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chargeController
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修改前端输入功率较低时的执行方式

This commit is contained in:
起床就犯困 2025-02-13 08:55:55 +08:00
parent a31b9af810
commit 25af1a47ff
11 changed files with 201 additions and 69 deletions
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5
APP/application/Src/start.c
View File

@ -62,6 +62,9 @@ void start(void)
uartCommonInit(); uartCommonInit();
// setDutyRatio(0.15f);
task_Init(); task_Init();
startInfo(); startInfo();
@ -72,7 +75,7 @@ void start(void)
// HAL_Delay(1000); // HAL_Delay(1000);
// } // }
/* 启动事件 */ /* 启动事件 */
insertEventsOrderRecord(startEvent); // insertEventsOrderRecord(startEvent);
TimeSliceOffset_Start(); TimeSliceOffset_Start();
} }

4
APP/businessLogic/Src/Init.c
View File

@ -23,7 +23,7 @@ void Init(void)
// HAL_Delay(10000); // HAL_Delay(10000);
config_info_start(); config_info_start();
Init_debug_uart(); Init_debug_uart();
ADC_Capture_Init(); ADC_Capture_Init();
@ -49,8 +49,8 @@ void Init(void)
// POW_OUT_PCON_Open(); // POW_OUT_PCON_Open();
HAL_Delay(100); HAL_Delay(100);
setPowerOutput(TRUE); setPowerOutput(TRUE);
resetCheckImpedanceState();
// EN_PWMOUT_Eable();
// setDutyRatio(0.5); // setDutyRatio(0.5);
// while (1) { // while (1) {
// log_info("Init_debug_uart \n"); // log_info("Init_debug_uart \n");

21
APP/businessLogic/Src/abnormalManage.c
View File

@ -299,12 +299,23 @@ void checkFFMOS_CON(void)
// FFMOS_CON_Close(); // FFMOS_CON_Close();
// } // }
if (getChargCurrent() > 5.0f && FALSE == FFMOS_CON_read()) { static uint8_t num = 100;
FFMOS_CON_Open(); if (getChargCurrent() > 8.0f && FALSE == FFMOS_CON_read()) {
num--;
if (!num) {
FFMOS_CON_Open();
}
} }
else if (getChargCurrent() < 2.0f && TRUE == FFMOS_CON_read()) { else if (getChargCurrent() < 2.0f && TRUE == FFMOS_CON_read()) {
// num--;
// if (!num) {
// FFMOS_CON_Close();
// }
FFMOS_CON_Close(); FFMOS_CON_Close();
} }
else {
num = 100;
}
} }
// /** // /**
@ -360,16 +371,18 @@ void setOverLoad(void)
*/ */
void lowInputLoadDetection(void) void lowInputLoadDetection(void)
{ {
static int num = 0; static int num = 0;
if (excessiveLoadInterruptFlag == TRUE && getOutputVoltage() < g_cfgParameter.inputPowerLowDetectionVolt) { if (excessiveLoadInterruptFlag == TRUE && getOutputVoltage() < g_cfgParameter.inputPowerLowDetectionVolt) {
num++; num++;
// setOverLoad();
} else { } else {
num = 0; num = 0;
excessiveLoadInterruptFlag = FALSE; excessiveLoadInterruptFlag = FALSE;
} }
if (excessiveLoadInterruptFlag == TRUE && num == g_cfgParameter.inputPowerLowDetectionDelay) { if (excessiveLoadInterruptFlag == TRUE && num == g_cfgParameter.inputPowerLowDetectionDelay) {
excessiveLoadInterruptFlag = FALSE;
setOverLoad(); setOverLoad();
} }
} }

141
APP/businessLogic/Src/bl_chargControl.c
View File

@ -334,20 +334,34 @@ void mppt_readJust(void)
// return; // return;
/* 调节电压,两个电压步调节 */ /* 调节电压,两个电压步调节 */
static float stepV1 = 0.2;
static float stepV2 = 0.05;
static float Power = 0; static float Power = 0;
static float totalPower = 0; // static float totalPower = 0;
static float powerData[50] = {0}; // static float powerData[50] = {0};
static uint8_t powerIndex = 0; // static uint8_t powerIndex = 0;
/* 获取50次的平均值 */ static float totalChargeCurr = 0;
totalPower -= powerData[powerIndex]; static float chargeCurrData[50] = {0};
powerData[powerIndex] = getOutputVoltage() * getChargCurrent(); static uint8_t chargeCurrIndex = 0;
totalPower += powerData[powerIndex];
powerIndex++; /* 获取50次值的和 */
if (powerIndex >= 50) { totalChargeCurr -= chargeCurrData[chargeCurrIndex];
powerIndex = 0; chargeCurrData[chargeCurrIndex] = getChargCurrent();
totalChargeCurr += chargeCurrData[chargeCurrIndex];
chargeCurrIndex++;
if (chargeCurrIndex >= 50) {
chargeCurrIndex = 0;
} }
// totalPower -= powerData[powerIndex];
// powerData[powerIndex] = getOutputVoltage() * getChargCurrent();
// totalPower += powerData[powerIndex];
// powerIndex++;
// if (powerIndex >= 50) {
// powerIndex = 0;
// }
static float lPower = 0; static float lPower = 0;
static float lLPower = 0; static float lLPower = 0;
// static float lLLPower = 0; // static float lLLPower = 0;
@ -356,9 +370,6 @@ void mppt_readJust(void)
// static float kp = 0.005; // static float kp = 0.005;
// static float ki = 0.00001; // static float ki = 0.00001;
static float stepV1 = 0.2;
static float stepV2 = 0.08;
static uint8_t flag1 = 0; //表明上次运算是加还是减 static uint8_t flag1 = 0; //表明上次运算是加还是减
/* 延时一段时间才判断 */ /* 延时一段时间才判断 */
@ -378,13 +389,14 @@ void mppt_readJust(void)
} }
if (getMosTemperState() == mosTemperReduce) { if (getMosTemperState() == mosTemperReduce) {
SolarInCircuitV = 16; SolarInCircuitV = 20;
} }
flag = 0; flag = 0;
// Power = totalPower / 30.0f; // Power = totalPower / 30.0f;
Power = totalPower; // Power = totalPower;
Power = totalChargeCurr * getOutputVoltage();
static float powerT = 0; static float powerT = 0;
powerT = Power - lPower; powerT = Power - lPower;
@ -392,13 +404,88 @@ void mppt_readJust(void)
powerT = -powerT; powerT = -powerT;
} }
/* 滞环值 */
float hysteresisValue1;
float hysteresisValue2;
/* 一段时间内电流都很小则固定电压输出 */
static uint8_t currMinFlag = 0;
static uint8_t currMinFlag1 = 0;
// if (getChargCurrent() < 0.8f) {
if (totalChargeCurr < 40) {
// hysteresisValue1 = getChargCurrent() * 1.7f;
// hysteresisValue2 = getChargCurrent() * 12;
currMinFlag++;
if (currMinFlag == 8) {
currMinFlag = 0;
SolarInCircuitV = 18.0f;
currMinFlag1 = 1;
}
return;
}
// else if (getChargCurrent() < 3 && currMinFlag1) {
else if (totalChargeCurr < 150 && currMinFlag1) {
currMinFlag1 = 0;
currMinFlag = 0;
return;
}
// else if (getChargCurrent() < 7) {
else if (totalChargeCurr < 350) {
currMinFlag1 = 0;
currMinFlag = 0;
// hysteresisValue1 = getChargCurrent() * 1.1f;
// hysteresisValue2 = getChargCurrent() * 10;
hysteresisValue1 = totalChargeCurr / 45.0f;
hysteresisValue2 = totalChargeCurr / 5.0f;
}
// else if (getChargCurrent() < 20) {
else if (totalChargeCurr < 1000) {
currMinFlag1 = 0;
currMinFlag = 0;
// hysteresisValue1 = getChargCurrent() * 0.7f;
// hysteresisValue2 = getChargCurrent() * 7;
hysteresisValue1 = totalChargeCurr / 70.0f;
hysteresisValue2 = totalChargeCurr / 7.0f;
}
// else if (getChargCurrent() < 25) {
else if (totalChargeCurr < 1250) {
currMinFlag1 = 0;
currMinFlag = 0;
// hysteresisValue1 = getChargCurrent() * 0.5f;
// hysteresisValue2 = getChargCurrent() * 5;
hysteresisValue1 = totalChargeCurr / 100.0f;
hysteresisValue2 = totalChargeCurr / 10.0f;
}
else {
currMinFlag1 = 0;
currMinFlag = 0;
// hysteresisValue1 = getChargCurrent() * 0.3f;
// hysteresisValue2 = getChargCurrent() * 3;
hysteresisValue1 = totalChargeCurr / 150.0f;
hysteresisValue2 = totalChargeCurr / 16.0f;
}
// else {
// currMinFlag1 = 0;
// currMinFlag = 0;
// hysteresisValue1 = 120;
// hysteresisValue2 = 100;
// }
static uint8_t numFlag = 0; static uint8_t numFlag = 0;
// if ((lPower + 0.8f < Power) && (lLPower + 0.8f < Power) && (lLLPower + 0.8f < Power)) { // if ((lPower + 0.8f < Power) && (lLPower + 0.8f < Power) && (lLLPower + 0.8f < Power)) {
// if ((lPower + 0.1f < Power) && (lLPower + 0.1f < Power)) { // if ((lPower + 0.1f < Power) && (lLPower + 0.1f < Power)) {
if ((lPower + 8.0f < Power) && (lLPower + 8.0f < Power)) {
if ((lPower + hysteresisValue1 < Power) && (lLPower + hysteresisValue1 < Power)) {
numFlag = 0; numFlag = 0;
// if ((lPower + 0.3f < Power)) { // if ((lPower + 0.3f < Power)) {
if (powerT > 250) { if (powerT > hysteresisValue2) {
if (flag1) { if (flag1) {
SolarInCircuitV += stepV1; SolarInCircuitV += stepV1;
flag1 = 1; flag1 = 1;
@ -416,9 +503,9 @@ void mppt_readJust(void)
} }
} }
// } else if ((lPower - 0.8f > Power) && (lLPower - 0.8f > Power) && (lLLPower - 0.8f > Power)) { // } else if ((lPower - 0.8f > Power) && (lLPower - 0.8f > Power) && (lLLPower - 0.8f > Power)) {
} else if ((lPower - 8.0f > Power) && (lLPower - 8.0f > Power)) { } else if ((lPower - hysteresisValue1 > Power) && (lLPower - hysteresisValue1 > Power)) {
// } else if ((lPower - 0.3f > Power)) { // } else if ((lPower - 0.3f > Power)) {
if (powerT > 250) { if (powerT > hysteresisValue2) {
numFlag = 0; numFlag = 0;
if (flag1) { if (flag1) {
SolarInCircuitV -= stepV1; SolarInCircuitV -= stepV1;
@ -441,7 +528,7 @@ void mppt_readJust(void)
} }
/* 一段时间内都未调节 */ /* 一段时间内都未调节 */
if (numFlag == 100) { if (numFlag == 10) {
if (Power < 300) { if (Power < 300) {
SolarInCircuitV = 17.0f; SolarInCircuitV = 17.0f;
} }
@ -456,9 +543,10 @@ void mppt_readJust(void)
} }
if (SolarInCircuitV > 20.0f) { if (SolarInCircuitV > 19.0f) {
SolarInCircuitV = 20.0f; SolarInCircuitV = 19.0f;
} }
else if (SolarInCircuitV < 16.0f) { else if (SolarInCircuitV < 16.0f) {
SolarInCircuitV = 16.0f; SolarInCircuitV = 16.0f;
} }
@ -479,7 +567,8 @@ void endChargWork(void)
setChargControlFlag(FALSE); setChargControlFlag(FALSE);
setDutyRatioToZero(); setDutyRatioToZero();
setMPPT_Mode(noWork); setMPPT_Mode(noWork);
beginStartControlTask(); beginStartControlTask();
EN_PWMOUT_Diseable();
} }
/** /**
@ -493,6 +582,7 @@ void stopChargWork(void)
setChargControlFlag(FALSE); setChargControlFlag(FALSE);
setDutyRatioToZero(); setDutyRatioToZero();
setMPPT_Mode(noWork); setMPPT_Mode(noWork);
EN_PWMOUT_Diseable();
} }
/** /**
@ -504,6 +594,7 @@ void stopChargWork(void)
void beginChargWork(void) void beginChargWork(void)
{ {
beginStartControlTask(); beginStartControlTask();
EN_PWMOUT_Eable();
} }
/** /**
@ -515,6 +606,7 @@ void beginChargWork(void)
void startChargWork(void) void startChargWork(void)
{ {
beginSoftStartTask(); beginSoftStartTask();
EN_PWMOUT_Eable();
} }
@ -562,7 +654,7 @@ BOOL floatChargConditions(void)
BOOL mpptChargConditions(void) BOOL mpptChargConditions(void)
{ {
if (((g_cfgParameter.constantVoltageChargeV - 0.2f) > getBatteryVoltage()) if (((g_cfgParameter.constantVoltageChargeV - 0.2f) > getBatteryVoltage())
&& (getChargCurrent() > 0.1f)) { && (getChargCurrent() > 0.05f)) {
return TRUE; return TRUE;
} }
@ -690,6 +782,7 @@ void BatteryChargControl(void)
case MPPT: case MPPT:
mpptCharge(); mpptCharge();
// mppt_constantVoltage(17.5f); // mppt_constantVoltage(17.5f);
// setDutyRatio(0.1f);
break; break;
case constantVoltage: case constantVoltage:

13
APP/businessLogic/Src/bl_usart.c
View File

@ -1447,6 +1447,9 @@ uint16_t SL_ReadRegisterYearMonth(void *pMsg)
{ {
timeInfo time; timeInfo time;
getRTC_Time(&time); getRTC_Time(&time);
// debug_printf("%d-%d\n", time.year, time.month);
return (time.year << 8) | time.month; return (time.year << 8) | time.month;
} }
@ -1459,6 +1462,9 @@ uint16_t SL_ReadRegisterDayHour(void *pMsg)
{ {
timeInfo time; timeInfo time;
getRTC_Time(&time); getRTC_Time(&time);
// debug_printf("%d-%d\n", time.day, time.hour);
return (time.day << 8) | time.hour; return (time.day << 8) | time.hour;
} }
@ -1471,6 +1477,9 @@ uint16_t SL_ReadRegisterMinuteSecond(void *pMsg)
{ {
timeInfo time; timeInfo time;
getRTC_Time(&time); getRTC_Time(&time);
// debug_printf("%d-%d\n", time.minute, time.second);
return (time.minute << 8) | time.second; return (time.minute << 8) | time.second;
} }
@ -1612,6 +1621,10 @@ uint16_t SL_WriteRegisterMinuteSecond(void *pMsg)
tempU8 = (uint8_t)(*(uint16_t*)pMsg); tempU8 = (uint8_t)(*(uint16_t*)pMsg);
writeTime.second = tempU8; writeTime.second = tempU8;
// debug_printf("%d-%d\n", writeTime.year, writeTime.month);
// debug_printf("%d-%d\n", writeTime.day, writeTime.hour);
// debug_printf("%d-%d\n", writeTime.minute, writeTime.second);
setRTC_Time(&writeTime); setRTC_Time(&writeTime);
return 0; return 0;

4
APP/businessLogic/Src/parameter.c
View File

@ -59,8 +59,8 @@ float getDutyRatio(void)
*/ */
void setDutyRatio(float DutyRatio) void setDutyRatio(float DutyRatio)
{ {
if (DutyRatio > 0.95f) { if (DutyRatio > 0.9f) {
dutyRatio = 0.95f; dutyRatio = 0.9f;
} }
else if (DutyRatio < 0.05f) { else if (DutyRatio < 0.05f) {
dutyRatio = 0.05f; dutyRatio = 0.05f;

48
APP/businessLogic/Src/task.c
View File

@ -160,7 +160,7 @@ void task_Init(void)
TimeSliceOffset_Register(&m_uart, Task_uart, uart_reloadVal, uart_offset); TimeSliceOffset_Register(&m_uart, Task_uart, uart_reloadVal, uart_offset);
TimeSliceOffset_Register(&m_busFree, Task_busFree, busFree_reloadVal, busFree_offset); TimeSliceOffset_Register(&m_busFree, Task_busFree, busFree_reloadVal, busFree_offset);
TimeSliceOffset_Register(&m_SOE, Task_SOE, SOE_reloadVal, SOE_offset); TimeSliceOffset_Register(&m_SOE, Task_SOE, SOE_reloadVal, SOE_offset);
} }
/** /**
@ -200,20 +200,20 @@ void Task_wdi(void)
{ {
feedDog(); feedDog();
debug_printf("chargCurrent:%f \n", getChargCurrent()); // debug_printf("chargCurrent:%f \n", getChargCurrent());
debug_printf("outputVoltage:%f \n", getOutputVoltage()); // debug_printf("outputVoltage:%f \n", getOutputVoltage());
debug_printf("BatteryVoltage:%f \n", getBatteryVoltage()); // debug_printf("BatteryVoltage:%f \n", getBatteryVoltage());
debug_printf("dischargCurrent:%f \n", getDischargCurrent()); // debug_printf("dischargCurrent:%f \n", getDischargCurrent());
debug_printf("solarInCircuitVoltage:%f \n", getSolarInCircuitVoltage()); // debug_printf("solarInCircuitVoltage:%f \n", getSolarInCircuitVoltage());
debug_printf("HighSideMosTemperature:%f \n", getHighSideMosTemperature()); // debug_printf("HighSideMosTemperature:%f \n", getHighSideMosTemperature());
debug_printf("InputVoltage:%f \n", getInputVoltage()); // debug_printf("InputVoltage:%f \n", getInputVoltage());
debug_printf("DischargMosState:%d \n", getDischargMosState()); // debug_printf("DischargMosState:%d \n", getDischargMosState());
debug_printf("MPPT_Mode:%d \n", getMPPT_Mode()); // debug_printf("MPPT_Mode:%d \n", getMPPT_Mode());
debug_printf("loopImpedance:%f \n", getLoopImpedance()); // debug_printf("loopImpedance:%f \n", getLoopImpedance());
debug_printf("DutyRatio:%f \n", getDutyRatio()); // debug_printf("DutyRatio:%f \n", getDutyRatio());
// debug_printf("OUT_VOLT_IN:%f \n", get_OUT_VOLT_IN()); // // debug_printf("OUT_VOLT_IN:%f \n", get_OUT_VOLT_IN());
debug_printf("HAL_GetTick:%d \n", HAL_GetTick()); // debug_printf("HAL_GetTick:%d \n", HAL_GetTick());
debug_printf("getExChargeCurr:%f \n", getExChargeCurr()); // debug_printf("getExChargeCurr:%f \n", getExChargeCurr());
// char buf[100]; // char buf[100];
@ -307,7 +307,7 @@ void Task_refreshJudgeData(void)
/* 有电池太阳能输出功率大电池电压低于14V同时回路阻抗未测试或需要重新测试 */ /* 有电池太阳能输出功率大电池电压低于14V同时回路阻抗未测试或需要重新测试 */
if ((getCheckImpedanceState() == FALSE || getLoopImpedance() == 0.0f) if ((getCheckImpedanceState() == FALSE || getLoopImpedance() == 0.0f)
&& (getBatteryState() == TRUE) && (getChargCurrent() > g_cfgParameter.maxChargCurr) && (getBatteryState() == TRUE) && (getChargCurrent() > g_cfgParameter.minCheckLoopImpedanceChargCurr)
&& (getOutputVoltage() > 9) && (getSolarInCircuitVoltage() > 14) && (getOutputVoltage() > 9) && (getSolarInCircuitVoltage() > 14)
&& (getBatteryVoltage() < 14)) { && (getBatteryVoltage() < 14)) {
TimeSliceOffset_Register(&m_impedanceCalculation, Task_impedanceCalculation TimeSliceOffset_Register(&m_impedanceCalculation, Task_impedanceCalculation
@ -378,7 +378,15 @@ void Task_startControl(void)
} }
/* 启动软起动任务 */ /* 启动软起动任务 */
TimeSliceOffset_Register(&m_softStart, Task_softStart, softStart_reloadVal, softStart_offset); // TimeSliceOffset_Register(&m_softStart, Task_softStart, softStart_reloadVal, softStart_offset);
if (getBatteryState() == TRUE) {
setMPPT_Mode(MPPT);
} else {
setMPPT_Mode(floatCharg);
}
setChargControlFlag(TRUE);
EN_PWMOUT_Eable();
} }
} }
/** /**
@ -387,7 +395,7 @@ void Task_startControl(void)
* @retval * @retval
*/ */
void beginStartControlTask(void) void beginStartControlTask(void)
{ {
TimeSliceOffset_Register(&m_startControl, Task_startControl, startControl_reloadVal, startControl_offset); TimeSliceOffset_Register(&m_startControl, Task_startControl, startControl_reloadVal, startControl_offset);
m_startControl.runFlag = 1; m_startControl.runFlag = 1;
} }
@ -409,7 +417,7 @@ void Task_softStart(void)
EN_PWMOUT_Eable(); EN_PWMOUT_Eable();
} }
else if (num > 70 || dutyRatio > 0.75f) { else if (num > 70 || dutyRatio > 0.6f) {
TimeSliceOffset_Unregister(&m_softStart); TimeSliceOffset_Unregister(&m_softStart);
m_softStart.runFlag = 0; m_softStart.runFlag = 0;
@ -423,7 +431,7 @@ void Task_softStart(void)
setMPPT_Mode(floatCharg); setMPPT_Mode(floatCharg);
} }
setChargControlFlag(TRUE); setChargControlFlag(TRUE);
} }
else { else {
setDutyRatio(getDutyRatio() + 0.01f); setDutyRatio(getDutyRatio() + 0.01f);

29
APP/functionalModule/Src/FM_GPIO.c
View File

@ -182,24 +182,25 @@ BOOL readOnlyPowerOutputState(void)
{ {
// static volatile GPIO_PinState gpioTemp1, gpioTemp2, gpioTemp3; // static volatile GPIO_PinState gpioTemp1, gpioTemp2, gpioTemp3;
// GPIO_PinState gpioTemp1, gpioTemp2, gpioTemp3; // GPIO_PinState gpioTemp1, gpioTemp2, gpioTemp3;
GPIO_PinState gpioTemp1, gpioTemp2; // GPIO_PinState gpioTemp1, gpioTemp2;
gpioTemp1 = HAL_GPIO_ReadPin(POW_FF_CON_GPIO_Port, POW_FF_CON_Pin); // gpioTemp1 = HAL_GPIO_ReadPin(POW_FF_CON_GPIO_Port, POW_FF_CON_Pin);
gpioTemp2 = HAL_GPIO_ReadPin(POW_OUT_CON_GPIO_Port, POW_OUT_CON_Pin); // gpioTemp2 = HAL_GPIO_ReadPin(POW_OUT_CON_GPIO_Port, POW_OUT_CON_Pin);
// gpioTemp3 = HAL_GPIO_ReadPin(DSG_PROT_GPIO_Port, DSG_PROT_Pin); // gpioTemp3 = HAL_GPIO_ReadPin(DSG_PROT_GPIO_Port, DSG_PROT_Pin);
if (gpioTemp1 == GPIO_PIN_SET // if (gpioTemp1 == GPIO_PIN_SET
&& gpioTemp2 == GPIO_PIN_SET // && gpioTemp2 == GPIO_PIN_SET
// && gpioTemp3 == GPIO_PIN_SET) { // // && gpioTemp3 == GPIO_PIN_SET) {
) { // ) {
return TRUE; // return TRUE;
} // }
// if (HAL_GPIO_ReadPin(POW_FF_CON_GPIO_Port, POW_FF_CON_Pin) if (!HAL_GPIO_ReadPin(POW_FF_CON_GPIO_Port, POW_FF_CON_Pin)
// && HAL_GPIO_ReadPin(POW_OUT_CON_GPIO_Port, POW_OUT_CON_Pin) && HAL_GPIO_ReadPin(POW_OUT_CON_GPIO_Port, POW_OUT_CON_Pin)
// && HAL_GPIO_ReadPin(DSG_PROT_GPIO_Port, DSG_PROT_Pin)) { && !HAL_GPIO_ReadPin(DSG_PROT_GPIO_Port, DSG_PROT_Pin)
// return TRUE; && !HAL_GPIO_ReadPin(EXCHG_CURR_GPIO_Port, EXCHG_CURR_Pin)) {
// } return TRUE;
}
return FALSE; return FALSE;
} }

1
Core/Src/gpio.c
View File

@ -104,6 +104,7 @@ void MX_GPIO_Init(void)
HAL_NVIC_SetPriority(EXTI15_10_IRQn, 0, 0); HAL_NVIC_SetPriority(EXTI15_10_IRQn, 0, 0);
HAL_NVIC_EnableIRQ(EXTI15_10_IRQn); HAL_NVIC_EnableIRQ(EXTI15_10_IRQn);
} }
/* USER CODE BEGIN 2 */ /* USER CODE BEGIN 2 */

2
Core/Src/tim.c
View File

@ -47,7 +47,7 @@ void MX_TIM3_Init(void)
htim3.Instance = TIM3; htim3.Instance = TIM3;
htim3.Init.Prescaler = 0; htim3.Init.Prescaler = 0;
htim3.Init.CounterMode = TIM_COUNTERMODE_UP; htim3.Init.CounterMode = TIM_COUNTERMODE_UP;
htim3.Init.Period = 720; htim3.Init.Period = 719;
htim3.Init.ClockDivision = TIM_CLOCKDIVISION_DIV1; htim3.Init.ClockDivision = TIM_CLOCKDIVISION_DIV1;
htim3.Init.AutoReloadPreload = TIM_AUTORELOAD_PRELOAD_DISABLE; htim3.Init.AutoReloadPreload = TIM_AUTORELOAD_PRELOAD_DISABLE;
if (HAL_TIM_PWM_Init(&htim3) != HAL_OK) if (HAL_TIM_PWM_Init(&htim3) != HAL_OK)

2
chargeController.ioc
View File

@ -413,7 +413,7 @@ TIM16.PeriodNoDither=999
TIM16.Prescaler=71 TIM16.Prescaler=71
TIM3.Channel-PWM\ Generation4\ CH4=TIM_CHANNEL_4 TIM3.Channel-PWM\ Generation4\ CH4=TIM_CHANNEL_4
TIM3.IPParameters=PeriodNoDither,Channel-PWM Generation4 CH4 TIM3.IPParameters=PeriodNoDither,Channel-PWM Generation4 CH4
TIM3.PeriodNoDither=720 TIM3.PeriodNoDither=719
TIM6.IPParameters=Prescaler,PeriodNoDither,TIM_MasterOutputTrigger TIM6.IPParameters=Prescaler,PeriodNoDither,TIM_MasterOutputTrigger
TIM6.PeriodNoDither=9 TIM6.PeriodNoDither=9
TIM6.Prescaler=71 TIM6.Prescaler=71