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Thor300 firmware - official from Fajdiga 

make Thor300_20s to build

Signed-off-by: Dado Mista <dadomista@gmail.com>
This commit is contained in:
Dado Mista 2023-07-17 07:25:10 -07:00
parent a9a1faf317
commit 85d9c39b49
3 changed files with 543 additions and 0 deletions
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286
hwconf/fungineers/hw_Thor300_20s.c Normal file
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/*
Copyright 2022 Benjamin Vedder benjamin@vedder.se
This program 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.
This program 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 "hw.h"
#include "ch.h"
#include "hal.h"
#include "stm32f4xx_conf.h"
#include "utils_math.h"
#include <math.h>
#include "mc_interface.h"
// Variables
static volatile bool i2c_running = false;
static mutex_t shutdown_mutex;
static float bt_diff = 0.0;
static int pressed_time = 0;
// I2C configuration
static const I2CConfig i2cfg = {
OPMODE_I2C,
100000,
STD_DUTY_CYCLE
};
void hw_init_gpio(void) {
chMtxObjectInit(&shutdown_mutex);
// GPIO clock enable
RCC_AHB1PeriphClockCmd(RCC_AHB1Periph_GPIOA, ENABLE);
RCC_AHB1PeriphClockCmd(RCC_AHB1Periph_GPIOB, ENABLE);
RCC_AHB1PeriphClockCmd(RCC_AHB1Periph_GPIOC, ENABLE);
RCC_AHB1PeriphClockCmd(RCC_AHB1Periph_GPIOD, ENABLE);
// LEDs
palSetPadMode(LED_GREEN_GPIO, LED_GREEN_PIN,
PAL_MODE_OUTPUT_PUSHPULL |
PAL_STM32_OSPEED_HIGHEST);
palSetPadMode(LED_RED_GPIO, LED_RED_PIN,
PAL_MODE_OUTPUT_PUSHPULL |
PAL_STM32_OSPEED_HIGHEST);
// GPIOA Configuration: Channel 1 to 3 as alternate function push-pull
palSetPadMode(GPIOA, 8, PAL_MODE_ALTERNATE(GPIO_AF_TIM1) |
PAL_STM32_OSPEED_HIGHEST |
PAL_STM32_PUDR_FLOATING);
palSetPadMode(GPIOA, 9, PAL_MODE_ALTERNATE(GPIO_AF_TIM1) |
PAL_STM32_OSPEED_HIGHEST |
PAL_STM32_PUDR_FLOATING);
palSetPadMode(GPIOA, 10, PAL_MODE_ALTERNATE(GPIO_AF_TIM1) |
PAL_STM32_OSPEED_HIGHEST |
PAL_STM32_PUDR_FLOATING);
palSetPadMode(GPIOB, 13, PAL_MODE_ALTERNATE(GPIO_AF_TIM1) |
PAL_STM32_OSPEED_HIGHEST |
PAL_STM32_PUDR_FLOATING);
palSetPadMode(GPIOB, 14, PAL_MODE_ALTERNATE(GPIO_AF_TIM1) |
PAL_STM32_OSPEED_HIGHEST |
PAL_STM32_PUDR_FLOATING);
palSetPadMode(GPIOB, 15, PAL_MODE_ALTERNATE(GPIO_AF_TIM1) |
PAL_STM32_OSPEED_HIGHEST |
PAL_STM32_PUDR_FLOATING);
// Hall sensors
palSetPadMode(HW_HALL_ENC_GPIO1, HW_HALL_ENC_PIN1, PAL_MODE_INPUT_PULLUP);
palSetPadMode(HW_HALL_ENC_GPIO2, HW_HALL_ENC_PIN2, PAL_MODE_INPUT_PULLUP);
palSetPadMode(HW_HALL_ENC_GPIO3, HW_HALL_ENC_PIN3, PAL_MODE_INPUT_PULLUP);
// Phase filters
palSetPadMode(GPIOC, 15, PAL_MODE_OUTPUT_OPENDRAIN);
palSetPadMode(GPIOC, 14, PAL_MODE_OUTPUT_OPENDRAIN);
palSetPadMode(GPIOC, 13, PAL_MODE_OUTPUT_OPENDRAIN);
PHASE_FILTER_OFF();
// ShutDown
palSetPadMode(HW_SHUTDOWN_GPIO, HW_SHUTDOWN_PIN, PAL_MODE_OUTPUT_OPENDRAIN);
palSetPadMode(HW_SHUTDOWN_SENSE_GPIO, HW_SHUTDOWN_SENSE_PIN, PAL_MODE_INPUT_ANALOG);
// ADC Pins
palSetPadMode(GPIOA, 0, PAL_MODE_INPUT_ANALOG);
palSetPadMode(GPIOA, 1, PAL_MODE_INPUT_ANALOG);
palSetPadMode(GPIOA, 2, PAL_MODE_INPUT_ANALOG);
palSetPadMode(GPIOA, 3, PAL_MODE_INPUT_ANALOG);
palSetPadMode(GPIOA, 5, PAL_MODE_INPUT_ANALOG);
palSetPadMode(GPIOA, 6, PAL_MODE_INPUT_ANALOG);
palSetPadMode(GPIOB, 0, PAL_MODE_INPUT_ANALOG);
palSetPadMode(GPIOB, 1, PAL_MODE_INPUT_ANALOG);
palSetPadMode(GPIOC, 0, PAL_MODE_INPUT_ANALOG);
palSetPadMode(GPIOC, 1, PAL_MODE_INPUT_ANALOG);
palSetPadMode(GPIOC, 2, PAL_MODE_INPUT_ANALOG);
palSetPadMode(GPIOC, 3, PAL_MODE_INPUT_ANALOG);
palSetPadMode(GPIOC, 4, PAL_MODE_INPUT_ANALOG);
palSetPadMode(GPIOC, 5, PAL_MODE_INPUT_ANALOG);
}
void hw_setup_adc_channels(void) {
// ADC1 regular channels
ADC_RegularChannelConfig(ADC1, ADC_Channel_10, 1, ADC_SampleTime_15Cycles);
ADC_RegularChannelConfig(ADC1, ADC_Channel_0, 2, ADC_SampleTime_15Cycles);
ADC_RegularChannelConfig(ADC1, ADC_Channel_5, 3, ADC_SampleTime_15Cycles);
ADC_RegularChannelConfig(ADC1, ADC_Channel_14, 4, ADC_SampleTime_15Cycles);
ADC_RegularChannelConfig(ADC1, ADC_Channel_Vrefint, 5, ADC_SampleTime_15Cycles);
ADC_RegularChannelConfig(ADC1, ADC_Channel_8, 6, ADC_SampleTime_15Cycles);
// ADC2 regular channels
ADC_RegularChannelConfig(ADC2, ADC_Channel_11, 1, ADC_SampleTime_15Cycles);
ADC_RegularChannelConfig(ADC2, ADC_Channel_1, 2, ADC_SampleTime_15Cycles);
ADC_RegularChannelConfig(ADC2, ADC_Channel_6, 3, ADC_SampleTime_15Cycles);
ADC_RegularChannelConfig(ADC2, ADC_Channel_15, 4, ADC_SampleTime_15Cycles);
ADC_RegularChannelConfig(ADC2, ADC_Channel_0, 5, ADC_SampleTime_15Cycles);
ADC_RegularChannelConfig(ADC2, ADC_Channel_9, 6, ADC_SampleTime_15Cycles);
// ADC3 regular channels
ADC_RegularChannelConfig(ADC3, ADC_Channel_12, 1, ADC_SampleTime_15Cycles);
ADC_RegularChannelConfig(ADC3, ADC_Channel_2, 2, ADC_SampleTime_15Cycles);
ADC_RegularChannelConfig(ADC3, ADC_Channel_3, 3, ADC_SampleTime_15Cycles);
ADC_RegularChannelConfig(ADC3, ADC_Channel_13, 4, ADC_SampleTime_15Cycles);
ADC_RegularChannelConfig(ADC3, ADC_Channel_1, 5, ADC_SampleTime_15Cycles);
ADC_RegularChannelConfig(ADC3, ADC_Channel_2, 6, ADC_SampleTime_15Cycles);
// Injected channels
ADC_InjectedChannelConfig(ADC1, ADC_Channel_10, 1, ADC_SampleTime_15Cycles);
ADC_InjectedChannelConfig(ADC2, ADC_Channel_11, 1, ADC_SampleTime_15Cycles);
ADC_InjectedChannelConfig(ADC3, ADC_Channel_12, 1, ADC_SampleTime_15Cycles);
ADC_InjectedChannelConfig(ADC1, ADC_Channel_10, 2, ADC_SampleTime_15Cycles);
ADC_InjectedChannelConfig(ADC2, ADC_Channel_11, 2, ADC_SampleTime_15Cycles);
ADC_InjectedChannelConfig(ADC3, ADC_Channel_12, 2, ADC_SampleTime_15Cycles);
ADC_InjectedChannelConfig(ADC1, ADC_Channel_10, 3, ADC_SampleTime_15Cycles);
ADC_InjectedChannelConfig(ADC2, ADC_Channel_11, 3, ADC_SampleTime_15Cycles);
ADC_InjectedChannelConfig(ADC3, ADC_Channel_12, 3, ADC_SampleTime_15Cycles);
}
void hw_start_i2c(void) {
i2cAcquireBus(&HW_I2C_DEV);
if (!i2c_running) {
palSetPadMode(HW_I2C_SCL_PORT, HW_I2C_SCL_PIN,
PAL_MODE_ALTERNATE(HW_I2C_GPIO_AF) |
PAL_STM32_OTYPE_OPENDRAIN |
PAL_STM32_OSPEED_MID1 |
PAL_STM32_PUDR_PULLUP);
palSetPadMode(HW_I2C_SDA_PORT, HW_I2C_SDA_PIN,
PAL_MODE_ALTERNATE(HW_I2C_GPIO_AF) |
PAL_STM32_OTYPE_OPENDRAIN |
PAL_STM32_OSPEED_MID1 |
PAL_STM32_PUDR_PULLUP);
i2cStart(&HW_I2C_DEV, &i2cfg);
i2c_running = true;
}
i2cReleaseBus(&HW_I2C_DEV);
}
void hw_stop_i2c(void) {
i2cAcquireBus(&HW_I2C_DEV);
if (i2c_running) {
palSetPadMode(HW_I2C_SCL_PORT, HW_I2C_SCL_PIN, PAL_MODE_INPUT);
palSetPadMode(HW_I2C_SDA_PORT, HW_I2C_SDA_PIN, PAL_MODE_INPUT);
i2cStop(&HW_I2C_DEV);
i2c_running = false;
}
i2cReleaseBus(&HW_I2C_DEV);
}
/**
* Try to restore the i2c bus
*/
void hw_try_restore_i2c(void) {
if (i2c_running) {
i2cAcquireBus(&HW_I2C_DEV);
palSetPadMode(HW_I2C_SCL_PORT, HW_I2C_SCL_PIN,
PAL_STM32_OTYPE_OPENDRAIN |
PAL_STM32_OSPEED_MID1 |
PAL_STM32_PUDR_PULLUP);
palSetPadMode(HW_I2C_SDA_PORT, HW_I2C_SDA_PIN,
PAL_STM32_OTYPE_OPENDRAIN |
PAL_STM32_OSPEED_MID1 |
PAL_STM32_PUDR_PULLUP);
palSetPad(HW_I2C_SCL_PORT, HW_I2C_SCL_PIN);
palSetPad(HW_I2C_SDA_PORT, HW_I2C_SDA_PIN);
chThdSleep(1);
for(int i = 0;i < 16;i++) {
palClearPad(HW_I2C_SCL_PORT, HW_I2C_SCL_PIN);
chThdSleep(1);
palSetPad(HW_I2C_SCL_PORT, HW_I2C_SCL_PIN);
chThdSleep(1);
}
// Generate start then stop condition
palClearPad(HW_I2C_SDA_PORT, HW_I2C_SDA_PIN);
chThdSleep(1);
palClearPad(HW_I2C_SCL_PORT, HW_I2C_SCL_PIN);
chThdSleep(1);
palSetPad(HW_I2C_SCL_PORT, HW_I2C_SCL_PIN);
chThdSleep(1);
palSetPad(HW_I2C_SDA_PORT, HW_I2C_SDA_PIN);
palSetPadMode(HW_I2C_SCL_PORT, HW_I2C_SCL_PIN,
PAL_MODE_ALTERNATE(HW_I2C_GPIO_AF) |
PAL_STM32_OTYPE_OPENDRAIN |
PAL_STM32_OSPEED_MID1 |
PAL_STM32_PUDR_PULLUP);
palSetPadMode(HW_I2C_SDA_PORT, HW_I2C_SDA_PIN,
PAL_MODE_ALTERNATE(HW_I2C_GPIO_AF) |
PAL_STM32_OTYPE_OPENDRAIN |
PAL_STM32_OSPEED_MID1 |
PAL_STM32_PUDR_PULLUP);
HW_I2C_DEV.state = I2C_STOP;
i2cStart(&HW_I2C_DEV, &i2cfg);
i2cReleaseBus(&HW_I2C_DEV);
}
}
bool hw_sample_shutdown_button(void) {
chMtxLock(&shutdown_mutex);
bt_diff = (ADC_VOLTS(ADC_IND_SHUTDOWN));
bt_diff = (bt_diff + ADC_VOLTS(ADC_IND_SHUTDOWN))/2;
chThdSleep(1);
bt_diff = (bt_diff + ADC_VOLTS(ADC_IND_SHUTDOWN))/2;
chThdSleep(1);
bt_diff = (bt_diff + ADC_VOLTS(ADC_IND_SHUTDOWN))/2;
chMtxUnlock(&shutdown_mutex);
if(bt_diff > 2.25){
pressed_time += 12;
return true;
}else{
if(pressed_time > 1000){
pressed_time = 0;
return false;
}else{
pressed_time = 0;
return true;
}
}
return pressed_time < 1000 ;
}
float hw_Thor_get_temp(void) {
float t1 = (1.0 / ((logf(NTC_RES(ADC_Value[ADC_IND_TEMP_MOS]) / 10000.0) / 3380.0) + (1.0 / 298.15)) - 273.15);
float t3 = (1.0 / ((logf(NTC_RES(ADC_Value[ADC_IND_TEMP_MOS_3]) / 10000.0) / 3380.0) + (1.0 / 298.15)) - 273.15);
float res = 0.0;
if (t1 >= t3) {
res = t1;
} else {
res = t3;
}
return res;
}

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hwconf/fungineers/hw_Thor300_20s.h Normal file
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/*
Copyright 2022 Benjamin Vedder benjamin@vedder.se
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/>.
*/
#ifndef HW_Thor300_20s_H_
#define HW_Thor300_20s_H_
#define HW_NAME "Thor300"
// HW properties
#define HW_HAS_3_SHUNTS
#define HW_HAS_PHASE_FILTERS
#define INVERTED_SHUNT_POLARITY
// Macros
#define LED_GREEN_GPIO GPIOB
#define LED_GREEN_PIN 2
#define LED_RED_GPIO GPIOA
#define LED_RED_PIN 15
#define LED_GREEN_ON() palSetPad(LED_GREEN_GPIO, LED_GREEN_PIN)
#define LED_GREEN_OFF() palClearPad(LED_GREEN_GPIO, LED_GREEN_PIN)
#define LED_RED_ON() palSetPad(LED_RED_GPIO, LED_RED_PIN)
#define LED_RED_OFF() palClearPad(LED_RED_GPIO, LED_RED_PIN)
// Phase filter
#define PHASE_FILTER_OFF() palSetPad(GPIOC, 15); palSetPad(GPIOC, 14); palSetPad(GPIOC, 13)
#define PHASE_FILTER_ON() palClearPad(GPIOC, 15); palClearPad(GPIOC, 14); palClearPad(GPIOC, 13)
// Shutdown pin
#define HW_SHUTDOWN_GPIO GPIOB
#define HW_SHUTDOWN_PIN 4
#define HW_SHUTDOWN_SENSE_GPIO GPIOC
#define HW_SHUTDOWN_SENSE_PIN 5
#define HW_SHUTDOWN_HOLD_ON() palSetPad(HW_SHUTDOWN_GPIO, HW_SHUTDOWN_PIN)
#define HW_SHUTDOWN_HOLD_OFF() palClearPad(HW_SHUTDOWN_GPIO, HW_SHUTDOWN_PIN)
#define HW_SAMPLE_SHUTDOWN() hw_sample_shutdown_button()
// ADC Config
#define HW_ADC_CHANNELS 18
#define HW_ADC_INJ_CHANNELS 3
#define HW_ADC_NBR_CONV 6
// ADC Indexes
#define ADC_IND_SENS1 3
#define ADC_IND_SENS2 4
#define ADC_IND_SENS3 5
#define ADC_IND_CURR1 0
#define ADC_IND_CURR2 1
#define ADC_IND_CURR3 2
#define ADC_IND_VIN_SENS 11
#define ADC_IND_EXT 6
#define ADC_IND_EXT2 7
#define ADC_IND_SHUTDOWN 10
#define ADC_IND_TEMP_MOS 8
//#define ADC_IND_TEMP_MOS_2 15
#define ADC_IND_TEMP_MOS_3 16
#define ADC_IND_TEMP_MOTOR 9
#define ADC_IND_VREFINT 12
// ADC macros and settings
// Component parameters (can be overridden)
#ifndef V_REG
#define V_REG 3.3
#endif
#ifndef VIN_R1
#define VIN_R1 100000.0
#endif
#ifndef VIN_R2
#define VIN_R2 3300.0
#endif
#ifndef CURRENT_AMP_GAIN
#define CURRENT_AMP_GAIN 20.0
#endif
#ifndef CURRENT_SHUNT_RES
#define CURRENT_SHUNT_RES (0.0005 / 2.0)
#endif
// Input voltage
#define GET_INPUT_VOLTAGE() ((V_REG / 4095.0) * (float)ADC_Value[ADC_IND_VIN_SENS] * ((VIN_R1 + VIN_R2) / VIN_R2))
// NTC Termistors
#define NTC_RES(adc_val) (10000.0 / ((4095.0 / (float)adc_val) - 1.0))
#define NTC_TEMP(adc_ind) hw_Thor_get_temp()
#define NTC_RES_MOTOR(adc_val) (10000.0 / ((4095.0 / (float)adc_val) - 1.0))
#define NTC_TEMP_MOTOR(beta) (1.0 / ((logf(NTC_RES_MOTOR(ADC_Value[ADC_IND_TEMP_MOTOR]) / 10000.0) / beta) + (1.0 / 298.15)) - 273.15)
#define NTC_TEMP_MOS1() (1.0 / ((logf(NTC_RES(ADC_Value[ADC_IND_TEMP_MOS]) / 10000.0) / 3380.0) + (1.0 / 298.15)) - 273.15)
//#define NTC_TEMP_MOS2() (1.0 / ((logf(NTC_RES(ADC_Value[ADC_IND_TEMP_MOS_2]) / 10000.0) / 3380.0) + (1.0 / 298.15)) - 273.15)
#define NTC_TEMP_MOS3() (1.0 / ((logf(NTC_RES(ADC_Value[ADC_IND_TEMP_MOS_3]) / 10000.0) / 3380.0) + (1.0 / 298.15)) - 273.15)
// Voltage on ADC channel
#define ADC_VOLTS(ch) ((float)ADC_Value[ch] / 4096.0 * V_REG)
// Double samples in beginning and end for positive current measurement.
// Useful when the shunt sense traces have noise that causes offset.
#ifndef CURR1_DOUBLE_SAMPLE
#define CURR1_DOUBLE_SAMPLE 0
#endif
#ifndef CURR2_DOUBLE_SAMPLE
#define CURR2_DOUBLE_SAMPLE 0
#endif
#ifndef CURR3_DOUBLE_SAMPLE
#define CURR3_DOUBLE_SAMPLE 0
#endif
// COMM-port ADC GPIOs
#define HW_ADC_EXT_GPIO GPIOA
#define HW_ADC_EXT_PIN 5
#define HW_ADC_EXT2_GPIO GPIOA
#define HW_ADC_EXT2_PIN 6
// ICU Peripheral for servo decoding
#define HW_USE_SERVO_TIM4
#define HW_ICU_TIMER TIM4
#define HW_ICU_TIM_CLK_EN() RCC_APB1PeriphClockCmd(RCC_APB1Periph_TIM4, ENABLE)
#define HW_ICU_DEV ICUD4
#define HW_ICU_CHANNEL ICU_CHANNEL_1
#define HW_ICU_GPIO_AF GPIO_AF_TIM4
#define HW_ICU_GPIO GPIOB
#define HW_ICU_PIN 6
// I2C Peripheral
#define HW_I2C_DEV I2CD2
#define HW_I2C_GPIO_AF GPIO_AF_I2C2
#define HW_I2C_SCL_PORT GPIOB
#define HW_I2C_SCL_PIN 12
#define HW_I2C_SDA_PORT GPIOC
#define HW_I2C_SDA_PIN 5
// Hall/encoder pins
#define HW_HALL_ENC_GPIO1 GPIOC
#define HW_HALL_ENC_PIN1 6
#define HW_HALL_ENC_GPIO2 GPIOC
#define HW_HALL_ENC_PIN2 7
#define HW_HALL_ENC_GPIO3 GPIOC
#define HW_HALL_ENC_PIN3 8
#define HW_ENC_TIM TIM3
#define HW_ENC_TIM_AF GPIO_AF_TIM3
#define HW_ENC_TIM_CLK_EN() RCC_APB1PeriphClockCmd(RCC_APB1Periph_TIM3, ENABLE)
#define HW_ENC_EXTI_PORTSRC EXTI_PortSourceGPIOC
#define HW_ENC_EXTI_PINSRC EXTI_PinSource8
#define HW_ENC_EXTI_CH EXTI9_5_IRQn
#define HW_ENC_EXTI_LINE EXTI_Line8
#define HW_ENC_EXTI_ISR_VEC EXTI9_5_IRQHandler
#define HW_ENC_TIM_ISR_CH TIM3_IRQn
#define HW_ENC_TIM_ISR_VEC TIM3_IRQHandler
// SPI pins
#define HW_SPI_DEV SPID3
#define HW_SPI_GPIO_AF GPIO_AF_SPI3
#define HW_SPI_PORT_NSS GPIOA
#define HW_SPI_PIN_NSS 4
#define HW_SPI_PORT_SCK GPIOC
#define HW_SPI_PIN_SCK 10
#define HW_SPI_PORT_MOSI GPIOC
#define HW_SPI_PIN_MOSI 12
#define HW_SPI_PORT_MISO GPIOC
#define HW_SPI_PIN_MISO 11
// I2C for IMU
#define LSM6DS3_SDA_GPIO GPIOD
#define LSM6DS3_SDA_PIN 2
#define LSM6DS3_SCL_GPIO GPIOB
#define LSM6DS3_SCL_PIN 5
// UART Peripheral
#define HW_UART_DEV SD4
#define HW_UART_GPIO_AF GPIO_AF_UART4
#define HW_UART_TX_PORT GPIOC
#define HW_UART_TX_PIN 10
#define HW_UART_RX_PORT GPIOC
#define HW_UART_RX_PIN 11
// Permanent UART Peripheral (for NRF52)
#define HW_UART_P_BAUD 115200
#define HW_UART_P_DEV SD3
#define HW_UART_P_GPIO_AF GPIO_AF_USART3
#define HW_UART_P_TX_PORT GPIOB
#define HW_UART_P_TX_PIN 10
#define HW_UART_P_RX_PORT GPIOB
#define HW_UART_P_RX_PIN 11
// Measurement macros
#define ADC_V_L1 ADC_Value[ADC_IND_SENS1]
#define ADC_V_L2 ADC_Value[ADC_IND_SENS2]
#define ADC_V_L3 ADC_Value[ADC_IND_SENS3]
#define ADC_V_ZERO (ADC_Value[ADC_IND_VIN_SENS] / 2)
// Macros
#define READ_HALL1() palReadPad(HW_HALL_ENC_GPIO1, HW_HALL_ENC_PIN1)
#define READ_HALL2() palReadPad(HW_HALL_ENC_GPIO2, HW_HALL_ENC_PIN2)
#define READ_HALL3() palReadPad(HW_HALL_ENC_GPIO3, HW_HALL_ENC_PIN3)
// Override dead time. See the stm32f4 reference manual for calculating this value.
#define HW_DEAD_TIME_NSEC 450.0
// Default setting overrides
#ifndef MCCONF_L_MIN_VOLTAGE
#define MCCONF_L_MIN_VOLTAGE 20.0 // Minimum input voltage
#endif
#ifndef MCCONF_L_MAX_VOLTAGE
#define MCCONF_L_MAX_VOLTAGE 90.0 // Maximum input voltage
#endif
#ifndef MCCONF_DEFAULT_MOTOR_TYPE
#define MCCONF_DEFAULT_MOTOR_TYPE MOTOR_TYPE_FOC
#endif
#ifndef MCCONF_FOC_F_ZV
#define MCCONF_FOC_F_ZV 30000.0
#endif
#ifndef MCCONF_L_MAX_ABS_CURRENT
#define MCCONF_L_MAX_ABS_CURRENT 300.0 // The maximum absolute current above which a fault is generated
#endif
#ifndef MCCONF_FOC_SAMPLE_V0_V7
#define MCCONF_FOC_SAMPLE_V0_V7 false // Run control loop in both v0 and v7 (requires phase shunts)
#endif
#ifndef MCCONF_L_IN_CURRENT_MAX
#define MCCONF_L_IN_CURRENT_MAX 100.0 // Input current limit in Amperes (Upper)
#endif
#ifndef MCCONF_L_IN_CURRENT_MIN
#define MCCONF_L_IN_CURRENT_MIN -100.0 // Input current limit in Amperes (Lower)
#endif
// Setting limits
#define HW_LIM_CURRENT -250.0, 250.0
#define HW_LIM_CURRENT_IN -150.0, 150.0
#define HW_LIM_CURRENT_ABS 0.0, 315.0
#define HW_LIM_VIN 18.0, 92.0
#define HW_LIM_ERPM -200e3, 200e3
#define HW_LIM_DUTY_MIN 0.0, 0.1
#define HW_LIM_DUTY_MAX 0.0, 0.95
#define HW_LIM_TEMP_FET -40.0, 100.0
// Functions
float hw_Thor_get_temp(void);
bool hw_sample_shutdown_button(void);
#endif /* Thor300_20s_v1_H_ */

1
package_firmware.py
View File

@ -97,6 +97,7 @@ package_dict["STORMCORE_100S"] = [['stormcore_100s', default_name],
package_dict["Little_FOCer"] = [['Little_FOCer', default_name]]
package_dict["Little_FOCer_V3"] = [['Little_FOCer_V3', default_name]]
package_dict["Little_FOCer_V3_1"] = [['Little_FOCer_V3_1', default_name]]
package_dict["Thor300"] = [['Thor_300_20s', default_name]]
package_dict["UXV_SR"] = [['uxv_sr', default_name]]
package_dict["GESC"] = [['gesc', default_name]]
package_dict["Warrior6"] = [['warrior6', default_name]]