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GbTModuleEV/Core/Src/connector.c

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/*
* connector.c
*
* All initialization before 12v_aux
*/
#include "connector.h"
#include "board.h"
#include "edcan.h"
#include <string.h>
#include <charger_gbt.h>
CONN_State_t connectorState;
CONN_t CONN;
uint8_t CC_STATE_FILTERED;
static void CONN_UpdateEdcanOutput(void);
void CONN_Init(){
memset(&CONN, 0, sizeof(CONN));
CONN.connControl = CMD_NONE;
CONN_SetState(Unknown);
}
void CONN_Task(){
switch (connectorState){
case Unknown:
CONN_SetState(Unplugged);
break;
case Disabled:
if(CONN.chargingError == 0) {
CONN_SetState(Unplugged);
}
break;
case Unplugged: // Ожидание подключения и начала сессии
{
// Обновляем признак физического подключения разъёма по уровню CC
if(CONN_CC_GetState() == GBT_CC_4V){
CONN.EvseConnected = 1;
CONN_SetState(AuthRequired);
}else{
CONN.EvseConnected = 0;
}
break;
}
case AuthRequired:
{
// Если уровень CC вернулся к 6/12В считаем, что коннектор выдернули
if(CONN_CC_GetState() != GBT_CC_4V){
CONN_SetState(Unplugged);
GBT_Reset();
break;
}
// Как только появляется 12V AUX от станции переходим в Preparing (инициализация протокола)
if(IN_ReadInput(IN_0) == 1){
CONN_SetState(Preparing);
GBT_SwitchState(GBT_EV_CONNECTING);
}
break;
}
case Preparing:
// Ожидаем переход стейт-машины GB/T в режим зарядки.
// Как только GBT_State уходит в режим CHARGING считаем, что начался заряд.
if(GBT_State == GBT_EV_CHARGING){
CONN_SetState(Charging);
}
if(IN_ReadInput(IN_0) == 0){
CONN_SetState(Unplugged);
GBT_Reset();
}
break;
case Charging: // Активная зарядка
// Завершение по окончанию GB/T-сессии или при падении тока/отключении AUX можно
// добавить позже. Пока ориентируемся только на завершение GB/T.
if(GBT_State == GBT_COMPLETE){
CONN_SetState(Finished);
}
if(IN_ReadInput(IN_0) == 0){
CONN_SetState(Finished);
}
break;
case Finished: // Сессия завершена, ждём окончания и возможного переподключения
// Когда GB/T стейт-машина полностью вернулась в исходное состояние,
// можно считать сессию закрытой и вернуться в Unplugged.
if(CONN_CC_GetState() != GBT_CC_4V){
CONN_SetState(Unplugged);
GBT_Reset();
}
break;
case FinishedEV:
case FinishedEVSE:
CONN_SetState(Finished);
break;
default:
CONN_SetState(Unknown);
}
}
void CONN_SetState(CONN_State_t state){
connectorState = state;
CONN.connState = state;
if(connectorState == Unknown) EDCAN_printf(LOG_INFO,"Unknown\n");
if(connectorState == Unplugged) EDCAN_printf(LOG_INFO,"Unplugged\n");
if(connectorState == Disabled) EDCAN_printf(LOG_INFO,"Disabled\n");
if(connectorState == Preparing) EDCAN_printf(LOG_INFO,"Preparing\n");
if(connectorState == AuthRequired) EDCAN_printf(LOG_INFO,"AuthRequired\n");
if(connectorState == WaitingForEnergy) EDCAN_printf(LOG_INFO,"WaitingForEnergy\n");
if(connectorState == ChargingPausedEV) EDCAN_printf(LOG_INFO,"ChargingPausedEV\n");
if(connectorState == ChargingPausedEVSE) EDCAN_printf(LOG_INFO,"ChargingPausedEVSE\n");
if(connectorState == Charging) EDCAN_printf(LOG_INFO,"Charging\n");
if(connectorState == AuthTimeout) EDCAN_printf(LOG_INFO,"AuthTimeout\n");
if(connectorState == Finished) EDCAN_printf(LOG_INFO,"Finished\n");
if(connectorState == FinishedEVSE) EDCAN_printf(LOG_INFO,"FinishedEVSE\n");
if(connectorState == FinishedEV) EDCAN_printf(LOG_INFO,"FinishedEV\n");
if(connectorState == Replugging) EDCAN_printf(LOG_INFO,"Replugging\n");
}
void CONN_CC_ReadStateFiltered() {
static uint32_t last_change_time;
static uint32_t last_check_time;
static uint8_t prev_state;
if((HAL_GetTick()-last_check_time)<100) return;
last_check_time = HAL_GetTick();
uint8_t new_state = CONN_CC_GetStateRaw();
if (new_state != prev_state) {
last_change_time = HAL_GetTick();
prev_state = new_state;
} else if ((HAL_GetTick() - last_change_time) >= 300) {
CC_STATE_FILTERED = prev_state;
}
}
uint8_t CONN_CC_GetState(){
return CC_STATE_FILTERED;
}
uint8_t CONN_CC_GetStateRaw(){
//Vref=3.3v = 4095
//k=1/11
//Vin = 12v
//Vin*k= 1.09v
//12vin = 1353 ADC
//TODO: Filter 100ms
uint32_t adc;
float volt;
ADC_Select_Channel(ADC_CHANNEL_3);
HAL_ADC_Start(&hadc1);
HAL_ADC_PollForConversion(&hadc1, 100);
adc = HAL_ADC_GetValue(&hadc1);
HAL_ADC_Stop(&hadc1);
volt = (float)adc/113.4f;
// if((volt<12.6f) && (volt>11.4f)) return GBT_CC_12V;
// if((volt<6.8f) && (volt>5.2f)) return GBT_CC_6V;
// if((volt<4.8f) && (volt>3.2f)) return GBT_CC_4V;
// if((volt<2.8f) && (volt>1.2f)) return GBT_CC_2V;
if((volt<13.0f) && (volt>11.0f)) return GBT_CC_12V;
if((volt<7.2f) && (volt>4.8f)) return GBT_CC_6V;
if((volt<4.8f) && (volt>3.0f)) return GBT_CC_4V;
if((volt<3.0f) && (volt>1.0f)) return GBT_CC_2V;
return GBT_CC_UNKNOWN;
}
float CONN_CC_GetAdc(){
//TODO: Filters
//Vref=3.3v = 4095
//k=1/11
//Vin = 12v
//Vin*k= 1.09v
//12vin = 1353 ADC
uint32_t adc;
float volt;
ADC_Select_Channel(ADC_CHANNEL_3);
HAL_ADC_Start(&hadc1);
HAL_ADC_PollForConversion(&hadc1, 100);
adc = HAL_ADC_GetValue(&hadc1);
HAL_ADC_Stop(&hadc1);
volt = (float)adc/113.4f;
return volt;
}
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