWO of 1.4 s during
operation
Typical tWO of 1.55 s
Window Close Time During Sleep
Typical tWC of 50 ms during sleep
Typical tWC of 50 ms
Window Open Time During Sleep
Typical tWO of 12 s during operation
Typical tWO of 12.75
s
RESET Delay
200 ms
200 ms
Output Logic
Open-drain
Open-drain
Maximum Device Current Consumption
20 μA
250 nA typical, 3 μA maximum
Design Parameters
PARAMETER
DESIGN REQUIREMENT
DESIGN RESULT
Voltage Threshold
Typical Voltage Threshold of 1.65 V
Typical Voltage Threshold of 1.65 V
Window Close Time During Operation
Typical tWC of 50 ms during opertation
Typical tWC of 50 ms
Window Open Time During Operation
Typical tWO of 1.4 s during
operation
Typical tWO of 1.55 s
Window Close Time During Sleep
Typical tWC of 50 ms during sleep
Typical tWC of 50 ms
Window Open Time During Sleep
Typical tWO of 12 s during operation
Typical tWO of 12.75
s
RESET Delay
200 ms
200 ms
Output Logic
Open-drain
Open-drain
Maximum Device Current Consumption
20 μA
250 nA typical, 3 μA maximum
PARAMETER
DESIGN REQUIREMENT
DESIGN RESULT
PARAMETER
DESIGN REQUIREMENT
DESIGN RESULT
PARAMETER
DESIGN REQUIREMENT
DESIGN REQUIREMENT
DESIGN RESULT
DESIGN RESULT
Voltage Threshold
Typical Voltage Threshold of 1.65 V
Typical Voltage Threshold of 1.65 V
Window Close Time During Operation
Typical tWC of 50 ms during opertation
Typical tWC of 50 ms
Window Open Time During Operation
Typical tWO of 1.4 s during
operation
Typical tWO of 1.55 s
Window Close Time During Sleep
Typical tWC of 50 ms during sleep
Typical tWC of 50 ms
Window Open Time During Sleep
Typical tWO of 12 s during operation
Typical tWO of 12.75
s
RESET Delay
200 ms
200 ms
Output Logic
Open-drain
Open-drain
Maximum Device Current Consumption
20 μA
250 nA typical, 3 μA maximum
Voltage Threshold
Typical Voltage Threshold of 1.65 V
Typical Voltage Threshold of 1.65 V
Voltage Threshold
Voltage Threshold
Typical Voltage Threshold of 1.65 V
Typical Voltage Threshold of 1.65 V
Typical Voltage Threshold of 1.65 V
Typical Voltage Threshold of 1.65 V
Window Close Time During Operation
Typical tWC of 50 ms during opertation
Typical tWC of 50 ms
Window Close Time During Operation
Window Close Time During Operation
Typical tWC of 50 ms during opertation
Typical tWC of 50 ms during opertationWC
Typical tWC of 50 ms
Typical tWC of 50 msWC
Window Open Time During Operation
Typical tWO of 1.4 s during
operation
Typical tWO of 1.55 s
Window Open Time During Operation
Window Open Time During Operation
Typical tWO of 1.4 s during
operation
Typical tWO of 1.4 s during
operationWO
Typical tWO of 1.55 s
Typical tWO of 1.55 sWO
Window Close Time During Sleep
Typical tWC of 50 ms during sleep
Typical tWC of 50 ms
Window Close Time During Sleep
Window Close Time During SleepTypical tWC of 50 ms during sleepWCTypical tWC of 50 msWC
Window Open Time During Sleep
Typical tWO of 12 s during operation
Typical tWO of 12.75
s
Window Open Time During Sleep
Window Open Time During SleepTypical tWO of 12 s during operationWOTypical tWO of 12.75
sWO
RESET Delay
200 ms
200 ms
RESET Delay
RESET Delay
200 ms
200 ms
200 ms
200 ms
Output Logic
Open-drain
Open-drain
Output Logic
Output Logic
Open-drain
Open-drain
Open-drain
Open-drain
Maximum Device Current Consumption
20 μA
250 nA typical, 3 μA maximum
Maximum Device Current Consumption
Maximum Device Current Consumption
20 μA
20 μA
250 nA typical, 3 μA maximum
250 nA typical, 3 μA maximum
Detailed Design Procedure
Setting Voltage Threshold
The negative-going threshold voltage, VIT-, is set by the device variant. #GUID-6C90B256-3A47-4AA0-878A-A3AC84C87BCA/EQUATION-BLOCK_XV1_5Z1_YTB shows how to calculate the "Threshold Voltage" section of the orderable part number.
OPN "Threshold
Voltage" number = (VIT- - 1) /
0.05
In this example, the nominal supply voltage for
the microcontroller is 1.8 V. The minimum supply voltage is 10% lower than the
nominal supply voltage, or 1.62 V. Setting a 1.65 V threshold ensures that the
device is reset just before the supply voltage reaches the minimum allowed. Thus a
1.65 V threshold is chosen and, using #GUID-6C90B256-3A47-4AA0-878A-A3AC84C87BCA/EQUATION-BLOCK_XV1_5Z1_YTB, the part number
is reduced to TPS36xx13xxxxxxxQ1. The hysteresis is 5% typical, resulting in a
positive-going threshold voltage, VIT+, of 1.73 V.
Determining Window Timings During Operation and Sleep Modes
The TPS36-Q1 allows for precise
10% accurate watchdog timings. This application requires two different window
timings in order to maximize power efficiency: one for the microcontroller's
operational state and one for its sleep state. To achieve this, the host can
reassign the SETx pins when it transitions between states. A window close time,
tWC, of 50 ms typical is chosen because of the application's 50 ms
typical tWC requirement. The application requires a minimum watchdog open
time, tWO, of 1.4 s during operation and a tWO of 12 s during
sleep. Thus, the possible variant options are narrowed to TPS36xx13FExDDFRQ1.
Meeting the Minimum Reset Delay
The TPS36-Q1 features two options for selecting reset delays: fixed delays and capacitor-programmable delays. The TPS36-Q1 supports only fixed watchdog timings and fixed reset delays or programmable watchdog timings and programmable reset delays. The application requires a 200 ms minimum reset delay, thus reset delay option G is used. Because of these requirements and no need for a startup delay, the TPS36CA13FEGDDFRQ1 is used.
Setting the Watchdog Window
In this application, the watchdog timing options
are based on the WDI signal that is provided to the TPS36-Q1. A
watchdog WDI setting must be chosen such that a transition must always occur within
the open watchdog window. There are several ways to achieve these window parameters.
An external capacitor can be placed on the CWD pin and calculated to have a
sufficient window close time. Another option is to use one of the factory-programmed
timing options. An additional advantage of choosing one of the factory-programmed
options is the ability to reduce the number of components required, thus reducing
overall BOM cost.
Calculating the RESET Pullup Resistor
The TPS36-Q1 uses an open-drain configuration for the RESET output, as shown in .When the FET is off, the resistor pulls the drain of the transistor to VDD and when the FET is turned on, the FET pulls the output to ground, thus creating an effective resistor divider. The resistors in this divider must be chosen to ensure that VOL is below its maximum value. To choose the proper pullup resistor, there are three key specifications to keep in mind: the pullup voltage (VPU), the recommended maximum RESET pin current (IRST), and VOL. The maximum VOL is 0.3 V, meaning that the effective resistor divider created must be able to bring the voltage on the reset pin below 0.3 V with IRST kept below 2 mA for VDD ≥ 3 V and 500 μA for VDD = 1.5 V. For this example, with a VPU =VDD = 1.5 V, a resistor must be chosen to keep IRST below 500 μA because this value is the maximum consumption current allowed. To ensure this specification is met, a pullup resistor value of 10 kΩ was selected, which sinks a maximum of 180 μA when RESET is asserted.
Open-Drain RESET Configuration
Detailed Design Procedure
Setting Voltage Threshold
The negative-going threshold voltage, VIT-, is set by the device variant. #GUID-6C90B256-3A47-4AA0-878A-A3AC84C87BCA/EQUATION-BLOCK_XV1_5Z1_YTB shows how to calculate the "Threshold Voltage" section of the orderable part number.
OPN "Threshold
Voltage" number = (VIT- - 1) /
0.05
In this example, the nominal supply voltage for
the microcontroller is 1.8 V. The minimum supply voltage is 10% lower than the
nominal supply voltage, or 1.62 V. Setting a 1.65 V threshold ensures that the
device is reset just before the supply voltage reaches the minimum allowed. Thus a
1.65 V threshold is chosen and, using #GUID-6C90B256-3A47-4AA0-878A-A3AC84C87BCA/EQUATION-BLOCK_XV1_5Z1_YTB, the part number
is reduced to TPS36xx13xxxxxxxQ1. The hysteresis is 5% typical, resulting in a
positive-going threshold voltage, VIT+, of 1.73 V.
Setting Voltage Threshold
The negative-going threshold voltage, VIT-, is set by the device variant. #GUID-6C90B256-3A47-4AA0-878A-A3AC84C87BCA/EQUATION-BLOCK_XV1_5Z1_YTB shows how to calculate the "Threshold Voltage" section of the orderable part number.
OPN "Threshold
Voltage" number = (VIT- - 1) /
0.05
In this example, the nominal supply voltage for
the microcontroller is 1.8 V. The minimum supply voltage is 10% lower than the
nominal supply voltage, or 1.62 V. Setting a 1.65 V threshold ensures that the
device is reset just before the supply voltage reaches the minimum allowed. Thus a
1.65 V threshold is chosen and, using #GUID-6C90B256-3A47-4AA0-878A-A3AC84C87BCA/EQUATION-BLOCK_XV1_5Z1_YTB, the part number
is reduced to TPS36xx13xxxxxxxQ1. The hysteresis is 5% typical, resulting in a
positive-going threshold voltage, VIT+, of 1.73 V.
The negative-going threshold voltage, VIT-, is set by the device variant. #GUID-6C90B256-3A47-4AA0-878A-A3AC84C87BCA/EQUATION-BLOCK_XV1_5Z1_YTB shows how to calculate the "Threshold Voltage" section of the orderable part number.
OPN "Threshold
Voltage" number = (VIT- - 1) /
0.05
In this example, the nominal supply voltage for
the microcontroller is 1.8 V. The minimum supply voltage is 10% lower than the
nominal supply voltage, or 1.62 V. Setting a 1.65 V threshold ensures that the
device is reset just before the supply voltage reaches the minimum allowed. Thus a
1.65 V threshold is chosen and, using #GUID-6C90B256-3A47-4AA0-878A-A3AC84C87BCA/EQUATION-BLOCK_XV1_5Z1_YTB, the part number
is reduced to TPS36xx13xxxxxxxQ1. The hysteresis is 5% typical, resulting in a
positive-going threshold voltage, VIT+, of 1.73 V.
The negative-going threshold voltage, VIT-, is set by the device variant. #GUID-6C90B256-3A47-4AA0-878A-A3AC84C87BCA/EQUATION-BLOCK_XV1_5Z1_YTB shows how to calculate the "Threshold Voltage" section of the orderable part number.IT-#GUID-6C90B256-3A47-4AA0-878A-A3AC84C87BCA/EQUATION-BLOCK_XV1_5Z1_YTB
OPN "Threshold
Voltage" number = (VIT- - 1) /
0.05
OPN "Threshold
Voltage" number = (VIT- - 1) /
0.05IT-In this example, the nominal supply voltage for
the microcontroller is 1.8 V. The minimum supply voltage is 10% lower than the
nominal supply voltage, or 1.62 V. Setting a 1.65 V threshold ensures that the
device is reset just before the supply voltage reaches the minimum allowed. Thus a
1.65 V threshold is chosen and, using #GUID-6C90B256-3A47-4AA0-878A-A3AC84C87BCA/EQUATION-BLOCK_XV1_5Z1_YTB, the part number
is reduced to TPS36xx13xxxxxxxQ1. The hysteresis is 5% typical, resulting in a
positive-going threshold voltage, VIT+, of 1.73 V.#GUID-6C90B256-3A47-4AA0-878A-A3AC84C87BCA/EQUATION-BLOCK_XV1_5Z1_YTBIT+
Determining Window Timings During Operation and Sleep Modes
The TPS36-Q1 allows for precise
10% accurate watchdog timings. This application requires two different window
timings in order to maximize power efficiency: one for the microcontroller's
operational state and one for its sleep state. To achieve this, the host can
reassign the SETx pins when it transitions between states. A window close time,
tWC, of 50 ms typical is chosen because of the application's 50 ms
typical tWC requirement. The application requires a minimum watchdog open
time, tWO, of 1.4 s during operation and a tWO of 12 s during
sleep. Thus, the possible variant options are narrowed to TPS36xx13FExDDFRQ1.
Determining Window Timings During Operation and Sleep Modes
The TPS36-Q1 allows for precise
10% accurate watchdog timings. This application requires two different window
timings in order to maximize power efficiency: one for the microcontroller's
operational state and one for its sleep state. To achieve this, the host can
reassign the SETx pins when it transitions between states. A window close time,
tWC, of 50 ms typical is chosen because of the application's 50 ms
typical tWC requirement. The application requires a minimum watchdog open
time, tWO, of 1.4 s during operation and a tWO of 12 s during
sleep. Thus, the possible variant options are narrowed to TPS36xx13FExDDFRQ1.
The TPS36-Q1 allows for precise
10% accurate watchdog timings. This application requires two different window
timings in order to maximize power efficiency: one for the microcontroller's
operational state and one for its sleep state. To achieve this, the host can
reassign the SETx pins when it transitions between states. A window close time,
tWC, of 50 ms typical is chosen because of the application's 50 ms
typical tWC requirement. The application requires a minimum watchdog open
time, tWO, of 1.4 s during operation and a tWO of 12 s during
sleep. Thus, the possible variant options are narrowed to TPS36xx13FExDDFRQ1.
The TPS36-Q1 allows for precise
10% accurate watchdog timings. This application requires two different window
timings in order to maximize power efficiency: one for the microcontroller's
operational state and one for its sleep state. To achieve this, the host can
reassign the SETx pins when it transitions between states. A window close time,
tWC, of 50 ms typical is chosen because of the application's 50 ms
typical tWC requirement. The application requires a minimum watchdog open
time, tWO, of 1.4 s during operation and a tWO of 12 s during
sleep. Thus, the possible variant options are narrowed to TPS36xx13FExDDFRQ1.TPS36-Q1WCWCWOWO
Meeting the Minimum Reset Delay
The TPS36-Q1 features two options for selecting reset delays: fixed delays and capacitor-programmable delays. The TPS36-Q1 supports only fixed watchdog timings and fixed reset delays or programmable watchdog timings and programmable reset delays. The application requires a 200 ms minimum reset delay, thus reset delay option G is used. Because of these requirements and no need for a startup delay, the TPS36CA13FEGDDFRQ1 is used.
Meeting the Minimum Reset Delay
The TPS36-Q1 features two options for selecting reset delays: fixed delays and capacitor-programmable delays. The TPS36-Q1 supports only fixed watchdog timings and fixed reset delays or programmable watchdog timings and programmable reset delays. The application requires a 200 ms minimum reset delay, thus reset delay option G is used. Because of these requirements and no need for a startup delay, the TPS36CA13FEGDDFRQ1 is used.
The TPS36-Q1 features two options for selecting reset delays: fixed delays and capacitor-programmable delays. The TPS36-Q1 supports only fixed watchdog timings and fixed reset delays or programmable watchdog timings and programmable reset delays. The application requires a 200 ms minimum reset delay, thus reset delay option G is used. Because of these requirements and no need for a startup delay, the TPS36CA13FEGDDFRQ1 is used.
The TPS36-Q1 features two options for selecting reset delays: fixed delays and capacitor-programmable delays. The TPS36-Q1 supports only fixed watchdog timings and fixed reset delays or programmable watchdog timings and programmable reset delays. The application requires a 200 ms minimum reset delay, thus reset delay option G is used. Because of these requirements and no need for a startup delay, the TPS36CA13FEGDDFRQ1 is used.TPS36-Q1
Setting the Watchdog Window
In this application, the watchdog timing options
are based on the WDI signal that is provided to the TPS36-Q1. A
watchdog WDI setting must be chosen such that a transition must always occur within
the open watchdog window. There are several ways to achieve these window parameters.
An external capacitor can be placed on the CWD pin and calculated to have a
sufficient window close time. Another option is to use one of the factory-programmed
timing options. An additional advantage of choosing one of the factory-programmed
options is the ability to reduce the number of components required, thus reducing
overall BOM cost.
Setting the Watchdog Window
In this application, the watchdog timing options
are based on the WDI signal that is provided to the TPS36-Q1. A
watchdog WDI setting must be chosen such that a transition must always occur within
the open watchdog window. There are several ways to achieve these window parameters.
An external capacitor can be placed on the CWD pin and calculated to have a
sufficient window close time. Another option is to use one of the factory-programmed
timing options. An additional advantage of choosing one of the factory-programmed
options is the ability to reduce the number of components required, thus reducing
overall BOM cost.
In this application, the watchdog timing options
are based on the WDI signal that is provided to the TPS36-Q1. A
watchdog WDI setting must be chosen such that a transition must always occur within
the open watchdog window. There are several ways to achieve these window parameters.
An external capacitor can be placed on the CWD pin and calculated to have a
sufficient window close time. Another option is to use one of the factory-programmed
timing options. An additional advantage of choosing one of the factory-programmed
options is the ability to reduce the number of components required, thus reducing
overall BOM cost.
In this application, the watchdog timing options
are based on the WDI signal that is provided to the TPS36-Q1. A
watchdog WDI setting must be chosen such that a transition must always occur within
the open watchdog window. There are several ways to achieve these window parameters.
An external capacitor can be placed on the CWD pin and calculated to have a
sufficient window close time. Another option is to use one of the factory-programmed
timing options. An additional advantage of choosing one of the factory-programmed
options is the ability to reduce the number of components required, thus reducing
overall BOM cost.TPS36-Q1
Calculating the RESET Pullup Resistor
The TPS36-Q1 uses an open-drain configuration for the RESET output, as shown in .When the FET is off, the resistor pulls the drain of the transistor to VDD and when the FET is turned on, the FET pulls the output to ground, thus creating an effective resistor divider. The resistors in this divider must be chosen to ensure that VOL is below its maximum value. To choose the proper pullup resistor, there are three key specifications to keep in mind: the pullup voltage (VPU), the recommended maximum RESET pin current (IRST), and VOL. The maximum VOL is 0.3 V, meaning that the effective resistor divider created must be able to bring the voltage on the reset pin below 0.3 V with IRST kept below 2 mA for VDD ≥ 3 V and 500 μA for VDD = 1.5 V. For this example, with a VPU =VDD = 1.5 V, a resistor must be chosen to keep IRST below 500 μA because this value is the maximum consumption current allowed. To ensure this specification is met, a pullup resistor value of 10 kΩ was selected, which sinks a maximum of 180 μA when RESET is asserted.
Open-Drain RESET Configuration
Calculating the RESET Pullup ResistorRESET
The TPS36-Q1 uses an open-drain configuration for the RESET output, as shown in .When the FET is off, the resistor pulls the drain of the transistor to VDD and when the FET is turned on, the FET pulls the output to ground, thus creating an effective resistor divider. The resistors in this divider must be chosen to ensure that VOL is below its maximum value. To choose the proper pullup resistor, there are three key specifications to keep in mind: the pullup voltage (VPU), the recommended maximum RESET pin current (IRST), and VOL. The maximum VOL is 0.3 V, meaning that the effective resistor divider created must be able to bring the voltage on the reset pin below 0.3 V with IRST kept below 2 mA for VDD ≥ 3 V and 500 μA for VDD = 1.5 V. For this example, with a VPU =VDD = 1.5 V, a resistor must be chosen to keep IRST below 500 μA because this value is the maximum consumption current allowed. To ensure this specification is met, a pullup resistor value of 10 kΩ was selected, which sinks a maximum of 180 μA when RESET is asserted.
Open-Drain RESET Configuration
The TPS36-Q1 uses an open-drain configuration for the RESET output, as shown in .When the FET is off, the resistor pulls the drain of the transistor to VDD and when the FET is turned on, the FET pulls the output to ground, thus creating an effective resistor divider. The resistors in this divider must be chosen to ensure that VOL is below its maximum value. To choose the proper pullup resistor, there are three key specifications to keep in mind: the pullup voltage (VPU), the recommended maximum RESET pin current (IRST), and VOL. The maximum VOL is 0.3 V, meaning that the effective resistor divider created must be able to bring the voltage on the reset pin below 0.3 V with IRST kept below 2 mA for VDD ≥ 3 V and 500 μA for VDD = 1.5 V. For this example, with a VPU =VDD = 1.5 V, a resistor must be chosen to keep IRST below 500 μA because this value is the maximum consumption current allowed. To ensure this specification is met, a pullup resistor value of 10 kΩ was selected, which sinks a maximum of 180 μA when RESET is asserted.
Open-Drain RESET Configuration
The TPS36-Q1 uses an open-drain configuration for the RESET output, as shown in .When the FET is off, the resistor pulls the drain of the transistor to VDD and when the FET is turned on, the FET pulls the output to ground, thus creating an effective resistor divider. The resistors in this divider must be chosen to ensure that VOL is below its maximum value. To choose the proper pullup resistor, there are three key specifications to keep in mind: the pullup voltage (VPU), the recommended maximum RESET pin current (IRST), and VOL. The maximum VOL is 0.3 V, meaning that the effective resistor divider created must be able to bring the voltage on the reset pin below 0.3 V with IRST kept below 2 mA for VDD ≥ 3 V and 500 μA for VDD = 1.5 V. For this example, with a VPU =VDD = 1.5 V, a resistor must be chosen to keep IRST below 500 μA because this value is the maximum consumption current allowed. To ensure this specification is met, a pullup resistor value of 10 kΩ was selected, which sinks a maximum of 180 μA when RESET is asserted.TPS36-Q1RESETOLPURESETRSTOLOLRSTDDDDPUDDRSTRESET
Open-Drain RESET Configuration
Open-Drain RESET Configuration
Open-Drain RESET ConfigurationRESET
Power Supply Recommendations
This device is designed to operate from
an input supply with a voltage range between 1.04 V and 6 V. An input supply capacitor is
not required for this device; however, if the input supply is noisy, then good analog
practice is to place a 0.1-µF capacitor between the VDD pin and the GND pin.
Power Supply Recommendations
This device is designed to operate from
an input supply with a voltage range between 1.04 V and 6 V. An input supply capacitor is
not required for this device; however, if the input supply is noisy, then good analog
practice is to place a 0.1-µF capacitor between the VDD pin and the GND pin.
This device is designed to operate from
an input supply with a voltage range between 1.04 V and 6 V. An input supply capacitor is
not required for this device; however, if the input supply is noisy, then good analog
practice is to place a 0.1-µF capacitor between the VDD pin and the GND pin.
This device is designed to operate from
an input supply with a voltage range between 1.04 V and 6 V. An input supply capacitor is
not required for this device; however, if the input supply is noisy, then good analog
practice is to place a 0.1-µF capacitor between the VDD pin and the GND pin.
Layout
Layout Guidelines
Make sure that the connection to the VDD pin is
low impedance. Good analog design practice recommends placing a 0.1-µF ceramic
capacitor as near as possible to the VDD pin. If a capacitor is not connected to the
CRST pin, then minimize parasitic capacitance on this pin so the
RESET
delay time is not adversely affected.
Make sure that the connection
to the VDD pin is low impedance. Good analog design practice is to place a
0.1-µF ceramic capacitor as near as possible to the VDD pin.
Place CCRST
capacitor as close as possible to the CRST pin.
Place CCWD
capacitor as close as possible to the CWD pin.
Place the pullup resistor on
the
RESET
pin as close to the pin as
possible.
Layout Example
Typical
Layout for the pinout C of TPS36-Q1
Layout
Layout Guidelines
Make sure that the connection to the VDD pin is
low impedance. Good analog design practice recommends placing a 0.1-µF ceramic
capacitor as near as possible to the VDD pin. If a capacitor is not connected to the
CRST pin, then minimize parasitic capacitance on this pin so the
RESET
delay time is not adversely affected.
Make sure that the connection
to the VDD pin is low impedance. Good analog design practice is to place a
0.1-µF ceramic capacitor as near as possible to the VDD pin.
Place CCRST
capacitor as close as possible to the CRST pin.
Place CCWD
capacitor as close as possible to the CWD pin.
Place the pullup resistor on
the
RESET
pin as close to the pin as
possible.
Layout Guidelines
Make sure that the connection to the VDD pin is
low impedance. Good analog design practice recommends placing a 0.1-µF ceramic
capacitor as near as possible to the VDD pin. If a capacitor is not connected to the
CRST pin, then minimize parasitic capacitance on this pin so the
RESET
delay time is not adversely affected.
Make sure that the connection
to the VDD pin is low impedance. Good analog design practice is to place a
0.1-µF ceramic capacitor as near as possible to the VDD pin.
Place CCRST
capacitor as close as possible to the CRST pin.
Place CCWD
capacitor as close as possible to the CWD pin.
Place the pullup resistor on
the
RESET
pin as close to the pin as
possible.
Make sure that the connection to the VDD pin is
low impedance. Good analog design practice recommends placing a 0.1-µF ceramic
capacitor as near as possible to the VDD pin. If a capacitor is not connected to the
CRST pin, then minimize parasitic capacitance on this pin so the
RESET
delay time is not adversely affected.
Make sure that the connection
to the VDD pin is low impedance. Good analog design practice is to place a
0.1-µF ceramic capacitor as near as possible to the VDD pin.
Place CCRST
capacitor as close as possible to the CRST pin.
Place CCWD
capacitor as close as possible to the CWD pin.
Place the pullup resistor on
the
RESET
pin as close to the pin as
possible.
Make sure that the connection to the VDD pin is
low impedance. Good analog design practice recommends placing a 0.1-µF ceramic
capacitor as near as possible to the VDD pin. If a capacitor is not connected to the
CRST pin, then minimize parasitic capacitance on this pin so the
RESET
delay time is not adversely affected.
Make sure that the connection
to the VDD pin is low impedance. Good analog design practice is to place a
0.1-µF ceramic capacitor as near as possible to the VDD pin.
Place CCRST
capacitor as close as possible to the CRST pin.
Place CCWD
capacitor as close as possible to the CWD pin.
Place the pullup resistor on
the
RESET
pin as close to the pin as
possible.
RESET
RESET
Make sure that the connection
to the VDD pin is low impedance. Good analog design practice is to place a
0.1-µF ceramic capacitor as near as possible to the VDD pin.
Place CCRST
capacitor as close as possible to the CRST pin.
Place CCWD
capacitor as close as possible to the CWD pin.
Place the pullup resistor on
the
RESET
pin as close to the pin as
possible.
Make sure that the connection
to the VDD pin is low impedance. Good analog design practice is to place a
0.1-µF ceramic capacitor as near as possible to the VDD pin.Place CCRST
capacitor as close as possible to the CRST pin.CRSTPlace CCWD
capacitor as close as possible to the CWD pin.CWDPlace the pullup resistor on
the
RESET
pin as close to the pin as
possible.
RESET
RESET
Layout Example
Typical
Layout for the pinout C of TPS36-Q1
Layout Example
Typical
Layout for the pinout C of TPS36-Q1
Typical
Layout for the pinout C of TPS36-Q1
Typical
Layout for the pinout C of TPS36-Q1
Typical
Layout for the pinout C of TPS36-Q1
TPS36-Q1
Device and Documentation Support
接收文档更新通知
要接收文档更新通知,请导航至 ti.com 上的器件米6体育平台手机版_好二三四文件夹。点击订阅更新 进行注册,即可每周接收米6体育平台手机版_好二三四信息更改摘要。有关更改的详细信息,请查看任何已修订文档中包含的修订历史记录。
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》。
Trademarks
静电放电警告
静电放电 (ESD) 会损坏这个集成电路。米6体育平台手机版_好二三四 (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。
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。
Device and Documentation Support
接收文档更新通知
要接收文档更新通知,请导航至 ti.com 上的器件米6体育平台手机版_好二三四文件夹。点击订阅更新 进行注册,即可每周接收米6体育平台手机版_好二三四信息更改摘要。有关更改的详细信息,请查看任何已修订文档中包含的修订历史记录。
接收文档更新通知
要接收文档更新通知,请导航至 ti.com 上的器件米6体育平台手机版_好二三四文件夹。点击订阅更新 进行注册,即可每周接收米6体育平台手机版_好二三四信息更改摘要。有关更改的详细信息,请查看任何已修订文档中包含的修订历史记录。
要接收文档更新通知,请导航至 ti.com 上的器件米6体育平台手机版_好二三四文件夹。点击订阅更新 进行注册,即可每周接收米6体育平台手机版_好二三四信息更改摘要。有关更改的详细信息,请查看任何已修订文档中包含的修订历史记录。
要接收文档更新通知,请导航至 ti.com 上的器件米6体育平台手机版_好二三四文件夹。点击订阅更新 进行注册,即可每周接收米6体育平台手机版_好二三四信息更改摘要。有关更改的详细信息,请查看任何已修订文档中包含的修订历史记录。ti.com订阅更新
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》。
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》。
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。
TI E2E 支持论坛TI E2E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》。《使用条款》
Trademarks
Trademarks
静电放电警告
静电放电 (ESD) 会损坏这个集成电路。米6体育平台手机版_好二三四 (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。
静电放电警告
静电放电 (ESD) 会损坏这个集成电路。米6体育平台手机版_好二三四 (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。
静电放电 (ESD) 会损坏这个集成电路。米6体育平台手机版_好二三四 (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。
静电放电 (ESD) 会损坏这个集成电路。米6体育平台手机版_好二三四 (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。
静电放电 (ESD) 会损坏这个集成电路。米6体育平台手机版_好二三四 (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。
静电放电 (ESD) 会损坏这个集成电路。米6体育平台手机版_好二三四 (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。
静电放电 (ESD) 会损坏这个集成电路。米6体育平台手机版_好二三四 (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。
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。
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。
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。
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。
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。
TI 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。
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The following pages include
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The following pages include
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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.
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.
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TI“按原样”提供技术和可靠性数据(包括数据表)、设计资源(包括参考设计)、应用或其他设计建议、网络工具、安全信息和其他资源,不保证没有瑕疵且不做出任何明示或暗示的担保,包括但不限于对适销性、某特定用途方面的适用性或不侵犯任何第三方知识产权的暗示担保。
这些资源可供使用 TI 米6体育平台手机版_好二三四进行设计的熟练开发人员使用。您将自行承担以下全部责任:(1) 针对您的应用选择合适的
TI 米6体育平台手机版_好二三四,(2) 设计、验证并测试您的应用,(3) 确保您的应用满足相应标准以及任何其他功能安全、信息安全、监管或其他要求。
这些资源如有变更,恕不另行通知。TI 授权您仅可将这些资源用于研发本资源所述的 TI
米6体育平台手机版_好二三四的应用。严禁对这些资源进行其他复制或展示。您无权使用任何其他 TI 知识产权或任何第三方知识产权。您应全额赔偿因在这些资源的使用中对 TI
及其代表造成的任何索赔、损害、成本、损失和债务,TI 对此概不负责。
TI 提供的米6体育平台手机版_好二三四受 TI 的销售条款或 ti.com 上其他适用条款/TI
米6体育平台手机版_好二三四随附的其他适用条款的约束。TI 提供这些资源并不会扩展或以其他方式更改 TI 针对 TI
米6体育平台手机版_好二三四发布的适用的担保或担保免责声明。
TI 反对并拒绝您可能提出的任何其他或不同的条款。IMPORTANT NOTICE
邮寄地址:Texas
Instruments, Post Office Box 655303, Dallas, Texas 75265Copyright © 2023,米6体育平台手机版_好二三四
(TI) 公司
重要声明和免责声明
TI“按原样”提供技术和可靠性数据(包括数据表)、设计资源(包括参考设计)、应用或其他设计建议、网络工具、安全信息和其他资源,不保证没有瑕疵且不做出任何明示或暗示的担保,包括但不限于对适销性、某特定用途方面的适用性或不侵犯任何第三方知识产权的暗示担保。
这些资源可供使用 TI 米6体育平台手机版_好二三四进行设计的熟练开发人员使用。您将自行承担以下全部责任:(1) 针对您的应用选择合适的
TI 米6体育平台手机版_好二三四,(2) 设计、验证并测试您的应用,(3) 确保您的应用满足相应标准以及任何其他功能安全、信息安全、监管或其他要求。
这些资源如有变更,恕不另行通知。TI 授权您仅可将这些资源用于研发本资源所述的 TI
米6体育平台手机版_好二三四的应用。严禁对这些资源进行其他复制或展示。您无权使用任何其他 TI 知识产权或任何第三方知识产权。您应全额赔偿因在这些资源的使用中对 TI
及其代表造成的任何索赔、损害、成本、损失和债务,TI 对此概不负责。
TI 提供的米6体育平台手机版_好二三四受 TI 的销售条款或 ti.com 上其他适用条款/TI
米6体育平台手机版_好二三四随附的其他适用条款的约束。TI 提供这些资源并不会扩展或以其他方式更改 TI 针对 TI
米6体育平台手机版_好二三四发布的适用的担保或担保免责声明。
TI 反对并拒绝您可能提出的任何其他或不同的条款。IMPORTANT NOTICE
邮寄地址:Texas
Instruments, Post Office Box 655303, Dallas, Texas 75265Copyright © 2023,米6体育平台手机版_好二三四
(TI) 公司
TI“按原样”提供技术和可靠性数据(包括数据表)、设计资源(包括参考设计)、应用或其他设计建议、网络工具、安全信息和其他资源,不保证没有瑕疵且不做出任何明示或暗示的担保,包括但不限于对适销性、某特定用途方面的适用性或不侵犯任何第三方知识产权的暗示担保。
这些资源可供使用 TI 米6体育平台手机版_好二三四进行设计的熟练开发人员使用。您将自行承担以下全部责任:(1) 针对您的应用选择合适的
TI 米6体育平台手机版_好二三四,(2) 设计、验证并测试您的应用,(3) 确保您的应用满足相应标准以及任何其他功能安全、信息安全、监管或其他要求。
这些资源如有变更,恕不另行通知。TI 授权您仅可将这些资源用于研发本资源所述的 TI
米6体育平台手机版_好二三四的应用。严禁对这些资源进行其他复制或展示。您无权使用任何其他 TI 知识产权或任何第三方知识产权。您应全额赔偿因在这些资源的使用中对 TI
及其代表造成的任何索赔、损害、成本、损失和债务,TI 对此概不负责。
TI 提供的米6体育平台手机版_好二三四受 TI 的销售条款或 ti.com 上其他适用条款/TI
米6体育平台手机版_好二三四随附的其他适用条款的约束。TI 提供这些资源并不会扩展或以其他方式更改 TI 针对 TI
米6体育平台手机版_好二三四发布的适用的担保或担保免责声明。
TI 反对并拒绝您可能提出的任何其他或不同的条款。IMPORTANT NOTICE
TI“按原样”提供技术和可靠性数据(包括数据表)、设计资源(包括参考设计)、应用或其他设计建议、网络工具、安全信息和其他资源,不保证没有瑕疵且不做出任何明示或暗示的担保,包括但不限于对适销性、某特定用途方面的适用性或不侵犯任何第三方知识产权的暗示担保。
这些资源可供使用 TI 米6体育平台手机版_好二三四进行设计的熟练开发人员使用。您将自行承担以下全部责任:(1) 针对您的应用选择合适的
TI 米6体育平台手机版_好二三四,(2) 设计、验证并测试您的应用,(3) 确保您的应用满足相应标准以及任何其他功能安全、信息安全、监管或其他要求。
这些资源如有变更,恕不另行通知。TI 授权您仅可将这些资源用于研发本资源所述的 TI
米6体育平台手机版_好二三四的应用。严禁对这些资源进行其他复制或展示。您无权使用任何其他 TI 知识产权或任何第三方知识产权。您应全额赔偿因在这些资源的使用中对 TI
及其代表造成的任何索赔、损害、成本、损失和债务,TI 对此概不负责。
TI 提供的米6体育平台手机版_好二三四受 TI 的销售条款或 ti.com 上其他适用条款/TI
米6体育平台手机版_好二三四随附的其他适用条款的约束。TI 提供这些资源并不会扩展或以其他方式更改 TI 针对 TI
米6体育平台手机版_好二三四发布的适用的担保或担保免责声明。
TI 反对并拒绝您可能提出的任何其他或不同的条款。IMPORTANT NOTICE
TI“按原样”提供技术和可靠性数据(包括数据表)、设计资源(包括参考设计)、应用或其他设计建议、网络工具、安全信息和其他资源,不保证没有瑕疵且不做出任何明示或暗示的担保,包括但不限于对适销性、某特定用途方面的适用性或不侵犯任何第三方知识产权的暗示担保。
这些资源可供使用 TI 米6体育平台手机版_好二三四进行设计的熟练开发人员使用。您将自行承担以下全部责任:(1) 针对您的应用选择合适的
TI 米6体育平台手机版_好二三四,(2) 设计、验证并测试您的应用,(3) 确保您的应用满足相应标准以及任何其他功能安全、信息安全、监管或其他要求。
这些资源如有变更,恕不另行通知。TI 授权您仅可将这些资源用于研发本资源所述的 TI
米6体育平台手机版_好二三四的应用。严禁对这些资源进行其他复制或展示。您无权使用任何其他 TI 知识产权或任何第三方知识产权。您应全额赔偿因在这些资源的使用中对 TI
及其代表造成的任何索赔、损害、成本、损失和债务,TI 对此概不负责。
TI 提供的米6体育平台手机版_好二三四受 TI 的销售条款或 ti.com 上其他适用条款/TI
米6体育平台手机版_好二三四随附的其他适用条款的约束。TI 提供这些资源并不会扩展或以其他方式更改 TI 针对 TI
米6体育平台手机版_好二三四发布的适用的担保或担保免责声明。
TI 反对并拒绝您可能提出的任何其他或不同的条款。IMPORTANT NOTICE
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TI 反对并拒绝您可能提出的任何其他或不同的条款。IMPORTANT NOTICE
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IMPORTANT NOTICE
邮寄地址:Texas
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Instruments, Post Office Box 655303, Dallas, Texas 75265Copyright © 2023,米6体育平台手机版_好二三四
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Instruments, Post Office Box 655303, Dallas, Texas 75265Copyright © 2023,米6体育平台手机版_好二三四
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Instruments, Post Office Box 655303, Dallas, Texas 75265Copyright © 2023,米6体育平台手机版_好二三四
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Copyright © 2023,米6体育平台手机版_好二三四
(TI) 公司 for the tD value computation. For a capacitor based tD delay option, the RESET will be asserted for tSTRT + 2 msec time if the CRST pin is open.
Device pinout options A to C offer only RESET output. In these devices the internal RESET output from supervisor and WDO output from watchdog timer are ANDed together to drive the external RESET output.
The supervisor offers wide range of fixed
monitoring thresholds (VIT-) from 1.05 V to 5.40 V in steps of 50 mV. The
device asserts the RESET output when the VDD signal falls below VIT-
threshold. The device offers hysteresis functionality for voltage supervision. This
ensures the supply has recovered above the monitoring threshold before the RESET
output is deasserted. The TPS36-Q1 typical voltage hysteresis
(VHYS) is 5%. Along with the voltage hysteresis, the device keeps the
RESET output asserted for time duration tD after the supply has risen
above VIT+. The RESET output assert duration changes from tD
to tSTRT + tD if the VDD signal is ramping from voltage <
VPOR. The tD time duration can be programmable using an
external capacitor or fixed time options offered by the device.
The typical timing behavior for a voltage
supervisor and the RESET output is showcased in Figure 8-5. The voltage
supervisor monitoring output has higher priority over watchdog functionality. If the
device voltage supervisor output is asserted, the watchdog functionality will be
disabled including WDO assert control. The device resumes watchdog related
functionality only after the supply is stable and the tD time duration
has elapsed.