コード例 #1
0
ファイル: main.c プロジェクト: ADTL/stm32f4-lab
/**
  * @brief  Main program
  * @param  None
  * @retval None
  */
int main(void)
{
  uint16_t pulse_width = 0;
  /* TIM Configuration */
  TIM_Config();
  /* LED Configuration */
  LED_Config();
  /* PWM Configuration */
  PWM_Config(MAX_PERIOD);

  PWM_SetDC(1,100);
  PWM_SetDC(2,100);
  PWM_SetDC(3,100);
  PWM_SetDC(4,100);
  while (1)
  {
    /* PD12 to be toggled */
//    GPIO_ToggleBits(GPIOD, GPIO_Pin_13);
    PWM_SetDC(1,pulse_width++);
    if (pulse_width > MAX_PERIOD / 10)
    {
      pulse_width = MAX_PERIOD / 20;
    }
    Delay(900000);
  }
}
コード例 #2
0
void platformFineAdjust(void) {
	float diff = 0.0;
	uint16_t ticks = getOrderCurrentTicks();
	if(checkRightWall()) {
		//_stop();
		process_sensors();
		diff = getIRSensorReadingCM(IR_SENSOR_RF)-getIRSensorReadingCM(IR_SENSOR_RB);

		if(diff <= -MOTOR_ADJUSTMENT_CM || diff >= MOTOR_ADJUSTMENT_CM) {
			while(diff <= -MOTOR_ADJUSTMENT_CM || diff >= MOTOR_ADJUSTMENT_CM) {
				process_sensors();

				if(!checkRightWall()) {
					break;
				}

				diff = getIRSensorReadingCM(IR_SENSOR_RF)-getIRSensorReadingCM(IR_SENSOR_RB);
				if(diff >= MOTOR_ADJUSTMENT_CM ) {
					_stop();
					PWM_SetDC(PLATFORM_LEFT_FORWARD ,PLATFORM_PERIOD_PERCENTAGE*MOTOR_ADJUSTMENT_SPEED*MP._left_side._calibrate_speed);
					PWM_SetDC(PLATFORM_RIGHT_BACKWARD ,PLATFORM_PERIOD_PERCENTAGE*MOTOR_ADJUSTMENT_SPEED*MP._right_side._calibrate_speed);
				} else if ( diff <= -MOTOR_ADJUSTMENT_CM) {
					_stop();
					PWM_SetDC(PLATFORM_LEFT_BACKWARD ,PLATFORM_PERIOD_PERCENTAGE*MOTOR_ADJUSTMENT_SPEED*MP._left_side._calibrate_speed);
					PWM_SetDC(PLATFORM_RIGHT_FORWARD ,PLATFORM_PERIOD_PERCENTAGE*MOTOR_ADJUSTMENT_SPEED*MP._right_side._calibrate_speed);
				} else {
					break;
				}

			}
			MP.adjust_state |= PLATFORM_ADJUST_DONE;
			setOrderCurrentTicks(ticks);
			resetPIDIntergrator();
			_stop();
			setChange(1);
			deactivatePID();
		}

	}
}
コード例 #3
0
ファイル: main.c プロジェクト: MbedTinkerer/uart_dma
/**
  * @brief  Main program
  * @param  None
  * @retval None
  */
int main(void)
{
  /*!< At this stage the microcontroller clock setting is already configured, 
       this is done through SystemInit() function which is called from startup
       files (startup_stm32f40xx.s/startup_stm32f427x.s) before to branch to 
       application main. 
       To reconfigure the default setting of SystemInit() function, refer to
       system_stm32f4xx.c file
     */

  /* USART configuration -----------------------------------------------------*/
  USART_Config();
    
  /* SysTick configuration ---------------------------------------------------*/
  SysTickConfig();
  
  /* LEDs configuration ------------------------------------------------------*/
  STM_EVAL_LEDInit(LED3);
  STM_EVAL_LEDInit(LED4);
  STM_EVAL_LEDInit(LED5);
  STM_EVAL_LEDInit(LED6);
  
  STM_EVAL_LEDOn(LED3);//orange
  STM_EVAL_LEDOn(LED4);//verte
  STM_EVAL_LEDOn(LED5);//rouge
  STM_EVAL_LEDOn(LED6);//bleue
  
  //PWM config (motor control)
  TIM1_Config();
  PWM1_Config(10000);
  
  /* Tamper Button Configuration ---------------------------------------------*/
  STM_EVAL_PBInit(BUTTON_USER,BUTTON_MODE_GPIO);
    
  //Set motor speed
  PWM_SetDC(1, SPEED_100); //PE9 | PC6//ON 2ms
  PWM_SetDC(2, SPEED_100); //PE11 | PC 7
  PWM_SetDC(3, SPEED_100); //PE13
  PWM_SetDC(4, SPEED_100); //PE14

  //  /* Wait until Tamper Button is released */
  while (STM_EVAL_PBGetState(BUTTON_USER));  
  
  PWM_SetDC(1, SPEED_0); //PE9 | PC6//ON 2ms
  PWM_SetDC(2, SPEED_0); //PE11 | PC 7
  PWM_SetDC(3, SPEED_0); //PE13
  PWM_SetDC(4, SPEED_0); //PE14

  /* Initialization of the accelerometer -------------------------------------*/
  MPU6050_I2C_Init();
  MPU6050_Initialize();

  if (MPU6050_TestConnection()) {
		// connection success
		STM_EVAL_LEDOff(LED3);
  }else{
                STM_EVAL_LEDOff(LED4);
  }

  //Calibration process
  //  Use the following global variables and access functions
  //  to calibrate the acceleration sensor
  calibrate_sensors();

  zeroError();
  
  //Ready to receive message
  /* Enable DMA USART RX Stream */
  DMA_Cmd(USARTx_RX_DMA_STREAM,ENABLE);
  /* Enable USART DMA RX Requsts */
  USART_DMACmd(USARTx, USART_DMAReq_Rx, ENABLE);
  
  while(1){
    //--------------------------------------------------------
    //------ Used to configure the speed controller ----------
    //--------------------------------------------------------
    
    // press blue button to force motor at SPEED_100
    if (STM_EVAL_PBGetState(BUTTON_USER)){
      PWM_SetDC(1, SPEED_100); //PE9 | PC6//ON 2ms
      PWM_SetDC(2, SPEED_100); //PE11 | PC 7
      PWM_SetDC(3, SPEED_100); //PE13
      PWM_SetDC(4, SPEED_100); //PE14
      
      //  /* Wait until Tamper Button is released */
      while (STM_EVAL_PBGetState(BUTTON_USER));  
      
      PWM_SetDC(1, SPEED_0); //PE9 | PC6//ON 2ms
      PWM_SetDC(2, SPEED_0); //PE11 | PC 7
      PWM_SetDC(3, SPEED_0); //PE13
      PWM_SetDC(4, SPEED_0); //PE14
      
      Delay(100);
    }
    
    //--------------------------------------------------------
    //------ Get gyro information                   ----------
    //--------------------------------------------------------
    
    // Read the raw values.
    MPU6050_GetRawAccelGyro(AccelGyro);

    // Get the time of reading for rotation computations
    unsigned long t_now = millis();
    STM_EVAL_LEDToggle(LED5);
    // The temperature sensor is -40 to +85 degrees Celsius.
    // It is a signed integer.
    // According to the datasheet:
    //   340 per degrees Celsius, -512 at 35 degrees.
    // At 0 degrees: -512 – (340 * 35) = -12412
    //dT = ( (double) AccelGyro[TEMP] + 12412.0) / 340.0;

    // Convert gyro values to degrees/sec
    gyro_x = (AccelGyro[GYRO_X] - base_x_gyro) / FSSEL;
    gyro_y = (AccelGyro[GYRO_Y] - base_y_gyro) / FSSEL;
    gyro_z = (AccelGyro[GYRO_Z] - base_z_gyro) / FSSEL;

    // Get raw acceleration values
    accel_x = AccelGyro[ACC_X];
    accel_y = AccelGyro[ACC_Y];
    accel_z = AccelGyro[ACC_Z];

    // Get angle values from accelerometer
    //float accel_vector_length = sqrt(pow(accel_x,2) + pow(accel_y,2) + pow(accel_z,2));
    float accel_angle_y = atan(-1*accel_x/sqrt(pow(accel_y,2) + pow(accel_z,2)))*RADIANS2DEGREES;
    float accel_angle_x = atan(accel_y/sqrt(pow(accel_x,2) + pow(accel_z,2)))*RADIANS2DEGREES;

    //float accel_angle_z = 0;

    //// Compute the (filtered) gyro angles
    //Get the value in second, a tick is every 10ms
    dt = (t_now - last_read_time)/100.0;
    float gyro_angle_x = gyro_x*dt + lastAngle[X];//get_last_x_angle();
    float gyro_angle_y = gyro_y*dt + lastAngle[Y];//(get_last_y_angle();
    float gyro_angle_z = gyro_z*dt + lastAngle[Z];//get_last_z_angle();

    // Compute the drifting gyro angles
    float unfiltered_gyro_angle_x = gyro_x*dt + lastGyroAngle[X];//get_last_gyro_x_angle();
    float unfiltered_gyro_angle_y = gyro_y*dt + lastGyroAngle[Y];//get_last_gyro_y_angle();
    float unfiltered_gyro_angle_z = gyro_z*dt + lastGyroAngle[Z];//get_last_gyro_z_angle();

    // Apply the complementary filter to figure out the change in angle – choice of alpha is
    // estimated now.  Alpha depends on the sampling rate…
    float alpha = 0.96;
    angle_x = alpha * gyro_angle_x + (1.0 - alpha) * accel_angle_x;
    angle_y = alpha * gyro_angle_y + (1.0 - alpha) * accel_angle_y;
    angle_z = gyro_angle_z;  //Accelerometer doesn’t give z-angle

    //printf("%4.2f %4.2f %4.2f\r\n",angle_x,angle_y,angle_z);

    //// Update the saved data with the latest values
    set_last_read_angle_data(t_now, angle_x, angle_y, angle_z, unfiltered_gyro_angle_x, unfiltered_gyro_angle_y, unfiltered_gyro_angle_z);

   //Stabilisation
   // Stable Mode
    angl = getAngleFromRC(rcBluetooth[ROLL]);
    levelRoll = (getAngleFromRC(rcBluetooth[ROLL]) - angle_x) * PID[LEVELROLL].P;
    levelPitch = (getAngleFromRC(rcBluetooth[PITCH]) - angle_y) * PID[LEVELPITCH].P;
    // Check if pilot commands are not in hover, don't auto trim
//    if ((abs(receiver.getTrimData(ROLL)) > levelOff) || (abs(receiver.getTrimData(PITCH)) > levelOff)) {
//      zeroIntegralError();
//    }
//    else {
      PID[LEVELROLL].integratedError = constrain(PID[LEVELROLL].integratedError + (((getAngleFromRC(rcBluetooth[ROLL]) - angle_x) * dt) * PID[LEVELROLL].I), -LEVEL_LIMIT, LEVEL_LIMIT);
      PID[LEVELPITCH].integratedError = constrain(PID[LEVELPITCH].integratedError + (((getAngleFromRC(rcBluetooth[PITCH]) + angle_y) * dt) * PID[LEVELROLL].I), -LEVEL_LIMIT, LEVEL_LIMIT);
//    }
    //motors.setMotorAxisCommand(ROLL,
    motor[ROLL] = updatePID(rcBluetooth[ROLL] + levelRoll, gyro_x + 1500, &PID[LEVELGYROROLL],dt) + PID[LEVELROLL].integratedError;//);
    //motors.setMotorAxisCommand(PITCH,
    motor[PITCH] = updatePID(rcBluetooth[PITCH] + levelPitch, gyro_y + 1500, &PID[LEVELGYROPITCH],dt) + PID[LEVELPITCH].integratedError;//);
   
    getLastSpeedFromMsg(); 
    
    PWM_SetDC(1, SPEED_0 + SPEED_RANGE*rcSpeed[1] + motor[ROLL] *0.10f); //PE9 | PC6//ON 2ms
  
        //Send data on UART
    *(float*)(aTxBuffer) = angle_x;
    *(float*)(aTxBuffer+4) = angle_y;
    *(float*)(aTxBuffer+8) = angle_z;
    *(float*)(aTxBuffer+12) = motor[ROLL];
    *(float*)(aTxBuffer+16) =  motor[PITCH];
   sendTxDMA((uint32_t)aTxBuffer,20);
   
   //Wait a little bit
   Delay(3); //30 ms
   
  }
}
コード例 #4
0
void _stop(void) {
	PWM_SetDC(1,0);
	PWM_SetDC(2,0);
	PWM_SetDC(3,0);
	PWM_SetDC(4,0);
}
コード例 #5
0
void _turn_right(void) {
	_stop();
	PWM_SetDC(PLATFORM_LEFT_FORWARD ,PLATFORM_PERIOD_PERCENTAGE*MP._Lspeed*MP._left_side._calibrate_speed);
	PWM_SetDC(PLATFORM_RIGHT_BACKWARD ,PLATFORM_PERIOD_PERCENTAGE*MP._Rspeed*MP._right_side._calibrate_speed);
}