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mc_interface.c
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mc_interface.c
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/*
Copyright 2016 - 2017 Benjamin Vedder [email protected]
Copyright 2017 Nico Ackermann added cruise control status and changed and added functions to handle the speed control based on the status,
changed acceleration and braking calculation
This file is part of the VESC firmware.
The VESC 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 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 "mc_interface.h"
#include "mcpwm.h"
#include "mcpwm_foc.h"
#include "ledpwm.h"
#include "stm32f4xx_conf.h"
#include "hw.h"
#include "terminal.h"
#include "utils.h"
#include "ch.h"
#include "hal.h"
#include "commands.h"
#include "encoder.h"
#include "drv8301.h"
#include "drv8320.h"
#include "buffer.h"
#include <math.h>
// Macros
#define DIR_MULT (m_conf.m_invert_direction ? -1.0 : 1.0)
// Global variables
volatile uint16_t ADC_Value[HW_ADC_CHANNELS];
volatile int ADC_curr_norm_value[3];
// Private variables
static volatile mc_configuration m_conf;
static mc_fault_code m_fault_now;
static int m_ignore_iterations;
static volatile unsigned int m_cycles_running;
static volatile bool m_lock_enabled;
static volatile bool m_lock_override_once;
static volatile float m_motor_current_sum;
static volatile float m_input_current_sum;
static volatile float m_motor_current_iterations;
static volatile float m_input_current_iterations;
static volatile float m_motor_id_sum;
static volatile float m_motor_iq_sum;
static volatile float m_motor_id_iterations;
static volatile float m_motor_iq_iterations;
static volatile float m_amp_seconds;
static volatile float m_amp_seconds_charged;
static volatile float m_watt_seconds;
static volatile float m_watt_seconds_charged;
static volatile float m_position_set;
static volatile float m_temp_fet;
static volatile float m_temp_motor;
// new
static volatile ppm_cruise cruise_control_status;
// Sampling variables
#define ADC_SAMPLE_MAX_LEN 2000
__attribute__((section(".ram4"))) static volatile int16_t m_curr0_samples[ADC_SAMPLE_MAX_LEN];
__attribute__((section(".ram4"))) static volatile int16_t m_curr1_samples[ADC_SAMPLE_MAX_LEN];
__attribute__((section(".ram4"))) static volatile int16_t m_ph1_samples[ADC_SAMPLE_MAX_LEN];
__attribute__((section(".ram4"))) static volatile int16_t m_ph2_samples[ADC_SAMPLE_MAX_LEN];
__attribute__((section(".ram4"))) static volatile int16_t m_ph3_samples[ADC_SAMPLE_MAX_LEN];
__attribute__((section(".ram4"))) static volatile int16_t m_vzero_samples[ADC_SAMPLE_MAX_LEN];
__attribute__((section(".ram4"))) static volatile uint8_t m_status_samples[ADC_SAMPLE_MAX_LEN];
__attribute__((section(".ram4"))) static volatile int16_t m_curr_fir_samples[ADC_SAMPLE_MAX_LEN];
__attribute__((section(".ram4"))) static volatile int16_t m_f_sw_samples[ADC_SAMPLE_MAX_LEN];
__attribute__((section(".ram4"))) static volatile int8_t m_phase_samples[ADC_SAMPLE_MAX_LEN];
static volatile int m_sample_len;
static volatile int m_sample_int;
static volatile debug_sampling_mode m_sample_mode;
static volatile debug_sampling_mode m_sample_mode_last;
static volatile int m_sample_now;
static volatile int m_sample_trigger;
static volatile float m_last_adc_duration_sample;
// Private functions
static void update_override_limits(volatile mc_configuration *conf);
// Function pointers
static void(*pwn_done_func)(void) = 0;
// Threads
static THD_WORKING_AREA(timer_thread_wa, 1024);
static THD_FUNCTION(timer_thread, arg);
static THD_WORKING_AREA(sample_send_thread_wa, 1024);
static THD_FUNCTION(sample_send_thread, arg);
static thread_t *sample_send_tp;
void mc_interface_init(mc_configuration *configuration) {
m_conf = *configuration;
m_fault_now = FAULT_CODE_NONE;
m_ignore_iterations = 0;
m_cycles_running = 0;
m_lock_enabled = false;
m_lock_override_once = false;
m_motor_current_sum = 0.0;
m_input_current_sum = 0.0;
m_motor_current_iterations = 0.0;
m_input_current_iterations = 0.0;
m_motor_id_sum = 0.0;
m_motor_iq_sum = 0.0;
m_motor_id_iterations = 0.0;
m_motor_iq_iterations = 0.0;
m_amp_seconds = 0.0;
m_amp_seconds_charged = 0.0;
m_watt_seconds = 0.0;
m_watt_seconds_charged = 0.0;
m_position_set = 0.0;
m_last_adc_duration_sample = 0.0;
m_temp_fet = 0.0;
m_temp_motor = 0.0;
cruise_control_status = CRUISE_CONTROL_INACTIVE;
m_sample_len = 1000;
m_sample_int = 1;
m_sample_now = 0;
m_sample_trigger = 0;
m_sample_mode = DEBUG_SAMPLING_OFF;
m_sample_mode_last = DEBUG_SAMPLING_OFF;
// Start threads
chThdCreateStatic(timer_thread_wa, sizeof(timer_thread_wa), NORMALPRIO, timer_thread, NULL);
chThdCreateStatic(sample_send_thread_wa, sizeof(sample_send_thread_wa), NORMALPRIO - 1, sample_send_thread, NULL);
#ifdef HW_HAS_DRV8301
drv8301_set_oc_mode(configuration->m_drv8301_oc_mode);
drv8301_set_oc_adj(configuration->m_drv8301_oc_adj);
#elif defined(HW_HAS_DRV8320)
drv8320_set_oc_mode(configuration->m_drv8301_oc_mode);
drv8320_set_oc_adj(configuration->m_drv8301_oc_adj);
#endif
// Initialize encoder
#if !WS2811_ENABLE
switch (m_conf.m_sensor_port_mode) {
case SENSOR_PORT_MODE_ABI:
encoder_init_abi(m_conf.m_encoder_counts);
break;
case SENSOR_PORT_MODE_AS5047_SPI:
encoder_init_as5047p_spi();
break;
default:
break;
}
#endif
// Initialize selected implementation
switch (m_conf.motor_type) {
case MOTOR_TYPE_BLDC:
case MOTOR_TYPE_DC:
mcpwm_init(&m_conf);
break;
case MOTOR_TYPE_FOC:
mcpwm_foc_init(&m_conf);
break;
default:
break;
}
}
const volatile mc_configuration* mc_interface_get_configuration(void) {
return &m_conf;
}
void mc_interface_set_configuration(mc_configuration *configuration) {
#if !WS2811_ENABLE
if (m_conf.m_sensor_port_mode != configuration->m_sensor_port_mode) {
encoder_deinit();
switch (configuration->m_sensor_port_mode) {
case SENSOR_PORT_MODE_ABI:
encoder_init_abi(configuration->m_encoder_counts);
break;
case SENSOR_PORT_MODE_AS5047_SPI:
encoder_init_as5047p_spi();
break;
default:
break;
}
}
if (configuration->m_sensor_port_mode == SENSOR_PORT_MODE_ABI) {
encoder_set_counts(configuration->m_encoder_counts);
}
#endif
#ifdef HW_HAS_DRV8301
drv8301_set_oc_mode(configuration->m_drv8301_oc_mode);
drv8301_set_oc_adj(configuration->m_drv8301_oc_adj);
#elif defined(HW_HAS_DRV8320)
drv8320_set_oc_mode(configuration->m_drv8301_oc_mode);
drv8320_set_oc_adj(configuration->m_drv8301_oc_adj);
#endif
if (m_conf.motor_type == MOTOR_TYPE_FOC
&& configuration->motor_type != MOTOR_TYPE_FOC) {
mcpwm_foc_deinit();
m_conf = *configuration;
mcpwm_init(&m_conf);
} else if (m_conf.motor_type != MOTOR_TYPE_FOC
&& configuration->motor_type == MOTOR_TYPE_FOC) {
mcpwm_deinit();
m_conf = *configuration;
mcpwm_foc_init(&m_conf);
} else {
m_conf = *configuration;
}
update_override_limits(&m_conf);
switch (m_conf.motor_type) {
case MOTOR_TYPE_BLDC:
case MOTOR_TYPE_DC:
mcpwm_set_configuration(&m_conf);
break;
case MOTOR_TYPE_FOC:
mcpwm_foc_set_configuration(&m_conf);
break;
default:
break;
}
}
bool mc_interface_dccal_done(void) {
bool ret = false;
switch (m_conf.motor_type) {
case MOTOR_TYPE_BLDC:
case MOTOR_TYPE_DC:
ret = mcpwm_is_dccal_done();
break;
case MOTOR_TYPE_FOC:
ret = mcpwm_foc_is_dccal_done();
break;
default:
break;
}
return ret;
}
/**
* Set a function that should be called after each PWM cycle.
*
* @param p_func
* The function to be called. 0 will not call any function.
*/
void mc_interface_set_pwm_callback(void (*p_func)(void)) {
pwn_done_func = p_func;
}
/**
* Lock the control by disabling all control commands.
*/
void mc_interface_lock(void) {
m_lock_enabled = true;
}
/**
* Unlock all control commands.
*/
void mc_interface_unlock(void) {
m_lock_enabled = false;
}
/**
* Allow just one motor control command in the locked state.
*/
void mc_interface_lock_override_once(void) {
m_lock_override_once = true;
}
mc_fault_code mc_interface_get_fault(void) {
return m_fault_now;
}
const char* mc_interface_fault_to_string(mc_fault_code fault) {
switch (fault) {
case FAULT_CODE_NONE: return "FAULT_CODE_NONE"; break;
case FAULT_CODE_OVER_VOLTAGE: return "FAULT_CODE_OVER_VOLTAGE"; break;
case FAULT_CODE_UNDER_VOLTAGE: return "FAULT_CODE_UNDER_VOLTAGE"; break;
case FAULT_CODE_DRV: return "FAULT_CODE_DRV"; break;
case FAULT_CODE_ABS_OVER_CURRENT: return "FAULT_CODE_ABS_OVER_CURRENT"; break;
case FAULT_CODE_OVER_TEMP_FET: return "FAULT_CODE_OVER_TEMP_FET"; break;
case FAULT_CODE_OVER_TEMP_MOTOR: return "FAULT_CODE_OVER_TEMP_MOTOR"; break;
default: return "FAULT_UNKNOWN"; break;
}
}
mc_state mc_interface_get_state(void) {
mc_state ret = MC_STATE_OFF;
switch (m_conf.motor_type) {
case MOTOR_TYPE_BLDC:
case MOTOR_TYPE_DC:
ret = mcpwm_get_state();
break;
case MOTOR_TYPE_FOC:
ret = mcpwm_foc_get_state();
break;
default:
break;
}
return ret;
}
void mc_interface_set_duty(float dutyCycle) {
if (mc_interface_try_input()) {
return;
}
switch (m_conf.motor_type) {
case MOTOR_TYPE_BLDC:
case MOTOR_TYPE_DC:
mcpwm_set_duty(DIR_MULT * dutyCycle);
break;
case MOTOR_TYPE_FOC:
mcpwm_foc_set_duty(DIR_MULT * dutyCycle);
break;
default:
break;
}
}
void mc_interface_set_duty_noramp(float dutyCycle) {
if (mc_interface_try_input()) {
return;
}
switch (m_conf.motor_type) {
case MOTOR_TYPE_BLDC:
case MOTOR_TYPE_DC:
mcpwm_set_duty_noramp(DIR_MULT * dutyCycle);
break;
case MOTOR_TYPE_FOC:
mcpwm_foc_set_duty_noramp(DIR_MULT * dutyCycle);
break;
default:
break;
}
}
void mc_interface_set_pid_speed(float rpm) {
if (mc_interface_try_input()) {
return;
}
switch (m_conf.motor_type) {
case MOTOR_TYPE_BLDC:
case MOTOR_TYPE_DC:
mcpwm_set_pid_speed(DIR_MULT * rpm);
break;
case MOTOR_TYPE_FOC:
mcpwm_foc_set_pid_speed(DIR_MULT * rpm);
break;
default:
break;
}
}
void mc_interface_set_pid_speed_with_cruise_status(float rpm, ppm_cruise cruise_status) {
if (mc_interface_try_input()) {
return;
}
switch (m_conf.motor_type) {
case MOTOR_TYPE_BLDC:
case MOTOR_TYPE_DC:
mcpwm_set_pid_speed_with_cruise_status(DIR_MULT * rpm, cruise_status);
break;
case MOTOR_TYPE_FOC:
mcpwm_foc_set_pid_speed_with_cruise_status(DIR_MULT * rpm, cruise_status);
break;
default:
break;
}
}
ppm_cruise mc_interface_get_cruise_control_status(void){
return cruise_control_status;
}
// true = active false = inactive
void mc_interface_set_cruise_control_status(ppm_cruise status){
cruise_control_status = status;
}
void mc_interface_set_pid_pos(float pos) {
if (mc_interface_try_input()) {
return;
}
m_position_set = pos;
pos *= DIR_MULT;
utils_norm_angle(&pos);
switch (m_conf.motor_type) {
case MOTOR_TYPE_BLDC:
case MOTOR_TYPE_DC:
mcpwm_set_pid_pos(pos);
break;
case MOTOR_TYPE_FOC:
mcpwm_foc_set_pid_pos(pos);
break;
default:
break;
}
}
void mc_interface_set_current(float current) {
if (mc_interface_try_input()) {
return;
}
switch (m_conf.motor_type) {
case MOTOR_TYPE_BLDC:
case MOTOR_TYPE_DC:
mcpwm_set_current(DIR_MULT * current);
break;
case MOTOR_TYPE_FOC:
mcpwm_foc_set_current(DIR_MULT * current);
break;
default:
break;
}
}
void mc_interface_set_brake_current(float current) {
if (mc_interface_try_input()) {
return;
}
switch (m_conf.motor_type) {
case MOTOR_TYPE_BLDC:
case MOTOR_TYPE_DC:
mcpwm_set_brake_current(DIR_MULT * current);
break;
case MOTOR_TYPE_FOC:
mcpwm_foc_set_brake_current(DIR_MULT * current);
break;
default:
break;
}
}
/**
* Set current relative to the minimum and maximum current limits.
*
* @param current
* The relative current value, range [-1.0 1.0]
*/
void mc_interface_set_current_rel(float val) {
if (val > 0.0) {
mc_interface_set_current(val * m_conf.lo_current_motor_max_now);
} else {
mc_interface_set_current(val * fabsf(m_conf.lo_current_motor_min_now));
}
}
/**
* Set brake current relative to the minimum current limit.
*
* @param current
* The relative current value, range [0.0 1.0]
*/
void mc_interface_set_brake_current_rel(float val) {
mc_interface_set_brake_current(val * m_conf.lo_current_motor_min_now);
}
/**
* Set open loop current vector to brake motor.
*
* @param current
* The current value.
*/
void mc_interface_set_handbrake(float current) {
if (mc_interface_try_input()) {
return;
}
switch (m_conf.motor_type) {
case MOTOR_TYPE_BLDC:
case MOTOR_TYPE_DC:
// TODO: Not implemented yet, use brake mode for now.
mcpwm_set_brake_current(current);
break;
case MOTOR_TYPE_FOC:
mcpwm_foc_set_handbrake(current);
break;
default:
break;
}
}
/**
* Set handbrake brake current relative to the minimum current limit.
*
* @param current
* The relative current value, range [0.0 1.0]
*/
void mc_interface_set_handbrake_rel(float val) {
mc_interface_set_handbrake(val * fabsf(m_conf.lo_current_motor_min_now));
}
void mc_interface_brake_now(void) {
mc_interface_set_duty(0.0);
}
/**
* Disconnect the motor and let it turn freely.
*/
void mc_interface_release_motor(void) {
mc_interface_set_current(0.0);
}
/**
* Stop the motor and use braking.
*/
float mc_interface_get_duty_cycle_set(void) {
float ret = 0.0;
switch (m_conf.motor_type) {
case MOTOR_TYPE_BLDC:
case MOTOR_TYPE_DC:
ret = mcpwm_get_duty_cycle_set();
break;
case MOTOR_TYPE_FOC:
ret = mcpwm_foc_get_duty_cycle_set();
break;
default:
break;
}
return DIR_MULT * ret;
}
float mc_interface_get_duty_cycle_now(void) {
float ret = 0.0;
switch (m_conf.motor_type) {
case MOTOR_TYPE_BLDC:
case MOTOR_TYPE_DC:
ret = mcpwm_get_duty_cycle_now();
break;
case MOTOR_TYPE_FOC:
ret = mcpwm_foc_get_duty_cycle_now();
break;
default:
break;
}
return DIR_MULT * ret;
}
float mc_interface_get_sampling_frequency_now(void) {
float ret = 0.0;
switch (m_conf.motor_type) {
case MOTOR_TYPE_BLDC:
case MOTOR_TYPE_DC:
ret = mcpwm_get_switching_frequency_now();
break;
case MOTOR_TYPE_FOC:
ret = mcpwm_foc_get_sampling_frequency_now();
break;
default:
break;
}
return ret;
}
float mc_interface_get_rpm(void) {
float ret = 0.0;
switch (m_conf.motor_type) {
case MOTOR_TYPE_BLDC:
case MOTOR_TYPE_DC:
ret = mcpwm_get_rpm();
break;
case MOTOR_TYPE_FOC:
ret = mcpwm_foc_get_rpm();
break;
default:
break;
}
return DIR_MULT * ret;
}
/**
* Get the amount of amp hours drawn from the input source.
*
* @param reset
* If true, the counter will be reset after this call.
*
* @return
* The amount of amp hours drawn.
*/
float mc_interface_get_amp_hours(bool reset) {
float val = m_amp_seconds / 3600;
if (reset) {
m_amp_seconds = 0.0;
}
return val;
}
/**
* Get the amount of amp hours fed back into the input source.
*
* @param reset
* If true, the counter will be reset after this call.
*
* @return
* The amount of amp hours fed back.
*/
float mc_interface_get_amp_hours_charged(bool reset) {
float val = m_amp_seconds_charged / 3600;
if (reset) {
m_amp_seconds_charged = 0.0;
}
return val;
}
/**
* Get the amount of watt hours drawn from the input source.
*
* @param reset
* If true, the counter will be reset after this call.
*
* @return
* The amount of watt hours drawn.
*/
float mc_interface_get_watt_hours(bool reset) {
float val = m_watt_seconds / 3600;
if (reset) {
m_watt_seconds = 0.0;
}
return val;
}
/**
* Get the amount of watt hours fed back into the input source.
*
* @param reset
* If true, the counter will be reset after this call.
*
* @return
* The amount of watt hours fed back.
*/
float mc_interface_get_watt_hours_charged(bool reset) {
float val = m_watt_seconds_charged / 3600;
if (reset) {
m_watt_seconds_charged = 0.0;
}
return val;
}
float mc_interface_get_tot_current(void) {
float ret = 0.0;
switch (m_conf.motor_type) {
case MOTOR_TYPE_BLDC:
case MOTOR_TYPE_DC:
ret = mcpwm_get_tot_current();
break;
case MOTOR_TYPE_FOC:
ret = mcpwm_foc_get_tot_current();
break;
default:
break;
}
return ret;
}
float mc_interface_get_tot_current_filtered(void) {
float ret = 0.0;
switch (m_conf.motor_type) {
case MOTOR_TYPE_BLDC:
case MOTOR_TYPE_DC:
ret = mcpwm_get_tot_current_filtered();
break;
case MOTOR_TYPE_FOC:
ret = mcpwm_foc_get_tot_current_filtered();
break;
default:
break;
}
return ret;
}
float mc_interface_get_tot_current_directional(void) {
float ret = 0.0;
switch (m_conf.motor_type) {
case MOTOR_TYPE_BLDC:
case MOTOR_TYPE_DC:
ret = mcpwm_get_tot_current_directional();
break;
case MOTOR_TYPE_FOC:
ret = mcpwm_foc_get_tot_current_directional();
break;
default:
break;
}
return DIR_MULT * ret;
}
float mc_interface_get_tot_current_directional_filtered(void) {
float ret = 0.0;
switch (m_conf.motor_type) {
case MOTOR_TYPE_BLDC:
case MOTOR_TYPE_DC:
ret = mcpwm_get_tot_current_directional_filtered();
break;
case MOTOR_TYPE_FOC:
ret = mcpwm_foc_get_tot_current_directional_filtered();
break;
default:
break;
}
return DIR_MULT * ret;
}
float mc_interface_get_tot_current_in(void) {
float ret = 0.0;
switch (m_conf.motor_type) {
case MOTOR_TYPE_BLDC:
case MOTOR_TYPE_DC:
ret = mcpwm_get_tot_current_in();
break;
case MOTOR_TYPE_FOC:
ret = mcpwm_foc_get_tot_current_in();
break;
default:
break;
}
return ret;
}
float mc_interface_get_tot_current_in_filtered(void) {
float ret = 0.0;
switch (m_conf.motor_type) {
case MOTOR_TYPE_BLDC:
case MOTOR_TYPE_DC:
ret = mcpwm_get_tot_current_in_filtered();
break;
case MOTOR_TYPE_FOC:
ret = mcpwm_foc_get_tot_current_in_filtered();
break;
default:
break;
}
return ret;
}
int mc_interface_get_tachometer_value(bool reset) {
int ret = 0;
switch (m_conf.motor_type) {
case MOTOR_TYPE_BLDC:
case MOTOR_TYPE_DC:
ret = mcpwm_get_tachometer_value(reset);
break;
case MOTOR_TYPE_FOC:
ret = mcpwm_foc_get_tachometer_value(reset);
break;
default:
break;
}
return DIR_MULT * ret;
}
int mc_interface_get_tachometer_abs_value(bool reset) {
int ret = 0;
switch (m_conf.motor_type) {
case MOTOR_TYPE_BLDC:
case MOTOR_TYPE_DC:
ret = mcpwm_get_tachometer_abs_value(reset);
break;
case MOTOR_TYPE_FOC:
ret = mcpwm_foc_get_tachometer_abs_value(reset);
break;
default:
break;
}
return ret;
}
float mc_interface_get_last_inj_adc_isr_duration(void) {
float ret = 0.0;
switch (m_conf.motor_type) {
case MOTOR_TYPE_BLDC:
case MOTOR_TYPE_DC:
ret = mcpwm_get_last_inj_adc_isr_duration();
break;
case MOTOR_TYPE_FOC:
ret = mcpwm_foc_get_last_inj_adc_isr_duration();
break;
default:
break;
}
return ret;
}
float mc_interface_read_reset_avg_motor_current(void) {
float res = m_motor_current_sum / m_motor_current_iterations;
m_motor_current_sum = 0.0;
m_motor_current_iterations = 0.0;
return res;
}
float mc_interface_read_reset_avg_input_current(void) {
float res = m_input_current_sum / m_input_current_iterations;
m_input_current_sum = 0.0;
m_input_current_iterations = 0.0;
return res;
}
/**
* Read and reset the average direct axis motor current. (FOC only)
*
* @return
* The average D axis current.
*/
float mc_interface_read_reset_avg_id(void) {
float res = m_motor_id_sum / m_motor_id_iterations;
m_motor_id_sum = 0.0;
m_motor_id_iterations = 0.0;
return DIR_MULT * res; // TODO: DIR_MULT?
}
/**
* Read and reset the average quadrature axis motor current. (FOC only)
*
* @return
* The average Q axis current.
*/
float mc_interface_read_reset_avg_iq(void) {
float res = m_motor_iq_sum / m_motor_iq_iterations;
m_motor_iq_sum = 0.0;
m_motor_iq_iterations = 0.0;
return DIR_MULT * res;
}
float mc_interface_get_pid_pos_set(void) {
return m_position_set;
}
float mc_interface_get_pid_pos_now(void) {
float ret = 0.0;
switch (m_conf.motor_type) {
case MOTOR_TYPE_BLDC:
case MOTOR_TYPE_DC:
ret = encoder_read_deg();
break;
case MOTOR_TYPE_FOC:
ret = mcpwm_foc_get_pid_pos_now();
break;
default:
break;
}
ret *= DIR_MULT;
utils_norm_angle(&ret);
return ret;
}
float mc_interface_get_last_sample_adc_isr_duration(void) {
return m_last_adc_duration_sample;
}
void mc_interface_sample_print_data(debug_sampling_mode mode, uint16_t len, uint8_t decimation) {
if (len > ADC_SAMPLE_MAX_LEN) {
len = ADC_SAMPLE_MAX_LEN;
}
if (mode == DEBUG_SAMPLING_SEND_LAST_SAMPLES) {
chEvtSignal(sample_send_tp, (eventmask_t) 1);
} else {
m_sample_trigger = -1;
m_sample_now = 0;
m_sample_len = len;
m_sample_int = decimation;
m_sample_mode = mode;
}
}
/**
* Get filtered MOSFET temperature. The temperature is pre-calculated, so this
* functions is fast.
*
* @return
* The filtered MOSFET temperature.
*/
float mc_interface_temp_fet_filtered(void) {
return m_temp_fet;
}
/**
* Get filtered motor temperature. The temperature is pre-calculated, so this
* functions is fast.
*
* @return
* The filtered motor temperature.