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/*
* This file is part of the hoverboard - firmware - hack project .
*
* Copyright ( C ) 2017 - 2018 Rene Hopf < renehopf @ mac . com >
* Copyright ( C ) 2017 - 2018 Nico Stute < crinq @ crinq . de >
* Copyright ( C ) 2017 - 2018 Niklas Fauth < niklas . fauth @ kit . fail >
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* Copyright ( C ) 2019 - 2020 Emanuel FERU < aerdronix @ gmail . com >
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*
* 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/>.
*/
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# include <stdio.h>
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# include <stdlib.h> // for abs()
# include "stm32f1xx_hal.h"
# include "defines.h"
# include "setup.h"
# include "config.h"
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# include "util.h"
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# include "comms.h"
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# include "BLDC_controller.h" /* BLDC's header file */
# include "rtwtypes.h"
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# if defined(DEBUG_I2C_LCD) || defined(SUPPORT_LCD)
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# include "hd44780.h"
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# endif
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void SystemClock_Config ( void ) ;
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//------------------------------------------------------------------------
// Global variables set externally
//------------------------------------------------------------------------
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extern TIM_HandleTypeDef htim_left ;
extern TIM_HandleTypeDef htim_right ;
extern ADC_HandleTypeDef hadc1 ;
extern ADC_HandleTypeDef hadc2 ;
extern volatile adc_buf_t adc_buffer ;
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# if defined(DEBUG_I2C_LCD) || defined(SUPPORT_LCD)
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extern LCD_PCF8574_HandleTypeDef lcd ;
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extern uint8_t LCDerrorFlag ;
# endif
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extern UART_HandleTypeDef huart2 ;
extern UART_HandleTypeDef huart3 ;
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volatile uint8_t uart_buf [ 200 ] ;
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// Matlab defines - from auto-code generation
//---------------
extern P rtP_Left ; /* Block parameters (auto storage) */
extern P rtP_Right ; /* Block parameters (auto storage) */
extern ExtY rtY_Left ; /* External outputs */
extern ExtY rtY_Right ; /* External outputs */
//---------------
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extern int16_t cmd1 ; // normalized input value. -1000 to 1000
extern int16_t cmd2 ; // normalized input value. -1000 to 1000
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extern int16_t input1 ; // Non normalized input value
extern int16_t input2 ; // Non normalized input value
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extern int16_t speedAvg ; // Average measured speed
extern int16_t speedAvgAbs ; // Average measured speed in absolute
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extern volatile uint32_t timeoutCnt ; // Timeout counter for the General timeout (PPM, PWM, Nunchuck)
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extern uint8_t timeoutFlagADC ; // Timeout Flag for for ADC Protection: 0 = OK, 1 = Problem detected (line disconnected or wrong ADC data)
extern uint8_t timeoutFlagSerial ; // Timeout Flag for Rx Serial command: 0 = OK, 1 = Problem detected (line disconnected or wrong Rx data)
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extern volatile int pwml ; // global variable for pwm left. -1000 to 1000
extern volatile int pwmr ; // global variable for pwm right. -1000 to 1000
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extern uint8_t enable ; // global variable for motor enable
extern int16_t batVoltage ; // global variable for battery voltage
# if defined(SIDEBOARD_SERIAL_USART2)
extern SerialSideboard Sideboard_L ;
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# endif
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# if defined(SIDEBOARD_SERIAL_USART3)
extern SerialSideboard Sideboard_R ;
# endif
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# if (defined(CONTROL_PPM_LEFT) && defined(DEBUG_SERIAL_USART3)) || (defined(CONTROL_PPM_RIGHT) && defined(DEBUG_SERIAL_USART2))
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extern volatile uint16_t ppm_captured_value [ PPM_NUM_CHANNELS + 1 ] ;
# endif
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# if (defined(CONTROL_PWM_LEFT) && defined(DEBUG_SERIAL_USART3)) || (defined(CONTROL_PWM_RIGHT) && defined(DEBUG_SERIAL_USART2))
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extern volatile uint16_t pwm_captured_ch1_value ;
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extern volatile uint16_t pwm_captured_ch2_value ;
# endif
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//------------------------------------------------------------------------
// Global variables set here in main.c
//------------------------------------------------------------------------
uint8_t backwardDrive ;
volatile uint32_t main_loop_counter ;
//------------------------------------------------------------------------
// Local variables
//------------------------------------------------------------------------
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# if defined(FEEDBACK_SERIAL_USART2) || defined(FEEDBACK_SERIAL_USART3)
typedef struct {
uint16_t start ;
int16_t cmd1 ;
int16_t cmd2 ;
int16_t speedR_meas ;
int16_t speedL_meas ;
int16_t batVoltage ;
int16_t boardTemp ;
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uint16_t cmdLed ;
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uint16_t checksum ;
} SerialFeedback ;
static SerialFeedback Feedback ;
# endif
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# if defined(FEEDBACK_SERIAL_USART2)
static uint8_t sideboard_leds_L ;
# endif
# if defined(FEEDBACK_SERIAL_USART3)
static uint8_t sideboard_leds_R ;
# endif
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# ifdef VARIANT_TRANSPOTTER
extern uint8_t nunchuk_connected ;
extern float setDistance ;
static uint8_t checkRemote = 0 ;
static uint16_t distance ;
static float steering ;
static int distanceErr ;
static int lastDistance = 0 ;
static uint16_t transpotter_counter = 0 ;
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# endif
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static int16_t speed ; // local variable for speed. -1000 to 1000
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# ifndef VARIANT_TRANSPOTTER
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static int16_t steer ; // local variable for steering. -1000 to 1000
static int16_t steerRateFixdt ; // local fixed-point variable for steering rate limiter
static int16_t speedRateFixdt ; // local fixed-point variable for speed rate limiter
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static int32_t steerFixdt ; // local fixed-point variable for steering low-pass filter
static int32_t speedFixdt ; // local fixed-point variable for speed low-pass filter
# endif
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static uint32_t inactivity_timeout_counter ;
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static MultipleTap MultipleTapBrake ; // define multiple tap functionality for the Brake pedal
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int main ( void ) {
HAL_Init ( ) ;
__HAL_RCC_AFIO_CLK_ENABLE ( ) ;
HAL_NVIC_SetPriorityGrouping ( NVIC_PRIORITYGROUP_4 ) ;
/* System interrupt init*/
/* MemoryManagement_IRQn interrupt configuration */
HAL_NVIC_SetPriority ( MemoryManagement_IRQn , 0 , 0 ) ;
/* BusFault_IRQn interrupt configuration */
HAL_NVIC_SetPriority ( BusFault_IRQn , 0 , 0 ) ;
/* UsageFault_IRQn interrupt configuration */
HAL_NVIC_SetPriority ( UsageFault_IRQn , 0 , 0 ) ;
/* SVCall_IRQn interrupt configuration */
HAL_NVIC_SetPriority ( SVCall_IRQn , 0 , 0 ) ;
/* DebugMonitor_IRQn interrupt configuration */
HAL_NVIC_SetPriority ( DebugMonitor_IRQn , 0 , 0 ) ;
/* PendSV_IRQn interrupt configuration */
HAL_NVIC_SetPriority ( PendSV_IRQn , 0 , 0 ) ;
/* SysTick_IRQn interrupt configuration */
HAL_NVIC_SetPriority ( SysTick_IRQn , 0 , 0 ) ;
SystemClock_Config ( ) ;
__HAL_RCC_DMA1_CLK_DISABLE ( ) ;
MX_GPIO_Init ( ) ;
MX_TIM_Init ( ) ;
MX_ADC1_Init ( ) ;
MX_ADC2_Init ( ) ;
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BLDC_Init ( ) ; // BLDC Controller Init
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HAL_GPIO_WritePin ( OFF_PORT , OFF_PIN , GPIO_PIN_SET ) ; // Activate Latch
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Input_Lim_Init ( ) ; // Input Limitations Init
Input_Init ( ) ; // Input Init
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HAL_ADC_Start ( & hadc1 ) ;
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HAL_ADC_Start ( & hadc2 ) ;
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poweronMelody ( ) ;
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HAL_GPIO_WritePin ( LED_PORT , LED_PIN , GPIO_PIN_SET ) ;
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int16_t speedL = 0 , speedR = 0 ;
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int16_t lastSpeedL = 0 , lastSpeedR = 0 ;
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int32_t board_temp_adcFixdt = adc_buffer . temp < < 16 ; // Fixed-point filter output initialized with current ADC converted to fixed-point
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int16_t board_temp_adcFilt = adc_buffer . temp ;
int16_t board_temp_deg_c ;
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while ( 1 ) {
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HAL_Delay ( DELAY_IN_MAIN_LOOP ) ; //delay in ms
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readCommand ( ) ; // Read Command: cmd1, cmd2
calcAvgSpeed ( ) ; // Calculate average measured speed: speedAvg, speedAvgAbs
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# ifndef VARIANT_TRANSPOTTER
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// ####### MOTOR ENABLING: Only if the initial input is very small (for SAFETY) #######
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if ( enable = = 0 & & ( ! rtY_Left . z_errCode & & ! rtY_Right . z_errCode ) & & ( cmd1 > - 50 & & cmd1 < 50 ) & & ( cmd2 > - 50 & & cmd2 < 50 ) ) {
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beepShort ( 6 ) ; // make 2 beeps indicating the motor enable
beepShort ( 4 ) ; HAL_Delay ( 100 ) ;
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steerFixdt = speedFixdt = 0 ; // reset filters
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enable = 1 ; // enable motors
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printf ( " -- Motors enabled -- \r \n " ) ;
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}
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// ####### VARIANT_HOVERCAR #######
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# if defined(VARIANT_HOVERCAR) || defined(VARIANT_SKATEBOARD) || defined(ELECTRIC_BRAKE_ENABLE)
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uint16_t speedBlend ; // Calculate speed Blend, a number between [0, 1] in fixdt(0,16,15)
speedBlend = ( uint16_t ) ( ( ( CLAMP ( speedAvgAbs , 10 , 60 ) - 10 ) < < 15 ) / 50 ) ; // speedBlend [0,1] is within [10 rpm, 60rpm]
# endif
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# ifdef STANDSTILL_HOLD_ENABLE
standstillHold ( ) ; // Apply Standstill Hold functionality. Only available and makes sense for VOLTAGE or TORQUE Mode
# endif
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# ifdef VARIANT_HOVERCAR
if ( speedAvgAbs < 60 ) { // Check if Hovercar is physically close to standstill to enable Double tap detection on Brake pedal for Reverse functionality
multipleTapDet ( cmd1 , HAL_GetTick ( ) , & MultipleTapBrake ) ; // Brake pedal in this case is "cmd1" variable
}
if ( cmd1 > 30 ) { // If Brake pedal (cmd1) is pressed, bring to 0 also the Throttle pedal (cmd2) to avoid "Double pedal" driving
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cmd2 = ( int16_t ) ( ( cmd2 * speedBlend ) > > 15 ) ;
cruiseControl ( ( uint8_t ) rtP_Left . b_cruiseCtrlEna ) ; // Cruise control deactivated by Brake pedal if it was active
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}
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# endif
# ifdef ELECTRIC_BRAKE_ENABLE
electricBrake ( speedBlend , MultipleTapBrake . b_multipleTap ) ; // Apply Electric Brake. Only available and makes sense for TORQUE Mode
# endif
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# ifdef VARIANT_HOVERCAR
if ( speedAvg > 0 ) { // Make sure the Brake pedal is opposite to the direction of motion AND it goes to 0 as we reach standstill (to avoid Reverse driving by Brake pedal)
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cmd1 = ( int16_t ) ( ( - cmd1 * speedBlend ) > > 15 ) ;
} else {
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cmd1 = ( int16_t ) ( ( cmd1 * speedBlend ) > > 15 ) ;
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}
# endif
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# ifdef VARIANT_SKATEBOARD
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if ( cmd2 < 0 ) { // When Throttle is negative, it acts as brake. This condition is to make sure it goes to 0 as we reach standstill (to avoid Reverse driving)
if ( speedAvg > 0 ) { // Make sure the braking is opposite to the direction of motion
cmd2 = ( int16_t ) ( ( cmd2 * speedBlend ) > > 15 ) ;
} else {
cmd2 = ( int16_t ) ( ( - cmd2 * speedBlend ) > > 15 ) ;
}
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}
# endif
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// ####### LOW-PASS FILTER #######
rateLimiter16 ( cmd1 , RATE , & steerRateFixdt ) ;
rateLimiter16 ( cmd2 , RATE , & speedRateFixdt ) ;
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filtLowPass32 ( steerRateFixdt > > 4 , FILTER , & steerFixdt ) ;
filtLowPass32 ( speedRateFixdt > > 4 , FILTER , & speedFixdt ) ;
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steer = ( int16_t ) ( steerFixdt > > 16 ) ; // convert fixed-point to integer
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speed = ( int16_t ) ( speedFixdt > > 16 ) ; // convert fixed-point to integer
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// ####### VARIANT_HOVERCAR #######
# ifdef VARIANT_HOVERCAR
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if ( ! MultipleTapBrake . b_multipleTap ) { // Check driving direction
speed = steer + speed ; // Forward driving: in this case steer = Brake, speed = Throttle
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} else {
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speed = steer - speed ; // Reverse driving: in this case steer = Brake, speed = Throttle
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}
# endif
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// ####### MIXER #######
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// speedR = CLAMP((int)(speed * SPEED_COEFFICIENT - steer * STEER_COEFFICIENT), INPUT_MIN, INPUT_MA);
// speedL = CLAMP((int)(speed * SPEED_COEFFICIENT + steer * STEER_COEFFICIENT), INPUT_MIN, INPUT_MA);
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mixerFcn ( speed < < 4 , steer < < 4 , & speedR , & speedL ) ; // This function implements the equations above
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// ####### SET OUTPUTS (if the target change is less than +/- 100) #######
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if ( ( speedL > lastSpeedL - 100 & & speedL < lastSpeedL + 100 ) & & ( speedR > lastSpeedR - 100 & & speedR < lastSpeedR + 100 ) ) {
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# ifdef INVERT_R_DIRECTION
pwmr = speedR ;
# else
pwmr = - speedR ;
# endif
# ifdef INVERT_L_DIRECTION
pwml = - speedL ;
# else
pwml = speedL ;
# endif
}
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# endif
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# ifdef VARIANT_TRANSPOTTER
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distance = CLAMP ( cmd1 - 180 , 0 , 4095 ) ;
steering = ( cmd2 - 2048 ) / 2048.0 ;
distanceErr = distance - ( int ) ( setDistance * 1345 ) ;
if ( nunchuk_connected = = 0 ) {
speedL = speedL * 0.8f + ( CLAMP ( distanceErr + ( steering * ( ( float ) MAX ( ABS ( distanceErr ) , 50 ) ) * ROT_P ) , - 850 , 850 ) * - 0.2f ) ;
speedR = speedR * 0.8f + ( CLAMP ( distanceErr - ( steering * ( ( float ) MAX ( ABS ( distanceErr ) , 50 ) ) * ROT_P ) , - 850 , 850 ) * - 0.2f ) ;
if ( ( speedL < lastSpeedL + 50 & & speedL > lastSpeedL - 50 ) & & ( speedR < lastSpeedR + 50 & & speedR > lastSpeedR - 50 ) ) {
if ( distanceErr > 0 ) {
enable = 1 ;
}
if ( distanceErr > - 300 ) {
# ifdef INVERT_R_DIRECTION
pwmr = speedR ;
# else
pwmr = - speedR ;
# endif
# ifdef INVERT_L_DIRECTION
pwml = - speedL ;
# else
pwml = speedL ;
# endif
if ( checkRemote ) {
if ( ! HAL_GPIO_ReadPin ( LED_PORT , LED_PIN ) ) {
//enable = 1;
} else {
enable = 0 ;
}
}
} else {
enable = 0 ;
}
}
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timeoutCnt = 0 ;
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}
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if ( timeoutCnt > TIMEOUT ) {
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pwml = 0 ;
pwmr = 0 ;
enable = 0 ;
# ifdef SUPPORT_LCD
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LCD_SetLocation ( & lcd , 0 , 0 ) ; LCD_WriteString ( & lcd , " Len: " ) ;
LCD_SetLocation ( & lcd , 8 , 0 ) ; LCD_WriteString ( & lcd , " m( " ) ;
LCD_SetLocation ( & lcd , 14 , 0 ) ; LCD_WriteString ( & lcd , " m) " ) ;
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# endif
HAL_Delay ( 1000 ) ;
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nunchuk_connected = 0 ;
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}
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if ( ( distance / 1345.0 ) - setDistance > 0.5 & & ( lastDistance / 1345.0 ) - setDistance > 0.5 ) { // Error, robot too far away!
enable = 0 ;
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beepLong ( 5 ) ;
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# ifdef SUPPORT_LCD
LCD_ClearDisplay ( & lcd ) ;
HAL_Delay ( 5 ) ;
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LCD_SetLocation ( & lcd , 0 , 0 ) ; LCD_WriteString ( & lcd , " Emergency Off! " ) ;
LCD_SetLocation ( & lcd , 0 , 1 ) ; LCD_WriteString ( & lcd , " Keeper too fast. " ) ;
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# endif
poweroff ( ) ;
}
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# ifdef SUPPORT_NUNCHUK
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if ( transpotter_counter % 500 = = 0 ) {
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if ( nunchuk_connected = = 0 & & enable = = 0 ) {
if ( Nunchuk_Ping ( ) ) {
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HAL_Delay ( 500 ) ;
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Nunchuk_Init ( ) ;
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# ifdef SUPPORT_LCD
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LCD_SetLocation ( & lcd , 0 , 0 ) ; LCD_WriteString ( & lcd , " Nunchuk Control " ) ;
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# endif
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timeoutCnt = 0 ;
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HAL_Delay ( 1000 ) ;
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nunchuk_connected = 1 ;
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}
}
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}
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# endif
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# ifdef SUPPORT_LCD
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if ( transpotter_counter % 100 = = 0 ) {
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if ( LCDerrorFlag = = 1 & & enable = = 0 ) {
} else {
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if ( nunchuk_connected = = 0 ) {
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LCD_SetLocation ( & lcd , 4 , 0 ) ; LCD_WriteFloat ( & lcd , distance / 1345.0 , 2 ) ;
LCD_SetLocation ( & lcd , 10 , 0 ) ; LCD_WriteFloat ( & lcd , setDistance , 2 ) ;
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}
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LCD_SetLocation ( & lcd , 4 , 1 ) ; LCD_WriteFloat ( & lcd , batVoltage , 1 ) ;
// LCD_SetLocation(&lcd, 11, 1); LCD_WriteFloat(&lcd,MAX(ABS(currentR), ABS(currentL)),2);
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}
}
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# endif
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transpotter_counter + + ;
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# endif
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// ####### SIDEBOARDS HANDLING #######
# if defined(SIDEBOARD_SERIAL_USART2)
sideboardLeds ( & sideboard_leds_L ) ;
sideboardSensors ( ( uint8_t ) Sideboard_L . sensors ) ;
# endif
# if defined(SIDEBOARD_SERIAL_USART3)
sideboardLeds ( & sideboard_leds_R ) ;
sideboardSensors ( ( uint8_t ) Sideboard_R . sensors ) ;
# endif
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// ####### CALC BOARD TEMPERATURE #######
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filtLowPass32 ( adc_buffer . temp , TEMP_FILT_COEF , & board_temp_adcFixdt ) ;
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board_temp_adcFilt = ( int16_t ) ( board_temp_adcFixdt > > 16 ) ; // convert fixed-point to integer
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board_temp_deg_c = ( TEMP_CAL_HIGH_DEG_C - TEMP_CAL_LOW_DEG_C ) * ( board_temp_adcFilt - TEMP_CAL_LOW_ADC ) / ( TEMP_CAL_HIGH_ADC - TEMP_CAL_LOW_ADC ) + TEMP_CAL_LOW_DEG_C ;
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// ####### DEBUG SERIAL OUT #######
# if defined(DEBUG_SERIAL_USART2) || defined(DEBUG_SERIAL_USART3)
if ( main_loop_counter % 25 = = 0 ) { // Send data periodically every 125 ms
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printf ( " in1:%i in2:%i spdL:%i spdR:%i adcBat:%i BatV:%i adcTemp:%i Temp:%i \r \n " ,
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input1 , // 1: INPUT1
input2 , // 2: INPUT2
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speedL , // 3: output command: [-1000, 1000]
speedR , // 4: output command: [-1000, 1000]
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adc_buffer . batt1 , // 5: for battery voltage calibration
batVoltage * BAT_CALIB_REAL_VOLTAGE / BAT_CALIB_ADC , // 6: for verifying battery voltage calibration
board_temp_adcFilt , // 7: for board temperature calibration
board_temp_deg_c ) ; // 8: for verifying board temperature calibration
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}
# endif
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// ####### FEEDBACK SERIAL OUT #######
# if defined(FEEDBACK_SERIAL_USART2) || defined(FEEDBACK_SERIAL_USART3)
if ( main_loop_counter % 2 = = 0 ) { // Send data periodically every 10 ms
Feedback . start = ( uint16_t ) SERIAL_START_FRAME ;
Feedback . cmd1 = ( int16_t ) cmd1 ;
Feedback . cmd2 = ( int16_t ) cmd2 ;
Feedback . speedR_meas = ( int16_t ) rtY_Right . n_mot ;
Feedback . speedL_meas = ( int16_t ) rtY_Left . n_mot ;
Feedback . batVoltage = ( int16_t ) ( batVoltage * BAT_CALIB_REAL_VOLTAGE / BAT_CALIB_ADC ) ;
Feedback . boardTemp = ( int16_t ) board_temp_deg_c ;
# if defined(FEEDBACK_SERIAL_USART2)
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if ( __HAL_DMA_GET_COUNTER ( huart2 . hdmatx ) = = 0 ) {
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Feedback . cmdLed = ( uint16_t ) sideboard_leds_L ;
Feedback . checksum = ( uint16_t ) ( Feedback . start ^ Feedback . cmd1 ^ Feedback . cmd2 ^ Feedback . speedR_meas ^ Feedback . speedL_meas
^ Feedback . batVoltage ^ Feedback . boardTemp ^ Feedback . cmdLed ) ;
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HAL_UART_Transmit_DMA ( & huart2 , ( uint8_t * ) & Feedback , sizeof ( Feedback ) ) ;
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}
# endif
# if defined(FEEDBACK_SERIAL_USART3)
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if ( __HAL_DMA_GET_COUNTER ( huart3 . hdmatx ) = = 0 ) {
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Feedback . cmdLed = ( uint16_t ) sideboard_leds_R ;
Feedback . checksum = ( uint16_t ) ( Feedback . start ^ Feedback . cmd1 ^ Feedback . cmd2 ^ Feedback . speedR_meas ^ Feedback . speedL_meas
^ Feedback . batVoltage ^ Feedback . boardTemp ^ Feedback . cmdLed ) ;
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HAL_UART_Transmit_DMA ( & huart3 , ( uint8_t * ) & Feedback , sizeof ( Feedback ) ) ;
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}
# endif
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}
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# endif
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// ####### POWEROFF BY POWER-BUTTON #######
poweroffPressCheck ( ) ;
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// ####### BEEP AND EMERGENCY POWEROFF #######
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if ( ( TEMP_POWEROFF_ENABLE & & board_temp_deg_c > = TEMP_POWEROFF & & speedAvgAbs < 20 ) | | ( batVoltage < BAT_DEAD & & speedAvgAbs < 20 ) ) { // poweroff before mainboard burns OR low bat 3
poweroff ( ) ;
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} else if ( rtY_Left . z_errCode | | rtY_Right . z_errCode ) { // 1 beep (low pitch): Motor error, disable motors
enable = 0 ;
beepCount ( 1 , 24 , 1 ) ;
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printf ( " #ErrL: %i ErrR: %i \r \n " , rtY_Left . z_errCode , rtY_Right . z_errCode ) ;
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} else if ( timeoutFlagADC ) { // 2 beeps (low pitch): ADC timeout
beepCount ( 2 , 24 , 1 ) ;
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printf ( " #ADC timeout \r \n " ) ;
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} else if ( timeoutFlagSerial ) { // 3 beeps (low pitch): Serial timeout
beepCount ( 3 , 24 , 1 ) ;
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printf ( " #Serial timeout \r \n " ) ;
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} else if ( timeoutCnt > TIMEOUT ) { // 4 beeps (low pitch): General timeout (PPM, PWM, Nunchuck)
beepCount ( 4 , 24 , 1 ) ;
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printf ( " #General timeout \r \n " ) ;
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} else if ( TEMP_WARNING_ENABLE & & board_temp_deg_c > = TEMP_WARNING ) { // 5 beeps (low pitch): Mainboard temperature warning
beepCount ( 5 , 24 , 1 ) ;
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printf ( " #STM32 hot: %i \r \n " , board_temp_deg_c ) ;
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} else if ( BAT_LVL1_ENABLE & & batVoltage < BAT_LVL1 ) { // 1 beep fast (medium pitch): Low bat 1
beepCount ( 0 , 10 , 6 ) ;
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printf ( " #Battery empty: %i \r \n " , batVoltage * BAT_CALIB_REAL_VOLTAGE / BAT_CALIB_ADC ) ;
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} else if ( BAT_LVL2_ENABLE & & batVoltage < BAT_LVL2 ) { // 1 beep slow (medium pitch): Low bat 2
beepCount ( 0 , 10 , 30 ) ;
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printf ( " #Battery empty: %i \r \n " , batVoltage * BAT_CALIB_REAL_VOLTAGE / BAT_CALIB_ADC ) ;
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} else if ( BEEPS_BACKWARD & & ( ( speed < - 50 & & speedAvg < 0 ) | | MultipleTapBrake . b_multipleTap ) ) { // 1 beep fast (high pitch): Backward spinning motors
beepCount ( 0 , 5 , 1 ) ;
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backwardDrive = 1 ;
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} else { // do not beep
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beepCount ( 0 , 0 , 0 ) ;
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backwardDrive = 0 ;
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}
// ####### INACTIVITY TIMEOUT #######
if ( abs ( speedL ) > 50 | | abs ( speedR ) > 50 ) {
inactivity_timeout_counter = 0 ;
} else {
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inactivity_timeout_counter + + ;
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}
if ( inactivity_timeout_counter > ( INACTIVITY_TIMEOUT * 60 * 1000 ) / ( DELAY_IN_MAIN_LOOP + 1 ) ) { // rest of main loop needs maybe 1ms
poweroff ( ) ;
}
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// HAL_GPIO_TogglePin(LED_PORT, LED_PIN); // This is to measure the main() loop duration with an oscilloscope connected to LED_PIN
// Update main loop states
lastSpeedL = speedL ;
lastSpeedR = speedR ;
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main_loop_counter + + ;
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timeoutCnt + + ;
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}
}
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// ===========================================================
/** System Clock Configuration
*/
void SystemClock_Config ( void ) {
RCC_OscInitTypeDef RCC_OscInitStruct ;
RCC_ClkInitTypeDef RCC_ClkInitStruct ;
RCC_PeriphCLKInitTypeDef PeriphClkInit ;
/**Initializes the CPU, AHB and APB busses clocks
*/
RCC_OscInitStruct . OscillatorType = RCC_OSCILLATORTYPE_HSI ;
RCC_OscInitStruct . HSIState = RCC_HSI_ON ;
RCC_OscInitStruct . HSICalibrationValue = 16 ;
RCC_OscInitStruct . PLL . PLLState = RCC_PLL_ON ;
RCC_OscInitStruct . PLL . PLLSource = RCC_PLLSOURCE_HSI_DIV2 ;
RCC_OscInitStruct . PLL . PLLMUL = RCC_PLL_MUL16 ;
HAL_RCC_OscConfig ( & RCC_OscInitStruct ) ;
/**Initializes the CPU, AHB and APB busses clocks
*/
RCC_ClkInitStruct . ClockType = RCC_CLOCKTYPE_HCLK | RCC_CLOCKTYPE_SYSCLK | RCC_CLOCKTYPE_PCLK1 | RCC_CLOCKTYPE_PCLK2 ;
RCC_ClkInitStruct . SYSCLKSource = RCC_SYSCLKSOURCE_PLLCLK ;
RCC_ClkInitStruct . AHBCLKDivider = RCC_SYSCLK_DIV1 ;
RCC_ClkInitStruct . APB1CLKDivider = RCC_HCLK_DIV2 ;
RCC_ClkInitStruct . APB2CLKDivider = RCC_HCLK_DIV1 ;
HAL_RCC_ClockConfig ( & RCC_ClkInitStruct , FLASH_LATENCY_2 ) ;
PeriphClkInit . PeriphClockSelection = RCC_PERIPHCLK_ADC ;
// PeriphClkInit.AdcClockSelection = RCC_ADCPCLK2_DIV8; // 8 MHz
PeriphClkInit . AdcClockSelection = RCC_ADCPCLK2_DIV4 ; // 16 MHz
HAL_RCCEx_PeriphCLKConfig ( & PeriphClkInit ) ;
/**Configure the Systick interrupt time
*/
HAL_SYSTICK_Config ( HAL_RCC_GetHCLKFreq ( ) / 1000 ) ;
/**Configure the Systick
*/
HAL_SYSTICK_CLKSourceConfig ( SYSTICK_CLKSOURCE_HCLK ) ;
/* SysTick_IRQn interrupt configuration */
HAL_NVIC_SetPriority ( SysTick_IRQn , 0 , 0 ) ;
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}