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bms_if.c
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bms_if.c
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/*
Copyright 2019 - 2024 Benjamin Vedder [email protected]
This file is part of the VESC BMS firmware.
The VESC BMS firmware is free software: you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation, either version 3 of the License, or
(at your option) any later version.
The VESC BMS firmware is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with this program. If not, see <http://www.gnu.org/licenses/>.
*/
#include "ltc6813.h"
#include "main.h"
#include "bms_if.h"
#include "pwr.h"
#include "utils.h"
#include "hdc1080.h"
#include "sht30.h"
#include "shtc3.h"
#include "bme280_if.h"
#include "comm_can.h"
#include "timeout.h"
#include "sleep.h"
#include "terminal.h"
#include "flash_helper.h"
#include "commands.h"
#include <math.h>
// Settings
#define I_IN_FILTER_CONST 0.006
#define I_IN_FILTER_CONST_IC 0.006
#define IC_ISENSE_I_GAIN_CORR 0.997 // This gain correction is a hack and should probably be set in config or in hw config
// Private variables
static volatile float m_i_in_filter = 0.0;
static volatile float m_i_in_filter_ic = 0.0;
static volatile bool m_charge_allowed = true;
static volatile bool m_is_charging = false;
static volatile bool m_is_balancing = false;
static volatile float m_voltage_cell_min = 0.0;
static volatile float m_voltage_cell_max = 0.0;
static volatile int m_balance_override[HW_CELLS_SERIES] = {0};
static volatile bool m_bal_ok = false;
static volatile bool m_was_charge_overcurrent = false;
static float m_soc_filtered = 0.0;
static bool m_soc_filter_init_done = false;
static volatile int m_no_charge_cnt = 0;
bms_if_fault_cb m_fault_cb = NULL;
// Threads
static THD_WORKING_AREA(if_thd_wa, 2048);
static THD_FUNCTION(if_thd, p);
static THD_WORKING_AREA(charge_thd_wa, 2048);
static THD_FUNCTION(charge_thd, p);
static THD_WORKING_AREA(balance_thd_wa, 2048);
static THD_FUNCTION(balance_thd, p);
void bms_if_init(void) {
chThdCreateStatic(if_thd_wa, sizeof(if_thd_wa), NORMALPRIO, if_thd, 0);
chThdCreateStatic(charge_thd_wa, sizeof(charge_thd_wa), NORMALPRIO, charge_thd, 0);
chThdCreateStatic(balance_thd_wa, sizeof(balance_thd_wa), NORMALPRIO, balance_thd, 0);
}
bool bms_if_charge_ok(void) {
float max = m_is_charging ? backup.config.vc_charge_end : backup.config.vc_charge_start;
return m_voltage_cell_min > backup.config.vc_charge_min &&
m_voltage_cell_max < max &&
(!backup.config.t_charge_mon_en || (HW_TEMP_CELLS_MAX() < backup.config.t_charge_max &&
HW_TEMP_CELLS_MAX() > backup.config.t_charge_min));
}
static THD_FUNCTION(charge_thd, p) {
(void)p;
chRegSetThreadName("Charge");
for (;;) {
#ifdef ADC_CH_CURRENT
float chg_current = m_i_in_filter;
#else
float chg_current = m_i_in_filter_ic;
#endif
if (m_is_charging && HW_TEMP_CELLS_MAX() >= backup.config.t_charge_max &&
backup.config.t_charge_mon_en) {
bms_if_fault_report(FAULT_CODE_CHARGE_OVERTEMP);
}
bms_soc_soh_temp_stat *msg;
bool chg_can_ok = true;
for (int i = 0;i < CAN_BMS_STATUS_MSGS_TO_STORE;i++) {
msg = comm_can_get_bms_soc_soh_temp_stat_index(i);
if (msg->id >= 0) {
if (!msg->is_charge_ok) {
chg_can_ok = false;
break;
}
} else {
break;
}
}
if (chg_can_ok && HW_GET_V_CHARGE() > backup.config.v_charge_detect &&
bms_if_charge_ok() && m_charge_allowed && !m_was_charge_overcurrent) {
if (!m_is_charging) {
sleep_reset();
chThdSleepMilliseconds(2000);
if (bms_if_charge_ok() && HW_GET_V_CHARGE() > backup.config.v_charge_detect) {
m_is_charging = true;
CHARGE_ENABLE();
}
}
} else {
m_is_charging = false;
CHARGE_DISABLE();
}
chThdSleepMilliseconds(10);
if (fabsf(chg_current) < backup.config.min_charge_current && m_is_charging && !HW_CHARGER_DETECTED()) {
m_no_charge_cnt++;
if (m_no_charge_cnt > 100) {
m_no_charge_cnt = 0;
m_is_charging = false;
CHARGE_DISABLE();
chThdSleepMilliseconds(5000);
}
} else {
m_no_charge_cnt = 0;
}
if (m_is_charging) {
if (fabsf(chg_current) > backup.config.max_charge_current) {
m_was_charge_overcurrent = true;
m_is_charging = false;
CHARGE_DISABLE();
bms_if_fault_report(FAULT_CODE_CHARGE_OVERCURRENT);
}
sleep_reset();
}
// Charger must be disconnected and reconnected on charge overcurrent events
if (m_was_charge_overcurrent && HW_GET_V_CHARGE() < backup.config.v_charge_detect) {
m_was_charge_overcurrent = false;
}
// Store data and counters to flash every time charger is disconnected
static bool charger_connected_last = false;
if (charger_connected_last && HW_GET_V_CHARGE() < backup.config.v_charge_detect) {
flash_helper_store_backup_data();
}
charger_connected_last = HW_GET_V_CHARGE() > backup.config.v_charge_detect;
}
}
static THD_FUNCTION(balance_thd, p) {
(void)p;
chRegSetThreadName("Balance");
systime_t last_charge_time = 0.0;
while (!chThdShouldTerminateX()) {
float v_min = 10.0;
float v_max = 0.0;
// Allow some time to start balancing after unplugging the charger. This is useful if it is unplugged
// while the current was so high that balancing was prevented.
float time_since_charge = 1000.0;
if (UTILS_AGE_S(0) > 1.0) {
if (m_is_charging) {
last_charge_time = chVTGetSystemTimeX();
}
time_since_charge = UTILS_AGE_S(last_charge_time);
}
switch (backup.config.balance_mode) {
case BALANCE_MODE_DISABLED:
m_bal_ok = false;
break;
case BALANCE_MODE_CHARGING_ONLY:
if (m_is_charging) {
m_bal_ok = true;
} else {
m_bal_ok = false;
}
break;
case BALANCE_MODE_DURING_AND_AFTER_CHARGING:
if (time_since_charge < 2.0) {
m_bal_ok = true;
}
break;
case BALANCE_MODE_ALWAYS:
m_bal_ok = true;
break;
}
for (int i = backup.config.cell_first_index;i <
(backup.config.cell_num + backup.config.cell_first_index);i++) {
if (ltc_last_cell_voltage(i) > v_max) {
v_max = ltc_last_cell_voltage(i);
}
if (ltc_last_cell_voltage(i) < v_min) {
v_min = ltc_last_cell_voltage(i);
}
}
m_voltage_cell_min = v_min;
m_voltage_cell_max = v_max;
m_is_balancing = false;
bool is_balance_override = false;
int bal_ch = 0;
for (int i = backup.config.cell_first_index;
i < (backup.config.cell_num + backup.config.cell_first_index);i++) {
if (m_balance_override[i] == 1) {
is_balance_override = true;
ltc_set_dsc(i, false);
} else if (m_balance_override[i] == 2) {
is_balance_override = true;
ltc_set_dsc(i, true);
bal_ch++;
m_is_balancing = true;
}
}
if (backup.config.dist_bal) {
bms_soc_soh_temp_stat *msg = comm_can_get_bms_stat_v_cell_min();
if (msg->id >= 0 && UTILS_AGE_S(msg->rx_time) < 10.0 && msg->v_cell_min < v_min) {
v_min = msg->v_cell_min;
}
}
if (v_min > backup.config.vc_balance_min &&
m_bal_ok &&
!is_balance_override &&
fabsf(bms_if_get_i_in_ic()) < backup.config.balance_max_current) {
bal_ch = 0;
for (int i = backup.config.cell_first_index;i <
(backup.config.cell_num + backup.config.cell_first_index);i++) {
float limit = ltc_get_dsc(i) ? backup.config.vc_balance_end : backup.config.vc_balance_start;
limit += v_min;
if (ltc_last_cell_voltage(i) >= limit) {
ltc_set_dsc(i, true);
bal_ch++;
m_is_balancing = true;
} else {
ltc_set_dsc(i, false);
}
}
}
float t_bal = HW_GET_BAL_TEMP();
float t_bal_start = backup.config.t_bal_lim_start;
float t_bal_end = backup.config.t_bal_lim_end;
int bal_ch_max = backup.config.max_bal_ch;
if (t_bal > (t_bal_end - 0.5)) {
bal_ch_max = 0;
} else if (t_bal > t_bal_start) {
bal_ch_max = utils_map_int(t_bal, t_bal_start, t_bal_end, bal_ch_max, 0);
}
// Limit number of simultaneous balancing channels by disabling
// balancing on the cells with the highest voltage.
while (bal_ch > bal_ch_max) {
float v_min = 100.0;
int v_min_cell = 0;
for (int i = backup.config.cell_first_index;i <
(backup.config.cell_num + backup.config.cell_first_index);i++) {
if (ltc_last_cell_voltage(i) < v_min && ltc_get_dsc(i)) {
v_min = ltc_last_cell_voltage(i);
v_min_cell = i;
}
}
ltc_set_dsc(v_min_cell, false);
bal_ch--;
}
if (m_is_balancing) {
sleep_reset();
} else {
m_bal_ok = false;
for (int i = 0;i < HW_CELLS_SERIES;i++) {
ltc_set_dsc(i, false);
}
}
timeout_feed_WDT(THREAD_BAL);
chThdSleepMilliseconds(50);
}
}
static THD_FUNCTION(if_thd, p) {
(void)p;
chRegSetThreadName("IfThd");
systime_t tick_last = chVTGetSystemTimeX();
chThdSleepMilliseconds(2000);
for(;;) {
float ltc_curr_adc = ltc_last_gpio_voltage(LTC_GPIO_CURR_MON) - 1.65;
#ifdef LTC_GPIO_CURR_MON_2
ltc_curr_adc += ltc_last_gpio_voltage(LTC_GPIO_CURR_MON_2) - 1.65;
#endif
#ifdef LTC_INVERT_CURRENT
ltc_curr_adc = -ltc_curr_adc;
#endif
float i_bms_ic = -(ltc_curr_adc + backup.ic_i_sens_v_ofs) *
(1.0 / HW_SHUNT_AMP_GAIN) * (1.0 / backup.config.ext_shunt_res) * IC_ISENSE_I_GAIN_CORR;
float i_adc = pwr_get_iin();
#ifdef LTC_GPIO_CURR_MON_2
if (ltc_last_gpio_voltage(LTC_GPIO_CURR_MON) <= 0.0 ||
ltc_last_gpio_voltage(LTC_GPIO_CURR_MON_2) < 0.0) {
i_bms_ic = 0.0;
}
#else
if (ltc_last_gpio_voltage(LTC_GPIO_CURR_MON) <= 0.0) {
i_bms_ic = 0.0;
}
#endif
if (backup.config.i_measure_mode == I_MEASURE_MODE_VESC) {
for (int i = 0;i < CAN_STATUS_MSGS_TO_STORE;i++) {
can_status_msg_4 *msg = comm_can_get_status_msg_4_index(i);
if (msg->id >= 0 && UTILS_AGE_S(msg->rx_time) < 2.0) {
i_bms_ic += msg->current_in;
}
}
}
UTILS_LP_FAST(m_i_in_filter, i_adc, I_IN_FILTER_CONST);
UTILS_LP_FAST(m_i_in_filter_ic, i_bms_ic, I_IN_FILTER_CONST_IC);
double time = (double)TIME_I2US(chVTTimeElapsedSinceX(tick_last)) *
(double)1.0e-6 * ((double)1.0 / (double)60.0) * ((double)1.0 / (double)60.0);
tick_last = chVTGetSystemTimeX();
if (fabsf(m_i_in_filter_ic) > backup.config.min_current_ah_wh_cnt) {
double d_ah = (double)bms_if_get_i_in_ic() * time;
double d_wh = (double)bms_if_get_i_in_ic() * (double)bms_if_get_v_tot() * time;
backup.ah_cnt += d_ah;
backup.wh_cnt += d_wh;
if (m_i_in_filter_ic > 0.0) {
backup.ah_cnt_dis_total += d_ah;
backup.wh_cnt_dis_total += d_wh;
} else {
backup.ah_cnt_chg_total -= d_ah;
backup.wh_cnt_chg_total -= d_wh;
}
}
if (fabsf(bms_if_get_i_in_ic()) > backup.config.min_current_sleep) {
sleep_reset();
}
float soc_now = utils_batt_liion_norm_v_to_capacity(utils_map(m_voltage_cell_min, 3.2, 4.2, 0.0, 1.0));
if (!m_soc_filter_init_done) {
m_soc_filter_init_done = true;
m_soc_filtered = soc_now;
} else {
UTILS_LP_FAST(m_soc_filtered, soc_now, backup.config.soc_filter_const);
}
// RED LED
if (m_was_charge_overcurrent) {
// Prevent sleeping to keep the charge input disabled (as long as the battery does not run too low)
if (bms_if_get_soc() > 0.3) {
sleep_reset();
}
// Blink out fault on red LED
static int blink = 0;
blink++;
if (blink > 200) {
blink = 0;
}
if (blink < 100) {
LED_ON(LINE_LED_RED);
} else {
LED_OFF(LINE_LED_RED);
}
} else {
if (m_is_balancing) {
LED_ON(LINE_LED_RED);
} else {
LED_OFF(LINE_LED_RED);
}
}
chThdSleepMilliseconds(1);
}
}
float bms_if_get_i_in(void) {
return m_i_in_filter;
}
float bms_if_get_i_in_ic(void) {
return m_i_in_filter_ic;
}
float bms_if_get_v_cell(int cell) {
return ltc_last_cell_voltage(cell);
}
float bms_if_get_v_cell_min(void) {
return m_voltage_cell_min;
}
float bms_if_get_v_cell_max(void) {
return m_voltage_cell_max;
}
float bms_if_get_v_tot(void) {
float ret = 0.0;
for (int i = backup.config.cell_first_index;i <
(backup.config.cell_num + backup.config.cell_first_index);i++) {
ret += bms_if_get_v_cell(i);
}
return ret;
}
float bms_if_get_v_charge(void) {
return HW_GET_V_CHARGE();
}
float bms_if_get_temp(int sensor) {
#ifdef HW_GET_TEMP
return HW_GET_TEMP(sensor);
#else
return pwr_get_temp(sensor);
#endif
}
float bms_if_get_temp_ic(void) {
return ltc_last_temp();
}
bool bms_if_is_balancing_cell(int cell) {
return ltc_get_dsc(cell);
}
double bms_if_get_ah_cnt(void) {
return backup.ah_cnt;
}
double bms_if_get_wh_cnt(void) {
return backup.wh_cnt;
}
double bms_if_get_ah_cnt_chg_total(void) {
return backup.ah_cnt_chg_total;
}
double bms_if_get_wh_cnt_chg_total(void) {
return backup.wh_cnt_chg_total;
}
double bms_if_get_ah_cnt_dis_total(void) {
return backup.ah_cnt_dis_total;
}
double bms_if_get_wh_cnt_dis_total(void) {
return backup.wh_cnt_dis_total;
}
bool bms_if_is_charge_allowed(void) {
return m_charge_allowed;
}
void bms_if_set_charge_allowed(bool allowed) {
m_charge_allowed = allowed;
if (allowed) {
m_no_charge_cnt = 0;
}
}
bool bms_if_is_charging(void) {
return m_is_charging;
}
bool bms_if_is_balancing(void) {
return m_is_balancing;
}
/**
* Override balancing.
*
* cell
* Cell number
*
* override
* Override setting.
* 0: Do not override balancing
* 1: Override and disable balancing on cell
* 2: Override and enable balancing on cell
*/
void bms_if_set_balance_override(int cell, int override) {
if (cell >= 0 && cell < HW_CELLS_SERIES) {
m_balance_override[cell] = override;
}
}
void bms_if_reset_counter_ah(void) {
backup.ah_cnt = 0.0;
}
void bms_if_reset_counter_wh(void) {
backup.wh_cnt = 0.0;
}
void bms_if_force_balance(bool bal_en) {
if (bal_en) {
m_bal_ok = true;
} else {
m_bal_ok = false;
for (int i = 0;i < HW_CELLS_SERIES;i++) {
ltc_set_dsc(i, false);
}
}
}
void bms_if_zero_current_offset(void) {
float ofs_avg = 0.0;
float samples = 0.0;
for (int i = 0;i < 20;i++) {
float ltc_curr_adc = ltc_last_gpio_voltage(LTC_GPIO_CURR_MON) - 1.65;
#ifdef LTC_GPIO_CURR_MON_2
ltc_curr_adc += ltc_last_gpio_voltage(LTC_GPIO_CURR_MON_2) - 1.65;
#endif
#ifdef LTC_INVERT_CURRENT
ltc_curr_adc = -ltc_curr_adc;
#endif
ofs_avg -= ltc_curr_adc;
samples += 1.0;
chThdSleepMilliseconds(100);
}
backup.ic_i_sens_v_ofs = ofs_avg / samples;
flash_helper_store_backup_data();
}
float bms_if_get_humsens_hum_pcb(void) {
#ifdef HDC1080_SDA_GPIO
return hdc1080_get_hum();
#elif defined(SHT30_SDA_GPIO)
return sht30_get_hum();
#elif defined(SHTC3_SDA_GPIO)
return shtc3_get_hum();
#elif defined(BME280_SDA_GPIO)
return bme280_if_get_hum();
#else
return 0.0;
#endif
}
float bms_if_get_humsens_temp_pcb(void) {
#ifdef HDC1080_SDA_GPIO
return hdc1080_get_temp();
#elif defined(SHT30_SDA_GPIO)
return sht30_get_temp();
#elif defined(SHTC3_SDA_GPIO)
return shtc3_get_temp();
#elif defined(BME280_SDA_GPIO)
return bme280_if_get_temp();
#else
return 0.0;
#endif
}
float bms_if_get_humsens_pres_pcb(void) {
#if defined(BME280_SDA_GPIO)
return bme280_if_get_pres();
#else
return 0.0;
#endif
}
float bms_if_get_humsens_hum_ext(void) {
#if defined(BME280_SDA_GPIO)
return bme280_if_get_hum();
#else
return sht30_get_hum();
#endif
}
float bms_if_get_humsens_temp_ext(void) {
#if defined(BME280_SDA_GPIO)
return bme280_if_get_temp();
#else
return sht30_get_temp();
#endif
}
float bms_if_get_soc(void) {
// TODO: Estimate and compensate for ESR
if (HW_SOC_OVERRIDE() >= 0.0) {
return HW_SOC_OVERRIDE();
} else {
return m_soc_filtered;
}
}
float bms_if_get_soh(void) {
// TODO!
return 1.0;
}
void bms_if_sleep(void) {
ltc_sleep();
}
void bms_if_fault_report(bms_fault_code fault) {
fault_data f;
f.fault = fault;
f.fault_time = chVTGetSystemTimeX();
f.current = bms_if_get_i_in();
f.current_ic = bms_if_get_i_in_ic();
f.temp_batt = HW_TEMP_CELLS_MAX();
f.temp_pcb = bms_if_get_temp(0);
f.temp_ic = bms_if_get_temp_ic();
f.v_cell_min = bms_if_get_v_cell_min();
f.v_cell_max = bms_if_get_v_cell_max();
f.pcb_humidity = bms_if_get_humsens_hum_pcb();
terminal_add_fault_data(&f);
if (m_fault_cb)
m_fault_cb(&f);
}
bms_fault_code bms_if_fault_now(void) {
bms_fault_code res = FAULT_CODE_NONE;
if (m_was_charge_overcurrent) {
res = FAULT_CODE_CHARGE_OVERCURRENT;
}
return res;
}
void bms_if_register_fault_cb(const bms_if_fault_cb cb)
{
m_fault_cb = cb;
}