STM32F1_步进电机梯形加减速(标准库版本）_步进电机梯形算法stm32资源-CSDN文库

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h：31个

d：30个

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stm32

arm

嵌入式硬件

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STM32F1系列是意法半导体（STMicroelectronics）推出的基于ARM Cortex-M3内核的微控制器，广泛应用于各种嵌入式系统设计，包括工业自动化、机器人、仪表设备等。在本项目中，我们将讨论如何使用STM32F1单片机实现步进电机的梯形加减速控制，这是在许多运动控制系统中常见的方法。步进电机是一种将电脉冲转化为角位移的执行元件，每个脉冲使电机转过固定的角度，因此通过精确控制脉冲数量和频率，可以实现精确定位和速度控制。梯形加减速算法是一种简单有效的控制策略，它通过改变电机脉冲频率来调整电机的速度，实现平滑的启动、加速、匀速运行和减速停止。在STM32F1上实现这个功能，首先需要配置GPIO端口来驱动步进电机的四相线圈。这通常涉及设置GPIO模式为推挽输出，以便向电机线圈提供足够的驱动电流。同时，需要定时器来生成脉冲，定时器的工作模式可以设置为PWM或单脉冲模式，根据具体应用选择。在标准库版本的代码中，你需要初始化定时器，设置合适的预分频因子和比较值，以控制脉冲频率。例如，可以使用TIM_SetCompareX函数来设置比较寄存器值，以决定每次中断时电机应转过的角度。定时器中断服务程序是关键部分，它负责在每个中断发生时更新电机状态，可能是改变相序或调整脉冲频率。梯形加减速控制通常涉及到加速曲线的规划，可以预先定义加速时间和减速时间，然后在这些时间内线性增加或减少脉冲频率。例如，可以使用一个计数器变量，随着定时器中断的次数增加，逐步调整定时器的比较值，从而改变脉冲频率。当达到预设的加速或减速时间后，计数器停止变化，电机进入匀速运行阶段。在实际应用中，还需要考虑电机的空载启动和停止问题，以及过冲和振荡的抑制。这可能需要在加减速过程中引入适当的阻尼或者采用更复杂的控制算法，如S型曲线加减速。 STM32F1单片机结合梯形加减速算法，可以实现步进电机的精准控制。通过理解GPIO和定时器的配置，以及如何规划和执行加减速过程，开发者可以设计出满足不同需求的运动控制系统。源代码会详细展示这些步骤，对于初学者和有经验的工程师来说都是很好的学习资源。

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STM32F1_步进电机梯形加减速(标准库版本）（203个子文件）

STM32-F1.axf 323KB

CopyHex_Flash.bat 38B

stm32f10x_tim.c 107KB

stm32f10x_flash.c 61KB

stm32f10x_rcc.c 50KB

stm32f10x_adc.c 46KB

stm32f10x_i2c.c 45KB

stm32f10x_can.c 44KB

stm32f10x_usart.c 37KB

system_stm32f10x.c 36KB

stm32f10x_fsmc.c 35KB

stm32f10x_spi.c 30KB

stm32f10x_dma.c 29KB

stm32f10x_sdio.c 28KB

stm32f10x_gpio.c 23KB

bsp_TB6600_TIM.c 22KB

stm32f10x_dac.c 19KB

core_cm3.c 17KB

stm32f10x_cec.c 11KB

stm32f10x_pwr.c 9KB

stm32f10x_rtc.c 8KB

stm32f10x_bkp.c 8KB

misc.c 7KB

stm32f10x_exti.c 7KB

stm32f10x_wwdg.c 6KB

stm32f10x_dbgmcu.c 5KB

stm32f10x_iwdg.c 5KB

stm32f10x_it.c 4KB

bsp_debug_usart.c 4KB

bsp_key.c 4KB

stm32f10x_crc.c 3KB

main.c 1KB

stm32f10x_tim.crf 363KB

bsp_tb6600_tim.crf 355KB

main.crf 352KB

stm32f10x_can.crf 350KB

stm32f10x_adc.crf 348KB

stm32f10x_rcc.crf 348KB

stm32f10x_flash.crf 348KB

stm32f10x_i2c.crf 347KB

stm32f10x_usart.crf 347KB

stm32f10x_fsmc.crf 347KB

stm32f10x_sdio.crf 345KB

stm32f10x_spi.crf 345KB

stm32f10x_gpio.crf 345KB

stm32f10x_dma.crf 345KB

stm32f10x_dac.crf 343KB

stm32f10x_cec.crf 343KB

system_stm32f10x.crf 343KB

stm32f10x_bkp.crf 342KB

stm32f10x_rtc.crf 342KB

stm32f10x_pwr.crf 342KB

stm32f10x_exti.crf 342KB

bsp_key.crf 342KB

stm32f10x_wwdg.crf 342KB

misc.crf 341KB

stm32f10x_iwdg.crf 341KB

stm32f10x_crc.crf 341KB

stm32f10x_it.crf 341KB

stm32f10x_dbgmcu.crf 341KB

core_cm3.crf 4KB

bsp_tb6600_tim.d 3KB

stm32f10x_dbgmcu.d 3KB

stm32f10x_flash.d 3KB

stm32f10x_usart.d 3KB

stm32f10x_fsmc.d 3KB

stm32f10x_wwdg.d 3KB

stm32f10x_gpio.d 3KB

stm32f10x_exti.d 3KB

stm32f10x_sdio.d 3KB

stm32f10x_iwdg.d 3KB

system_stm32f10x.d 3KB

stm32f10x_dma.d 3KB

stm32f10x_can.d 3KB

stm32f10x_dac.d 3KB

stm32f10x_crc.d 3KB

stm32f10x_spi.d 3KB

stm32f10x_i2c.d 3KB

stm32f10x_pwr.d 3KB

stm32f10x_cec.d 3KB

stm32f10x_rcc.d 3KB

stm32f10x_rtc.d 3KB

stm32f10x_tim.d 3KB

stm32f10x_adc.d 3KB

stm32f10x_bkp.d 3KB

stm32f10x_it.d 3KB

main.d 2KB

bsp_key.d 2KB

misc.d 2KB

core_cm3.d 136B

startup_stm32f10x_hd.d 121B

YS-F1PRO_STM32F103ZE.dbgconf 7KB

STM32-F1_STM32F103ZE_1.0.0.dbgconf 7KB

YS-F1PRO_STM32F103ZE_1.0.0.dbgconf 7KB

STM32-F1PRO_STM32-F1.dep 78KB

YS-F1PRO_STM32-F1.dep 78KB

License.doc 39KB

stm32f10x.h 619KB

core_cm3.h 84KB

stm32f10x_tim.h 51KB

共 203 条

/** ****************************************************************************** * @file stm32f10x_tim.c * @author MCD Application Team * @version V3.5.0 * @date 11-March-2011 * @brief This file provides all the TIM firmware functions. ****************************************************************************** * @attention * * THE PRESENT FIRMWARE WHICH IS FOR GUIDANCE ONLY AIMS AT PROVIDING CUSTOMERS * WITH CODING INFORMATION REGARDING THEIR PRODUCTS IN ORDER FOR THEM TO SAVE * TIME. AS A RESULT, STMICROELECTRONICS SHALL NOT BE HELD LIABLE FOR ANY * DIRECT, INDIRECT OR CONSEQUENTIAL DAMAGES WITH RESPECT TO ANY CLAIMS ARISING * FROM THE CONTENT OF SUCH FIRMWARE AND/OR THE USE MADE BY CUSTOMERS OF THE * CODING INFORMATION CONTAINED HEREIN IN CONNECTION WITH THEIR PRODUCTS. * * <h2><center>© COPYRIGHT 2011 STMicroelectronics</center></h2> ****************************************************************************** */ /* Includes ------------------------------------------------------------------*/ #include "stm32f10x_tim.h" #include "stm32f10x_rcc.h" /** @addtogroup STM32F10x_StdPeriph_Driver * @{ */ /** @defgroup TIM * @brief TIM driver modules * @{ */ /** @defgroup TIM_Private_TypesDefinitions * @{ */ /** * @} */ /** @defgroup TIM_Private_Defines * @{ */ /* ---------------------- TIM registers bit mask ------------------------ */ #define SMCR_ETR_Mask ((uint16_t)0x00FF) #define CCMR_Offset ((uint16_t)0x0018) #define CCER_CCE_Set ((uint16_t)0x0001) #define CCER_CCNE_Set ((uint16_t)0x0004) /** * @} */ /** @defgroup TIM_Private_Macros * @{ */ /** * @} */ /** @defgroup TIM_Private_Variables * @{ */ /** * @} */ /** @defgroup TIM_Private_FunctionPrototypes * @{ */ static void TI1_Config(TIM_TypeDef* TIMx, uint16_t TIM_ICPolarity, uint16_t TIM_ICSelection, uint16_t TIM_ICFilter); static void TI2_Config(TIM_TypeDef* TIMx, uint16_t TIM_ICPolarity, uint16_t TIM_ICSelection, uint16_t TIM_ICFilter); static void TI3_Config(TIM_TypeDef* TIMx, uint16_t TIM_ICPolarity, uint16_t TIM_ICSelection, uint16_t TIM_ICFilter); static void TI4_Config(TIM_TypeDef* TIMx, uint16_t TIM_ICPolarity, uint16_t TIM_ICSelection, uint16_t TIM_ICFilter); /** * @} */ /** @defgroup TIM_Private_Macros * @{ */ /** * @} */ /** @defgroup TIM_Private_Variables * @{ */ /** * @} */ /** @defgroup TIM_Private_FunctionPrototypes * @{ */ /** * @} */ /** @defgroup TIM_Private_Functions * @{ */ /** * @brief Deinitializes the TIMx peripheral registers to their default reset values. * @param TIMx: where x can be 1 to 17 to select the TIM peripheral. * @retval None */ void TIM_DeInit(TIM_TypeDef* TIMx) { /* Check the parameters */ assert_param(IS_TIM_ALL_PERIPH(TIMx)); if (TIMx == TIM1) { RCC_APB2PeriphResetCmd(RCC_APB2Periph_TIM1, ENABLE); RCC_APB2PeriphResetCmd(RCC_APB2Periph_TIM1, DISABLE); } else if (TIMx == TIM2) { RCC_APB1PeriphResetCmd(RCC_APB1Periph_TIM2, ENABLE); RCC_APB1PeriphResetCmd(RCC_APB1Periph_TIM2, DISABLE); } else if (TIMx == TIM3) { RCC_APB1PeriphResetCmd(RCC_APB1Periph_TIM3, ENABLE); RCC_APB1PeriphResetCmd(RCC_APB1Periph_TIM3, DISABLE); } else if (TIMx == TIM4) { RCC_APB1PeriphResetCmd(RCC_APB1Periph_TIM4, ENABLE); RCC_APB1PeriphResetCmd(RCC_APB1Periph_TIM4, DISABLE); } else if (TIMx == TIM5) { RCC_APB1PeriphResetCmd(RCC_APB1Periph_TIM5, ENABLE); RCC_APB1PeriphResetCmd(RCC_APB1Periph_TIM5, DISABLE); } else if (TIMx == TIM6) { RCC_APB1PeriphResetCmd(RCC_APB1Periph_TIM6, ENABLE); RCC_APB1PeriphResetCmd(RCC_APB1Periph_TIM6, DISABLE); } else if (TIMx == TIM7) { RCC_APB1PeriphResetCmd(RCC_APB1Periph_TIM7, ENABLE); RCC_APB1PeriphResetCmd(RCC_APB1Periph_TIM7, DISABLE); } else if (TIMx == TIM8) { RCC_APB2PeriphResetCmd(RCC_APB2Periph_TIM8, ENABLE); RCC_APB2PeriphResetCmd(RCC_APB2Periph_TIM8, DISABLE); } else if (TIMx == TIM9) { RCC_APB2PeriphResetCmd(RCC_APB2Periph_TIM9, ENABLE); RCC_APB2PeriphResetCmd(RCC_APB2Periph_TIM9, DISABLE); } else if (TIMx == TIM10) { RCC_APB2PeriphResetCmd(RCC_APB2Periph_TIM10, ENABLE); RCC_APB2PeriphResetCmd(RCC_APB2Periph_TIM10, DISABLE); } else if (TIMx == TIM11) { RCC_APB2PeriphResetCmd(RCC_APB2Periph_TIM11, ENABLE); RCC_APB2PeriphResetCmd(RCC_APB2Periph_TIM11, DISABLE); } else if (TIMx == TIM12) { RCC_APB1PeriphResetCmd(RCC_APB1Periph_TIM12, ENABLE); RCC_APB1PeriphResetCmd(RCC_APB1Periph_TIM12, DISABLE); } else if (TIMx == TIM13) { RCC_APB1PeriphResetCmd(RCC_APB1Periph_TIM13, ENABLE); RCC_APB1PeriphResetCmd(RCC_APB1Periph_TIM13, DISABLE); } else if (TIMx == TIM14) { RCC_APB1PeriphResetCmd(RCC_APB1Periph_TIM14, ENABLE); RCC_APB1PeriphResetCmd(RCC_APB1Periph_TIM14, DISABLE); } else if (TIMx == TIM15) { RCC_APB2PeriphResetCmd(RCC_APB2Periph_TIM15, ENABLE); RCC_APB2PeriphResetCmd(RCC_APB2Periph_TIM15, DISABLE); } else if (TIMx == TIM16) { RCC_APB2PeriphResetCmd(RCC_APB2Periph_TIM16, ENABLE); RCC_APB2PeriphResetCmd(RCC_APB2Periph_TIM16, DISABLE); } else { if (TIMx == TIM17) { RCC_APB2PeriphResetCmd(RCC_APB2Periph_TIM17, ENABLE); RCC_APB2PeriphResetCmd(RCC_APB2Periph_TIM17, DISABLE); } } } /** * @brief Initializes the TIMx Time Base Unit peripheral according to * the specified parameters in the TIM_TimeBaseInitStruct. * @param TIMx: where x can be 1 to 17 to select the TIM peripheral. * @param TIM_TimeBaseInitStruct: pointer to a TIM_TimeBaseInitTypeDef * structure that contains the configuration information for the * specified TIM peripheral. * @retval None */ void TIM_TimeBaseInit(TIM_TypeDef* TIMx, TIM_TimeBaseInitTypeDef* TIM_TimeBaseInitStruct) { uint16_t tmpcr1 = 0; /* Check the parameters */ assert_param(IS_TIM_ALL_PERIPH(TIMx)); assert_param(IS_TIM_COUNTER_MODE(TIM_TimeBaseInitStruct->TIM_CounterMode)); assert_param(IS_TIM_CKD_DIV(TIM_TimeBaseInitStruct->TIM_ClockDivision)); tmpcr1 = TIMx->CR1; if((TIMx == TIM1) || (TIMx == TIM8)|| (TIMx == TIM2) || (TIMx == TIM3)|| (TIMx == TIM4) || (TIMx == TIM5)) { /* Select the Counter Mode */ tmpcr1 &= (uint16_t)(~((uint16_t)(TIM_CR1_DIR | TIM_CR1_CMS))); tmpcr1 |= (uint32_t)TIM_TimeBaseInitStruct->TIM_CounterMode; } if((TIMx != TIM6) && (TIMx != TIM7)) { /* Set the clock division */ tmpcr1 &= (uint16_t)(~((uint16_t)TIM_CR1_CKD)); tmpcr1 |= (uint32_t)TIM_TimeBaseInitStruct->TIM_ClockDivision; } TIMx->CR1 = tmpcr1; /* Set the Autoreload value */ TIMx->ARR = TIM_TimeBaseInitStruct->TIM_Period ; /* Set the Prescaler value */ TIMx->PSC = TIM_TimeBaseInitStruct->TIM_Prescaler; if ((TIMx == TIM1) || (TIMx == TIM8)|| (TIMx == TIM15)|| (TIMx == TIM16) || (TIMx == TIM17)) { /* Set the Repetition Counter value */ TIMx->RCR = TIM_TimeBaseInitStruct->TIM_RepetitionCounter; } /* Generate an update event to reload the Prescaler and the Repetition counter values immediately */ TIMx->EGR = TIM_PSCReloadMode_Immediate; } /** * @brief Initializes the TIMx Channel1 according to the specified * parameters in the TIM_OCInitStruct. * @param TIMx: where x can be 1 to 17 except 6 and 7 to select the TIM peripheral. * @param TIM_OCInitStru

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