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208d84e2a5
| Author | SHA1 | Date | |
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| 208d84e2a5 | |||
| 5dba504e10 | |||
| 2eb7109416 |
@ -10,16 +10,17 @@
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#define SHUNT_THRESH_OVERTEMP 1000 // 1/10 °C
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typedef struct {
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int32_t current;
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int32_t voltage_bat;
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int32_t voltage_veh;
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int32_t voltage3;
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int32_t current; // mA
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int32_t voltage_bat; // mV
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int32_t voltage_veh; // mV
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int32_t voltage3; // mV
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int32_t busbartemp;
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int32_t power;
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int32_t energy;
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int32_t current_counter;
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float current_counter; // mAs
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uint32_t last_message;
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uint32_t last_current_message;
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} ShuntData;
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extern ShuntData shunt_data;
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@ -28,6 +29,4 @@ void shunt_check();
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void shunt_handle_can_msg(uint16_t id, const uint8_t *data);
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int32_t shunt_getcurrent();
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#endif // INC_SHUNT_MONITORING_H
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@ -49,6 +49,5 @@ void slaves_check();
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void slaves_handle_panic(const uint8_t *data);
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void slaves_handle_status(const uint8_t *data);
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void slaves_handle_log(const uint8_t *data);
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uint16_t slaves_get_minimum_voltage();
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#endif // INC_SLAVE_MONITORING_H
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@ -3,16 +3,16 @@
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#include <stdint.h>
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extern uint8_t current_soc;
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#define N_MODELPARAMETERS 11
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#define BATTERYCAPACITYAs (21000.0*3600) //TODO Check if value is correct Cap in Ah * 3600 (Convert to As)
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extern float current_soc;
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void soc_init();
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void soc_update(int32_t shunt_current);
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void soe_update();
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void soap_update();
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void soc_update();
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typedef struct {
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uint16_t ocv;
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float soc;
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} ocv_soc_pair_t;
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extern ocv_soc_pair_t OCV_SOC_PAIRS[];
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float soc_for_ocv(uint16_t ocv);
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#endif // INC_SOC_ESTIMATION_H
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@ -8,6 +8,7 @@
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#include "can-halal.h"
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#include <math.h>
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#include <stdint.h>
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void can_init(CAN_HandleTypeDef *handle) {
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@ -22,7 +23,7 @@ void can_init(CAN_HandleTypeDef *handle) {
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HAL_StatusTypeDef can_send_status() {
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uint8_t data[6];
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data[0] = ts_state.current_state | (sdc_closed << 7);
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data[1] = current_soc;
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data[1] = roundf(current_soc);
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ftcan_marshal_unsigned(&data[2], min_voltage, 2);
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ftcan_marshal_signed(&data[4], max_temp, 2);
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return ftcan_transmit(CAN_ID_AMS_STATUS, data, sizeof(data));
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@ -50,7 +50,6 @@
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/* Private variables ---------------------------------------------------------*/
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ADC_HandleTypeDef hadc2;
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CAN_HandleTypeDef hcan;
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UART_HandleTypeDef huart1;
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@ -92,7 +91,7 @@ static void loop_delay() {
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*/
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int main(void) {
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/* USER CODE BEGIN 1 */
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uint8_t soc_init_complete = 0;
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/* USER CODE END 1 */
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/* MCU Configuration--------------------------------------------------------*/
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@ -122,6 +121,7 @@ int main(void) {
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slaves_init();
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shunt_init();
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ts_sm_init();
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soc_init();
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HAL_GPIO_WritePin(AMS_NERROR_GPIO_Port, AMS_NERROR_Pin, GPIO_PIN_SET);
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/* USER CODE END 2 */
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@ -138,17 +138,10 @@ int main(void) {
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slaves_check();
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shunt_check();
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ts_sm_update();
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if(soc_init_complete){
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soc_update(shunt_getcurrent());
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}
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else
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{
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soc_init();
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soc_init_complete = 1;
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}
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soc_update();
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can_send_status();
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loop_delay();
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loop_delay();
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}
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/* USER CODE END 3 */
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}
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@ -20,6 +20,7 @@ void shunt_init() {
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shunt_data.energy = 0;
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shunt_data.current_counter = 0;
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shunt_data.last_message = 0;
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shunt_data.last_current_message = 0;
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}
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void shunt_check() {
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@ -46,6 +47,12 @@ void shunt_handle_can_msg(uint16_t id, const uint8_t *data) {
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switch (id) {
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case CAN_ID_SHUNT_CURRENT:
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shunt_data.current = result;
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if (shunt_data.last_current_message > 0) {
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uint32_t now = HAL_GetTick();
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float dt = (now - shunt_data.last_current_message) * 0.001f;
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shunt_data.current_counter += shunt_data.current * dt;
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}
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shunt_data.last_current_message = HAL_GetTick();
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break;
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case CAN_ID_SHUNT_VOLTAGE1:
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shunt_data.voltage_bat = result;
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@ -63,15 +70,13 @@ void shunt_handle_can_msg(uint16_t id, const uint8_t *data) {
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shunt_data.power = result;
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break;
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case CAN_ID_SHUNT_CURRENT_COUNTER:
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shunt_data.current_counter = result;
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// TODO: Use this when we get the shunt to emit current counter data (the
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// shunt apparently emits As, not mAs)
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// shunt_data.current_counter = result * 1000;
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break;
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case CAN_ID_SHUNT_ENERGY_COUNTER:
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shunt_data.energy = result;
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break;
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}
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}
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int32_t shunt_getcurrent()
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{
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return shunt_data.current;
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}
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@ -136,14 +136,3 @@ void slaves_handle_status(const uint8_t *data) {
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void slaves_handle_log(const uint8_t *data) {
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// TODO
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}
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uint16_t slaves_get_minimum_voltage()
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{
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uint16_t minvoltage = 50000;
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for(uint8_t idx = 0; idx < N_SLAVES;idx++){
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if(slaves->min_voltage < minvoltage){
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min_voltage = slaves->min_voltage;
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}
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}
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return minvoltage;
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}
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@ -1,103 +1,91 @@
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#include "soc_estimation.h"
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#include <stdint.h>
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#include "shunt_monitoring.h"
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#include "slave_monitoring.h"
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#include "stm32f3xx_hal.h"
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#include <stddef.h>
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#include <stdint.h>
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//------------------------------------Battery RC and OCV-SoC Parameters-----------------------------------------
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//@Note Parameters were obtained by EIS Measurements at the start of the season
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//If the errror with this values is to large, consider retesting some cells
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const float SOC[N_MODELPARAMETERS]={0,0.1,0.2,0.3,0.4,0.5,0.6,0.7,0.8,0.9,1};
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const float R0[N_MODELPARAMETERS]={0.0089,0.0087,0.0090,0.0087,0.0087,0.0087,0.0088,0.0088,0.0087,0.0088,0.0089};
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const float R1[N_MODELPARAMETERS]={0.0164,0.0063,0.0050,0.0055,0.0051,0.0052,0.0057,0.0048,0.0059,0.0055,0.0061};
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const float C1[N_MODELPARAMETERS]={2.5694,0.2649,0.2876,0.2594,0.2415,0.2360,0.2946,0.2558,0.2818,0.2605,0.2763};
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const float OCV_Data[N_MODELPARAMETERS]={2.762504,3.326231,3.460875,3.57681,3.655326,3.738444,3.835977,3.925841,4.032575,4.078275,4.191449};
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#define SOC_ESTIMATION_NO_CURRENT_THRESH 200 // mA
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#define SOC_ESTIMATION_NO_CURRENT_TIME 100000 // ms
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#define SOC_ESTIMATION_BATTERY_CAPACITY 70300800 // mAs
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ocv_soc_pair_t OCV_SOC_PAIRS[] = {
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{25000, 0.00f}, {29900, 3.97f}, {32300, 9.36f}, {33200, 12.60f},
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{33500, 13.68f}, {34100, 20.15f}, {35300, 32.01f}, {38400, 66.53f},
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{40100, 83.79f}, {40200, 90.26f}, {40400, 94.58f}, {41000, 98.89f},
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{42000, 100.00f}};
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//---------------------------------------------------------------------------------------------------------------
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float current_soc;
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int current_was_flowing;
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uint32_t last_current_time;
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uint32_t first_current_time;
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float soc_before_current;
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float mAs_before_current;
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float soc_approxparameterbysoc(float,float*, uint8_t);
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float soc_approxsocbyocv(float);
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uint8_t current_soc;
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float current_floatsoc;
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float batterycapacity;
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/**
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* @brief This Function initializes the SoC Prediction
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* @note Because SoC is initalized using the OCV-Curve of the Cell, it is necessary to obtain a valid value
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* for the lowest cell voltage before calling this function
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*/
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void soc_init() {
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float minvoltage = ((float)slaves_get_minimum_voltage())/1000;
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current_floatsoc = soc_approxsocbyocv(minvoltage);
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batterycapacity = BATTERYCAPACITYAs*current_floatsoc;
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current_soc = (uint8_t)(current_floatsoc*100);
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current_soc = 0;
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last_current_time = 0;
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current_was_flowing = 1;
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}
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/**
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* @brief Update Function for the State of Charge. Call this Function every time the shunt sends a new current
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* @note The SoC Prediction works using a Coulomb Counter to track the SoC. Alternativly and maybe more elegant
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* would be to track the SoC using the integrated current counter of the shunt.
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* @param shunt_current
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*/
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void soc_update(int32_t shunt_current) {
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// TODO
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static uint32_t lasttick = 0;
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if(lasttick != 0)
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{
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uint32_t dt = HAL_GetTick() - lasttick;
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batterycapacity += batterycapacity + ((float) dt*shunt_current)/1000;
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current_floatsoc = batterycapacity/BATTERYCAPACITYAs;
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current_soc = (uint8_t) (current_floatsoc*100);
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}
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lasttick=HAL_GetTick();
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}
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void soe_update()
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{
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//TODO
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}
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void soap_update()
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{
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//TODO
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}
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float soc_approxparameterbysoc(float soc,float* lut, uint8_t lutlen)
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{
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//TODO
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return 0;
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}
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float soc_approxsocbyocv(float ocv)
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{
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if(ocv < OCV_Data[0])
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return 0;
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if(ocv > OCV_Data[N_MODELPARAMETERS])
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return 1;
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//Iterate through OCV Lookup
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uint8_t ocvindex = 0;
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for(uint8_t i = 0; i < (N_MODELPARAMETERS-1);i++)
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{
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if((OCV_Data[i] <= ocv) && (OCV_Data[i+1] > ocv))
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{
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ocvindex = i;
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void soc_update() {
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uint32_t now = HAL_GetTick();
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if (shunt_data.current >= SOC_ESTIMATION_NO_CURRENT_THRESH) {
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last_current_time = now;
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if (!current_was_flowing) {
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first_current_time = now;
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soc_before_current = current_soc;
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mAs_before_current = shunt_data.current_counter;
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}
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current_was_flowing = 1;
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} else {
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current_was_flowing = 0;
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}
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float m = (ocv-OCV_Data[ocvindex])/(OCV_Data[ocvindex+1]-OCV_Data[ocvindex]);
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float soc = (SOC[ocvindex+1] - SOC[ocvindex])*m + SOC[ocvindex];
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return soc;
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if (now - last_current_time >= SOC_ESTIMATION_NO_CURRENT_TIME ||
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last_current_time == 0) {
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// Assume we're measuring OCV if there's been no current for a while (or
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// we've just turned on the battery).
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current_soc = soc_for_ocv(min_voltage);
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} else {
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// Otherwise, use the current counter to update SoC
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float as_delta = shunt_data.current_counter - mAs_before_current;
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current_soc =
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soc_before_current + as_delta / SOC_ESTIMATION_BATTERY_CAPACITY;
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}
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}
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}
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float soc_for_ocv(uint16_t ocv) {
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size_t i = 0;
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size_t array_length = sizeof(OCV_SOC_PAIRS) / sizeof(*OCV_SOC_PAIRS);
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// Find the index of the first element with OCV greater than the target OCV
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while (i < array_length && OCV_SOC_PAIRS[i].ocv <= ocv) {
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i++;
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}
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// If the target OCV is lower than the smallest OCV in the array, return the
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// first SOC value
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if (i == 0) {
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return OCV_SOC_PAIRS[0].soc;
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}
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// If the target OCV is higher than the largest OCV in the array, return the
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// last SOC value
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if (i == array_length) {
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return OCV_SOC_PAIRS[array_length - 1].soc;
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}
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// Perform linear interpolation
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uint16_t ocv1 = OCV_SOC_PAIRS[i - 1].ocv;
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uint16_t ocv2 = OCV_SOC_PAIRS[i].ocv;
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float soc1 = OCV_SOC_PAIRS[i - 1].soc;
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float soc2 = OCV_SOC_PAIRS[i].soc;
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float slope = (soc2 - soc1) / (ocv2 - ocv1);
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float interpolated_soc = soc1 + slope * (ocv - ocv1);
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return interpolated_soc;
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}
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