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CCSModuleSW30Web/Core/Src/cp.c
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achamaikin 414d2cba60 clean project
2026-05-09 14:02:54 +03:00

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#include "cp.h"
#include "adc.h"
#include "board.h"
#include "debug.h"
#include "tim.h"
#include <stdint.h>
#include <stdlib.h>
#define MAX_DUTY 450
#define FILTER_ORDER 100
static int32_t cp_voltage_mv = 0;
static uint8_t cp_duty = 0;
CP_State_t fake_cp_state = EV_STATE_ACQUIRING;
CP_State_t cp_state_buffer = EV_STATE_ACQUIRING;
#define VREFINT_CAL_ADDR ((uint16_t*)0x1FFFF7BA) // для STM32F1!
static int32_t CP_ReadVoltageMv(void)
{
uint32_t adc_cp = adc_data.cp_raw;
uint32_t adc_vref = adc_data.vrefint_raw; // нужно измерять!
// VREFINT в мВ (берётся из даташита или калибровки MCU)
const int32_t VREFINT_MV = 1210;
// напряжение на входе АЦП
int32_t v_adc_mv = (adc_cp * VREFINT_MV) / adc_vref;
// дальше твоя формула
int32_t v_out_mv = ((v_adc_mv - 1723) * 7704) / 1000;
return v_out_mv;
}
void CP_Init(void) {
/* TIM3_CH2 (PA7): set 1kHz PWM like original CCS logic. */
htim3.Instance->PSC = 160 - 1;
htim3.Instance->ARR = MAX_DUTY - 1;
#if DUTY_INVERT == 0
htim3.Instance->CCR2 = MAX_DUTY;
htim3.Instance->CCR1 = MAX_DUTY + 5;
#else
htim3.Instance->CCR2 = 0;
htim3.Instance->CCR1 = 0;
#endif
HAL_TIM_PWM_Start(&htim3, TIM_CHANNEL_2);
HAL_TIM_OC_Start(&htim3, TIM_CHANNEL_1);
}
void CP_SetDuty(uint8_t percentage) {
uint32_t pwmduty = MAX_DUTY * percentage / 100;
cp_duty = percentage;
#if DUTY_INVERT == 0
htim3.Instance->CCR2 = pwmduty;
htim3.Instance->CCR1 = 0 + 1;
#else
htim3.Instance->CCR2 = MAX_DUTY - pwmduty;
htim3.Instance->CCR1 = MAX_DUTY - pwmduty + 5;
#endif
}
uint8_t CP_GetDuty(void) {
return cp_duty;
}
int32_t CP_GetVoltage(void) {
cp_voltage_mv = CP_ReadVoltageMv();
return cp_voltage_mv;
}
CP_State_t CP_GetState(void) {
int32_t voltage_real = CP_GetVoltage();
if(fake_cp_state != EV_STATE_ACQUIRING) {
return fake_cp_state;
}
if (voltage_real >= (12000-1000)) {
return EV_STATE_A_IDLE;
} else if (voltage_real >= (9000-1000) && voltage_real <= (9000+1000)) {
return EV_STATE_B_CONN_PREP;
} else if (voltage_real >= (6000-1000) && voltage_real <= (6000+1000)) {
return EV_STATE_C_CONN_ACTIVE;
} else if (voltage_real >= (3000-1000) && voltage_real <= (3000 + 1000)) {
return EV_STATE_D_CONN_ACT_VENT;
} else if (voltage_real >= (0-1000) && voltage_real <= (0+2000)){
return EV_STATE_E_NO_POWER;
} else if (voltage_real <= (-12000+1000)) {
return EV_STATE_F_ERROR;
} else {
return EV_STATE_ACQUIRING;
}
}
CP_State_t CP_GetFilteredState(void) {
return cp_state_buffer;
}
void CP_FilterState(void) {
static CP_State_t pending_state = EV_STATE_ACQUIRING;
static uint8_t stable_count = 0u;
CP_State_t current_state = CP_GetState();
/* Keep last accepted state while CP is still acquiring. */
if (current_state == EV_STATE_ACQUIRING) {
pending_state = EV_STATE_ACQUIRING;
stable_count = 0u;
return;
}
if (current_state != pending_state) {
pending_state = current_state;
stable_count = 1u;
return;
}
if (stable_count < FILTER_ORDER) {
stable_count++;
}
if (stable_count >= FILTER_ORDER) {
cp_state_buffer = pending_state;
}
}
void CP_Loop(void) {
static uint32_t tick;
if ((int32_t)(HAL_GetTick() - tick) < 1) return;
tick = HAL_GetTick();
static uint8_t initialized = 0;
static CP_State_t prev_state = EV_STATE_ACQUIRING;
static uint8_t prev_duty = 0;
CP_FilterState();
CP_State_t current_state = CP_GetFilteredState();
uint8_t current_duty = cp_duty;
if (!initialized) {
prev_state = current_state;
prev_duty = current_duty;
initialized = 1;
return;
}
if (current_state != prev_state) {
log_printf(LOG_INFO, "CP state changed: %d -> %d\n", prev_state, current_state);
prev_state = current_state;
}
if (current_duty != prev_duty) {
log_printf(LOG_INFO, "CP duty changed: %u -> %u\n", prev_duty, current_duty);
prev_duty = current_duty;
}
}
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