NRF51822自學筆記（二）PWM

本文轉載自查看原文 2016-09-08 19:05 2422 NRF51822/ PWM

PWM這個東西我在32上用來電機調速過……通過改變高低電平占空比來實現一些功能。

keil的nrf51822目錄下沒有pwm.c..就在網上找了個pwm蜂鳴器的例程……看畫風應該是官方的……吧……

例程的define為NRF51 SETUPA BOARD_PCA10028..修改一下，設置如下。

然后通過兩個燈來實現一下兩路pwm波……pin為20和21的LED_2和LED_3

先看main.c（非例程）

[cpp] view plain copy

print ?

#include <stdbool.h>
#include <stdint.h>
#include "nrf_delay.h"
#include "nrf_gpio.h"
#include "boards.h"
#include "nrf_pwm.h"
/**
* @brief Function for application main entry.
*/
int main(void)
{
// Configure LED-pins as outputs
nrf_gpio_cfg_output(20);
nrf_gpio_cfg_output(21);
nrf_pwm_config_t pwm_config = PWM_DEFAULT_CONFIG;
pwm_config.mode = PWM_MODE_LED_255;
pwm_config.num_channels = 2;
pwm_config.gpio_num[0] = 21;
pwm_config.gpio_num[1] = 20;
nrf_pwm_init(&pwm_config);
nrf_pwm_set_value(0,20);
nrf_pwm_set_value(1,255);
}

#include <stdbool.h>
#include <stdint.h>
#include "nrf_delay.h"
#include "nrf_gpio.h"
#include "boards.h"
#include "nrf_pwm.h"

/**
 * @brief Function for application main entry.
 */
int main(void)
{
    // Configure LED-pins as outputs
	  nrf_gpio_cfg_output(20);
	  nrf_gpio_cfg_output(21);
	
	  nrf_pwm_config_t pwm_config = PWM_DEFAULT_CONFIG;
    
          pwm_config.mode             = PWM_MODE_LED_255;
          pwm_config.num_channels     = 2;
          pwm_config.gpio_num[0]      = 21;
          pwm_config.gpio_num[1]      = 20;
	  nrf_pwm_init(&pwm_config);
	  nrf_pwm_set_value(0,20);
	  nrf_pwm_set_value(1,255);
}

第一步把要操作的燈的pin配置一下，設置成outputs

第二步用一個結構體來設置一下PWM的一些參數。

追蹤一下PWM_DEFAULT_CONFIG，發現它在PWM.H里

[cpp] view plain copy

print ?

#define PWM_DEFAULT_CONFIG {.num_channels = 2, \
.gpio_num = {8,9,10,11}, \
.ppi_channel = {0,1,2,3,4,5,6,7}, \
.gpiote_channel = {2,3,0,1}, \
.mode = PWM_MODE_LED_100};

#define PWM_DEFAULT_CONFIG  {.num_channels   = 2,                \
                             .gpio_num       = {8,9,10,11},         \
                             .ppi_channel    = {0,1,2,3,4,5,6,7},    \
                             .gpiote_channel = {2,3,0,1},          \
                             .mode           = PWM_MODE_LED_100};

然后配置mode為PWM_MODE_LED_255，兩個通道，兩個通道的pin為21和20。把結構體地址傳給初始化函數，初始化之后調用nrf_pwm_set_value()來設置一下占空比。

追蹤一下那個mode

[cpp] view plain copy

print ?

typedef enum
{
PWM_MODE_LED_100, // 0-100 resolution, 156Hz PWM frequency, 32kHz timer frequency (prescaler 9)
PWM_MODE_LED_255, // 8-bit resolution, 122Hz PWM frequency, 32kHz timer frequency (prescaler 9)
PWM_MODE_LED_1000, // 0-1000 resolution, 125Hz PWM frequency, 250kHz timer frequency (prescaler 6)
PWM_MODE_MTR_100, // 0-100 resolution, 20kHz PWM frequency, 2MHz timer frequency (prescaler 3)
PWM_MODE_MTR_255, // 8-bit resolution, 31kHz PWM frequency, 8MHz timer frequency (prescaler 1)
PWM_MODE_BUZZER_255 // 8-bit resolution, 62.5kHz PWM frequency, 16MHz timer frequency (prescaler 0)
} nrf_pwm_mode_t;

typedef enum
{
    PWM_MODE_LED_100,   // 0-100 resolution, 156Hz PWM frequency, 32kHz timer frequency (prescaler 9)
    PWM_MODE_LED_255,   // 8-bit resolution, 122Hz PWM frequency, 32kHz timer frequency (prescaler 9)
    PWM_MODE_LED_1000,  // 0-1000 resolution, 125Hz PWM frequency, 250kHz timer frequency (prescaler 6)
    
    PWM_MODE_MTR_100,   // 0-100 resolution, 20kHz PWM frequency, 2MHz timer frequency (prescaler 3)
    PWM_MODE_MTR_255,   // 8-bit resolution, 31kHz PWM frequency, 8MHz timer frequency (prescaler 1)
    
    PWM_MODE_BUZZER_255  // 8-bit resolution, 62.5kHz PWM frequency, 16MHz timer frequency (prescaler 0)
} nrf_pwm_mode_t;

= =一堆枚舉常量，LED，蜂鳴器和MTR。在初始化函數里利用它們和switch語句實現了配置………

uint32_t nrf_pwm_init(nrf_pwm_config_t *config)
{
if(config->num_channels == 0 || config->num_channels > PWM_MAX_CHANNELS) return 0xFFFFFFFF;
switch(config->mode)
{
case PWM_MODE_LED_100: // 0-100 resolution, 321Hz PWM frequency, 32kHz timer frequency (prescaler 9)
PWM_TIMER->PRESCALER = 9;
pwm_max_value = 100;
break;
case PWM_MODE_LED_255: // 8-bit resolution, 122Hz PWM frequency, 32kHz timer frequency (prescaler 9)
PWM_TIMER->PRESCALER = 9;
pwm_max_value = 255;
break;
case PWM_MODE_LED_1000: // 0-1000 resolution, 250Hz PWM frequency, 250kHz timer frequency (prescaler 6)
PWM_TIMER->PRESCALER = 6;
pwm_max_value = 1000;
break;
case PWM_MODE_MTR_100: // 0-100 resolution, 20kHz PWM frequency, 2MHz timer frequency (prescaler 3)
PWM_TIMER->PRESCALER = 3;
pwm_max_value = 100;
break;
case PWM_MODE_MTR_255: // 8-bit resolution, 31kHz PWM frequency, 8MHz timer frequency (prescaler 1)
PWM_TIMER->PRESCALER = 1;
pwm_max_value = 255;
break;
case PWM_MODE_BUZZER_255: // 8-bit resolution, 62.5kHz PWM frequency, 16MHz timer frequency (prescaler 0)
PWM_TIMER->PRESCALER = 0;
pwm_max_value = 255;
break;
default:
return 0xFFFFFFFF;
}
pwm_cc_update_margin_ticks = pwm_cc_margin_by_prescaler[PWM_TIMER->PRESCALER];
pwm_num_channels = config->num_channels;
for(int i = 0; i < pwm_num_channels; i++)
{
pwm_io_ch[i] = (uint32_t)config->gpio_num[i];
nrf_gpio_cfg_output(pwm_io_ch[i]);
pwm_running[i] = 0;
pwm_gpiote_channel[i] = config->gpiote_channel[i];
}
PWM_TIMER->TASKS_CLEAR = 1;
PWM_TIMER->BITMODE = TIMER_BITMODE_BITMODE_16Bit;
PWM_TIMER->CC[2] = pwm_next_max_value = pwm_max_value;
PWM_TIMER->MODE = TIMER_MODE_MODE_Timer;
PWM_TIMER->SHORTS = TIMER_SHORTS_COMPARE2_CLEAR_Msk;
PWM_TIMER->EVENTS_COMPARE[0] = PWM_TIMER->EVENTS_COMPARE[1] = PWM_TIMER->EVENTS_COMPARE[2] = PWM_TIMER->EVENTS_COMPARE[3] = 0;
if(pwm_num_channels > 2)
{
PWM_TIMER2->TASKS_CLEAR = 1;
PWM_TIMER2->BITMODE = TIMER_BITMODE_BITMODE_16Bit;
PWM_TIMER2->CC[2] = pwm_next_max_value = pwm_max_value;
PWM_TIMER2->MODE = TIMER_MODE_MODE_Timer;
PWM_TIMER2->SHORTS = TIMER_SHORTS_COMPARE2_CLEAR_Msk;
PWM_TIMER2->EVENTS_COMPARE[0] = PWM_TIMER2->EVENTS_COMPARE[1] = PWM_TIMER2->EVENTS_COMPARE[2] = PWM_TIMER2->EVENTS_COMPARE[3] = 0;
PWM_TIMER2->PRESCALER = PWM_TIMER->PRESCALER;
}
for(int i = 0; i < pwm_num_channels && i < 2; i++)
{
ppi_enable_channel(config->ppi_channel[i*2], &PWM_TIMER->EVENTS_COMPARE[i], &NRF_GPIOTE->TASKS_OUT[pwm_gpiote_channel[i]]);
ppi_enable_channel(config->ppi_channel[i*2+1],&PWM_TIMER->EVENTS_COMPARE[2], &NRF_GPIOTE->TASKS_OUT[pwm_gpiote_channel[i]]);
pwm_modified[i] = false;
}
for(int i = 2; i < pwm_num_channels; i++)
{
ppi_enable_channel(config->ppi_channel[i*2], &PWM_TIMER2->EVENTS_COMPARE[i-2], &NRF_GPIOTE->TASKS_OUT[pwm_gpiote_channel[i]]);
ppi_enable_channel(config->ppi_channel[i*2+1],&PWM_TIMER2->EVENTS_COMPARE[2], &NRF_GPIOTE->TASKS_OUT[pwm_gpiote_channel[i]]);
pwm_modified[i] = false;
}
#if(USE_WITH_SOFTDEVICE == 1)
sd_radio_session_open(nrf_radio_signal_callback);
#else
NVIC_SetPriority(PWM_IRQn, 0);
NVIC_EnableIRQ(PWM_IRQn);
#endif
apply_pan73_workaround(PWM_TIMER, true);
PWM_TIMER->TASKS_START = 1;
if(pwm_num_channels > 2)
{
apply_pan73_workaround(PWM_TIMER2, true);
PWM_TIMER2->TASKS_START = 1;
}
return 0;
}

uint32_t nrf_pwm_init(nrf_pwm_config_t *config)
{
    if(config->num_channels == 0 || config->num_channels > PWM_MAX_CHANNELS) return 0xFFFFFFFF;
    
    switch(config->mode)
    {
        case PWM_MODE_LED_100:   // 0-100 resolution, 321Hz PWM frequency, 32kHz timer frequency (prescaler 9)
            PWM_TIMER->PRESCALER = 9; 
            pwm_max_value = 100;
            break;
        case PWM_MODE_LED_255:   // 8-bit resolution, 122Hz PWM frequency, 32kHz timer frequency (prescaler 9)
            PWM_TIMER->PRESCALER = 9;
            pwm_max_value = 255;  
            break;
        case PWM_MODE_LED_1000:  // 0-1000 resolution, 250Hz PWM frequency, 250kHz timer frequency (prescaler 6)
            PWM_TIMER->PRESCALER = 6;
            pwm_max_value = 1000;
            break;
        case PWM_MODE_MTR_100:   // 0-100 resolution, 20kHz PWM frequency, 2MHz timer frequency (prescaler 3)
            PWM_TIMER->PRESCALER = 3;
            pwm_max_value = 100;
            break;
        case PWM_MODE_MTR_255:    // 8-bit resolution, 31kHz PWM frequency, 8MHz timer frequency (prescaler 1)	
            PWM_TIMER->PRESCALER = 1;
            pwm_max_value = 255;
            break;
        case PWM_MODE_BUZZER_255:  // 8-bit resolution, 62.5kHz PWM frequency, 16MHz timer frequency (prescaler 0)
            PWM_TIMER->PRESCALER = 0;
            pwm_max_value = 255;
            break;
        default:
            return 0xFFFFFFFF;
    }
    pwm_cc_update_margin_ticks = pwm_cc_margin_by_prescaler[PWM_TIMER->PRESCALER];
    pwm_num_channels = config->num_channels;
    for(int i = 0; i < pwm_num_channels; i++)
    {
        pwm_io_ch[i] = (uint32_t)config->gpio_num[i];
        nrf_gpio_cfg_output(pwm_io_ch[i]);
        pwm_running[i] = 0;       
        pwm_gpiote_channel[i] = config->gpiote_channel[i];        
    }
    PWM_TIMER->TASKS_CLEAR = 1;
    PWM_TIMER->BITMODE = TIMER_BITMODE_BITMODE_16Bit;
    PWM_TIMER->CC[2] = pwm_next_max_value = pwm_max_value;
	PWM_TIMER->MODE = TIMER_MODE_MODE_Timer;
    PWM_TIMER->SHORTS = TIMER_SHORTS_COMPARE2_CLEAR_Msk;
    PWM_TIMER->EVENTS_COMPARE[0] = PWM_TIMER->EVENTS_COMPARE[1] = PWM_TIMER->EVENTS_COMPARE[2] = PWM_TIMER->EVENTS_COMPARE[3] = 0;     
    
    if(pwm_num_channels > 2)
    {
        PWM_TIMER2->TASKS_CLEAR = 1;
        PWM_TIMER2->BITMODE = TIMER_BITMODE_BITMODE_16Bit;
        PWM_TIMER2->CC[2] = pwm_next_max_value = pwm_max_value;
        PWM_TIMER2->MODE = TIMER_MODE_MODE_Timer;
        PWM_TIMER2->SHORTS = TIMER_SHORTS_COMPARE2_CLEAR_Msk;
        PWM_TIMER2->EVENTS_COMPARE[0] = PWM_TIMER2->EVENTS_COMPARE[1] = PWM_TIMER2->EVENTS_COMPARE[2] = PWM_TIMER2->EVENTS_COMPARE[3] = 0;             
        PWM_TIMER2->PRESCALER = PWM_TIMER->PRESCALER;
    }

    for(int i = 0; i < pwm_num_channels && i < 2; i++)
    {
        ppi_enable_channel(config->ppi_channel[i*2],  &PWM_TIMER->EVENTS_COMPARE[i], &NRF_GPIOTE->TASKS_OUT[pwm_gpiote_channel[i]]);
        ppi_enable_channel(config->ppi_channel[i*2+1],&PWM_TIMER->EVENTS_COMPARE[2], &NRF_GPIOTE->TASKS_OUT[pwm_gpiote_channel[i]]);  
        pwm_modified[i] = false;        
    }
    for(int i = 2; i < pwm_num_channels; i++)
    {
        ppi_enable_channel(config->ppi_channel[i*2],  &PWM_TIMER2->EVENTS_COMPARE[i-2], &NRF_GPIOTE->TASKS_OUT[pwm_gpiote_channel[i]]);
        ppi_enable_channel(config->ppi_channel[i*2+1],&PWM_TIMER2->EVENTS_COMPARE[2], &NRF_GPIOTE->TASKS_OUT[pwm_gpiote_channel[i]]);  
        pwm_modified[i] = false;        
    }
#if(USE_WITH_SOFTDEVICE == 1)
    sd_radio_session_open(nrf_radio_signal_callback);
#else
    NVIC_SetPriority(PWM_IRQn, 0);
    NVIC_EnableIRQ(PWM_IRQn);
#endif
    apply_pan73_workaround(PWM_TIMER, true);
    PWM_TIMER->TASKS_START = 1;
    if(pwm_num_channels > 2)
    {
        apply_pan73_workaround(PWM_TIMER2, true);
        PWM_TIMER2->TASKS_START = 1;
    }
    return 0;
}

當通道數大於2時，就要使用TIMER2了。下面是設置占空比的

void nrf_pwm_set_value(uint32_t pwm_channel, uint32_t pwm_value)
{
pwm_next_value[pwm_channel] = pwm_value;
pwm_modified[pwm_channel] = true;
#if(USE_WITH_SOFTDEVICE == 1)
nrf_radio_request_t radio_request;
radio_request.request_type = NRF_RADIO_REQ_TYPE_EARLIEST;
radio_request.params.earliest.hfclk = NRF_RADIO_HFCLK_CFG_DEFAULT;
radio_request.params.earliest.length_us = 250;
radio_request.params.earliest.priority = NRF_RADIO_PRIORITY_HIGH;
radio_request.params.earliest.timeout_us = 100000;
sd_radio_request(&radio_request);
#else
NVIC_SetPendingIRQ(PWM_IRQn);
#endif

void nrf_pwm_set_value(uint32_t pwm_channel, uint32_t pwm_value)
{
    pwm_next_value[pwm_channel] = pwm_value;
    pwm_modified[pwm_channel] = true;
#if(USE_WITH_SOFTDEVICE == 1)
    nrf_radio_request_t radio_request;
    radio_request.request_type = NRF_RADIO_REQ_TYPE_EARLIEST;
    radio_request.params.earliest.hfclk = NRF_RADIO_HFCLK_CFG_DEFAULT;
    radio_request.params.earliest.length_us = 250;
    radio_request.params.earliest.priority = NRF_RADIO_PRIORITY_HIGH;
    radio_request.params.earliest.timeout_us = 100000;
    sd_radio_request(&radio_request);
#else
    NVIC_SetPendingIRQ(PWM_IRQn);
#endif

void nrf_pwm_set_values(uint32_t pwm_channel_num, uint32_t *pwm_values)
{
for(int i = 0; i < pwm_channel_num; i++)
{
pwm_next_value[i] = pwm_values[i];
pwm_modified[i] = true;
}
#if(USE_WITH_SOFTDEVICE == 1)
nrf_radio_request_t radio_request;
radio_request.request_type = NRF_RADIO_REQ_TYPE_EARLIEST;
radio_request.params.earliest.hfclk = NRF_RADIO_HFCLK_CFG_DEFAULT;
radio_request.params.earliest.length_us = 250;
radio_request.params.earliest.priority = NRF_RADIO_PRIORITY_HIGH;
radio_request.params.earliest.timeout_us = 100000;
sd_radio_request(&radio_request);
#else
NVIC_SetPendingIRQ(PWM_IRQn);
#endif
}

void nrf_pwm_set_values(uint32_t pwm_channel_num, uint32_t *pwm_values)
{
    for(int i = 0; i < pwm_channel_num; i++)
    {
        pwm_next_value[i] = pwm_values[i];
        pwm_modified[i] = true;
    }
#if(USE_WITH_SOFTDEVICE == 1)
    nrf_radio_request_t radio_request;
    radio_request.request_type = NRF_RADIO_REQ_TYPE_EARLIEST;
    radio_request.params.earliest.hfclk = NRF_RADIO_HFCLK_CFG_DEFAULT;
    radio_request.params.earliest.length_us = 250;
    radio_request.params.earliest.priority = NRF_RADIO_PRIORITY_HIGH;
    radio_request.params.earliest.timeout_us = 100000;
    sd_radio_request(&radio_request);
#else
    NVIC_SetPendingIRQ(PWM_IRQn);
#endif
}

這兩個函數功能是一樣的……區別在后者先設置好了一組數……

最后看看中斷服務函數

void PWM_IRQHandler(void)
{
static uint32_t i, new_capture, old_capture;
PWM_TIMER->CC[2] = pwm_max_value = pwm_next_max_value;
if(pwm_num_channels > 2) PWM_TIMER2->CC[2] = pwm_max_value;
for(i = 0; i < pwm_num_channels; i++)
{
if(pwm_modified[i])
{
pwm_modified[i] = false;
if(pwm_next_value[i] == 0)
{
nrf_gpiote_unconfig(pwm_gpiote_channel[i]);
nrf_gpio_pin_write(pwm_io_ch[i], 0);
pwm_running[i] = 0;
}
else if (pwm_next_value[i] >= pwm_max_value)
{
nrf_gpiote_unconfig(pwm_gpiote_channel[i]);
nrf_gpio_pin_write(pwm_io_ch[i], 1);
pwm_running[i] = 0;
}
else
{
if(i < 2)
{
new_capture = pwm_next_value[i];
old_capture = PWM_TIMER->CC[i];
if(!pwm_running[i])
{
nrf_gpiote_task_config(pwm_gpiote_channel[i], pwm_io_ch[i], NRF_GPIOTE_POLARITY_TOGGLE, NRF_GPIOTE_INITIAL_VALUE_HIGH);
pwm_running[i] = 1;
PWM_TIMER->TASKS_CAPTURE[3] = 1;
if(PWM_TIMER->CC[3] > new_capture) NRF_GPIOTE->TASKS_OUT[pwm_gpiote_channel[i]] = 1;
PWM_TIMER->CC[i] = new_capture;
}
else
{
while(1)
{
PWM_TIMER->TASKS_CAPTURE[3] = 1;
if(safe_margins_present(PWM_TIMER_CURRENT, old_capture) && safe_margins_present(PWM_TIMER_CURRENT, new_capture)) break;
}
if((PWM_TIMER_CURRENT >= old_capture && PWM_TIMER_CURRENT < new_capture) || (PWM_TIMER_CURRENT < old_capture && PWM_TIMER_CURRENT >= new_capture))
{
NRF_GPIOTE->TASKS_OUT[pwm_gpiote_channel[i]] = 1;
}
PWM_TIMER->CC[i] = new_capture;
}
}
else
{
new_capture = pwm_next_value[i];
old_capture = PWM_TIMER2->CC[i-2];
if(!pwm_running[i])
{
nrf_gpiote_task_config(pwm_gpiote_channel[i], pwm_io_ch[i], NRF_GPIOTE_POLARITY_TOGGLE, NRF_GPIOTE_INITIAL_VALUE_HIGH);
pwm_running[i] = 1;
PWM_TIMER2->TASKS_CAPTURE[3] = 1;
if(PWM_TIMER2->CC[3] > new_capture) NRF_GPIOTE->TASKS_OUT[pwm_gpiote_channel[i]] = 1;
PWM_TIMER2->CC[i-2] = new_capture;
}
else
{
while(1)
{
PWM_TIMER2->TASKS_CAPTURE[3] = 1;
if(safe_margins_present(PWM_TIMER2_CURRENT, old_capture) && safe_margins_present(PWM_TIMER2_CURRENT, new_capture)) break;
}
if((PWM_TIMER2_CURRENT >= old_capture && PWM_TIMER2_CURRENT < new_capture) || (PWM_TIMER2_CURRENT < old_capture && PWM_TIMER2_CURRENT >= new_capture))
{
NRF_GPIOTE->TASKS_OUT[pwm_gpiote_channel[i]] = 1;
}
PWM_TIMER2->CC[i-2] = new_capture;
}
}
}
}
}

void PWM_IRQHandler(void)
{
    static uint32_t i, new_capture, old_capture;
    PWM_TIMER->CC[2] = pwm_max_value = pwm_next_max_value;
    if(pwm_num_channels > 2) PWM_TIMER2->CC[2] = pwm_max_value;
    for(i = 0; i < pwm_num_channels; i++)
    {
        if(pwm_modified[i])
        {
            pwm_modified[i] = false;
            if(pwm_next_value[i] == 0)
            {
                nrf_gpiote_unconfig(pwm_gpiote_channel[i]);
                nrf_gpio_pin_write(pwm_io_ch[i], 0);
                pwm_running[i] = 0;
            }
            else if (pwm_next_value[i] >= pwm_max_value)
            {
                nrf_gpiote_unconfig(pwm_gpiote_channel[i]);
                nrf_gpio_pin_write(pwm_io_ch[i], 1); 
                pwm_running[i] = 0;
            }
            else
            {
                if(i < 2)
                {
                    new_capture = pwm_next_value[i];
                    old_capture = PWM_TIMER->CC[i];
                    if(!pwm_running[i])
                    {
                        nrf_gpiote_task_config(pwm_gpiote_channel[i], pwm_io_ch[i], NRF_GPIOTE_POLARITY_TOGGLE, NRF_GPIOTE_INITIAL_VALUE_HIGH);  
                        pwm_running[i] = 1;
                        PWM_TIMER->TASKS_CAPTURE[3] = 1;
                        if(PWM_TIMER->CC[3] > new_capture) NRF_GPIOTE->TASKS_OUT[pwm_gpiote_channel[i]] = 1;
                        PWM_TIMER->CC[i] = new_capture;
                    }
                    else
                    {
                        while(1)
                        {
                            PWM_TIMER->TASKS_CAPTURE[3] = 1;
                            if(safe_margins_present(PWM_TIMER_CURRENT, old_capture) && safe_margins_present(PWM_TIMER_CURRENT, new_capture)) break;
                        }
                        if((PWM_TIMER_CURRENT >= old_capture && PWM_TIMER_CURRENT < new_capture) || (PWM_TIMER_CURRENT < old_capture && PWM_TIMER_CURRENT >= new_capture))
                        {
                            NRF_GPIOTE->TASKS_OUT[pwm_gpiote_channel[i]] = 1;
                        }
                        PWM_TIMER->CC[i] = new_capture;
                    }
                }
                else
                {
                    new_capture = pwm_next_value[i];
                    old_capture = PWM_TIMER2->CC[i-2];
                    if(!pwm_running[i])
                    {
                        nrf_gpiote_task_config(pwm_gpiote_channel[i], pwm_io_ch[i], NRF_GPIOTE_POLARITY_TOGGLE, NRF_GPIOTE_INITIAL_VALUE_HIGH);  
                        pwm_running[i] = 1;
                        PWM_TIMER2->TASKS_CAPTURE[3] = 1;
                        if(PWM_TIMER2->CC[3] > new_capture) NRF_GPIOTE->TASKS_OUT[pwm_gpiote_channel[i]] = 1;
                        PWM_TIMER2->CC[i-2] = new_capture;
                    }
                    else
                    {
                        while(1)
                        {
                            PWM_TIMER2->TASKS_CAPTURE[3] = 1;
                            if(safe_margins_present(PWM_TIMER2_CURRENT, old_capture) && safe_margins_present(PWM_TIMER2_CURRENT, new_capture)) break;
                        }
                        if((PWM_TIMER2_CURRENT >= old_capture && PWM_TIMER2_CURRENT < new_capture) || (PWM_TIMER2_CURRENT < old_capture && PWM_TIMER2_CURRENT >= new_capture))
                        {
                            NRF_GPIOTE->TASKS_OUT[pwm_gpiote_channel[i]] = 1;
                        }
                        PWM_TIMER2->CC[i-2] = new_capture;
                    }                    
                }
            }
        }
    }

然后運行一下~會看見占空比不同，兩個led燈的亮度不同。占空比為255的LED_1要比占空比為20的LED_1亮

免責聲明！

本站轉載的文章為個人學習借鑒使用，本站對版權不負任何法律責任。如果侵犯了您的隱私權益，請聯系本站郵箱yoyou2525@163.com刪除。

猜您在找 NRF51822自學筆記（一）流水燈 NRF51822自學筆記（四）mpu6050讀取原始數據 nRF51822 的兩路 PWM 極性 NRF51822之SPI NRF51822之pstorage介紹 NRF51822之發射功率 NRF51822之WDT淺析 [nRF51822] 12、基礎實驗代碼解析大全 · 實驗19 - PWM nRF51822學習之SWD接線及配置 NRF51822之app_button使用