修改flash中保存的数据,设置两个结构体,保存全局所需数据

This commit is contained in:
起床就犯困 2024-10-12 17:51:15 +08:00
parent 3ec7ad0781
commit f72590e9a8
37 changed files with 4725 additions and 19120 deletions

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@ -52,11 +52,8 @@ typedef enum
}HY_AnalyzeDataLen;
/* 指定对齐方式为1字节 */
#pragma pack(push,1)
/* 默认参数 */
typedef struct _HY_default_Value{
uint8_t start_Flag; /* 起始标志 */
@ -558,8 +555,6 @@ typedef struct _HY_checkMotherboardTemperatureResponse{
#define HY_checkMotherboardTemperatureResponse_PACK_SIZE (sizeof(HY_checkMotherboardTemperatureResponse))
/* 恢复默认的对齐设置 */
#pragma pack(pop)

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@ -12,71 +12,78 @@
#pragma pack(push,1)
typedef struct _uint8_config_info{
uint8_t start_Flag[2]; /* 起始标志 */
/* 高字节在前,低字节在后 */
typedef struct _recv_config_info{
uint8_t start_Flag[2]; /* 开始标志 */
/* SL */
uint8_t address[7]; /* 地址 */
uint8_t end_Flag; /* 结束标志 */
uint8_t Access_Node_Type[2]; /* 接入节点类型 */
uint8_t Communication_Methods[2]; /* 通信方式 */
uint8_t bat485_Baud[4]; /* 串口波特率,为0代表bms不支持通信 */
uint8_t gw485_Baud[4]; /* 串口波特率 */
uint8_t ConstantCurrentV[2]; /* 高于该(电压 / 100),小于ConstantVoltageV * 100电压进行恒流充电 */
uint8_t gw485_Baud[4]; /* 串口波特率,为0代表bms不支持通信 */
uint8_t bat485_Baud[4]; /* 串口波特率 */
/* HY */
uint8_t hardwareID[6]; /* 硬件ID */
uint8_t communicationID[4]; /* 通信ID */
uint8_t protocolType; /* 协议类型; 0x01表示汇源协议(波特率9600) 0x02表示南瑞协议(波特率115200)*/
uint8_t ConstantVoltageV[2]; /* 高于该(电压 / 100)且电流大于FloatI * 100进行恒压充电 */
uint8_t FloatI[2]; /* 高于该(电压 / 100)且电流低于FloatI * 100进行浮充充电 */
uint8_t startSolarOpenCircuitV[2]; /* 高于该(电压 / 100)开始充电 */
}uint8_config_info;
uint8_t stopSolarOpenCircuitV[2]; /* 太阳能板开路电压高于该电压停止充电 (V) */
uint8_t constantVoltageChargeV[2]; /* 恒压充电时的输出电压 (V) */
uint8_t FloatV[2]; /* 浮充充电时的输出电压 (V) */
uint8_t HighSideMosTemperature_stop[2]; /* 当上桥温度达到该值时,停止输出 (°C) */
uint8_t HighSideMosTemperature_end[2]; /* 当上桥温度上升到该值时,降低功率运行 (°C) */
uint8_t HighSideMosTemperature_start[2];/* 当上桥温度降低到该值时,按照正常情况输出 (°C) */
uint8_t loopImpedance[2]; /* 回路阻抗大小 (mΩ) */
//typedef struct _config_info{
// uint8_t start_Flag[2]; /* 起始标志 */
// uint8_t address[7]; /* 地址 */
// uint8_t end_Flag; /* 结束标志 */
// uint16_t Access_Node_Type; /* 接入节点类型 */
// uint16_t Communication_Methods; /* 通信方式 */
// uint32_t bat485_Baud; /* 串口波特率 */
// uint32_t gw485_Baud; /* 串口波特率 */
// uint16_t ConstantCurrentV; /* 高于该(电压 / 100),小于ConstantVoltageV / 100电压进行恒流充电 */
// uint16_t ConstantVoltageV; /* 高于该(电压 / 100)且电流大于FloatI / 100进行恒压充电 */
// uint16_t FloatI; /* 高于该(电压 / 100)且电流低于FloatI / 100进行浮充充电 */
// uint16_t startSolarOpenCircuitV;/* 高于该(电压 / 100)开始充电 */
//}config_info;
uint8_t checkSolarOpenCircuitVTime[2]; /* 启动任务中太阳能板开路电压检测间隔时间 (S) */
uint8_t outputAgainFlagTime[2]; /* 出现短路保护后延长该段时间再次检测是否短路,仍然短路则关闭输出 (S) */
uint8_t excessiveLoadFlagTime[2]; /* 出现过载后在该间隔时间中多次2次出现过载则关闭输出 (S) */
uint8_t eLAgainTime[2]; /* 出现过载过载保护后,在该间隔段时间后,再次尝试输出 (S) */
uint8_t crc[2]; /* 校验 */
uint8_t end_Flag; /* 结束标志 */
}recv_config_info;
typedef struct _config_info{
uint8_t start_Flag[2]; /* 起始标志 */
/* SL */
uint8_t address[7]; /* 地址 */
uint32_t baud_485; /* 串口波特率 */
uint16_t constantCurrentV; /* 电压高于(ConstantCurrentV / 100 + 0.4),小于ConstantVoltageV / 100 - 0.4进入mppt模式 */
uint8_t Access_Node_Type[2]; /* 接入节点类型 */
uint8_t Communication_Methods[2]; /* 通信方式 */
uint8_t gw485_Baud[4]; /* 串口波特率,为0代表bms不支持通信 */
uint8_t bat485_Baud[4]; /* 串口波特率 */
/* HY */
uint8_t hardwareID[6]; /* 硬件ID */
uint8_t communicationID[4]; /* 通信ID */
uint8_t protocolType; /* 协议类型; 0x01表示汇源协议(波特率9600) 0x02表示南瑞协议(波特率115200)*/
uint16_t constantVoltageV; /* 电压高于该(ConstantVoltageV / 100)且电流大于FloatI / 100 + 0.1)进行恒压充电 */
uint16_t floatI; /* 电压高于该(ConstantVoltageV / 100)且电流低于FloatI / 100进行浮充充电 */
uint16_t startSolarOpenCircuitV; /* 太阳能板开路电压高于该(电压 / 100)开始充电 */
uint16_t stopSolarOpenCircuitV; /* 太阳能板开路电压高于该(电压 / 100)停止充电 */
uint16_t constantVoltageChargeV; /* 恒压充电时的输出电压 */
uint16_t trickleChargeC; /* 涓流充电电流 */
// uint16_t FloatTime; /* 浮充时间(秒) */
uint16_t FloatV; /* 浮充电压 */
uint16_t checkSolarOpenCircuitVTime; /* 启动任务中太阳能板开路电压检测时间 */
uint16_t registerRefreshTime; /* 寄存器数据刷新时间 */
uint16_t loopImpedance; /* 回路阻抗大小 */
// uint16_t resRefreshTime; /* 回路阻抗计算间隔时长 */
uint16_t sensorEnableBroadcastTime; /* 传感器运行再次注册的间隔 */
uint16_t HighSideMosTemperature_stop; /* 当上桥温度达到该值时,停止输出 */
uint16_t HighSideMosTemperature_end; /* 当上桥温度上升到该值时,降低功率运行 */
uint16_t HighSideMosTemperature_start; /* 当上桥温度降低到该值时,按照正常情况输出 */
uint16_t loopImpedance; /* 回路阻抗大小 (mΩ) */
uint16_t outputAgainFlagTime; /* 出现短路保护后延长该段时间再次检测是否短路,仍然短路则关闭输出 */
uint16_t excessiveLoadFlagTime; /* 出现过载后,在该段时间中再次出现过载,则关闭输出 */
uint16_t eLAgainTime; /* 出现过载过载保护后,该段时间后,再次尝试输出 */
uint8_t end_Flag; /* 结束标志 */
uint16_t crc; /* 校验 */
}config_info;
#define CONFIG_INFO_SIZE (sizeof(config_info))
#pragma pack(pop)
extern config_info g_slConfigInfo;
#define CONFIG_SAVE_ADDR_BEGIN (0x00)
#define CONFIG_SAVE_ADDR_END (0x00 + CONFIG_INFO_SIZE)
#define FLASH_SAVE_ADDR_BEGIN (0x00)
#define FLASH_SAVE_ADDR_END (0x00 + CONFIG_INFO_SIZE)
void save_config_info(config_info *save_config_info);
uint8_t read_config_info(void);
uint8_t read_config_info1(config_info *in_config_info);
#endif /* APP_INC_INFLASH_H_ */

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@ -11,14 +11,5 @@
#include "debug.h"
#include <math.h>
extern float g_duty_ratio;
void mppt_readJust(void);
void MpptMode(void);
void mppt_constantVoltage(float InVoltage);
void test(void);
void printf_data(void);
//float_t get_capturedata(float_t (*fun)(void));
uint16_t get_mpptMode(void);
#endif /* APP_INC_MPPT_CONTROL_H_ */

79
App/inc/parameter.h Normal file
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@ -0,0 +1,79 @@
/*
* parameter.h
*
* Created on: 20241012
* Author: psx
*/
#ifndef APP_INC_PARAMETER_H_
#define APP_INC_PARAMETER_H_
#include "debug.h"
#include "math.h"
#include "uart_dev.h"
typedef struct _Mppt_controlparameter{
float_t constantVoltageV; /* 电压高于ConstantVoltageV且电流大于FloatI + 0.1)进行恒压充电
(ConstantVoltageV - 0.2) (V) */
float_t floatI; /* 电压高于该ConstantVoltageV且电流低于FloatI进行浮充充电 (A) */
float_t startSolarOpenCircuitV; /* 太阳能板开路电压高于该电压开始充电 (V) */
float_t stopSolarOpenCircuitV; /* 太阳能板开路电压高于该电压停止充电 (V) */
float_t constantVoltageChargeV; /* 恒压充电时的输出电压 (V) */
float_t FloatV; /* 浮充充电时的输出电压 (V) */
float_t loopImpedance; /* 回路阻抗大小 (mΩ) */
float_t HighSideMosTemperature_stop; /* 当上桥温度达到该值时,停止输出 (°C) */
float_t HighSideMosTemperature_end; /* 当上桥温度上升到该值时,降低功率运行 (°C) */
float_t HighSideMosTemperature_start; /* 当上桥温度降低到该值时,按照正常情况输出 (°C) */
uint16_t sensorEnableBroadcastTime; /* 传感器运行再次注册的间隔 */
uint16_t checkSolarOpenCircuitVTime; /* 启动任务中太阳能板开路电压检测间隔时间 (S) */
uint16_t outputAgainFlagTime; /* 出现短路保护后延长该段时间再次检测是否短路,仍然短路则关闭输出 (S) */
uint16_t excessiveLoadFlagTime; /* 出现过载后在该间隔时间中多次2次出现过载则关闭输出 (S) */
uint16_t eLAgainTime; /* 出现过载过载保护后,在该间隔段时间后,再次尝试输出 (S) */
} Mppt_controlparameter;
extern Mppt_controlparameter g_controlParameter;
typedef struct _Mppt_otherParameter{
/* SL */
uint8_t address[7]; /* 地址 */
uint16_t Access_Node_Type; /* 接入节点类型 */
uint16_t Communication_Methods; /* 通信方式 */
uint16_t Registration_Status; /* 注册状态 */
uint32_t gw485_Baud; /* 串口波特率 */
uint32_t bat485_Baud; /* 串口波特率,为0代表bms不支持通信 */
/* HY */
uint8_t hardwareID[6]; /* 硬件ID */
uint8_t communicationID[4]; /* 通信ID */
uint8_t protocolType; /* 协议类型; 0x01表示汇源协议(波特率9600) 0x02表示南瑞协议(波特率115200)*/
float_t Battery_Voltage; /* 电池电压 (V) */
float_t Output_Voltage; /* 输出电压 */
float_t Charg_Current; /* 充电电流(流向电池+负载) (A) */
float_t Discharg_Current; /* 放电电流(流向负载) (A) */
float_t Input_Voltage; /* 太阳能板输入电压 (V) */
float_t Solar_Open_Circuit_Voltage; /* 太阳能板开路电压 (V) */
float_t HighSideMos_Temperature; /* 高端mos的温度 (°C) */
float_t Solar_In_Circuit_Voltage; /* 太阳能板输入电压 (V) */
float_t Charg_BatteryCurrent; /* 电池充电电流(流向电池) (A) */
float_t totalElectricityConsumption; /* 总电量消耗 */
float_t totalChargCapacity; /* 总充电电量 */
float_t SOC; /* 剩余电量 */
uint16_t chargMos_State; /* 充电开关状态 */
uint16_t DischargMos_State; /* 放电mos的状态 */
uint16_t MPPT_Mode; /* 工作模式 */
uint8_t versionInformation[13]; /* 软件版本信息 */
}Mppt_otherParameter;
extern Mppt_otherParameter g_otherParameter;
#endif /* APP_INC_PARAMETER_H_ */

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@ -219,23 +219,6 @@ typedef struct _default_Value{
extern default_Value defaultValue;
typedef struct _SL_Mppt_para{
uint16_t Registration_Status; /* 注册状态 */
uint8_t address[7]; /* 地址 */
uint16_t Access_Node_Type; /* 接入节点类型 */
uint16_t Communication_Methods; /* 通信方式 */
float_t Output_Voltage; /* 输出电压 */
float_t Battery_Voltage; /* 电池电压 */
float_t Charg_Current; /* 充电电流(流向电池+负载) */
float_t Discharg_Current; /* 放电电流(流向负载) */
float_t Input_Voltage; /* 太阳能板输出电压 */
float_t Solar_Open_Circuit_Voltage; /* 太阳能板开路电压 */
float_t HighSideMos_Temperature; /* 高端mos的温度 */
uint16_t DischargMos_State; /* 放电mos的状态 */
uint16_t MPPT_Mode; /* 工作模式 */
}SL_Mppt_para;
extern SL_Mppt_para g_Mppt_Para;
/* 恢复默认的对齐设置 */
#pragma pack(pop)

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@ -13,79 +13,9 @@
#include "uart_dev.h"
#include "math.h"
//extern uint8_t g_interruptNum;
void stop_mpptWork(void);
void start_mpptWork(void);
#define runled_reloadVal 1000 /* 任务执行间隔 */
#define runled_offset 0 /* 任务执行偏移量 */
extern STR_TimeSliceOffset m_runled;
extern void Task_RunLED(void);
#define startMpptControl_reloadVal 1000 /* 任务执行间隔 */
#define startMpptControl_offset 0 /* 任务执行偏移量 */
extern STR_TimeSliceOffset m_startMpptControl;;
extern void Task_startMpptControl(void);
#define softStart_reloadVal 30 /* 任务执行间隔 */
#define softStart_offset 0 /* 任务执行偏移量 */
extern STR_TimeSliceOffset m_softStart;
extern void Task_softStart(void);
#define usart_reloadVal 100 /* 任务执行间隔 */
#define usart_offset 0 /* 任务执行偏移量 */
extern STR_TimeSliceOffset m_usart;
extern uint8_t RegistrationRequestFlag; /* 接收到广播帧标志位 */
void Task_usart(void);
#define wdi_reloadVal 1000 /* 任务执行间隔 */
#define wdi_offset 30 /* 任务执行偏移量 */
#define wdi_RESET (60 * 60 * 24) /* 一天复位一次 */
extern STR_TimeSliceOffset m_wdi;
extern void Task_wdi(void);
#define refreshRegister_reloadVal 1000 /* 任务执行间隔 */
#define refreshRegister_offset 100 /* 任务执行偏移量 */
extern STR_TimeSliceOffset m_refreshRegister;
extern uint8_t overTemperature;
extern void Task_refreshRegister(void);
#define recvbroadcast_reloadVal 3000 /* 任务执行间隔 */
#define recvbroadcast_offset 0 /* 任务执行偏移量 */
extern uint8_t recvbroadcast_flag; /* 是否需要再次发送标志 */
extern device_handle g_recvBroadcastDevice; /* 串口句柄 */
extern uint8_t g_recvBroadcastRegisterNumber; /* 寄存器长度 */
extern STR_TimeSliceOffset m_recvbroadcast;
extern void Task_recvbroadcast(void);
#define impedanceCalculation_reloadVal 200 /* 任务执行间隔 */
#define impedanceCalculation_offset 0 /* 任务执行偏移量 */
extern float_t g_impedance;
extern uint8_t g_batteryState;
extern uint8_t g_impedanceStart;
extern STR_TimeSliceOffset m_impedanceCalculation;
extern void Task_impedanceCalculation(void);
#define outputAgain_reloadVal 1000 /* 任务执行间隔 */
#define outputAgain_offset 0 /* 任务执行偏移量 */
extern uint8_t outputAgainFlag;
extern STR_TimeSliceOffset m_outputAgain;
extern void Task_outputAgain(void);
#define excessiveLoad_reloadVal 1000 /* 任务执行间隔 */
#define excessiveLoad_offset 0 /* 任务执行偏移量 */
extern uint8_t excessiveLoadFlag;
extern STR_TimeSliceOffset m_excessiveLoad;
extern void Task_excessiveLoad(void);
#define sensorEnableBroadcast_reloadVal 1000 /* 任务执行间隔 */
#define sensorEnableBroadcast_offset 0 /* 任务执行偏移量 */
extern STR_TimeSliceOffset m_sensorEnableBroadcast;
/* 是否接收广播帧标志位 */
extern uint8_t run_Broadcast;
extern void Task_sensorEnableBroadcast(void);
void task_Init(void);
void hardware_Init(void);
#endif /* APP_INC_TASK_H_ */

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@ -95,7 +95,7 @@ HY_FuncionMsgProcTable g_hyMsgTbl[] =
* @retval 1 ·±Ã¦
* 0 ¿ÕÏÐ
*/
uint8_t Check_485_bus_busy(device_handle device)
uint8_t HY_Check_485_bus_busy(device_handle device)
{
if (device == g_bat485_uart3_handle) {
USART_ITConfig(USART3, USART_IT_RXNE, ENABLE);
@ -146,20 +146,20 @@ uint8_t HY_CheckFunc(uint8_t *arr_buff, uint8_t len)
*/
static int HY_matchhardwareID(u_int8_t hardwareID[6])
{
// if (!strcmp(address, g_slConfigInfo.address)) {
// log_info("Match_address fail \r\n");
//// if (!strcmp(address, g_slConfigInfo.address)) {
//// log_info("Match_address fail \r\n");
//// return 1;
//// }
// if ((hardwareID[0] == g_slConfigInfo.address[0]) && \
// (hardwareID[1] == g_slConfigInfo.address[1]) && \
// (hardwareID[2] == g_slConfigInfo.address[2]) && \
// (hardwareID[3] == g_slConfigInfo.address[3]) && \
// (hardwareID[4] == g_slConfigInfo.address[4]) && \
// (hardwareID[5] == g_slConfigInfo.address[5]) && \
// (hardwareID[6] == g_slConfigInfo.address[6])) {
// log_info("Match_address success \r\n");
// return 1;
// }
if ((hardwareID[0] == g_slConfigInfo.address[0]) && \
(hardwareID[1] == g_slConfigInfo.address[1]) && \
(hardwareID[2] == g_slConfigInfo.address[2]) && \
(hardwareID[3] == g_slConfigInfo.address[3]) && \
(hardwareID[4] == g_slConfigInfo.address[4]) && \
(hardwareID[5] == g_slConfigInfo.address[5]) && \
(hardwareID[6] == g_slConfigInfo.address[6])) {
log_info("Match_address success \r\n");
return 1;
}
return 0;
}

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@ -9,103 +9,6 @@
#include "flash.h"
#include "sl_protocol.h"
config_info g_slConfigInfo = {
.constantCurrentV = 1000,
.constantVoltageV = 1420,
.floatI = 20,
.startSolarOpenCircuitV = 1700,
.stopSolarOpenCircuitV = 1500,
.constantVoltageChargeV = 1440,
.trickleChargeC = 100,
// .FloatTime = 10,
.FloatV = 1420,
.checkSolarOpenCircuitVTime = 10,
.registerRefreshTime = 1,
.loopImpedance = 20,
// .resRefreshTime = 1,
.sensorEnableBroadcastTime = 20,
.HighSideMosTemperature_stop = 70,
.HighSideMosTemperature_end = 50,
.HighSideMosTemperature_start = 40,
.outputAgainFlagTime = 10,
.excessiveLoadFlagTime = 60,
.eLAgainTime = 3600,
};
/**
* @brief
* @param save_config_info
* @retval
*/
void save_config_info(config_info *save_config_info)
{
SPI_Flash_Write((uint8_t *)save_config_info, FLASH_SAVE_ADDR_BEGIN, CONFIG_INFO_SIZE);
}
/**
* @brief
* @param read_config_info
* @retval 0 flash中读取配置失败
* 1 flash中读取配置成功
*/
uint8_t read_config_info(void)
{
config_info temp_config_info;
SPI_Flash_Read((uint8_t *)&temp_config_info, FLASH_SAVE_ADDR_BEGIN, CONFIG_INFO_SIZE);
if (temp_config_info.start_Flag[0] == 'S'
&& temp_config_info.start_Flag[1] == 'L'
&& temp_config_info.end_Flag == 0x16) {
g_slConfigInfo = temp_config_info;
return 1;
}
else {
g_slConfigInfo.start_Flag[0] = defaultValue.start_Flag[0];
g_slConfigInfo.start_Flag[1] = defaultValue.start_Flag[1];
g_slConfigInfo.address[0] = defaultValue.address[0];
g_slConfigInfo.address[1] = defaultValue.address[1];
g_slConfigInfo.address[2] = defaultValue.address[2];
g_slConfigInfo.address[3] = defaultValue.address[3];
g_slConfigInfo.address[4] = defaultValue.address[4];
g_slConfigInfo.address[5] = defaultValue.address[5];
g_slConfigInfo.address[6] = defaultValue.address[6];
g_slConfigInfo.end_Flag = defaultValue.end_Flag;
}
return 0;
}
/**
* @brief
* @param read_config_info1 in_config_info中
* @retval 0 flash中读取配置失败使
* 1 flash中读取配置成功
*/
uint8_t read_config_info1(config_info *in_config_info)
{
config_info temp_config_info;
SPI_Flash_Read((uint8_t *)&temp_config_info, FLASH_SAVE_ADDR_BEGIN, CONFIG_INFO_SIZE);
if (temp_config_info.start_Flag[0] == 'S'
&& temp_config_info.start_Flag[1] == 'L'
&& temp_config_info.end_Flag == 0x16) {
*in_config_info = temp_config_info;
return 1;
} else {
in_config_info->start_Flag[0] = defaultValue.start_Flag[0];
in_config_info->start_Flag[1] = defaultValue.start_Flag[1];
in_config_info->address[0] = defaultValue.address[0];
in_config_info->address[1] = defaultValue.address[1];
in_config_info->address[2] = defaultValue.address[2];
in_config_info->address[3] = defaultValue.address[3];
in_config_info->address[4] = defaultValue.address[4];
in_config_info->address[5] = defaultValue.address[5];
in_config_info->address[6] = defaultValue.address[6];
in_config_info->end_Flag = defaultValue.end_Flag;
}
return 0;
}

View File

@ -12,916 +12,5 @@
#include "gpio.h"
#include "sl_protocol.h"
#include "task.h"
#include "uart_dev.h"
static void TrickleCharge(void);
static void ConstantCurrentCharge(void);
static void ConstantVoltageCharge(void);
static void FloatingCharge(void);
//static void NoBatteryCharge(void);
/* 占空比 */
float g_duty_ratio = 0.75;
/* 用于确定工作模式 */
//static uint8_t modeFlag = 2;
/**
* @brief
* @param
* @retval OutputPower
*/
static float Get_OutputPower(void)
{
static float OutputPower;
static float V_out, I_out;
V_out = get_PV_VOLT_OUT();
I_out = get_CHG_CURR();
OutputPower = V_out * I_out;
printf(" V = %d/100, I = %d/10000, OutputPower = %d/10000 \r\n",
(int)(V_out*100), (int)(I_out * 10000), (int)(OutputPower * 10000));
return OutputPower;
}
/**
* @brief 使,,使
* @param
* @retval
*/
/* pwm占空比调节步长 */
const float step1_pwm = 0.01;
const float step2_pwm = 0.005;
//#define array_num 10
void mppt_readJust(void)
{
// static float last_duty_ratio = 0.5;
// static float now_duty_ratio;
// static float last_OutputPower;
// static float now_OutputPower;
// static float step_pwm = step1_pwm;
//
// last_OutputPower = Get_OutputPower();
//
// printf(" duty_ratio = %d/1000 \r\n", (int)(last_duty_ratio * 1000));
//
// /* 正向调节查看功率是否会变大 */
// now_duty_ratio = last_duty_ratio + step_pwm;
// if (now_duty_ratio > 1) {
// now_duty_ratio = 1;
// }
// Set_duty_ratio(now_duty_ratio);
// now_OutputPower = Get_OutputPower();
// if (now_OutputPower > last_OutputPower) {
// printf(" now_OutputPower > last_OutputPower1 \r\n");
// last_duty_ratio = now_duty_ratio;
// return;
// }
//
// /* 负向调节查看功率是否会变大 */
// now_duty_ratio = last_duty_ratio - step_pwm;
// if (now_duty_ratio < 0) {
// now_duty_ratio = 0;
// }
// Set_duty_ratio(now_duty_ratio);
// now_OutputPower = Get_OutputPower();
// if (now_OutputPower > last_OutputPower) {
// printf(" now_OutputPower > last_OutputPower2 \r\n");
// last_duty_ratio = now_duty_ratio;
// return;
// }
//
// /* 正负向调节功率均未变大,此时设置功率为原来的点 */
// Set_duty_ratio(last_duty_ratio);
// step_pwm = step2_pwm;
static float last_duty_ratio = 0.5;
static float last_OutputPower;
static float now_OutputPower;
static float step_pwm = step1_pwm;
last_OutputPower = Get_OutputPower();
printf(" duty_ratio = %d/1000 \r\n", (int)(last_duty_ratio * 1000));
/* 正向调节查看功率是否会变大 */
g_duty_ratio = last_duty_ratio + step_pwm;
Set_duty_ratio(&g_duty_ratio);
now_OutputPower = Get_OutputPower();
if (now_OutputPower > last_OutputPower) {
printf(" now_OutputPower > last_OutputPower1 \r\n");
last_duty_ratio = g_duty_ratio;
return;
}
/* 负向调节查看功率是否会变大 */
g_duty_ratio = last_duty_ratio - step_pwm;
Set_duty_ratio(&g_duty_ratio);
now_OutputPower = Get_OutputPower();
if (now_OutputPower > last_OutputPower) {
printf(" now_OutputPower > last_OutputPower2 \r\n");
last_duty_ratio = g_duty_ratio;
return;
}
/* 正负向调节功率均未变大,此时设置功率为原来的点 */
g_duty_ratio = last_duty_ratio;
Set_duty_ratio(&g_duty_ratio);
step_pwm = step2_pwm;
}
void printf_data(void)
{
printf("\n");
// get_CHG_CURR();
// get_PV_VOLT_OUT();
// get_DSG_CURR();
// get_PV1_VOLT_IN();
// get_PV_VOLT_IN1();
// get_MOSFET_Temper();
// get_PV2_VOLT_IN();
printf("\n");
}
//float_t get_capturedata(float_t (*fun)(void))
//{
// float_t temp1;
// float_t temp[3];
//
// for (int i = 0; i < 3; ++i) {
// temp[i] = fun();
//// Delay_Us(1);
// }
//
// if (temp[0] > temp[1]) {
// temp1 = temp[0];
// temp[0] = temp[1];
// temp[1] = temp1;
// }
//
// if (temp[0] > temp[2]) {
// temp1 = temp[0];
// temp[0] = temp[2];
// temp[2] = temp1;
// if (temp[1] > temp[2]) {
// temp1 = temp[1];
// temp[1] = temp[2];
// temp[2] = temp1;
// }
// }
//
// return temp[1];
//}
//uint16_t get_mpptMode(void)
//{
// return (uint16_t)modeFlag;
//}
/**
* @brief
* @param
* @retval
*
*/
void mppt_constantVoltage(float InVoltage)
{
// static uint8_t ConstantVoltageFlag = 1;
// float PV1_V = get_PV1_VOLT_IN();
//
// if (ConstantVoltageFlag) {
// if (PV1_V > InVoltage) {
// g_duty_ratio += step1_pwm;
// Set_duty_ratio(&g_duty_ratio);
// } else {
// g_duty_ratio -= step1_pwm;
// Set_duty_ratio(&g_duty_ratio);
// }
//
// if (PV1_V - InVoltage < 0.1) {
// ConstantVoltageFlag = 0;
// }
// } else {
// if (PV1_V > InVoltage) {
// g_duty_ratio += step2_pwm;
// Set_duty_ratio(&g_duty_ratio);
// } else {
// g_duty_ratio -= step2_pwm;
// Set_duty_ratio(&g_duty_ratio);
// }
//
// if (PV1_V - InVoltage > 0.1) {
// ConstantVoltageFlag = 1;
// }
// }
static float_t kp = 0.005;
static float_t ki = 0.00001;
// static float_t allError = 0;
// float_t error = (get_PV1_VOLT_IN()) - InVoltage;
// float_t error = InVoltage - (get_PV2_VOLT_IN());
// allError += error;
// printf("111\n");
// float_t pv1Volt = get_capturedata(get_PV1_VOLT_IN);
// float_t pv1Volt = get_PV1_VOLT_IN();
float_t pv1Volt = g_Mppt_Para.Input_Voltage;
// printf("volt in : %d \n", pv1Volt);
float_t error = pv1Volt - InVoltage;
// float_t error = InVoltage - pv1Volt;
float_t stepPwm = kp * error + ki * pv1Volt;
g_duty_ratio += stepPwm;
// printf("setPwm : %d/10000 \n", (int)(stepPwm * 10000));
// printf("setPwm : %d/10000 \n", (int)(stepPwm * 10000));
// printf("g_duty_ratio : %d/10000 \n", (int)(g_duty_ratio * 10000));
Set_duty_ratio(&g_duty_ratio);
}
/**
* @brief ()
* @param
* @retval
*
*/
void mppt_constantVoltageB(float OutVoltage)
{
// static uint8_t ConstantVoltageFlag = 1;
// float PV1_V = get_PV_VOLT_OUT();
//
// if (ConstantVoltageFlag) {
// if (PV1_V > OutVoltage) {
// g_duty_ratio -= step1_pwm;
// Set_duty_ratio(&g_duty_ratio);
// } else {
// g_duty_ratio += step1_pwm;
// Set_duty_ratio(&g_duty_ratio);
// }
//
// if (PV1_V - OutVoltage < 0.1) {
// ConstantVoltageFlag = 0;
// }
// } else {
// if (PV1_V > OutVoltage) {
// g_duty_ratio -= step2_pwm;
// Set_duty_ratio(&g_duty_ratio);
// } else {
// g_duty_ratio += step2_pwm;
// Set_duty_ratio(&g_duty_ratio);
// }
//
// if (PV1_V - OutVoltage > 0.1) {
// ConstantVoltageFlag = 1;
// }
// }
// static float_t kp = 0.0005;
// static float_t ki = 0.000001;
static float_t kp = 0.005;
static float_t ki = 0.00001;
// static float_t kp = 0.1;
// static float_t ki = 0.001;
// float_t outVolt = get_PV_VOLT_OUT();
float_t outVolt = g_Mppt_Para.Battery_Voltage;
// float_t outVolt = voltOut;
// float_t error = outVolt - OutVoltage;
float_t error = OutVoltage - outVolt;
float_t stepPwm = kp * error + ki * outVolt;
g_duty_ratio += stepPwm;
// printf("setPwm : %d/10000 \n", (int)(stepPwm * 10000));
Set_duty_ratio(&g_duty_ratio);
}
/**
* @brief
* @param
* @retval
*
*/
void mppt_constantVoltageO(float OutVoltage)
{
// static uint8_t ConstantVoltageFlag = 1;
// float PV1_V = get_PV_VOLT_OUT();
//
// if (ConstantVoltageFlag) {
// if (PV1_V > OutVoltage) {
// g_duty_ratio -= step1_pwm;
// Set_duty_ratio(&g_duty_ratio);
// } else {
// g_duty_ratio += step1_pwm;
// Set_duty_ratio(&g_duty_ratio);
// }
//
// if (PV1_V - OutVoltage < 0.1) {
// ConstantVoltageFlag = 0;
// }
// } else {
// if (PV1_V > OutVoltage) {
// g_duty_ratio -= step2_pwm;
// Set_duty_ratio(&g_duty_ratio);
// } else {
// g_duty_ratio += step2_pwm;
// Set_duty_ratio(&g_duty_ratio);
// }
//
// if (PV1_V - OutVoltage > 0.1) {
// ConstantVoltageFlag = 1;
// }
// }
// static float_t kp = 0.0005;
// static float_t ki = 0.000001;
static float_t kp = 0.005;
static float_t ki = 0.00001;
// static float_t kp = 0.1;
// static float_t ki = 0.001;
// float_t outVolt = get_PV_VOLT_OUT();
float_t outVolt = g_Mppt_Para.Output_Voltage;
// float_t outVolt = voltOut;
// float_t error = outVolt - OutVoltage;
float_t error = OutVoltage - outVolt;
float_t stepPwm = kp * error + ki * outVolt;
g_duty_ratio += stepPwm;
// printf("setPwm : %d/10000 \n", (int)(stepPwm * 10000));
Set_duty_ratio(&g_duty_ratio);
}
/**
* @brief
* @param
* @retval
*
*/
void mppt_constantCurrentO(float outCurrent)
{
// static uint8_t ConstantCurrent = 1;
// float out_I = get_CHG_CURR();
//
// if (ConstantCurrent) {
// if (out_I > outCurrent) {
// g_duty_ratio -= step1_pwm;
// Set_duty_ratio(&g_duty_ratio);
// } else {
// g_duty_ratio += step1_pwm;
// Set_duty_ratio(&g_duty_ratio);
// }
//
// if (out_I - outCurrent < 0.1) {
// ConstantCurrent = 0;
// }
// }
//
// else {
// if (out_I > outCurrent) {
// g_duty_ratio -= step2_pwm;
// Set_duty_ratio(&g_duty_ratio);
// } else {
// g_duty_ratio += step2_pwm;
// Set_duty_ratio(&g_duty_ratio);
// }
//
// if (out_I - outCurrent > 0.1) {
// ConstantCurrent = 1;
// }
// }
static float_t kp = 0.005;
static float_t ki = 0.00005;
// static float_t last_CHG_CURR = 0;
// static float_t flag = 1;
// static float_t last_OutputPower = 0;
// float_t outCurr = get_CHG_CURR();
float_t outCurr = g_Mppt_Para.Charg_Current;
// float_t OutputPower = outCurr * get_PV_VOLT_OUT();
float_t error = outCurrent - outCurr;
// float_t error = outCurr - outCurrent;
float_t stepPwm = kp * error + ki * outCurr;
// if (flag) {
// if (OutputPower > last_OutputPower) {
// g_duty_ratio += stepPwm;
// flag = 1;
// } else {
// g_duty_ratio -= stepPwm;
// flag = 0;
// }
// } else {
// if (OutputPower > last_OutputPower) {
// g_duty_ratio -= stepPwm;
// flag = 0;
// } else {
// g_duty_ratio += stepPwm;
// flag = 1;
// }
// }
//
// last_OutputPower = OutputPower;
g_duty_ratio += stepPwm;
// printf("setPwm : %d/10000 \n", (int)(stepPwm * 10000));
// printf("g_duty_ratio : %d/10000 \n", (int)(g_duty_ratio * 10000));
Set_duty_ratio(&g_duty_ratio);
// last_CHG_CURR = outCurr;
// if (stepPwm > 0 && (last_CHG_CURR > outCurr)) {
// flag = 1;
// } else {
// flag = 0;
// }
}
/**
* @brief
* @param
* @retval
*
*/
void TrickleCharge(void)
{
static float_t TrickleChargeC;
static uint8_t onlyOnce = 1;
if (onlyOnce) {
TrickleChargeC = (float_t)g_slConfigInfo.trickleChargeC / 100;
onlyOnce = 0;
}
// printf("Trickle\n");
mppt_constantCurrentO(TrickleChargeC + g_Mppt_Para.Discharg_Current);
}
/**
* @brief mppt最大功率充电
* @param
* @retval
*
*/
void ConstantCurrentCharge(void)
{
// mppt_readJust();
mppt_constantVoltage(18);
// printf("ConstantCurrent\n");
}
/**
* @brief
* @param
* @retval
*
*/
void ConstantVoltageCharge(void)
{
static float_t ConstantVoltageChargeV;
static uint8_t onlyOnce = 1;
if (onlyOnce) {
ConstantVoltageChargeV = (float_t)g_slConfigInfo.constantVoltageChargeV / 100;
onlyOnce = 0;
}
mppt_constantVoltageO(ConstantVoltageChargeV);
}
/**
* @brief
* @param
* @retval
*
*/
void FloatingCharge(void)
{
// static uint32_t num = 0;
// static uint32_t numLenFlag;
// static uint8_t onlyOnce = 1;
// if (onlyOnce) {
// numLenFlag = g_slConfigInfo.FloatTime * 1000;
// onlyOnce = 0;
// }
// printf("float\n");
// TIM_SetCompare4(TIM4, 0);
// if (numLenFlag == ++num) {
// num = 0;
// for (int var = 0; var < 10; ++var) {
// ConstantVoltageCharge();
// }
// g_Mppt_Para.MPPT_Mode = CONSTANTVOLTAGE;
// printf("float\n");
// }
static float_t FloatChargeV;
static uint8_t onlyOnce = 1;
if (onlyOnce) {
FloatChargeV = (float_t)g_slConfigInfo.FloatV / 100;
onlyOnce = 0;
}
mppt_constantVoltageO(FloatChargeV);
}
/**
* @brief
* @param
* @retval
*
*/
void NoBatteryCharge(void)
{
// static float_t NoBatteryChargeV;
// static uint8_t onlyOnce = 1;
// if (onlyOnce) {
// NoBatteryChargeV = (float_t)g_slConfigInfo.noBatteryChargeV / 100;
// onlyOnce = 0;
// }
mppt_constantVoltageO(14.2);
// if ((g_Mppt_Para.Battery_Voltage - NoBatteryChargeV > 0.2 && g_Mppt_Para.Charg_Current < 0.1)
// || (NoBatteryChargeV - g_Mppt_Para.Battery_Voltage > 0.1 && g_Mppt_Para.Charg_Current > 0.5)) {
// ConstantCurrentCharge();
// g_Mppt_Para.MPPT_Mode = CONSTANTCURRENT;
// }
// if (!overTemperature) {
// if (!(g_Mppt_Para.Charg_Current - g_Mppt_Para.Discharg_Current < 0.3
// && g_Mppt_Para.Discharg_Current - g_Mppt_Para.Charg_Current < 0.3)) {
// ConstantCurrentCharge();
// g_Mppt_Para.MPPT_Mode = CONSTANTCURRENT;
// }
// }
}
void MpptContorl(void)
{
switch(g_Mppt_Para.MPPT_Mode) {
case TRICKLE:
// printf("111\n");
TrickleCharge();
break;
case CONSTANTCURRENT:
// printf("222222\n");
ConstantCurrentCharge();
// ConstantVoltageCharge();
break;
case CONSTANTVOLTAGE:
// printf("333333333\n");
ConstantVoltageCharge();
break;
case FLOAT:
// printf("444444444444\n");
FloatingCharge();
break;
// case NoBattery:
//// printf("555555555555555\n");
// NoBatteryCharge();
// break;
default:
break;
}
}
void MpptMode(void)
{
// printf("vout : %d /100 \n", (int)(g_Mppt_Para.Battery_Voltage * 100));
// printf("iout : %d /1000 \n", (int)(g_Mppt_Para.Charg_Current * 1000));
// printf("in checkSolarOpenCircuitVoltage v: %d/100 \n", (int)(g_Mppt_Para.Solar_Open_Circuit_Voltage * 100));
static float ConstantCurrentV;
static float ConstantVoltageV;
static float FloatI;
static float StopSolarOpenCircuitV;
/* 赋值仅执行一次 */
static uint8_t only_once = 1;
if (only_once) {
ConstantCurrentV = (float)g_slConfigInfo.constantCurrentV / 100;
ConstantVoltageV = (float)g_slConfigInfo.constantVoltageV / 100;
FloatI = (float)g_slConfigInfo.floatI / 100;
printf("FloatI: %d / 100 \n", (int)(FloatI * 100));
StopSolarOpenCircuitV = (float)g_slConfigInfo.stopSolarOpenCircuitV / 100;
only_once = 0;
}
//// if (g_Mppt_Para.Battery_Voltage > 16 || g_Mppt_Para.Battery_Voltage < 8
//// || modeFlag == NoBattery) {
//// modeFlag = NoBattery;
// if (g_Mppt_Para.Battery_Voltage > 16 || g_Mppt_Para.Battery_Voltage < 8
// || g_Mppt_Para.MPPT_Mode == NoBattery) {
// g_Mppt_Para.MPPT_Mode = NoBattery;
// return;
// }
//
//// if (((ConstantVoltageV < g_Mppt_Para.Battery_Voltage) &&
//// (FloatI > g_Mppt_Para.Charg_Current)) || modeFlag == FLOAT) {
//// modeFlag = FLOAT;
// if (((ConstantVoltageV < g_Mppt_Para.Battery_Voltage) &&
// (FloatI > g_Mppt_Para.Charg_Current)) || g_Mppt_Para.MPPT_Mode == FLOAT) {
// g_Mppt_Para.MPPT_Mode = FLOAT;
// return;
// }
//
// if (((ConstantCurrentV + 0.4) < g_Mppt_Para.Battery_Voltage) &&
// ((ConstantVoltageV - 0.4) >= g_Mppt_Para.Battery_Voltage)) {
//// modeFlag = CONSTANTCURRENT;
// g_Mppt_Para.MPPT_Mode = CONSTANTCURRENT;
// return;
// }
//
// if ((ConstantVoltageV < g_Mppt_Para.Battery_Voltage) &&
// (FloatI + 0.1 <= g_Mppt_Para.Charg_Current)) {
//// modeFlag = CONSTANTVOLTAGE;
// g_Mppt_Para.MPPT_Mode = CONSTANTVOLTAGE;
// return;
// }
//
// if (ConstantCurrentV > g_Mppt_Para.Battery_Voltage) {
//// modeFlag = TRICKLE;
// g_Mppt_Para.MPPT_Mode = TRICKLE;
// return;
// }
// if (g_Mppt_Para.Battery_Voltage > 16 || g_Mppt_Para.Battery_Voltage < 8
// || g_Mppt_Para.MPPT_Mode == NoBattery) {
// g_Mppt_Para.MPPT_Mode = NoBattery;
// return;
// }
// if (g_Mppt_Para.Charg_Current - g_Mppt_Para.Discharg_Current < 0.05
// || g_Mppt_Para.Discharg_Current - g_Mppt_Para.Charg_Current < 0.05) {
// g_Mppt_Para.MPPT_Mode = NoBattery;
// return;
// }
//
// if (((ConstantVoltageV < g_Mppt_Para.Battery_Voltage) &&
// (FloatI > g_Mppt_Para.Charg_Current)) || g_Mppt_Para.MPPT_Mode == FLOAT) {
// g_Mppt_Para.MPPT_Mode = FLOAT;
// return;
// }
//
// if (((ConstantCurrentV + 0.4) < g_Mppt_Para.Battery_Voltage) &&
// ((ConstantVoltageV - 0.4) >= g_Mppt_Para.Battery_Voltage)) {
// g_Mppt_Para.MPPT_Mode = CONSTANTCURRENT;
// return;
// }
//
// if ((ConstantVoltageV < g_Mppt_Para.Battery_Voltage) &&
// (FloatI + 0.1 <= g_Mppt_Para.Charg_Current)) {
// g_Mppt_Para.MPPT_Mode = CONSTANTVOLTAGE;
// return;
// }
//
// if (ConstantCurrentV > g_Mppt_Para.Battery_Voltage) {
// g_Mppt_Para.MPPT_Mode = TRICKLE;
// return;
// }
// if (g_Mppt_Para.Input_Voltage < StopSolarOpenCircuitV
// && (g_Mppt_Para.Discharg_Current >= g_Mppt_Para.Charg_Current
// || g_Mppt_Para.Charg_Current - g_Mppt_Para.Discharg_Current < 0.05)) {
if ((g_Mppt_Para.Input_Voltage < StopSolarOpenCircuitV && g_Mppt_Para.Charg_Current < 0.05)
&& g_Mppt_Para.MPPT_Mode != NoWork) {
g_Mppt_Para.MPPT_Mode = NoWork;
// printf("nowork \n");
stop_mpptWork();
TimeSliceOffset_Register(&m_startMpptControl, Task_startMpptControl
, startMpptControl_reloadVal, startMpptControl_offset);
return;
}
// if (((g_Mppt_Para.Charg_Current - g_Mppt_Para.Discharg_Current < 0.03
// && g_Mppt_Para.Discharg_Current - g_Mppt_Para.Charg_Current < 0.03)
// && (g_Mppt_Para.Battery_Voltage < ConstantVoltageV - 1
// || g_Mppt_Para.Battery_Voltage > ConstantVoltageV + 1))
// || g_Mppt_Para.MPPT_Mode == NoBattery) {
// g_Mppt_Para.MPPT_Mode = NoBattery;
// return;
// }
// if (((ConstantVoltageV < g_Mppt_Para.Battery_Voltage) &&
// (FloatI > g_Mppt_Para.Charg_Current)) || g_Mppt_Para.MPPT_Mode == FLOAT) {
// g_Mppt_Para.MPPT_Mode = FLOAT;
// return;
// }
if ((g_Mppt_Para.Charg_Current - g_Mppt_Para.Discharg_Current < 0.05
&& g_Mppt_Para.Discharg_Current - g_Mppt_Para.Charg_Current < 0.05)
|| g_Mppt_Para.Battery_Voltage > 16 || g_Mppt_Para.Battery_Voltage < 8) {
// || g_Mppt_Para.MPPT_Mode == NoBattery) {
// g_Mppt_Para.MPPT_Mode = NoBattery;
// g_Mppt_Para.MPPT_Mode = CONSTANTVOLTAGE;
g_Mppt_Para.MPPT_Mode = FLOAT;
// printf("Charg_Current : %d/100 \n", (int)(g_Mppt_Para.Charg_Current * 100));
// printf("Discharg_Current : %d/100 \n", (int)(g_Mppt_Para.Discharg_Current * 100));
// printf("Battery_Voltage : %d/100 \n", (int)(g_Mppt_Para.Battery_Voltage * 100));
g_batteryState = 0;
return;
}
if ((((ConstantCurrentV + 0.2) < g_Mppt_Para.Battery_Voltage)
&&((ConstantVoltageV - 0.2) >= g_Mppt_Para.Battery_Voltage))
&&(g_Mppt_Para.Charg_Current - g_Mppt_Para.Discharg_Current > 0.1)) {
g_Mppt_Para.MPPT_Mode = CONSTANTCURRENT;
return;
}
// if ((g_Mppt_Para.Charg_Current - g_Mppt_Para.Discharg_Current > 4)) {
// g_Mppt_Para.MPPT_Mode = CONSTANTCURRENT;
// return;
// }
// if (((ConstantVoltageV < g_Mppt_Para.Battery_Voltage)
// &&(FloatI + 0.1 <= g_Mppt_Para.Charg_Current))
// || (FloatI + 0.1 <= g_Mppt_Para.Discharg_Current)) {
//// || (g_Mppt_Para.Charg_Current - g_Mppt_Para.Discharg_Current < 0.03
//// && g_Mppt_Para.Discharg_Current - g_Mppt_Para.Charg_Current < 0.03)) {
//
//// printf("mppt mode \n");
//// printf(" vout : %d/100 \n", (int)(g_Mppt_Para.Battery_Voltage * 100));
// g_Mppt_Para.MPPT_Mode = CONSTANTVOLTAGE;
// return;
// }
if (((ConstantVoltageV < g_Mppt_Para.Battery_Voltage)
&&(FloatI + 0.1 <= g_Mppt_Para.Charg_Current - g_Mppt_Para.Discharg_Current))) {
g_Mppt_Para.MPPT_Mode = CONSTANTVOLTAGE;
return;
}
if ((((ConstantVoltageV < g_Mppt_Para.Battery_Voltage)
&& (FloatI > g_Mppt_Para.Charg_Current))
&& (FloatI > g_Mppt_Para.Discharg_Current))) {
// || g_Mppt_Para.MPPT_Mode == FLOAT) {
g_Mppt_Para.MPPT_Mode = FLOAT;
return;
}
if (ConstantCurrentV > g_Mppt_Para.Battery_Voltage) {
g_Mppt_Para.MPPT_Mode = TRICKLE;
return;
}
}
void findMiNDutyRatio(void)
{
static uint8_t num = 100;
if (0.05 < get_CHG_CURR()) {
num -= 1;
TIM_SetCompare4(TIM4, num);
}
else {
printf("min duty ratio : %d/200 \n", num);
}
}
void test(void)
{
// mppt_readjust();
// Get_OutputPower();
// mppt_constantVoltage(18);
// findMiNDutyRatio();
// MpptContorl();
// printf_data();
// void MpptContorl();
// mppt_constantVoltageO(12);
// FloatingCharge();
// mppt_readJust();
// mppt_constantCurrentO(1);
// if (g_interruptNum < 5) {
// g_interruptNum++;
// return;
// }
// g_Mppt_Para.Charg_Current = get_capturedata(get_CHG_CURR);
// g_Mppt_Para.Discharg_Current = get_capturedata(get_DSG_CURR);
// g_Mppt_Para.Output_Voltage = get_capturedata(get_PV_VOLT_OUT);
// g_Mppt_Para.Battery_Voltage = g_Mppt_Para.Output_Voltage;
g_Mppt_Para.Charg_Current = get_CHG_CURR();
g_Mppt_Para.Discharg_Current = get_DSG_CURR();
g_Mppt_Para.Output_Voltage = get_PV_VOLT_OUT();
g_Mppt_Para.Input_Voltage = get_PV1_VOLT_IN();
// mppt_constantVoltage(18);
// return;
if (g_Mppt_Para.Discharg_Current == 0 && g_Mppt_Para.Charg_Current == 0) {
return;
}
// g_Mppt_Para.Battery_Voltage = g_Mppt_Para.Output_Voltage;
// static float_t Volt = 0.7;
// static float_t Curr = 5.5;
// static float_t loopImpedance;
// static uint8_t onlyone = 1;
// if (onlyone) {
// loopImpedance = (float_t)g_slConfigInfo.loopImpedance / 100;
// }
static float_t inBatteryCurr;
static float_t outBatteryCurr;
inBatteryCurr = g_Mppt_Para.Charg_Current - g_Mppt_Para.Discharg_Current;
outBatteryCurr = g_Mppt_Para.Discharg_Current - g_Mppt_Para.Charg_Current;
if (inBatteryCurr > 0.1) {
g_Mppt_Para.Battery_Voltage = g_Mppt_Para.Output_Voltage - inBatteryCurr * g_impedance;
} else {
g_Mppt_Para.Battery_Voltage = g_Mppt_Para.Output_Voltage;
}
if (g_batteryState == 0 && (inBatteryCurr > 0.1 || outBatteryCurr > 0.1) && g_Mppt_Para.Output_Voltage < 14.2) {
// printf("int g_batteryState : %d\n", g_batteryState);
g_batteryState = 1;
// TimeSliceOffset_Register(&m_impedanceCalculation, Task_impedanceCalculation
// , impedanceCalculation_reloadVal, impedanceCalculation_reloadVal);
}
// mppt_constantVoltage(18);
// if (g_Mppt_Para.MPPT_Mode == CONSTANTCURRENT
// || g_Mppt_Para.MPPT_Mode == CONSTANTVOLTAGE) {
//
// g_Mppt_Para.Battery_Voltage = get_capturedata(get_PV_VOLT_OUT)
// - g_impedance * (g_Mppt_Para.Charg_Current - g_Mppt_Para.Discharg_Current);
// } else {
// g_Mppt_Para.Battery_Voltage = get_capturedata(get_PV_VOLT_OUT);
// }
// voltOut = get_capturedata(get_PV_VOLT_OUT);
// g_Mppt_Para.Battery_Voltage = voltOut - g_impedance * (g_Mppt_Para.Charg_Current - g_Mppt_Para.Discharg_Current);
// ConstantVoltageCharge();
// return;
if (!overTemperature) {
MpptMode();
MpptContorl();
}
// mppt_constantVoltageO(12);
// static uint32_t run_num = 0;
// if (1000 < run_num++) {
// FloatingCharge();
// run_num = 1200;
// printf("in floatcharge \n");
// return;
// }
// mppt_readJust();
// mppt_constantCurrentO(1.2);
// int16_t var = 0;
// char buff[4];
// for (var = 0; var < 100; ++var) {
// sprintf(buff, "%3d:", var);
// uart_dev_write(g_gw485_uart4_handle, buff, sizeof(buff));
// uart_dev_write(g_gw485_uart4_handle, "1234567890\n", sizeof("1234567890\n"));
// Delay_Ms(1);
// }
// uart_dev_write(g_gw485_uart4_handle, "\n\n\n\n\n\n", sizeof("\n\n\n\n\n\n"));
}
#include "parameter.h"

12
App/src/parameter.c Normal file
View File

@ -0,0 +1,12 @@
/*
* parameter.c
*
* Created on: 20241012
* Author: psx
*/
#include "parameter.h"
Mppt_controlparameter g_controlParameter = {0};
Mppt_otherParameter g_otherParameter = {0};

View File

@ -13,858 +13,10 @@
#include <stdlib.h>
#include "task.h"
#include "tim.h"
#include "parameter.h"
default_Value defaultValue = {'S', 'L'\
, 0x11, 0x11, 0x11, 0x11, 0x11, 0x11, 0x11\
, POWERBOX\
, RS485
, 0x16};
SL_Mppt_para g_Mppt_Para = {0};
/* 静态函数申明 */
static void SL_MsgProcFunc_Read_Register(device_handle device, void *pMsg, uint32_t MsgLen);
static void SL_MsgProcFunc_Write_Register(device_handle device, void *pMsg, uint32_t MsgLen);
static void SL_MsgProcFunc_Broadcast_Scan(device_handle device, void *pMsg, uint32_t MsgLen);
static void SL_MsgProcFunc_Registration_request(device_handle device, void *pMsg, uint32_t MsgLen);
static void SL_MsgProcFunc_Update_Profile(device_handle device, void *pMsg, uint32_t MsgLen);
static void SL_MsgProcFunc_Remote_Upgrade(device_handle device, void *pMsg, uint32_t MsgLen);
//static uint16_t SL_ReadRegisterRegistrationStatus(void *pMsg);
//static uint16_t SL_ReadRegisteraddress(void *pMsg);
//static uint16_t SL_ReadRegisterAccessNodeType(void *pMsg);
//static uint16_t SL_ReadRegisterCommunicationMethods(void *pMsg);
static uint16_t SL_ReadRegisterBatteryVoltage(void *pMsg);
static uint16_t SL_ReadRegisterChargCurrent(void *pMsg);
static uint16_t SL_ReadRegisterDischargCurrent(void *pMsg);
static uint16_t SL_ReadRegisterSolarOpenCircuitVoltage(void *pMsg);
static uint16_t SL_ReadRegisterHighSideMosTemperature(void *pMsg);
static uint16_t SL_ReadRegisterDischargMosState(void *pMsg);
static uint16_t SL_ReadRegisterMPPTMode(void *pMsg);
//static uint16_t SL_WriteRegisterRegistrationStatus(void *pMsg);
//static uint16_t SL_WriteRegisteraddress(void *pMsg);
//static uint16_t SL_WriteRegisterAccessNodeType(void *pMsg);
//static uint16_t SL_WriteRegisterCommunicationMethods(void *pMsg);
//static uint16_t SL_WriteRegisterBatteryVoltage(void *pMsg);
//static uint16_t SL_WriteRegisterBatterytemperature(void *pMsg);
//static uint16_t SL_WriteRegisterRemainingBatteryBower(void *pMsg);
//static uint16_t SL_WriteRegisterSolarOpenCircuitVoltage1(void *pMsg);
//static uint16_t SL_WriteRegisterSolarOpenCircuitVoltage2(void *pMsg);
/* 读取串口数据时用该数组解析 */
static uint8_t rs485_buff[50]={0x00};
/* 一次最多读写的寄存器个数,由设备决定 */
#define Register_Number_Max 5
/* 寄存器个数,由设备决定 */
#define MPPT_Register_Number 5
/* 读写的寄存器的最大起始位置,由设备决定 */
#define Register_Start_Address_Max 0x0200
/* 用于解析串口包时的长度 */
#define analyzeStartFlag 2 //长度为2时解析起始标志
#define analyzeAddress 9 //长度为9时解析地址
#define analyzeFunctionCode 10 //长度为10时解析功能码
#define analyzeWritelen 14 //功能码为写入寄存器且buffer长度为14时可以解析出写入寄存器包的长度
/* 功能码处理表 */
SL_FuncionMsgProcTable g_MsgTbl[] =
{
{SL_Function_Code_Read_Register, SL_MsgProcFunc_Read_Register},
{SL_Function_Code_Write_Register, SL_MsgProcFunc_Write_Register},
{SL_Function_Code_Broadcast_Scan, SL_MsgProcFunc_Broadcast_Scan},
{SL_Function_Code_Registration_request, SL_MsgProcFunc_Registration_request},
{SL_Function_Code_Update_Profile, SL_MsgProcFunc_Update_Profile},
{SL_Function_Code_Remote_Upgrade, SL_MsgProcFunc_Remote_Upgrade},
};
/* 寄存器处理表 */
SL_RegProcTable g_RegTblR[] =
{
// {SL_Register_Registration_Status, SL_ReadRegisterRegistrationStatus},
// {SL_Register_address, SL_ReadRegisteraddress},
// {SL_Register_Access_Node_Type, SL_ReadRegisterAccessNodeType},
// {SL_Register_Communication_Methods, SL_ReadRegisterCommunicationMethods},
{SL_Register_Battery_Voltage, SL_ReadRegisterBatteryVoltage},
{SL_Register_Charg_Current, SL_ReadRegisterChargCurrent},
{SL_Register_Discharg_Current, SL_ReadRegisterDischargCurrent},
{SL_Register_Solar_Open_Circuit_Voltage, SL_ReadRegisterSolarOpenCircuitVoltage},
{SL_Register_HighSideMos_Temperature, SL_ReadRegisterHighSideMosTemperature},
{SL_Register_DischargMos_State, SL_ReadRegisterDischargMosState},
{SL_Register_MPPT_Mode, SL_ReadRegisterMPPTMode},
};
/* 寄存器处理表 */
SL_RegProcTable g_RegTblW[] =
{
// {SL_Register_Registration_Status, SL_WriteRegisterRegistrationStatus},
// {SL_Register_address, SL_WriteRegisteraddress},
// {SL_Register_Access_Node_Type, SL_WriteRegisterAccessNodeType},
// {SL_Register_Communication_Methods, SL_WriteRegisterCommunicationMethods},
// {SL_Register_Battery_Voltage, SL_WriteRegisterBatteryVoltage},
// {SL_Register_Battery_temperature, SL_WriteRegisterBatterytemperature},
// {SL_Register_Remaining_Battery_Bower, SL_WriteRegisterRemainingBatteryBower},
// {SL_Register_Solar_Open_Circuit_Voltage1, SL_WriteRegisterSolarOpenCircuitVoltage1},
// {SL_Register_Solar_Open_Circuit_Voltage2, SL_WriteRegisterSolarOpenCircuitVoltage2},
};
/**
* @brief
* @param
* @retval
*/
uint16_t CheckFunc(uint8_t *arr_buff, uint8_t len)
{
uint16_t crc = 0xFFFF;
uint16_t i, j;
for (j = 0; j < len; ++j) {
crc = crc ^ (*arr_buff++);
for (i = 0; i < 8; ++i) {
if ((crc&0x0001) > 0) {
crc = crc >> 1;
crc = crc ^ 0xa001;
}
else {
crc = crc >> 1;
}
}
}
return crc;
}
/**
* @brief ,100-2500ms10ms  
* @param
* @retval
*/
int randomDelay()
{
int minSeconds = 10;
int maxSeconds = 250;
// srand(SystemCoreClock);//time(NULL)替换为对应操作系统时钟
srand(TIM_GetCounter(TIM4));
int delaySeconds = minSeconds + rand() % (maxSeconds - minSeconds + 1);
return delaySeconds * 10;
}
/**
* @brief 485线
* @param
* @retval 1
* 0
*/
uint8_t Check_485_bus_busy(device_handle device)
{
if (device == g_bat485_uart3_handle) {
USART_ITConfig(USART3, USART_IT_RXNE, ENABLE);
} else {
USART_ITConfig(USART4, USART_IT_RXNE, ENABLE);
}
uint16_t num_ago = ring_queue_length(device);
Delay_Ms(2);
uint16_t num_now = ring_queue_length(device);
if (device == g_bat485_uart3_handle) {
USART_ITConfig(USART3, USART_IT_RXNE, DISABLE);
} else {
USART_ITConfig(USART4, USART_IT_RXNE, DISABLE);
}
if (num_now == num_ago) {
return 0;
}
return 1;
}
/**
* @brief
* @param
* @retval
*/
void SL_MsgProcFunc_Read_Register(device_handle device, void *pMsg, uint32_t MsgLen)
{
SL_Mppt_Rorecv_pack *rpack = (SL_Mppt_Rorecv_pack *)pMsg;
uint16_t Register_Number_16 = chang_8_to_16(rpack->read_Register_Number_L,rpack->read_Register_Number_H);
if (Register_Number_16 > Register_Number_Max) {
log_error(" Register_Number error:%x \r\n", Register_Number_16);
return;
}
uint16_t Start_Address_16 = chang_8_to_16(rpack->read_Register_Start_Address_L,rpack->read_Register_Start_Address_H);
if (Start_Address_16 > Register_Start_Address_Max) {
log_error(" Register_Start_Address error : %x \r\n", Start_Address_16);
return;
}
/* 读取寄存器数据 */
// uint8_t reply_Data_Content[2 * 5] = {0};
uint16_t reply_Data_Content[Register_Number_Max] = {0};
for ( uint16_t pos = 0; pos < Register_Number_16; pos++) {
for (uint16_t var = 0; var < sizeof(g_RegTblR) / sizeof(SL_RegProcTable); var++) {
if (g_RegTblR[var].regId == (Start_Address_16 + pos)) {
// *(uint16_t *)&reply_Data_Content[pos * 2] = g_RegTblR[var].pRegProc(NULL);
reply_Data_Content[pos] = g_RegTblR[var].pRegProc(NULL);
}
}
}
/* 打包 */
memset(rs485_buff, 0, sizeof(rs485_buff));
uint8_t *replay_pack = rs485_buff;
// strlcpy(replay_pack, g_slConfigInfo.start_Flag, 2);
*(replay_pack) = g_slConfigInfo.start_Flag[0];
*(replay_pack + 1) = g_slConfigInfo.start_Flag[1];
replay_pack += 2;
// strlcpy(replay_pack, g_slConfigInfo.address, 7);
*(replay_pack) = g_slConfigInfo.address[0];
*(replay_pack + 1) = g_slConfigInfo.address[1];
*(replay_pack + 2) = g_slConfigInfo.address[2];
*(replay_pack + 3) = g_slConfigInfo.address[3];
*(replay_pack + 4) = g_slConfigInfo.address[4];
*(replay_pack + 5) = g_slConfigInfo.address[5];
*(replay_pack + 6) = g_slConfigInfo.address[6];
replay_pack += 7;
*replay_pack = SL_Function_Code_Read_Register;
replay_pack += 1;
// *(uint16_t *)&replay_pack = rpack->read_Register_Number;
*replay_pack = (Register_Number_16 >> 8);
*(replay_pack + 1) = (Register_Number_16);
replay_pack += 2;
for (uint8_t var = 0; var < Register_Number_16 * 2; var++) {
if (0 == (var & 0x01)) {
*(replay_pack + var) = (reply_Data_Content[var / 2] >> 8);
} else {
*(replay_pack + var) = (reply_Data_Content[var / 2]);
}
}
replay_pack += Register_Number_16 * 2;
uint16_t crc_temp = CheckFunc(rs485_buff, (2 + 7 + 1 + 2 + Register_Number_16 * 2));
// log_info("CheckFunc crc_temp: %x \r\n", crc_temp);
*replay_pack = (uint8_t)(crc_temp >> 8);
replay_pack += 1;
*replay_pack = (uint8_t)crc_temp;
replay_pack += 1;
*replay_pack = g_slConfigInfo.end_Flag;
while (1) {
Delay_Ms(randomDelay());
if (!Check_485_bus_busy(device)) {
// log_info("pack : %s", (uint8_t *)&replay_pack);
// uart_dev_write(device, (uint8_t *)&replay_pack, 16 + Register_Number_16 * 2 + 1);
uart_dev_write(device, rs485_buff, 16 + Register_Number_16 * 2);
if (device == g_bat485_uart3_handle) {
USART_ITConfig(USART3, USART_IT_RXNE, ENABLE);
} else {
USART_ITConfig(USART4, USART_IT_RXNE, ENABLE);
}
break;
}
}
}
void SL_MsgProcFunc_Write_Register(device_handle device, void *pMsg, uint32_t MsgLen)
{
SL_Mppt_Worecv_pack *wpack = (SL_Mppt_Worecv_pack *)pMsg;
uint8_t *buff = (uint8_t *)pMsg;
uint16_t Register_Number = \
chang_8_to_16(wpack->write_Register_Number_L, wpack->write_Register_Number_H);
if (Register_Number > Register_Number_Max) {
log_error(" Register_Number error:%x \r\n", Register_Number);
return;
}
uint16_t Register_Start_Address = \
chang_8_to_16(wpack->write_Register_Start_Address_L, wpack->write_Register_Start_Address_H);
if (Register_Start_Address > Register_Start_Address_Max) {
log_error(" Register_Start_Address error : %x \r\n", Register_Start_Address);
return;
}
printf("in write register \n");
uint16_t content[Register_Number_Max] = {0};
for (uint16_t var = 0; var < Register_Number; var++) {
content[var] = buff[14 + 2 * var] << 8 | buff[14 + 2 * var + 1];
}
for ( uint16_t pos = 0; pos < Register_Number; pos++) {
for (uint16_t i = 0; i < sizeof(g_RegTblW) / sizeof(SL_RegProcTable); i++) {
if (g_RegTblW[i].regId == (Register_Start_Address + pos)) {
g_RegTblW[i].pRegProc(&content[pos]);
}
}
}
}
void SL_MsgProcFunc_Broadcast_Scan(device_handle device, void *pMsg, uint32_t MsgLen)
{
g_recvBroadcastDevice = device;
g_recvBroadcastRegisterNumber = MPPT_Register_Number;
RegistrationRequestFlag = 1;
/* 任务创立后,立即执行一次 */
TimeSliceOffset_Register(&m_recvbroadcast, Task_recvbroadcast \
, recvbroadcast_reloadVal, recvbroadcast_offset);
m_recvbroadcast.runFlag = 1;
}
void SL_MsgProcFunc_Registration_request(device_handle device, void *pMsg, uint32_t MsgLen)
{
log_info("Registration success \r\n");
recvbroadcast_flag = 1;
RegistrationRequestFlag = 0;
TimeSliceOffset_Unregister(&m_recvbroadcast);
m_recvbroadcast.runFlag = 0;
SL_Mppt_RegistrationReply_pack *rpack = (SL_Mppt_RegistrationReply_pack *)pMsg;
g_Mppt_Para.Registration_Status = chang_8_to_16(rpack->registration_Status_L, rpack->registration_Status_H);
/* 20s内不再接收广播帧 */
TimeSliceOffset_Register(&m_sensorEnableBroadcast, Task_sensorEnableBroadcast
, sensorEnableBroadcast_reloadVal, sensorEnableBroadcast_offset);
}
void SL_MsgProcFunc_Update_Profile(device_handle device, void *pMsg, uint32_t MsgLen)
{
SL_Mppt_SOther_pack SUpdateProfile_pack = {0};
SUpdateProfile_pack.start_Flag[0] = g_slConfigInfo.start_Flag[0];
SUpdateProfile_pack.start_Flag[1] = g_slConfigInfo.start_Flag[1];
SUpdateProfile_pack.address[0] = g_slConfigInfo.address[0];
SUpdateProfile_pack.address[1] = g_slConfigInfo.address[1];
SUpdateProfile_pack.address[2] = g_slConfigInfo.address[2];
SUpdateProfile_pack.address[3] = g_slConfigInfo.address[3];
SUpdateProfile_pack.address[4] = g_slConfigInfo.address[4];
SUpdateProfile_pack.address[5] = g_slConfigInfo.address[5];
SUpdateProfile_pack.address[6] = g_slConfigInfo.address[6];
SUpdateProfile_pack.function_Code = SL_Function_Code_Update_Profile;
SUpdateProfile_pack.state = 0x01;
uint16_t crc = CheckFunc((uint8_t *)&SUpdateProfile_pack, SL_MPPT_SOTHER_PACK_SIZE - 3);
SUpdateProfile_pack.check_Bit_H = crc >> 8;
SUpdateProfile_pack.check_Bit_L = crc;
SUpdateProfile_pack.end_Flag = g_slConfigInfo.end_Flag;
while (1) {
Delay_Ms(randomDelay());
if (!Check_485_bus_busy(device)) {
uart_dev_write(device, (uint8_t *)&SUpdateProfile_pack, SL_MPPT_SOTHER_PACK_SIZE + 1);
if (device == g_bat485_uart3_handle) {
USART_ITConfig(USART3, USART_IT_RXNE, ENABLE);
} else {
USART_ITConfig(USART4, USART_IT_RXNE, ENABLE);
}
break;
}
}
}
void SL_MsgProcFunc_Remote_Upgrade(device_handle device, void *pMsg, uint32_t MsgLen)
{
SL_Mppt_SOther_pack SUpdateProfile_pack = {0};
SUpdateProfile_pack.start_Flag[0] = g_slConfigInfo.start_Flag[0];
SUpdateProfile_pack.start_Flag[1] = g_slConfigInfo.start_Flag[1];
SUpdateProfile_pack.address[0] = g_slConfigInfo.address[0];
SUpdateProfile_pack.address[1] = g_slConfigInfo.address[1];
SUpdateProfile_pack.address[2] = g_slConfigInfo.address[2];
SUpdateProfile_pack.address[3] = g_slConfigInfo.address[3];
SUpdateProfile_pack.address[4] = g_slConfigInfo.address[4];
SUpdateProfile_pack.address[5] = g_slConfigInfo.address[5];
SUpdateProfile_pack.address[6] = g_slConfigInfo.address[6];
SUpdateProfile_pack.function_Code = SL_Function_Code_Remote_Upgrade;
SUpdateProfile_pack.state = 0x01;
uint16_t crc = CheckFunc((uint8_t *)&SUpdateProfile_pack, SL_MPPT_SOTHER_PACK_SIZE - 3);
SUpdateProfile_pack.check_Bit_H = crc >> 8;
SUpdateProfile_pack.check_Bit_L = crc;
SUpdateProfile_pack.end_Flag = g_slConfigInfo.end_Flag;
while (1) {
Delay_Ms(randomDelay());
if (!Check_485_bus_busy(device)) {
uart_dev_write(device, (uint8_t *)&SUpdateProfile_pack, SL_MPPT_SOTHER_PACK_SIZE + 1);
if (device == g_bat485_uart3_handle) {
USART_ITConfig(USART3, USART_IT_RXNE, ENABLE);
} else {
USART_ITConfig(USART4, USART_IT_RXNE, ENABLE);
}
break;
}
}
}
///**
// * @brief 读取注册状态寄存器
// * @param
// * @retval
// */
//uint16_t SL_ReadRegisterRegistrationStatus(void *pMsg)
//{
// log_info(" SL_ReadRegisterRegistrationStatus ");
// uint16_t value = g_Mppt_Para.Registration_Status;
// return value;
//}
//
///**
// * @brief 读取地址寄存器
// * @param
// * @retval
// */
//uint16_t SL_ReadRegisteraddress(void *pMsg)
//{
// log_info(" SL_ReadRegisteraddress ");
//
// return 0;
//}
//
///**
// * @brief 读取接入节点类型寄存器
// * @param
// * @retval
// */
//uint16_t SL_ReadRegisterAccessNodeType(void *pMsg)
//{
// log_info(" SL_ReadRegisterAccessNodeType ");
// uint16_t value = g_Mppt_Para.Access_Node_Type;
// return value;
//}
//
///**
// * @brief 读取通信方式寄存器
// * @param
// * @retval
// */
//uint16_t SL_ReadRegisterCommunicationMethods(void *pMsg)
//{
// log_info(" SL_ReadRegisterCommunicationMethods ");
// uint16_t value = g_Mppt_Para.Communication_Methods;
// return value;
//}
/**
* @brief
* @param
* @retval
*/
uint16_t SL_ReadRegisterBatteryVoltage(void *pMsg)
{
log_info(" SL_ReadRegisterBatteryVoltage ");
uint16_t value = (uint16_t)(g_Mppt_Para.Battery_Voltage * 10);
return value;
}
/**
* @brief
* @param
* @retval
*/
uint16_t SL_ReadRegisterChargCurrent(void *pMsg)
{
log_info(" SL_ReadRegisterChargCurrent ");
uint16_t value = (uint16_t)(g_Mppt_Para.Charg_Current * 10);
return value;
}
/**
* @brief
* @param
* @retval
*/
uint16_t SL_ReadRegisterDischargCurrent(void *pMsg)
{
log_info(" SL_ReadRegisterDischargCurrent ");
uint16_t value = (uint16_t)(g_Mppt_Para.Discharg_Current * 10);
return value;
}
/**
* @brief
* @param
* @retval
*/
uint16_t SL_ReadRegisterSolarOpenCircuitVoltage(void *pMsg)
{
log_info(" SL_ReadRegisterSolarOpenCircuitVoltage ");
uint16_t value = (uint16_t)(g_Mppt_Para.Solar_Open_Circuit_Voltage * 10);
return value;
}
/**
* @brief mos管的温度寄存器
* @param
* @retval
*/
uint16_t SL_ReadRegisterHighSideMosTemperature(void *pMsg)
{
log_info(" SL_ReadRegisterHighSideMosTemperature ");
uint16_t value = (uint16_t)(g_Mppt_Para.HighSideMos_Temperature * 10);
return value;
}
/**
* @brief mos管状态寄存器
* @param
* @retval
*/
uint16_t SL_ReadRegisterDischargMosState(void *pMsg)
{
log_info(" SL_ReadRegisterDischargMosState ");
uint16_t value = (uint16_t)g_Mppt_Para.DischargMos_State;
return value;
}
/**
* @brief mppt工作模式寄存器
* @param
* @retval
*/
uint16_t SL_ReadRegisterMPPTMode(void *pMsg)
{
log_info(" SL_ReadRegisterMPPTMode ");
uint16_t value = (uint16_t)g_Mppt_Para.MPPT_Mode;
return value;
}
///**
// * @brief 写入注册状态寄存器
// * @param
// * @retval
// */
//uint16_t SL_WriteRegisterRegistrationStatus(void *pMsg)
//{
// log_info(" WriteRegisterRegistrationStatus %x", *(uint16_t *)pMsg);
//
// return 0;
//}
//
///**
// * @brief 写入地址寄存器
// * @param
// * @retval
// */
//uint16_t SL_WriteRegisteraddress(void *pMsg)
//{
// log_info(" WriteRegisteraddress %x", *(uint16_t *)pMsg);
//
// return 0;
//}
//
///**
// * @brief 写入接入节点类型寄存器
// * @param
// * @retval
// */
//uint16_t SL_WriteRegisterAccessNodeType(void *pMsg)
//{
// log_info(" WriteRegisterAccessNodeType %x", *(uint16_t *)pMsg);
//
// return 0;
//}
//
///**
// * @brief 写入通信方式寄存器
// * @param
// * @retval
// */
//uint16_t SL_WriteRegisterCommunicationMethods(void *pMsg)
//{
// log_info(" WriteRegisterCommunicationMethods %x", *(uint16_t *)pMsg);
//
// return 0;
//}
/**
* @brief "SL"
* @param start_buff
* @retval 1
* 0
*/
static int Match_Startflag(uint8_t start_buff[2])
{
// if (!strcmp(start_buff, g_slConfigInfo.start_Flag)) {
// log_info("Match_Startflag fail \r\n");
// return 1;
// }
if ((start_buff[0] == g_slConfigInfo.start_Flag[0]) && \
(start_buff[1] == g_slConfigInfo.start_Flag[1])) {
log_info("Match_Startflag success \r\n");
return 1;
}
return 0;
}
/**
* @brief
* @param address
* @retval 1
* 0
*/
static int Match_address(u_int8_t address[7])
{
// if (!strcmp(address, g_slConfigInfo.address)) {
// log_info("Match_address fail \r\n");
// return 1;
// }
if ((address[0] == g_slConfigInfo.address[0]) && \
(address[1] == g_slConfigInfo.address[1]) && \
(address[2] == g_slConfigInfo.address[2]) && \
(address[3] == g_slConfigInfo.address[3]) && \
(address[4] == g_slConfigInfo.address[4]) && \
(address[5] == g_slConfigInfo.address[5]) && \
(address[6] == g_slConfigInfo.address[6])) {
log_info("Match_address success \r\n");
return 1;
}
return 0;
}
/**
* @brief 广
* @param address
* @retval 1
* 0
*/
static int Match_Broadcastaddress(u_int8_t address[7])
{
if (address[0] == 0xFF && \
address[1] == 0xFF && \
address[2] == 0xFF && \
address[3] == 0xFF && \
address[4] == 0xFF && \
address[5] == 0xFF && \
address[6] == 0xFF) {
log_info("Match_Broadcastaddress success\r\n");
return 1;
}
return 0;
}
/**
* @brief
* @param uart_handle
* @param buff
* @param buff_size
* @retval
*/
static int uart_read_climate_pack(device_handle uart_handle,uint8_t *buff, uint32_t buff_size)
{
uint32_t offset = 0;
uint32_t len = 0;
uint8_t flag_run = 0;
char c = 0;
SL_Mppt_Recv_pack *pack = (SL_Mppt_Recv_pack *)buff;
buff_size--; //预留一个'\0'位置
for (; offset < buff_size;){
if (ring_queue_length(uart_handle) == 0) {
break;
}
c = uart_dev_in_char(uart_handle);
buff[offset++] = c;
/* 匹配起始标志位 */
if (offset == analyzeStartFlag || (flag_run > 0)) {
if (!Match_Startflag(pack->start_Flag)) {
memcpy(buff, buff+1, offset-1);
offset--;
continue;
}
}
/* 匹配地址 */
if (offset == analyzeAddress || (flag_run > 1)) {
if (!((((g_Mppt_Para.Registration_Status == 2) || RegistrationRequestFlag) && Match_address(pack->address))
|| (run_Broadcast && Match_Broadcastaddress(pack->address)))) {
if (flag_run < 1) {
flag_run = 1;
}
memcpy(buff, buff+1, offset-1);
offset--;
continue;
}
}
/* 匹配功能码 */
if (offset == analyzeFunctionCode || (flag_run > 2)) {
/* 未注册时,不处理读写和其他帧 */
if (g_Mppt_Para.Registration_Status == 2) {
/* 读寄存器数据 */
if (pack->function_Code == SL_Function_Code_Read_Register) {
log_info("Read_Register\r\n");
len = SL_MPPT_RORECV_PACK_SIZE;
}
/* 写寄存器数据 */
else if (pack->function_Code == SL_Function_Code_Write_Register) {
log_info("Write_Register\r\n");
}
/* 其他帧格式 */
else if (pack->function_Code == SL_Function_Code_Update_Profile
|| pack->function_Code == SL_Function_Code_Remote_Upgrade) {
len = SL_MPPT_ROTHER_PACK_SIZE;
log_info("Other frames\r\n");
}
else if (run_Broadcast) {
/* 广播扫描 */
if (pack->function_Code == SL_Function_Code_Broadcast_Scan) {
log_info("Broadcast_Scan\r\n");
len = SL_MPPT_SCAN_BROADCAST_PACK_SIZE;
}
/* 注册请求 */
else if (pack->function_Code == SL_Function_Code_Registration_request) {
log_info("Registration_request\r\n");
len = SL_MPPT_REGISTRATIONREPLY_PACK_SIZE;
}
else {
if (flag_run < 2) {
flag_run = 2;
}
log_info("funcode error %x\r\n", pack->function_Code);
memcpy(buff, buff+1, offset-1);
offset--;
continue;
}
}
else {
if (flag_run < 2) {
flag_run = 2;
}
log_info("funcode error %x\r\n", pack->function_Code);
memcpy(buff, buff+1, offset-1);
offset--;
continue;
}
}
/* 广播扫描 */
else if (pack->function_Code == SL_Function_Code_Broadcast_Scan) {
log_info("Broadcast_Scan\r\n");
len = SL_MPPT_SCAN_BROADCAST_PACK_SIZE;
}
/* 注册请求 */
else if (pack->function_Code == SL_Function_Code_Registration_request) {
log_info("Registration_request\r\n");
len = SL_MPPT_REGISTRATIONREPLY_PACK_SIZE;
}
else {
if (flag_run < 2) {
flag_run = 2;
}
log_info("funcode error %x\r\n", pack->function_Code);
memcpy(buff, buff+1, offset-1);
offset--;
continue;
}
}
if ((pack->function_Code == SL_Function_Code_Write_Register) && (offset >= 14)) {
SL_Mppt_Worecv_pack *wpack = (SL_Mppt_Worecv_pack *)buff;
uint8_t Register_Number = (wpack->write_Register_Number_H << 8) | wpack->write_Register_Number_L;
len = Register_Number * 2 + SL_MPPT_WORECV_PACK_SIZE - 4;
continue;
}
if (offset == len) {
uint16_t crc_16 = chang_8_to_16(buff[offset - 2], buff[offset - 3]);
if ((CheckFunc(buff, offset - 3) != crc_16) || (buff[offset - 1] != 0x16)) {
if (flag_run < 3) {
flag_run = 3;
}
memcpy(buff, buff+1, offset-1);
offset--;
} else {
return offset;
}
}
}
return 0;
}
/**
* @brief
* @param
* @retval
*/
static void FRT_MsgHandler(device_handle device, uint8_t *pMsg, uint32_t MsgLen)
{
SL_Mppt_Recv_pack *pack = (SL_Mppt_Recv_pack *)pMsg;
for (u_int16_t i = 0; i < sizeof(g_MsgTbl) / sizeof(SL_FuncionMsgProcTable); i++){
if (pack->function_Code == g_MsgTbl[i].msgId){
g_MsgTbl[i].pMsgProc(device, pMsg, MsgLen);
}
}
}
/**
* @brief
* @param
* @retval
*/
void read_and_process_uart_data(device_handle device)
{
// printf("ring_queue_length = %d \n", ring_queue_length(device));
// if (ring_queue_length(device) > 10) {uart_dev_char_present(device_handle device)
if (uart_dev_char_present(device)) {
Delay_Ms(20);
// printf("ring_queue_length = %d \n", ring_queue_length(device));
memset(rs485_buff, 0, sizeof(rs485_buff));
int ret = uart_read_climate_pack(device, rs485_buff, sizeof(rs485_buff));
if(ret > 0){
FRT_MsgHandler(device, rs485_buff, ret);
}
}
}

View File

@ -22,811 +22,6 @@
#include "inflash.h"
#include <stdlib.h>
#include "collect_Conversion.h"
#include "parameter.h"
//uint8_t g_interruptNum = 0; /* 每次关闭或重新开启定时器3时先清零该引脚 */
void stop_mpptWork(void)
{
// GPIO_WriteBit(EnPowerSupply_GPIO, EnPowerSupply_PIN, SET);
g_duty_ratio = 0.7;
TIM_Cmd(TIM3, DISABLE);
// g_interruptNum = 0;
TIM_SetCompare4(TIM4, 0);
// TimeSliceOffset_Register(&m_startMpptControl, Task_startMpptControl
// , startMpptControl_reloadVal, startMpptControl_offset);
// GPIO_WriteBit(POW_OUT_CON_GPIO, POW_OUT_CON_PIN, RESET);
}
void start_mpptWork(void)
{
// GPIO_WriteBit(EnPowerSupply_GPIO, EnPowerSupply_PIN, RESET);
// g_interruptNum = 0;
TIM_Cmd(TIM3, ENABLE);
// TIM3->CNT = 0;
g_Mppt_Para.MPPT_Mode = CONSTANTCURRENT;
// TimeSliceOffset_Unregister(&m_startMpptControl);
// Delay_Ms(500);
// GPIO_WriteBit(POW_OUT_CON_GPIO, POW_OUT_CON_PIN, SET);
}
/**
* @brief
* @param
* @retval
*/
STR_TimeSliceOffset m_runled;
void Task_RunLED(void)
{
// uart_sendstr(g_gw485_uart4_handle, "\n\n\n\n\n");
// uart_sendstr(g_gw485_uart4_handle, "is gw485\n");
// uart_sendstr(g_bat485_uart3_handle, "is bat485\n");get_PV1_VOLT_IN();
// printf(" \n");
// printf(" duty_ratio : %d/1000 \n", (int)(g_duty_ratio * 1000));
//
// printf(" vout : %d/100 \n", (int)(g_Mppt_Para.Battery_Voltage * 100));
// printf(" Iout : %d/100 \n", (int)(g_Mppt_Para.Charg_Current * 100));
// printf(" Idisout : %d/100 \n", (int)(g_Mppt_Para.Discharg_Current * 100));
// printf(" mosT : %d/10 \n", (int)(g_Mppt_Para.HighSideMos_Temperature * 10));
// printf(" mosState : %d \n", (int)(g_Mppt_Para.DischargMos_State));
//// printf(" mosState : %d \n", GPIO_ReadOutputDataBit(POW_OUT_CON_GPIO, POW_OUT_CON_PIN));
//// printf(" mosState : %d \n", GPIO_ReadInputDataBit(DSG_PROT_GPIO, DSG_PROT_PIN));
//
// printf(" 0.没有工作; 1.涓流模式; 2.恒流模式; 3.恒压模式; 4.浮充模式; 5.没有电池 : %d \n", g_Mppt_Para.MPPT_Mode);
//
// printf(" \n");
// uart_sendstr(g_bat485_uart3_handle, " \n");
uart_dev_write(g_bat485_uart3_handle, " \n", sizeof(" \n"));
char buffer[80];
memset(buffer, 0, sizeof(buffer));
sprintf(buffer, " duty_ratio : %d/1000 \n", (int)(g_duty_ratio * 1000));
uart_dev_write(g_bat485_uart3_handle, buffer, sizeof(buffer));
memset(buffer, 0, sizeof(buffer));
sprintf(buffer, " Input_Voltage : %d/100 \n", (int)(g_Mppt_Para.Input_Voltage * 100));
uart_dev_write(g_bat485_uart3_handle, buffer, sizeof(buffer));
memset(buffer, 0, sizeof(buffer));
sprintf(buffer, " vout : %d/100 \n", (int)(g_Mppt_Para.Output_Voltage * 100));
uart_dev_write(g_bat485_uart3_handle, buffer, sizeof(buffer));
memset(buffer, 0, sizeof(buffer));
sprintf(buffer, " vBattery : %d/100 \n", (int)(g_Mppt_Para.Battery_Voltage * 100));
uart_dev_write(g_bat485_uart3_handle, buffer, sizeof(buffer));
memset(buffer, 0, sizeof(buffer));
sprintf(buffer, " Iout : %d/100 \n", (int)(g_Mppt_Para.Charg_Current * 100));
uart_dev_write(g_bat485_uart3_handle, buffer, sizeof(buffer));
memset(buffer, 0, sizeof(buffer));
sprintf(buffer, " Idisout : %d/100 \n", (int)(g_Mppt_Para.Discharg_Current * 100));
uart_dev_write(g_bat485_uart3_handle, buffer, sizeof(buffer));
memset(buffer, 0, sizeof(buffer));
sprintf(buffer, " mosT : %d/10 \n", (int)(g_Mppt_Para.HighSideMos_Temperature * 10));
uart_dev_write(g_bat485_uart3_handle, buffer, sizeof(buffer));
memset(buffer, 0, sizeof(buffer));
sprintf(buffer, " impedance : %d/1000 \n", (int)(g_impedance * 1000));
uart_dev_write(g_bat485_uart3_handle, buffer, sizeof(buffer));
memset(buffer, 0, sizeof(buffer));
sprintf(buffer, " g_impedanceStart : %d \n", g_impedanceStart);
uart_dev_write(g_bat485_uart3_handle, buffer, sizeof(buffer));
memset(buffer, 0, sizeof(buffer));
sprintf(buffer, " mosState : %d \n", (int)(g_Mppt_Para.DischargMos_State));
uart_dev_write(g_bat485_uart3_handle, buffer, sizeof(buffer));
memset(buffer, 0, sizeof(buffer));
sprintf(buffer, " batteryState : %d \n", g_batteryState);
uart_dev_write(g_bat485_uart3_handle, buffer, sizeof(buffer));
memset(buffer, 0, sizeof(buffer));
sprintf(buffer, " outputAgainFlag : %d \n", outputAgainFlag);
uart_dev_write(g_bat485_uart3_handle, buffer, sizeof(buffer));
memset(buffer, 0, sizeof(buffer));
sprintf(buffer, " excessiveLoadFlag : %d \n", excessiveLoadFlag);
uart_dev_write(g_bat485_uart3_handle, buffer, sizeof(buffer));
memset(buffer, 0, sizeof(buffer));
sprintf(buffer, " 0.没有工作; 1.涓流模式; 2.恒流模式; 3.恒压模式; 4.浮充模式; 5.没有电池 : %d \n", g_Mppt_Para.MPPT_Mode);
uart_dev_write(g_bat485_uart3_handle, buffer, sizeof(buffer));
uart_dev_write(g_bat485_uart3_handle, " \n", sizeof(" \n"));
// printf("vout : %d/100 \n", (int)(get_capturedata(get_PV_VOLT_OUT) * 100));
// get_CHG_CURR();
static uint8_t flag = RESET;
flag = !flag;
GPIO_WriteBit(RUN_LED_GPIO, RUN_LED_PIN, flag);
static uint8_t num = 0;
if (10 == ++num) {
GPIO_WriteBit(POW_OUT_CON_GPIO, POW_OUT_CON_PIN, SET);
}
return;
}
/**
* @brief mppt控制
* @param
* @retval
*/
STR_TimeSliceOffset m_startMpptControl;
void Task_startMpptControl(void)
{
static uint16_t checkSolarOpenCircuitVTimeFlag;
static uint8_t only_once = 1;
if (only_once) {
only_once = 0;
checkSolarOpenCircuitVTimeFlag = g_slConfigInfo.checkSolarOpenCircuitVTime - 3;
}
if (g_slConfigInfo.checkSolarOpenCircuitVTime == ++checkSolarOpenCircuitVTimeFlag) {
checkSolarOpenCircuitVTimeFlag = 0;
g_Mppt_Para.Solar_Open_Circuit_Voltage = get_PV1_VOLT_IN();
// printf("volt in : %d/100 \n", (int)(g_Mppt_Para.Solar_Open_Circuit_Voltage * 100));
// char buff[50];
// memset(buff, 0, sizeof(buff));
// sprintf(buff, "volt in : %d/100 \n", (int)(g_Mppt_Para.Solar_Open_Circuit_Voltage * 100));
// uart_dev_write(g_bat485_uart3_handle, buff, sizeof(buff));
if (g_Mppt_Para.Solar_Open_Circuit_Voltage
> ((float_t)g_slConfigInfo.startSolarOpenCircuitV / 100)) {
TimeSliceOffset_Unregister(&m_startMpptControl);
m_startMpptControl.runFlag = 0;
// printf("1\n");
// start_mpptWork();
if (g_Mppt_Para.Output_Voltage > 11) {
g_batteryState = 1;
} else {
g_batteryState = 0;
}
TimeSliceOffset_Register(&m_softStart, Task_softStart, softStart_reloadVal, softStart_offset);
}
}
return;
}
/**
* @brief
* @param
* @retval
*/
STR_TimeSliceOffset m_softStart;
void Task_softStart(void)
{
static uint16_t num = 0;
static float_t dutyRatio = 0;
num++;
// if (num == 1) {
// GPIO_WriteBit(EnPowerSupply_GPIO, EnPowerSupply_PIN, RESET);
// }
if (num < 5) {
TIM_SetCompare4(TIM4, 100);
}
else if (num > 70 || dutyRatio > g_duty_ratio) {
TimeSliceOffset_Unregister(&m_softStart);
m_softStart.runFlag = 0;
dutyRatio = 0;
num = 0;
Set_duty_ratio(&g_duty_ratio);
if (g_batteryState == 1) {
start_mpptWork();
// GPIO_WriteBit(POW_OUT_CON_GPIO, POW_OUT_CON_PIN, SET);
// TimeSliceOffset_Register(&m_impedanceCalculation, Task_impedanceCalculation
// , impedanceCalculation_reloadVal, impedanceCalculation_reloadVal);
return;
} else {
dutyRatio = 0;
num = 0;
Set_duty_ratio(&g_duty_ratio);
// TimeSliceOffset_Unregister(&m_softStart);
// m_softStart.runFlag = 0;
//软起动后bms保护板开启电池充电
if (get_CHG_CURR() - get_DSG_CURR() > 0.1
|| get_DSG_CURR() - get_CHG_CURR() > 0.1) {
// printf("111\n");
// TimeSliceOffset_Register(&m_impedanceCalculation, Task_impedanceCalculation
// , impedanceCalculation_reloadVal, impedanceCalculation_reloadVal);
start_mpptWork();
// GPIO_WriteBit(POW_OUT_CON_GPIO, POW_OUT_CON_PIN, SET);
return;
}
g_Mppt_Para.MPPT_Mode = FLOAT;
TIM_Cmd(TIM3, ENABLE);
// GPIO_WriteBit(POW_OUT_CON_GPIO, POW_OUT_CON_PIN, SET);
return;
}
}
else {
dutyRatio += 0.01;
Set_duty_ratio(&dutyRatio);
}
}
/**
* @brief
* @param
* @retval
*/
STR_TimeSliceOffset m_usart;
uint8_t RegistrationRequestFlag = 0;
void Task_usart(void)
{
read_and_process_uart_data(g_gw485_uart4_handle);
// read_and_process_uart_data(g_bat485_uart3_handle);
// uart_dev_write(g_bat485_uart3_handle, "hello world \n", sizeof("hello world \n"));
return;
}
/**
* @brief
* @param
* @retval
*/
STR_TimeSliceOffset m_wdi;
void Task_wdi(void)
{
static uint32_t temp = 0;
if (wdi_RESET == temp++) {
temp = 0;
NVIC_SystemReset();
}
GPIO_WriteBit(WDI_INPUT_GPIO, WDI_INPUT_PIN, SET);
GPIO_WriteBit(WDI_INPUT_GPIO, WDI_INPUT_PIN, RESET);
return;
}
/**
* @brief ,mos管温度
* @param
* @retval
*/
STR_TimeSliceOffset m_refreshRegister;
uint8_t overTemperature = 0;
void Task_refreshRegister(void)
{
static uint16_t checkRegisterRefreshTimeFlag;
if (g_slConfigInfo.registerRefreshTime == ++checkRegisterRefreshTimeFlag) {
checkRegisterRefreshTimeFlag = 0;
// g_Mppt_Para.Battery_Voltage = get_capturedata(get_PV_VOLT_OUT);
// g_Mppt_Para.Charg_Current = get_capturedata(get_CHG_CURR);
// g_Mppt_Para.Discharg_Current = get_capturedata(get_DSG_CURR);
// g_Mppt_Para.HighSideMos_Temperature = get_capturedata(get_MOSFET_Temper);
// g_Mppt_Para.Battery_Voltage = get_PV_VOLT_OUT();
g_Mppt_Para.Output_Voltage = get_PV_VOLT_OUT();
g_Mppt_Para.Charg_Current = get_CHG_CURR();
g_Mppt_Para.Discharg_Current = get_DSG_CURR();
g_Mppt_Para.HighSideMos_Temperature = get_MOSFET_Temper();
g_Mppt_Para.DischargMos_State = GPIO_ReadOutputDataBit(POW_OUT_CON_GPIO, POW_OUT_CON_PIN)
&& GPIO_ReadInputDataBit(DSG_PROT_GPIO, DSG_PROT_PIN);
if (g_Mppt_Para.Charg_Current - g_Mppt_Para.Discharg_Current < -0.1) {
g_Mppt_Para.Battery_Voltage = g_Mppt_Para.Output_Voltage
- (g_Mppt_Para.Charg_Current - g_Mppt_Para.Discharg_Current) * g_impedance;
}
float_t inBatteryCurr = g_Mppt_Para.Charg_Current - g_Mppt_Para.Discharg_Current;
float_t outBatteryCurr = g_Mppt_Para.Discharg_Current - g_Mppt_Para.Charg_Current;
if (g_batteryState == 0 && (inBatteryCurr > 0.1 || outBatteryCurr > 0.1) && g_Mppt_Para.Output_Voltage < 14.2) {
g_batteryState = 1;
}
/* 有电池,太阳能输出功率大,同时回路阻抗未测试或需要重新测试 */
if (g_batteryState == 1 && (g_Mppt_Para.Charg_Current > 3.0) && (g_impedanceStart == 1 || g_impedance == 0.0)) {
TimeSliceOffset_Register(&m_impedanceCalculation, Task_impedanceCalculation
, impedanceCalculation_reloadVal, impedanceCalculation_reloadVal);
}
// g_Mppt_Para.DischargMos_State = GPIO_ReadOutputDataBit(POW_OUT_CON_GPIO, POW_OUT_CON_PIN);
// g_Mppt_Para.Solar_Open_Circuit_Voltage = get_capturedata(get_PV1_VOLT_IN);
g_Mppt_Para.Input_Voltage = get_PV1_VOLT_IN();
if (g_Mppt_Para.HighSideMos_Temperature < g_slConfigInfo.HighSideMosTemperature_start + 3) {
if (overTemperature == 2) {
// start_mpptWork();
TimeSliceOffset_Register(&m_softStart, Task_softStart, softStart_reloadVal, softStart_offset);
}
overTemperature = 0;
return;
}
if (g_Mppt_Para.HighSideMos_Temperature > g_slConfigInfo.HighSideMosTemperature_end + 3
&& g_Mppt_Para.HighSideMos_Temperature < g_slConfigInfo.HighSideMosTemperature_stop) {
// g_Mppt_Para.MPPT_Mode = NoBattery;
// g_duty_ratio -= 0.1;
g_duty_ratio = 0.6;
Set_duty_ratio(&g_duty_ratio);
overTemperature = 1;
}
if (g_Mppt_Para.HighSideMos_Temperature > g_slConfigInfo.HighSideMosTemperature_stop + 3) {
overTemperature = 2;
stop_mpptWork();
}
}
}
/**
* @brief 广,3s
* @param
* @retval
*/
uint8_t recvbroadcast_flag = 0;
device_handle g_recvBroadcastDevice;
uint8_t g_recvBroadcastRegisterNumber;
STR_TimeSliceOffset m_recvbroadcast;
void Task_recvbroadcast(void)
{
static uint8_t run_number = 0;
/* 超过三次,不再发送 */
if (run_number++ == 3 || run_number > 3) {
RegistrationRequestFlag = 0;
run_number = 0;
TimeSliceOffset_Unregister(&m_recvbroadcast);
m_recvbroadcast.runFlag = 0;
return;
}
// if (g_Mppt_Para.Registration_Status == REGISTER_SUCCESS) {
// TimeSliceOffset_Unregister(&m_recvbroadcast);
// return;
// }
SL_Mppt_RegistrationRequest_pack recvpack = {0};
/* 起始标志 */
recvpack.start_Flag[0] = g_slConfigInfo.start_Flag[0];
recvpack.start_Flag[1] = g_slConfigInfo.start_Flag[1];
/* ID */
recvpack.address[0] = 0xFF;
recvpack.address[1] = 0xFF;
recvpack.address[2] = 0xFF;
recvpack.address[3] = 0xFF;
recvpack.address[4] = 0xFF;
recvpack.address[5] = 0xFF;
recvpack.address[6] = 0xFF;
/* 功能码 */
recvpack.function_Code = SL_Function_Code_Registration_request;
/* 寄存器长度 */
recvpack.register_Length_H = g_recvBroadcastRegisterNumber >> 8;
recvpack.register_Length_L = g_recvBroadcastRegisterNumber;
/* 注册状态 */
recvpack.registration_Status_H = g_Mppt_Para.Registration_Status >> 8;
recvpack.registration_Status_L = g_Mppt_Para.Registration_Status;
/* 接入节点ID */
recvpack.access_Node_ID[0] = g_slConfigInfo.address[0];
recvpack.access_Node_ID[1] = g_slConfigInfo.address[1];
recvpack.access_Node_ID[2] = g_slConfigInfo.address[2];
recvpack.access_Node_ID[3] = g_slConfigInfo.address[3];
recvpack.access_Node_ID[4] = g_slConfigInfo.address[4];
recvpack.access_Node_ID[5] = g_slConfigInfo.address[5];
recvpack.access_Node_ID[6] = g_slConfigInfo.address[6];
/* 接入节点类型 */
recvpack.access_Node_Type_H = g_Mppt_Para.Access_Node_Type >> 8;
recvpack.access_Node_Type_L = g_Mppt_Para.Access_Node_Type;
/* 校验位 */
// uint8_t *rpack_buf = (uint8_t *)&recvpack;
uint16_t crc = CheckFunc((uint8_t *)&recvpack, SL_MPPT_REGISTRATIONREQUEST_PACK_SIZE - 3);
recvpack.check_Bit_H = crc >> 8;
recvpack.check_Bit_L = crc;
/* 结束标志 */
recvpack.end_Flag = g_slConfigInfo.end_Flag;
/* 校验位 */
for (uint8_t var = 0; var < 10; ++var) {
Delay_Ms(randomDelay());
if (!Check_485_bus_busy(g_recvBroadcastDevice)) {
if (recvbroadcast_flag == 1) {
recvbroadcast_flag = 0;
run_number = 0;
return;
}
uart_dev_write(g_recvBroadcastDevice, (uint8_t *)&recvpack, SL_MPPT_REGISTRATIONREQUEST_PACK_SIZE + 1);
if (g_recvBroadcastDevice == g_bat485_uart3_handle) {
USART_ITConfig(USART3, USART_IT_RXNE, ENABLE);
} else {
USART_ITConfig(USART4, USART_IT_RXNE, ENABLE);
}
break;
}
}
}
/**
* @brief
* @param
* @retval
*/
STR_TimeSliceOffset m_impedanceCalculation;
float_t g_impedance = 0; /* 回路阻抗的值 */
uint8_t g_batteryState = 0; /* 有无电池 */
uint8_t g_impedanceStart = 0; /* 是否开始测量回路阻抗 */
//config_info tempConfigInfo;
void Task_impedanceCalculation(void)
{
static uint8_t num = 0;
static float_t currOne = 0;
static float_t voltOne = 0;
static float_t currTwo = 0;
static float_t voltTwo = 0;
// static uint8_t only_one = 1;
// if (only_one) {
// g_impedance = g_slConfigInfo.loopImpedance;
// }
// if (g_Mppt_Para.MPPT_Mode == CONSTANTCURRENT
// || g_Mppt_Para.MPPT_Mode == CONSTANTVOLTAGE) {
// ++num;
// } else {
// num = 0;
// }
//
// if (num == 10) {
// num = 0;
// TIM_Cmd(TIM3, DISABLE);
//
// TIM_SetCompare4(TIM4, 300);
// Delay_Ms(500);
//
// TIM_SetCompare4(TIM4, 420);
// Delay_Ms(5);
//// currOne = get_capturedata(get_CHG_CURR) - get_capturedata(get_DSG_CURR);
//// voltOne = get_capturedata(get_PV_VOLT_OUT);
// currOne = get_CHG_CURR() - get_DSG_CURR();
// voltOne = get_PV_VOLT_OUT();
//
//// currTwo = get_capturedata(get_CHG_CURR) - get_capturedata(get_DSG_CURR);
//// voltTwo = get_capturedata(get_PV_VOLT_OUT);
// currTwo = get_CHG_CURR() - get_DSG_CURR();
// voltTwo = get_PV_VOLT_OUT();
//
// g_impedance = (voltOne - voltTwo) / (currOne - currTwo);
//
// printf("currOne = %d/1000, voltOne = %d/100 \n", (int)(currOne * 1000), (int)(voltOne * 100));
// printf("currTwo = %d/1000, voltTwo = %d/100 \n", (int)(currTwo * 1000), (int)(voltTwo * 100));
// printf("Res = %d/1000, E = %d/100 \n", (int)(g_impedance * 1000), (int)((voltTwo - currTwo * g_impedance) * 100));
//
//// TIM_Cmd(TIM3, ENABLE);
// }
num++;
// printf("g_batteryState : %d\n", g_batteryState);
if (num == 1) {
TIM_Cmd(TIM3, DISABLE);
// g_interruptNum = 0;
TIM_SetCompare4(TIM4, 300);
return;
}
if (num == 11) {
currOne = get_CHG_CURR() - get_DSG_CURR();
voltOne = get_PV_VOLT_OUT();
TIM_SetCompare4(TIM4, 420);
return;
}
if (num == 21) {
TimeSliceOffset_Unregister(&m_impedanceCalculation);
m_impedanceCalculation.runFlag = 0;
currTwo = get_CHG_CURR() - get_DSG_CURR();
voltTwo = get_PV_VOLT_OUT();
g_impedance = (voltOne - voltTwo) / (currOne - currTwo);
// printf("g_batteryState : %d\n", g_batteryState);
// printf("currOne = %d/1000, voltOne = %d/100 \n", (int)(currOne * 1000), (int)(voltOne * 100));
// printf("currTwo = %d/1000, voltTwo = %d/100 \n", (int)(currTwo * 1000), (int)(voltTwo * 100));
// printf("Res = %d/1000, E = %d/100 \n", (int)(g_impedance * 1000), (int)((voltTwo - currTwo * g_impedance) * 100));
/* 判断回路阻抗是否合理 */
if (g_impedance > 1.0 || g_impedance < 0.05) {
g_impedance = 0;
num = 0;
start_mpptWork();
return;
}
/* 将回路阻抗的值放入flash中 */
config_info tempConfigInfo;
if (read_config_info1(&tempConfigInfo)) {
tempConfigInfo.loopImpedance = (uint16_t)(g_impedance * 1000);
save_config_info(&tempConfigInfo);
} else {
tempConfigInfo = g_slConfigInfo;
tempConfigInfo.loopImpedance = (uint16_t)(g_impedance * 1000);
save_config_info(&tempConfigInfo);
}
// uart_dev_write(g_bat485_uart3_handle, "\n\n\n\n\n", sizeof("\n\n\n\n\n"));
// char buffer[80];
// memset(buffer, 0, sizeof(buffer));
// sprintf(buffer, " tempConfigInfo.loopImpedance : %d/1000 \n", tempConfigInfo.loopImpedance);
// uart_dev_write(g_bat485_uart3_handle, buffer, sizeof(buffer));
// memset(buffer, 0, sizeof(buffer));
// config_info tempConfigInfo2 = {0};
// read_config_info1(&tempConfigInfo2);
// sprintf(buffer, " tempConfigInfo2.loopImpedance : %d/1000 \n", tempConfigInfo2.loopImpedance);
// uart_dev_write(g_bat485_uart3_handle, buffer, sizeof(buffer));
// uart_dev_write(g_bat485_uart3_handle, "\n\n\n\n\n", sizeof("\n\n\n\n\n"));
g_impedanceStart = 0;
num = 0;
start_mpptWork();
// TIM_Cmd(TIM3, ENABLE);
return;
}
return;
}
/**
* @brief
* @param
* @retval
*/
STR_TimeSliceOffset m_outputAgain;
uint8_t outputAgainFlag = 0;
void Task_outputAgain(void)
{
static uint8_t num = 0;
num++;
// if (outputAgainFlag == 1) {
//// outputAgainFlag = 0;
// GPIO_WriteBit(POW_OUT_CON_GPIO, POW_OUT_CON_PIN, RESET);
// TimeSliceOffset_Unregister(&m_outputAgain);
// m_outputAgain.runFlag = 0;
// num = 0;
// }
// printf(" in POW_OUT_CON\n");
if (num == g_slConfigInfo.outputAgainFlagTime) {
num = 0;
outputAgainFlag = 0;
TimeSliceOffset_Unregister(&m_outputAgain);
m_outputAgain.runFlag = 0;
// printf(" in POW_OUT_CON control %d \n", GPIO_ReadInputDataBit(DSG_PROT_GPIO, DSG_PROT_PIN));
if (!(GPIO_ReadInputDataBit(DSG_PROT_GPIO, DSG_PROT_PIN))) {
// uart_dev_write(g_bat485_uart3_handle, " \n\n\n\n\n", sizeof(" \n\n\n\n\n"));
// uart_dev_write(g_bat485_uart3_handle, " in task pow_out_con reset", sizeof(" in task pow_out_con reset"));
// uart_dev_write(g_bat485_uart3_handle, " \n\n\n\n\n", sizeof(" \n\n\n\n\n"));
// printf(" in POW_OUT_CON RESET \n");
GPIO_WriteBit(POW_OUT_CON_GPIO, POW_OUT_CON_PIN, RESET);
}
}
return;
}
/**
* @brief
* @param
* @retval
*/
STR_TimeSliceOffset m_excessiveLoad;
uint8_t excessiveLoadFlag = 0;
void Task_excessiveLoad(void)
{
static uint8_t num = 0;
static uint16_t numLong = 0;
// if (outputAgainFlag == 1) {
//// outputAgainFlag = 0;
// GPIO_WriteBit(POW_OUT_CON_GPIO, POW_OUT_CON_PIN, RESET);
// TimeSliceOffset_Unregister(&m_outputAgain);
// m_outputAgain.runFlag = 0;
// num = 0;
// }
// printf(" in POW_OUT_CON\n");
if (outputAgainFlag == 1) {
num = 0;
numLong = 0;
excessiveLoadFlag = 0;
TimeSliceOffset_Unregister(&m_excessiveLoad);
m_excessiveLoad.runFlag = 0;
}
if (excessiveLoadFlag == 1) {
num++;
}
if (num == g_slConfigInfo.excessiveLoadFlagTime) {
num = 0;
excessiveLoadFlag = 0;
TimeSliceOffset_Unregister(&m_excessiveLoad);
m_excessiveLoad.runFlag = 0;
return;
}
if (excessiveLoadFlag >= 2) {
GPIO_WriteBit(POW_OUT_CON_GPIO, POW_OUT_CON_PIN, RESET);
num = 0;
}
if (!(GPIO_ReadOutputDataBit(POW_OUT_CON_GPIO, POW_OUT_CON_PIN))) {
numLong++;
}
if (numLong == g_slConfigInfo.eLAgainTime) {
numLong = 0;
GPIO_WriteBit(POW_OUT_CON_GPIO, POW_OUT_CON_PIN, SET);
excessiveLoadFlag = 0;
TimeSliceOffset_Unregister(&m_excessiveLoad);
m_excessiveLoad.runFlag = 0;
}
return;
}
/**
* @brief
* @param
* @retval
*/
STR_TimeSliceOffset m_sensorEnableBroadcast;
/* 是否接收广播帧标志位 */
uint8_t run_Broadcast = 1;
void Task_sensorEnableBroadcast(void)
{
static uint32_t enabBroadcastTimeFlag = 0;
enabBroadcastTimeFlag++;
run_Broadcast = 0;
if (enabBroadcastTimeFlag == g_slConfigInfo.sensorEnableBroadcastTime) {
enabBroadcastTimeFlag = 0;
run_Broadcast = 1;
TimeSliceOffset_Unregister(&m_sensorEnableBroadcast);
m_sensorEnableBroadcast.runFlag = 0;
}
return;
}
/**
* @brief
* @param
* @retval
*/
void g_Mppt_Para_Init(void)
{
g_impedance = (float_t)g_slConfigInfo.loopImpedance / 1000;
g_Mppt_Para.Registration_Status = UNREGISTER;
g_Mppt_Para.address[0] = g_slConfigInfo.address[0];
g_Mppt_Para.address[1] = g_slConfigInfo.address[1];
g_Mppt_Para.address[2] = g_slConfigInfo.address[2];
g_Mppt_Para.address[3] = g_slConfigInfo.address[3];
g_Mppt_Para.address[4] = g_slConfigInfo.address[4];
g_Mppt_Para.address[5] = g_slConfigInfo.address[5];
g_Mppt_Para.address[6] = g_slConfigInfo.address[6];
g_Mppt_Para.Access_Node_Type = defaultValue.access_Node_Type;
g_Mppt_Para.Communication_Methods = defaultValue.communication_Methods;
// g_Mppt_Para.Output_Voltage = get_capturedata(get_PV_VOLT_OUT);
// g_Mppt_Para.Battery_Voltage = g_Mppt_Para.Output_Voltage;
// g_Mppt_Para.Charg_Current = get_capturedata(get_CHG_CURR);
// g_Mppt_Para.Discharg_Current = get_capturedata(get_DSG_CURR);
// g_Mppt_Para.Solar_Open_Circuit_Voltage = get_capturedata(get_PV1_VOLT_IN);
// g_Mppt_Para.HighSideMos_Temperature = get_capturedata(get_MOSFET_Temper); g_Mppt_Para.Output_Voltage = get_capturedata(get_PV_VOLT_OUT);
g_Mppt_Para.Output_Voltage = get_PV_VOLT_OUT();
// g_Mppt_Para.Battery_Voltage = g_Mppt_Para.Output_Voltage;
g_Mppt_Para.Charg_Current = get_CHG_CURR();
g_Mppt_Para.Discharg_Current = get_DSG_CURR();
g_Mppt_Para.Battery_Voltage = g_Mppt_Para.Output_Voltage
- (g_Mppt_Para.Charg_Current - g_Mppt_Para.Discharg_Current) * g_impedance;
g_Mppt_Para.Solar_Open_Circuit_Voltage = get_PV1_VOLT_IN();
g_Mppt_Para.HighSideMos_Temperature = get_MOSFET_Temper();
if (g_Mppt_Para.Battery_Voltage < 15 || g_Mppt_Para.Battery_Voltage > 11) {
// GPIO_WriteBit(POW_OUT_CON_GPIO, POW_OUT_CON_PIN, SET);
g_impedanceStart = 1;
}
g_Mppt_Para.DischargMos_State = GPIO_ReadOutputDataBit(POW_OUT_CON_GPIO, POW_OUT_CON_PIN)
&& GPIO_ReadInputDataBit(DSG_PROT_GPIO, DSG_PROT_PIN);
g_Mppt_Para.MPPT_Mode = NoWork;
// printf("start_flag : %s \n", g_slConfigInfo.start_Flag);
// for (int var = 0; var < 7; ++var) {
// printf("address[%d] : %x\n", var, g_slConfigInfo.address[var]);
// }
// printf("end_flag : %x\n", g_slConfigInfo.end_Flag);
// printf("access_Node_Type : %x\n", defaultValue.access_Node_Type);
// printf("communication_Methods : %x\n", defaultValue.communication_Methods);
}
/**
* @brief
* @param
* @retval
*/
void task_Init(void)
{
read_config_info();
g_Mppt_Para_Init();
TimeSliceOffset_Register(&m_runled, Task_RunLED, runled_reloadVal, runled_offset);
TimeSliceOffset_Register(&m_usart, Task_usart, usart_reloadVal, usart_offset);
TimeSliceOffset_Register(&m_wdi, Task_wdi, wdi_reloadVal, wdi_offset);
// TimeSliceOffset_Register(&m_impedanceCalculation, Task_impedanceCalculation
// , impedanceCalculation_reloadVal, impedanceCalculation_reloadVal);
TimeSliceOffset_Register(&m_refreshRegister, Task_refreshRegister
, refreshRegister_reloadVal, refreshRegister_reloadVal);
TimeSliceOffset_Register(&m_startMpptControl, Task_startMpptControl
, startMpptControl_reloadVal, startMpptControl_offset);
TimeSliceOffset_Start(); /* 启动时间片轮询 */
}
/**
* @brief
* @param
* @retval
*/
void hardware_Init(void)
{
TIM2_Init(1);
uart_dev_init();
PWM_TIM_Configuration();
// TIM_SetCompare4(TIM4, 0);
ADC_all_Init();
RUN_LED_Init();
WDI_INPUT_Init();
SPI_Flash_Init();
POW_OUT_CON_Init();
DSG_PROT_Init();
WORK_VOLT_INT_Init();
// EnPowerSupply_Init();
// Set_duty_ratio(&g_duty_ratio);
// uart_dev_write(g_bat485_uart3_handle, " hello world \n", sizeof(" hello world \n"));
TIM3_Init(10);
// TIM_Cmd(TIM3, ENABLE); //TIM3使能
}

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@ -7,6 +7,7 @@
#include "uart_dev.h"
#include "inflash.h"
#include "parameter.h"
/* ʹÄÜ485·¢ËÍ */
#define rs485_send_enable 1
@ -80,12 +81,12 @@ device_handle uart_dev_init(void)
// }
// }
InitRingQueue(&uart_devices[0].uart_ring_queue, bat485_in_buff, sizeof(bat485_in_buff));
uart_init(BAT485_UART_INDEX, g_slConfigInfo.baud_485);
uart_init(BAT485_UART_INDEX, g_otherParameter.bat485_Baud);
uart_devices[0].init = 1;
g_bat485_uart3_handle = (device_handle)(&uart_devices[0]);
InitRingQueue(&uart_devices[1].uart_ring_queue, gw485_in_buff, sizeof(gw485_in_buff));
uart_init(GW485_UART_INDEX, g_slConfigInfo.baud_485);
uart_init(GW485_UART_INDEX, g_otherParameter.gw485_Baud);
uart_devices[1].init = 1;
g_gw485_uart4_handle = (device_handle)(&uart_devices[1]);

View File

@ -103,17 +103,11 @@ void EXTI2_IRQHandler(void)
// GPIO_WriteBit(DSG_PROT_GPIO, DSG_PROT_PIN, RESET);
EXTI_ClearITPendingBit(EXTI_Line2); //清除中断标志位
// printf("Run at EXTI 111\r\n");
if (outputAgainFlag == 0) {
outputAgainFlag = 1;
TimeSliceOffset_Register(&m_outputAgain, Task_outputAgain
, outputAgain_reloadVal, outputAgain_offset);
// if (outputAgainFlag == 0) {
// outputAgainFlag = 1;
// TimeSliceOffset_Register(&m_outputAgain, Task_outputAgain
// , outputAgain_reloadVal, outputAgain_offset);
// m_outputAgain.runFlag = 1;
return;
}
// if (outputAgainFlag == 1) {
// GPIO_WriteBit(POW_OUT_CON_GPIO, POW_OUT_CON_PIN, RESET);
// EXTI_ClearITPendingBit(EXTI_Line2); //清除中断标志位
// return;
// }
@ -163,19 +157,13 @@ void WORK_VOLT_INT_Init(void)
void EXTI15_10_IRQHandler(void)
{
if(EXTI_GetITStatus(EXTI_Line12)==SET) { //EXTI_GetITStatus用来获取中断标志位状态如果EXTI线产生中断则返回SET否则返回RESET
// printf(" vout low 11V \n");
EXTI_ClearITPendingBit(EXTI_Line12); //清除中断标志位
excessiveLoadFlag++;
TimeSliceOffset_Register(&m_excessiveLoad, Task_excessiveLoad
, excessiveLoad_reloadVal, excessiveLoad_offset);
// EXTI_ClearITPendingBit(EXTI_Line12); //清除中断标志位
// excessiveLoadFlag++;
// TimeSliceOffset_Register(&m_excessiveLoad, Task_excessiveLoad
// , excessiveLoad_reloadVal, excessiveLoad_offset);
// uart_dev_write(g_bat485_uart3_handle, "\n\n\n\n\n in vout low 8V (Set)\n\n\n\n\n", sizeof("\n\n\n\n\n in vout low 8V (Set)\n\n\n\n\n"));
}
// uart_dev_write(g_bat485_uart3_handle, "\n\n\n\n\n in vout low 8V\n\n\n\n\n", sizeof("\n\n\n\n\n in vout low 8V\n\n\n\n\n"));
// if(EXTI_GetITStatus(EXTI_Line12)==SET) { //EXTI_GetITStatus用来获取中断标志位状态如果EXTI线产生中断则返回SET否则返回RESET
//// printf(" vout low 11V \n");
// uart_dev_write(g_bat485_uart3_handle, "\n\n\n\n\n in vout low 8V\n\n\n\n\n", sizeof("\n\n\n\n\n in vout low 8V\n\n\n\n\n"));
// }
}

View File

@ -59,7 +59,7 @@ void TIM3_IRQHandler(void)
if (TIM_GetITStatus(TIM3, TIM_IT_Update) != RESET) { //检查TIM3中断是否发生。
TIM_ClearITPendingBit(TIM3, TIM_IT_Update); //清除TIM3的中断挂起位。
// uart_dev_write(g_bat485_uart3_handle, "\n\n\n\n\nin tim3 irt\n\n\n\n\n", sizeof("\n\n\n\n\nin tim3 irt\n\n\n\n\n"));
test();
// test();
}
}

View File

@ -39,6 +39,6 @@ int main(void)
printf("SystemClk:%d\r\n", SystemCoreClock);
printf( "ChipID:%08x\r\n", DBGMCU_GetCHIPID());
hardware_Init();
task_Init();
// hardware_Init();
// task_Init();
}

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@ -33,7 +33,7 @@ App/src/mppt_control.o: ../App/src/mppt_control.c \
D:\psx\MPPT\git\Drivers\RingQueue/ring_queue.h \
D:\psx\MPPT\git\Hardware\inc/rs485.h D:\psx\MPPT\git\App\inc/task.h \
D:\psx\MPPT\git\Drivers\TimeSliceOffset/timeSliceOffset.h \
D:\psx\MPPT\git\App\inc/uart_dev.h
D:\psx\MPPT\git\App\inc/uart_dev.h D:\psx\MPPT\git\App\inc/parameter.h
D:\psx\MPPT\git\App\inc/mppt_control.h:
@ -116,3 +116,5 @@ D:\psx\MPPT\git\App\inc/task.h:
D:\psx\MPPT\git\Drivers\TimeSliceOffset/timeSliceOffset.h:
D:\psx\MPPT\git\App\inc/uart_dev.h:
D:\psx\MPPT\git\App\inc/parameter.h:

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95
obj/App/src/parameter.d Normal file
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@ -0,0 +1,95 @@
App/src/parameter.o: ../App/src/parameter.c \
D:\psx\MPPT\git\App\inc/parameter.h D:\psx\MPPT\git\Debug/debug.h \
D:\psx\MPPT\git\Peripheral\inc/ch32l103.h \
D:\psx\MPPT\git\Core/core_riscv.h D:\psx\MPPT\git\User/system_ch32l103.h \
D:\psx\MPPT\git\User/ch32l103_conf.h \
D:\psx\MPPT\git\Peripheral\inc/ch32l103_adc.h \
D:\psx\MPPT\git\Peripheral\inc/ch32l103.h \
D:\psx\MPPT\git\Peripheral\inc/ch32l103_bkp.h \
D:\psx\MPPT\git\Peripheral\inc/ch32l103_can.h \
D:\psx\MPPT\git\Peripheral\inc/ch32l103_crc.h \
D:\psx\MPPT\git\Peripheral\inc/ch32l103_dbgmcu.h \
D:\psx\MPPT\git\Peripheral\inc/ch32l103_dma.h \
D:\psx\MPPT\git\Peripheral\inc/ch32l103_exti.h \
D:\psx\MPPT\git\Peripheral\inc/ch32l103_flash.h \
D:\psx\MPPT\git\Peripheral\inc/ch32l103_gpio.h \
D:\psx\MPPT\git\Peripheral\inc/ch32l103_i2c.h \
D:\psx\MPPT\git\Peripheral\inc/ch32l103_iwdg.h \
D:\psx\MPPT\git\Peripheral\inc/ch32l103_pwr.h \
D:\psx\MPPT\git\Peripheral\inc/ch32l103_rcc.h \
D:\psx\MPPT\git\Peripheral\inc/ch32l103_rtc.h \
D:\psx\MPPT\git\Peripheral\inc/ch32l103_spi.h \
D:\psx\MPPT\git\Peripheral\inc/ch32l103_tim.h \
D:\psx\MPPT\git\Peripheral\inc/ch32l103_usart.h \
D:\psx\MPPT\git\Peripheral\inc/ch32l103_wwdg.h \
D:\psx\MPPT\git\User/ch32l103_it.h \
D:\psx\MPPT\git\Peripheral\inc/ch32l103_misc.h \
D:\psx\MPPT\git\Peripheral\inc/ch32l103_lptim.h \
D:\psx\MPPT\git\Peripheral\inc/ch32l103_opa.h \
D:\psx\MPPT\git\App\inc/uart_dev.h \
D:\psx\MPPT\git\Drivers\RingQueue/ring_queue.h \
D:\psx\MPPT\git\Hardware\inc/rs485.h
D:\psx\MPPT\git\App\inc/parameter.h:
D:\psx\MPPT\git\Debug/debug.h:
D:\psx\MPPT\git\Peripheral\inc/ch32l103.h:
D:\psx\MPPT\git\Core/core_riscv.h:
D:\psx\MPPT\git\User/system_ch32l103.h:
D:\psx\MPPT\git\User/ch32l103_conf.h:
D:\psx\MPPT\git\Peripheral\inc/ch32l103_adc.h:
D:\psx\MPPT\git\Peripheral\inc/ch32l103.h:
D:\psx\MPPT\git\Peripheral\inc/ch32l103_bkp.h:
D:\psx\MPPT\git\Peripheral\inc/ch32l103_can.h:
D:\psx\MPPT\git\Peripheral\inc/ch32l103_crc.h:
D:\psx\MPPT\git\Peripheral\inc/ch32l103_dbgmcu.h:
D:\psx\MPPT\git\Peripheral\inc/ch32l103_dma.h:
D:\psx\MPPT\git\Peripheral\inc/ch32l103_exti.h:
D:\psx\MPPT\git\Peripheral\inc/ch32l103_flash.h:
D:\psx\MPPT\git\Peripheral\inc/ch32l103_gpio.h:
D:\psx\MPPT\git\Peripheral\inc/ch32l103_i2c.h:
D:\psx\MPPT\git\Peripheral\inc/ch32l103_iwdg.h:
D:\psx\MPPT\git\Peripheral\inc/ch32l103_pwr.h:
D:\psx\MPPT\git\Peripheral\inc/ch32l103_rcc.h:
D:\psx\MPPT\git\Peripheral\inc/ch32l103_rtc.h:
D:\psx\MPPT\git\Peripheral\inc/ch32l103_spi.h:
D:\psx\MPPT\git\Peripheral\inc/ch32l103_tim.h:
D:\psx\MPPT\git\Peripheral\inc/ch32l103_usart.h:
D:\psx\MPPT\git\Peripheral\inc/ch32l103_wwdg.h:
D:\psx\MPPT\git\User/ch32l103_it.h:
D:\psx\MPPT\git\Peripheral\inc/ch32l103_misc.h:
D:\psx\MPPT\git\Peripheral\inc/ch32l103_lptim.h:
D:\psx\MPPT\git\Peripheral\inc/ch32l103_opa.h:
D:\psx\MPPT\git\App\inc/uart_dev.h:
D:\psx\MPPT\git\Drivers\RingQueue/ring_queue.h:
D:\psx\MPPT\git\Hardware\inc/rs485.h:

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obj/App/src/parameter.o Normal file

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@ -32,7 +32,8 @@ App/src/sl_protocol.o: ../App/src/sl_protocol.c \
D:\psx\MPPT\git\App\inc/pdebug.h D:\psx\MPPT\git\App\inc/mppt_control.h \
D:\psx\MPPT\git\App\inc/task.h \
D:\psx\MPPT\git\Drivers\TimeSliceOffset/timeSliceOffset.h \
D:\psx\MPPT\git\App\inc/uart_dev.h D:\psx\MPPT\git\Hardware\inc/tim.h
D:\psx\MPPT\git\App\inc/uart_dev.h D:\psx\MPPT\git\Hardware\inc/tim.h \
D:\psx\MPPT\git\App\inc/parameter.h
D:\psx\MPPT\git\App\inc/sl_protocol.h:
@ -111,3 +112,5 @@ D:\psx\MPPT\git\Drivers\TimeSliceOffset/timeSliceOffset.h:
D:\psx\MPPT\git\App\inc/uart_dev.h:
D:\psx\MPPT\git\Hardware\inc/tim.h:
D:\psx\MPPT\git\App\inc/parameter.h:

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@ -9,6 +9,7 @@ C_SRCS += \
../App/src/hy_protocol.c \
../App/src/inflash.c \
../App/src/mppt_control.c \
../App/src/parameter.c \
../App/src/sl_protocol.c \
../App/src/task.c \
../App/src/uart_dev.c
@ -18,6 +19,7 @@ OBJS += \
./App/src/hy_protocol.o \
./App/src/inflash.o \
./App/src/mppt_control.o \
./App/src/parameter.o \
./App/src/sl_protocol.o \
./App/src/task.o \
./App/src/uart_dev.o
@ -27,6 +29,7 @@ C_DEPS += \
./App/src/hy_protocol.d \
./App/src/inflash.d \
./App/src/mppt_control.d \
./App/src/parameter.d \
./App/src/sl_protocol.d \
./App/src/task.d \
./App/src/uart_dev.d

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@ -34,7 +34,8 @@ App/src/task.o: ../App/src/task.c D:\psx\MPPT\git\App\inc/task.h \
D:\psx\MPPT\git\Hardware\inc/flash.h \
D:\psx\MPPT\git\App\inc/sl_protocol.h \
D:\psx\MPPT\git\App\inc/mppt_control.h D:\psx\MPPT\git\App\inc/inflash.h \
D:\psx\MPPT\git\App\inc/collect_Conversion.h
D:\psx\MPPT\git\App\inc/collect_Conversion.h \
D:\psx\MPPT\git\App\inc/parameter.h
D:\psx\MPPT\git\App\inc/task.h:
@ -121,3 +122,5 @@ D:\psx\MPPT\git\App\inc/mppt_control.h:
D:\psx\MPPT\git\App\inc/inflash.h:
D:\psx\MPPT\git\App\inc/collect_Conversion.h:
D:\psx\MPPT\git\App\inc/parameter.h:

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@ -27,7 +27,8 @@ App/src/uart_dev.o: ../App/src/uart_dev.c \
D:\psx\MPPT\git\Peripheral\inc/ch32l103_lptim.h \
D:\psx\MPPT\git\Peripheral\inc/ch32l103_opa.h \
D:\psx\MPPT\git\Drivers\RingQueue/ring_queue.h \
D:\psx\MPPT\git\Hardware\inc/rs485.h D:\psx\MPPT\git\App\inc/inflash.h
D:\psx\MPPT\git\Hardware\inc/rs485.h D:\psx\MPPT\git\App\inc/inflash.h \
D:\psx\MPPT\git\App\inc/parameter.h D:\psx\MPPT\git\App\inc/uart_dev.h
D:\psx\MPPT\git\App\inc/uart_dev.h:
@ -92,3 +93,7 @@ D:\psx\MPPT\git\Drivers\RingQueue/ring_queue.h:
D:\psx\MPPT\git\Hardware\inc/rs485.h:
D:\psx\MPPT\git\App\inc/inflash.h:
D:\psx\MPPT\git\App\inc/parameter.h:
D:\psx\MPPT\git\App\inc/uart_dev.h:

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