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/**
@page TIM_BreakAndDeadtime TIM example
@verbatim
******************** (C) COPYRIGHT 2016 STMicroelectronics *******************
* @file Examples_LL/TIM/TIM_BreakAndDeadtime/readme.txt
* @author MCD Application Team
* @brief Description of the TIM_BreakAndDeadtime example.
******************************************************************************
* @attention
*
* Copyright (c) 2016 STMicroelectronics.
* All rights reserved.
*
* This software is licensed under terms that can be found in the LICENSE file
* in the root directory of this software component.
* If no LICENSE file comes with this software, it is provided AS-IS.
*
******************************************************************************
@endverbatim
@par Example Description
Configuration of the TIM peripheral to
three center-aligned PWM and complementary PWM signals,
insert a defined deadtime value,
use the break feature,
and lock the break and dead-time configuration.
This example is based on the STM32F0xx TIM LL API.The peripheral initialization
uses LL unitary services functions for optimization purposes (performance and size).
TIM1CLK is fixed to 48 MHz, the TIM1 Prescaler is set to have
TIM1 counter clock = 10 MHz.
The TIM1 auto-reload is set to generate PWM signal at 10 KHz:
The Three Duty cycles are computed as the following description:
The channel 1 duty cycle is set to 50% so channel 1N is set to 50%.
The channel 2 duty cycle is set to 25% so channel 2N is set to 75%.
The channel 3 duty cycle is set to 12.5% so channel 3N is set to 87.5%.
A dead time equal to 0,1 us is inserted between
the different complementary signals, and the Lock level 1 is selected.
- The OCx output signal is the same as the reference signal except for the rising edge,
which is delayed relative to the reference rising edge.
- The OCxN output signal is the opposite of the reference signal except for the rising
edge, which is delayed relative to the reference falling edge
Note that calculated duty cycles apply to the reference signal (OCxREF) from
which outputs OCx and OCxN are generated. As dead time insertion is enabled the
duty cycle measured on OCx will be slightly lower.
The break Polarity is used at High level.
The TIM1 waveforms can be displayed using an oscilloscope.
@par Directory contents
- TIM/TIM_BreakAndDeadtime/Inc/stm32f0xx_it.h Interrupt handlers header file
- TIM/TIM_BreakAndDeadtime/Inc/main.h Header for main.c module
- TIM/TIM_BreakAndDeadtime/Inc/stm32_assert.h Template file to include assert_failed function
- TIM/TIM_BreakAndDeadtime/Src/stm32f0xx_it.c Interrupt handlers
- TIM/TIM_BreakAndDeadtime/Src/main.c Main program
- TIM/TIM_BreakAndDeadtime/Src/system_stm32f0xx.c STM32F0xx system source file
@par Hardware and Software environment
- This example runs on STM32F072xB devices.
- This example has been tested with STM32F072RB-Nucleo RevC board and can be
easily tailored to any other supported device and development board.
- STM32F072RB-Nucleo RevC Set-up
- Connect the TIM1 pins to an oscilloscope to monitor the different waveforms:
- TIM1_CH1 PA.08: connected to pin 23 of CN10 connector
- TIM1_CH1N PA.07: connected to pin 15 of CN10 connector
- TIM1_CH2 PA.09: connected to pin 21 of CN10 connector
- TIM1_CH2N PB.00: connected to pin 34 of CN7 connector
- TIM1_CH3 PA.10: connected to pin 33 of CN10 connector
- TIM1_CH3N PB.01: connected to pin 24 of CN10 connector
- Connect the TIM1 break to the GND. To generate a break event, switch this
pin level from 0V to 3.3V.
- TIM1_BKIN PA.06: connected to pin 13 of CN10 connector
@par How to use it ?
In order to make the program work, you must do the following :
- Open your preferred toolchain
- Rebuild all files and load your image into target memory
- Run the example
*/