Sungwoo Kim
/
HydraulicControlBoard_Rainbow_v1_2_copy
2011
main.cpp
- Committer:
- Lightvalve
- Date:
- 23 months ago
- Revision:
- 244:8586c11b4c30
- Parent:
- 243:1ba0cc8fee52
File content as of revision 244:8586c11b4c30:
//Hydraulic Control Board Rainbow //distributed by Sungwoo Kim // 2022/05/31 #include "mbed.h" #include "FastPWM.h" #include "INIT_HW.h" #include "function_CAN.h" #include "SPI_EEP_ENC.h" #include "setting.h" #include "function_utilities.h" #include "stm32f4xx_flash.h" #include "FlashWriter.h" #include <string> #include <iostream> #include <cmath> // DAC /////////////////////////////////////////// AnalogOut dac_1(PA_4); // 0.0f ~ 1.0f AnalogOut dac_2(PA_5); // 0.0f ~ 1.0f // ADC /////////////////////////////////////////// ADC_HandleTypeDef hadc1; ADC_HandleTypeDef hadc2; ADC_HandleTypeDef hadc3; AnalogIn adc1(PC_4); //pressure_1 AnalogIn adc2(PC_5); //pressure_2 AnalogIn adc3(PC_1); //current AnalogIn adc4(PB_1); //V_EXI AnalogIn adc5(PA_1); //LVDT // PWM /////////////////////////////////////////// float PWM_duty = 0.0f; // SPI /////////////////////////////////////////// SPI eeprom(PB_15, PB_14, PB_13); // EEPROM //(SPI_MOSI, SPI_MISO, SPI_SCK); DigitalOut eeprom_cs(PB_12); SPI enc(PC_12,PC_11,PC_10); DigitalOut enc_cs(PD_2); // LED /////////////////////////////////////////// DigitalOut LED(PA_15); // LVDT /////////////////////////////////////////// DigitalOut LVDT_H(PB_6); DigitalOut LVDT_L(PB_7); // MOTOR_ENA /////////////////////////////////////////// DigitalOut M_ENABLE(PA_2); // CAN /////////////////////////////////////////// CAN can(PB_8, PB_9, 1000000); CANMessage msg; //void onMsgReceived() //{ // CAN_RX_HANDLER(); //} // Variables /////////////////////////////////////////// State pos; State vel; State Vout; State force; State torq; // unit : N State torq_dot; State pres_A; // unit : bar State pres_B; State cur; // unit : mA State valve_pos; State valve_pos_raw; extern int CID_RX_CMD; extern int CID_RX_REF_POSITION; extern int CID_RX_REF_OPENLOOP; extern int CID_RX_REF_PWM; extern int CID_TX_INFO; extern int CID_TX_POS_VEL_TORQ; extern int CID_TX_PWM; extern int CID_TX_CURRENT; extern int CID_TX_VOUT; extern int CID_TX_VALVE_POSITION; extern int CID_TX_SOMETHING; inline float tanh_inv(float y) { if(y >= 1.0f - 0.000001f) y = 1.0f - 0.000001f; if(y <= -1.0f + 0.000001f) y = -1.0f + 0.000001f; return log(sqrt((1.0f+y)/(1.0f-y))); } /******************************************************************************* * REFERENCE MODE ******************************************************************************/ enum _REFERENCE_MODE { MODE_REF_NO_ACT = 0, MODE_REF_DIRECT, MODE_REF_FINDHOME }; /******************************************************************************* * CONTROL MODE ******************************************************************************/ enum _CONTROL_MODE { //control mode MODE_NO_ACT = 0, //0 MODE_VALVE_POSITION_CONTROL, //1 MODE_JOINT_CONTROL, //2 MODE_VALVE_OPEN_LOOP, //3 MODE_JOINT_ADAPTIVE_BACKSTEPPING, //4 MODE_RL, //5 MODE_JOINT_POSITION_PRES_CONTROL_PWM, //6 MODE_JOINT_POSITION_PRES_CONTROL_VALVE_POSITION, //7 MODE_VALVE_POSITION_PRES_CONTROL_LEARNING, //8 MODE_TEST_CURRENT_CONTROL, //9 MODE_TEST_PWM_CONTROL, //10 MODE_CURRENT_CONTROL, //11 MODE_JOINT_POSITION_TORQUE_CONTROL_CURRENT, //12 MODE_JOINT_POSITION_PRES_CONTROL_CURRENT, //13 MODE_VALVE_POSITION_TORQUE_CONTROL_LEARNING, //14 //utility MODE_TORQUE_SENSOR_NULLING = 20, //20 MODE_VALVE_NULLING_AND_DEADZONE_SETTING, //21 MODE_FIND_HOME, //22 MODE_VALVE_GAIN_SETTING, //23 MODE_PRESSURE_SENSOR_NULLING, //24 MODE_PRESSURE_SENSOR_CALIB, //25 MODE_ROTARY_FRICTION_TUNING, //26 MODE_DDV_POS_VS_PWM_ID = 30, //30 MODE_DDV_DEADZONE_AND_CENTER, //31 MODE_DDV_POS_VS_FLOWRATE, //32 MODE_SYSTEM_ID, //33 MODE_FREQ_TEST, //34 MODE_SEND_BUFFER, //35 MODE_SEND_OVER, //36 MODE_STEP_TEST, //37 }; void SystemClock_Config(void) { RCC_OscInitTypeDef RCC_OscInitStruct = {0}; RCC_ClkInitTypeDef RCC_ClkInitStruct = {0}; __HAL_RCC_PWR_CLK_ENABLE(); __HAL_PWR_VOLTAGESCALING_CONFIG(PWR_REGULATOR_VOLTAGE_SCALE1); RCC_OscInitStruct.OscillatorType = RCC_OSCILLATORTYPE_HSE; RCC_OscInitStruct.HSEState = RCC_HSE_ON; // RCC_OscInitStruct.HSICalibrationValue = RCC_HSICALIBRATION_DEFAULT; RCC_OscInitStruct.PLL.PLLState = RCC_PLL_ON; RCC_OscInitStruct.PLL.PLLSource = RCC_PLLSOURCE_HSE; RCC_OscInitStruct.PLL.PLLM = 4;//4 RCC_OscInitStruct.PLL.PLLN = 96; //96 RCC_OscInitStruct.PLL.PLLP = RCC_PLLP_DIV2; RCC_OscInitStruct.PLL.PLLQ = 2; RCC_OscInitStruct.PLL.PLLR = 2; if (HAL_RCC_OscConfig(&RCC_OscInitStruct) != HAL_OK) { //Error_Handler(); } if (HAL_PWREx_EnableOverDrive() != HAL_OK) { //Error_Handler(); } 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_DIV4; RCC_ClkInitStruct.APB2CLKDivider = RCC_HCLK_DIV2; } int main() { HAL_Init(); SystemClock_Config(); LED = 0; // SPI INIT eeprom_cs = 1; eeprom.format(8,3); eeprom.frequency(5000000); //5M eeprom_cs = 0; make_delay(); enc_cs = 1; enc.format(8,0); enc.frequency(5000000); //10M enc_cs = 0; make_delay(); // spi _ enc spi_enc_set_init(); make_delay(); // bno rom spi_eeprom_write(RID_BNO, (int16_t) 0); make_delay(); //////// // rom ROM_CALL_DATA(); make_delay(); // ADC init RCC->APB2ENR |= RCC_APB2ENR_ADC1EN; // clock for ADC3 RCC->APB2ENR |= RCC_APB2ENR_ADC2EN; // clock for ADC2 RCC->APB2ENR |= RCC_APB2ENR_ADC3EN; // clock for ADC1 RCC->AHB1ENR |= RCC_AHB1ENR_GPIOAEN; // Enable clock for GPIOC RCC->AHB1ENR |= RCC_AHB1ENR_GPIOBEN; // Enable clock for GPIOB RCC->AHB1ENR |= RCC_AHB1ENR_GPIOCEN; // Enable clock for GPIOB Init_ADC1(); Init_ADC2(); Init_ADC3(); make_delay(); // CAN can.attach(&CAN_RX_HANDLER); CAN_ID_INIT(); make_delay(); //can.reset(); can.filter(msg.id, 0xFFFFF000, CANStandard); // can.filter(0b100000000, 0b100000010, CANStandard); //CAN ID 100~400번대 통과하게 // TMR1 init (PWM) Init_TMR1(); TIM1->CR1 &= ~(TIM_CR1_UDIS); make_delay(); // TMR2 init (Control) Init_TMR2(); TIM2->CR1 &= ~(TIM_CR1_UDIS); make_delay(); // TMR3 init (Sensors) Init_TMR3(); TIM3->CR1 &= ~(TIM_CR1_UDIS); make_delay(); // TIM4 init (LVDT) Init_TIM4(); TIM4->CR1 &= ~(TIM_CR1_UDIS); make_delay(); //Timer priority NVIC_SetPriority(TIM3_IRQn, 3); NVIC_SetPriority(TIM2_IRQn, 4); NVIC_SetPriority(TIM4_IRQn, 2); HAL_NVIC_SetPriority(CAN1_RX0_IRQn, 14, 0); //DAC init if (SENSING_MODE == 0) { dac_1 = FORCE_VREF / 3.3f; dac_2 = 0.0f; } else if (SENSING_MODE == 1) { dac_1 = PRES_A_VREF / 3.3f; dac_2 = PRES_B_VREF / 3.3f; } make_delay(); for (int i=0; i<50; i++) { if(i%2==0) ID_index_array[i] = - i * 0.5f; else ID_index_array[i] = (i+1) * 0.5f; } M_ENABLE = 1; /************************************ *** Program is operating! *************************************/ while(1) { // if (LED > 0) LED = 0; // else LED = 1; } } // Velocity feedforward for SW valve float DDV_JOINT_POS_FF(float REF_JOINT_VEL) { int i = 0; float Ref_Valve_Pos_FF = 0.0f; for(i=0; i<VALVE_POS_NUM; i++) { if(REF_JOINT_VEL >= min(JOINT_VEL[i],JOINT_VEL[i+1]) && REF_JOINT_VEL <= max(JOINT_VEL[i],JOINT_VEL[i+1])) { if(i==0) { if(JOINT_VEL[i+1] == JOINT_VEL[i]) { Ref_Valve_Pos_FF = (float) VALVE_CENTER; } else { Ref_Valve_Pos_FF = ((float) 10/(JOINT_VEL[i+1] - JOINT_VEL[i]) * (REF_JOINT_VEL - JOINT_VEL[i])) + (float) VALVE_CENTER; } } else { if(JOINT_VEL[i+1] == JOINT_VEL[i-1]) { Ref_Valve_Pos_FF = (float) VALVE_CENTER; } else { Ref_Valve_Pos_FF = ((float) 10*(ID_index_array[i+1] - ID_index_array[i-1])/(JOINT_VEL[i+1] - JOINT_VEL[i-1]) * (REF_JOINT_VEL - JOINT_VEL[i-1])) + (float) VALVE_CENTER + (float) (10*ID_index_array[i-1]); } } break; } } if(REF_JOINT_VEL > max(JOINT_VEL[VALVE_POS_NUM-1], JOINT_VEL[VALVE_POS_NUM-2])) { Ref_Valve_Pos_FF = (float) VALVE_MAX_POS; } else if(REF_JOINT_VEL < min(JOINT_VEL[VALVE_POS_NUM-1], JOINT_VEL[VALVE_POS_NUM-2])) { Ref_Valve_Pos_FF = (float) VALVE_MIN_POS; } Ref_Valve_Pos_FF = (float) VELOCITY_COMP_GAIN * 0.01f * (float) (Ref_Valve_Pos_FF - (float) VALVE_CENTER); //VELOCITY_COMP_GAIN : 0~100 return Ref_Valve_Pos_FF; } // Valve feedforward for SW valve void VALVE_POS_CONTROL(float REF_VALVE_POS) { int i = 0; if(REF_VALVE_POS > VALVE_MAX_POS) { REF_VALVE_POS = VALVE_MAX_POS; } else if(REF_VALVE_POS < VALVE_MIN_POS) { REF_VALVE_POS = VALVE_MIN_POS; } valve_pos_err = (float) (REF_VALVE_POS - valve_pos.sen); valve_pos_err_diff = valve_pos_err - valve_pos_err_old; valve_pos_err_old = valve_pos_err; valve_pos_err_sum += valve_pos_err; if (valve_pos_err_sum > 1000.0f) valve_pos_err_sum = 1000.0f; if (valve_pos_err_sum<-1000.0f) valve_pos_err_sum = -1000.0f; VALVE_PWM_RAW_FB = P_GAIN_VALVE_POSITION * valve_pos_err + I_GAIN_VALVE_POSITION * valve_pos_err_sum + D_GAIN_VALVE_POSITION * valve_pos_err_diff; for(i=0; i<24; i++) { if(REF_VALVE_POS >= min(VALVE_POS_VS_PWM[i],VALVE_POS_VS_PWM[i+1]) && (float) REF_VALVE_POS <= max(VALVE_POS_VS_PWM[i],VALVE_POS_VS_PWM[i+1])) { if(i==0) { VALVE_PWM_RAW_FF = (float) 1000.0f / (float) (VALVE_POS_VS_PWM[i+1] - VALVE_POS_VS_PWM[i]) * ((float) REF_VALVE_POS - VALVE_POS_VS_PWM[i]); } else { VALVE_PWM_RAW_FF = (float) 1000.0f* (float) (ID_index_array[i+1] - ID_index_array[i-1])/(VALVE_POS_VS_PWM[i+1] - VALVE_POS_VS_PWM[i-1]) * ((float) REF_VALVE_POS - VALVE_POS_VS_PWM[i-1]) + 1000.0f * (float) ID_index_array[i-1]; } break; } } Vout.ref = VALVE_PWM_RAW_FF + VALVE_PWM_RAW_FB; // int R_FET = 1.5f; // int R_Motor = 5.4f; // Vout.ref = Vout.ref + Vout.ref/R_Motor*R_FET*2.0f; } // Valve feedforward for SW valve void VALVE_POS_CONTROL_DZ(float REF_VALVE_POS) { int i = 0; if(REF_VALVE_POS > VALVE_MAX_POS) { REF_VALVE_POS = VALVE_MAX_POS; } else if(REF_VALVE_POS < VALVE_MIN_POS) { REF_VALVE_POS = VALVE_MIN_POS; } valve_pos_err = (float) (REF_VALVE_POS - valve_pos.sen); valve_pos_err_diff = valve_pos_err - valve_pos_err_old; valve_pos_err_old = valve_pos_err; valve_pos_err_sum += valve_pos_err; if (valve_pos_err_sum > 1000.0f) valve_pos_err_sum = 1000.0f; if (valve_pos_err_sum<-1000.0f) valve_pos_err_sum = -1000.0f; VALVE_PWM_RAW_FB = P_GAIN_VALVE_POSITION * valve_pos_err + I_GAIN_VALVE_POSITION * valve_pos_err_sum + D_GAIN_VALVE_POSITION * valve_pos_err_diff; for(i=0; i<24; i++) { if(REF_VALVE_POS >= min(VALVE_POS_VS_PWM[i],VALVE_POS_VS_PWM[i+1]) && (float) REF_VALVE_POS <= max(VALVE_POS_VS_PWM[i],VALVE_POS_VS_PWM[i+1])) { if(i==0) { VALVE_PWM_RAW_FF = (float) 1000.0f / (float) (VALVE_POS_VS_PWM[i+1] - VALVE_POS_VS_PWM[i]) * ((float) REF_VALVE_POS - VALVE_POS_VS_PWM[i]); } else { VALVE_PWM_RAW_FF = (float) 1000.0f* (float) (ID_index_array[i+1] - ID_index_array[i-1])/(VALVE_POS_VS_PWM[i+1] - VALVE_POS_VS_PWM[i-1]) * ((float) REF_VALVE_POS - VALVE_POS_VS_PWM[i-1]) + 1000.0f * (float) ID_index_array[i-1]; } break; } } Vout.ref = VALVE_PWM_RAW_FF + VALVE_PWM_RAW_FB; // int R_FET = 1.5f; // int R_Motor = 5.4f; // Vout.ref = Vout.ref + Vout.ref/R_Motor*R_FET*2.0f; } // PWM duty vs. voltage output of L6205 in STM board #define LT_MAX_IDX 57 float LT_PWM_duty[LT_MAX_IDX] = {-100.0f, -80.0f, -60.0f, -50.0f, -40.0f, -35.0f, -30.0f, -25.0f, -20.0f, -19.0f, -18.0f, -17.0f, -16.0f, -15.0f, -14.0f, -13.0f, -12.0f, -11.0f, -10.0f, -9.0f, -8.0f, -7.0f, -6.0f, -5.0f, -4.0f, -3.0f, -2.0f, -1.0f, 0.0f, 1.0f, 2.0f, 3.0f, 4.0f, 5.0f, 6.0f, 7.0f, 8.0f, 9.0f, 10.0f, 11.0f, 12.0f, 13.0f, 14.0f, 15.0f, 16.0f, 17.0f, 18.0f, 19.0f, 20.0f, 25.0f, 30.0f, 35.0f, 40.0f, 50.0f, 60.0f, 80.0f, 100.0f }; // duty float LT_Voltage_Output[LT_MAX_IDX] = {-230.0f, -215.0f, -192.5f, -185.0f, -177.5f, -170.0f, -164.0f, -160.0f, -150.0f, -150.0f, -145.0f, -145.0f, -145.0f, -135.0f, -135.0f, -135.0f, -127.5f, -127.5f, -115.0f, -115.0f, -115.0F, -100.0f, -100.0f, -100.0f, -60.0f, -60.0f, -10.0f, -5.0f, 0.0f, 7.5f, 14.0f, 14.0f, 14.0f, 42.5f, 42.5f, 42.5f, 80.0f, 80.0f, 105.0f, 105.0f, 105.0f, 120.0f, 120.0f, 120.0f, 131.0f, 131.0f, 140.0f, 140.0f, 140.0f, 155.0f, 160.0f, 170.0f, 174.0f, 182.0f, 191.0f, 212.0f, 230.0f }; // mV float PWM_duty_byLT(float Ref_V) { float PWM_duty = 0.0f; if(Ref_V<LT_Voltage_Output[0]) { PWM_duty = (Ref_V-LT_Voltage_Output[0])/1.5f+LT_PWM_duty[0]; } else if (Ref_V>=LT_Voltage_Output[LT_MAX_IDX-1]) { PWM_duty = (Ref_V-LT_Voltage_Output[LT_MAX_IDX-1])/1.5f+LT_PWM_duty[LT_MAX_IDX-1]; } else { int idx = 0; for(idx=0; idx<LT_MAX_IDX-1; idx++) { float ini_x = LT_Voltage_Output[idx]; float fin_x = LT_Voltage_Output[idx+1]; float ini_y = LT_PWM_duty[idx]; float fin_y = LT_PWM_duty[idx+1]; if(Ref_V>=ini_x && Ref_V<fin_x) { PWM_duty = (fin_y-ini_y)/(fin_x-ini_x)*(Ref_V-ini_x) + ini_y; break; } } } return PWM_duty; } /******************************************************************************* TIMER INTERRUPT *******************************************************************************/ //------------------------------------------------ // TMR3 : Sensor 20kHz //------------------------------------------------ float FREQ_TMR3 = (float)FREQ_20k; long CNT_TMR3 = 0; float DT_TMR3 = (float)DT_20k; extern "C" void TIM3_IRQHandler(void) { if (TIM3->SR & TIM_SR_UIF ) { // if (LED > 0) LED = 0; // else LED = 1; float PSEN1 = 0.0f; float PSEN2 = 0.0f; float CURRENT_SEN = 0.0f; /////////////////////////Current//////////////////////////////////////////////////////////////////////////// HAL_ADC_Start(&hadc2); HAL_ADC_PollForConversion(&hadc2, 1); CURRENT_SEN = (float) HAL_ADC_GetValue(&hadc2); cur.UpdateSen(((float)CURRENT_SEN-2047.5f)/2047.5f*10.0f, FREQ_TMR3, 500.0f); // unit : mA /////////////////////////V_EXI//////////////////////////////////////////////////////////////////////////// HAL_ADC_Start(&hadc2); HAL_ADC_PollForConversion(&hadc2, 1); V_EXI = (float) HAL_ADC_GetValue(&hadc2); /////////////////////////Encoder//////////////////////////////////////////////////////////////////////////// // if (CNT_TMR1 % 2) == 0) { ENC_UPDATE(); // } /////////////////////////Force or Pressure////////////////////////////////////////////////////////////////// if (SENSING_MODE == 0) { // Force sensing HAL_ADC_Start(&hadc1); HAL_ADC_PollForConversion(&hadc1, 1); PSEN1 = (float) HAL_ADC_GetValue(&hadc1); HAL_ADC_Start(&hadc1); HAL_ADC_PollForConversion(&hadc1, 1); PSEN2 = (float) HAL_ADC_GetValue(&hadc1); force.UpdateSen((((float)PSEN1) - 2047.5f)/TORQUE_SENSOR_PULSE_PER_TORQUE, FREQ_TMR3, 100.0f); // unit : N //100Hz } else if (SENSING_MODE == 1) { // Pressure sensing HAL_ADC_Start(&hadc1); HAL_ADC_PollForConversion(&hadc1, 1); PSEN1 = (float) HAL_ADC_GetValue(&hadc1); HAL_ADC_Start(&hadc1); HAL_ADC_PollForConversion(&hadc1, 1); PSEN2 = (float) HAL_ADC_GetValue(&hadc1); float pres_A_new, pres_B_new; pres_A_new = (((float)PSEN1) - PRES_A_NULL_pulse)/ PRES_SENSOR_A_PULSE_PER_BAR; // unit : bar pres_B_new = (((float)PSEN2) - PRES_B_NULL_pulse)/ PRES_SENSOR_B_PULSE_PER_BAR; pres_A.UpdateSen(pres_A_new,FREQ_TMR3,200.0f); pres_B.UpdateSen(pres_B_new,FREQ_TMR3,200.0f); if ((OPERATING_MODE & 0b01) == 0) { // Rotary Actuator float torq_new = (PISTON_AREA_A * pres_A.sen - PISTON_AREA_B * pres_B.sen) * 0.0001f; // mm^3*bar >> Nm torq.UpdateSen(torq_new,FREQ_TMR3,100.0f); // unit : Nm //1000Hz } else if ((OPERATING_MODE & 0b01) == 1) { // Linear Actuator float force_new = (PISTON_AREA_A * pres_A.sen - PISTON_AREA_B * pres_B.sen) * 0.1f; // mm^2*bar >> N force.UpdateSen(force_new,FREQ_TMR3,100.0f); // unit : N //1000Hz } } CNT_TMR3++; } TIM3->SR = 0x0; // reset the status register } //------------------------------------------------ // TMR4 : LVDT 1kHz //------------------------------------------------ float LVDT_new = 0.0f; float LVDT_old = 0.0f; float LVDT_f_cut = 1000.0f; float LVDT_LPF = 0.0f; float LVDT_sum = 0.0f; float FREQ_TMR4 = (float)FREQ_1k; float DT_TMR4 = (float)DT_1k; long CNT_TMR4 = 0; int TMR4_FREQ_10k = (int)FREQ_10k; extern "C" void TIM4_IRQHandler(void) { if (TIM4->SR & TIM_SR_UIF ) { float LVDT_OUT = 0.0f; LVDT_sum = 0.0f; LVDT_L = 0; LVDT_H = 1; for (int ij = 0; ij<120; ij++) { if (ij < 20) { continue; } else if (ij == 20) { // LED = 1; } else if (ij == 100) { LVDT_H = 0; LVDT_L = 0; } ADC3->CR2 |= 0x40000000; LVDT_new = ((float)ADC3->DR - 2047.0f); if(DIR_VALVE_ENC < 0) LVDT_new = 0.0f - LVDT_new; LVDT_sum = LVDT_sum + LVDT_new; } // LED = 0; // LVDT_H = 0; // LVDT_L = 0; LVDT_new = (LVDT_sum + 2047.0f * 100.0f) * 0.01f; float alpha_LVDT = 1.0f/(1.0f+TMR_FREQ_1k/(2.0f*PI*300.0f)); LVDT_LPF = (1.0f-alpha_LVDT) * LVDT_LPF + alpha_LVDT * LVDT_new; valve_pos.sen = LVDT_LPF; CNT_TMR4++; } TIM4->SR = 0x0; // reset the status register } //------------------------------------------------ // TMR2 : Control 5kHz //------------------------------------------------ float FREQ_TMR2 = (float)FREQ_5k; float DT_TMR2 = (float)DT_5k; int cnt_trans = 0; int cnt_jitter = 0; extern "C" void TIM2_IRQHandler(void) { if (TIM2->SR & TIM_SR_UIF ) { LED = 1; if(MODE_POS_FT_TRANS == 1) { if (alpha_trans == 1.0f) MODE_POS_FT_TRANS = 2; alpha_trans = (float)(1.0f - cos(3.141592f * (float)cnt_trans * DT_TMR2 /3.0f))/2.0f; cnt_trans++; torq.err_int = 0.0f; force.err_int = 0.0f; if((float)cnt_trans * DT_TMR2 > 3.0f) MODE_POS_FT_TRANS = 2; } else if(MODE_POS_FT_TRANS == 3) { if (alpha_trans == 0.0f) MODE_POS_FT_TRANS = 0; alpha_trans = (float)(1.0f + cos(3.141592f * (float)cnt_trans * DT_TMR2 /3.0f))/2.0f; cnt_trans++; torq.err_int = 0.0f; force.err_int = 0.0f; if((float) cnt_trans * DT_TMR2 > 3.0f ) MODE_POS_FT_TRANS = 0; } else if(MODE_POS_FT_TRANS == 2) { alpha_trans = 1.0f; cnt_trans = 0; } else { alpha_trans = 0.0f; cnt_trans = 0; } // Reference Update ========================================================== switch (REFERENCE_MODE) { case MODE_REF_NO_ACT: { break; } case MODE_REF_DIRECT: { pos.ref = REF_POSITION; vel.ref = REF_VELOCITY; torq.ref = REF_TORQUE; force.ref = REF_FORCE; break; } case MODE_REF_FINDHOME: { pos.ref = REF_POSITION_FINDHOME; vel.ref = 0.0f; torq.ref = 0.0f; force.ref = 0.0f; break; } default: break; } if (((OPERATING_MODE&0b110)>>1) == 0) { K_v = 1.03f; // Q = K_v*sqrt(deltaP)*tanh(C_d*Xv); C_d = 0.16f; mV_PER_mA = 500.0f; // 5000mV/10mA mV_PER_pulse = 0.5f; // 5000mV/10000pulse mA_PER_pulse = 0.001f; // 10mA/10000pulse } else if (((OPERATING_MODE&0b110)>>1) == 1) { K_v = 0.5f; // KNR (LPM >> mA) , 100bar mV_PER_mA = 166.6666f; // 5000mV/30mA mV_PER_pulse = 0.5f; // 5000mV/10000pulse mA_PER_pulse = 0.003f; // 30mA/10000pulse } else if (((OPERATING_MODE&0b110)>>1) == 2) { C_d = 0.0000845f; // Q = C_d * Valve_pos * sqrt(deltaP*alpha/(1+alpha)) : Valve_pos = 10000, deltaP = 70, alpha = 1 -> Q = 5 } // ===================================================================== // CONTROL LOOP -------------------------------------------------------- // ===================================================================== int UTILITY_MODE = 0; int CONTROL_MODE = 0; if (CONTROL_UTILITY_MODE >= 20 || CONTROL_UTILITY_MODE == 0) { UTILITY_MODE = CONTROL_UTILITY_MODE; CONTROL_MODE = MODE_NO_ACT; } else { CONTROL_MODE = CONTROL_UTILITY_MODE; UTILITY_MODE = MODE_NO_ACT; } // UTILITY MODE ------------------------------------------------------------ switch (UTILITY_MODE) { case MODE_NO_ACT: { break; } case MODE_TORQUE_SENSOR_NULLING: { static float FORCE_pulse_sum = 0.0f; static float PresA_pulse_sum = 0.0f; static float PresB_pulse_sum = 0.0f; // DAC Voltage reference set float VREF_TuningGain = -0.000003f; if (TMR3_COUNT_TORQUE_NULL < TMR_FREQ_5k * 5) { LED = 1; if(SENSING_MODE == 0) { // Force Sensor (Loadcell) FORCE_pulse_sum = FORCE_pulse_sum + force.sen*TORQUE_SENSOR_PULSE_PER_TORQUE; if (TMR3_COUNT_TORQUE_NULL % 10 == 0) { float FORCE_pluse_mean = FORCE_pulse_sum / 10.0f; FORCE_pulse_sum = 0.0f; FORCE_VREF += VREF_TuningGain * (0.0f - FORCE_pluse_mean); if (FORCE_VREF > 3.3f) FORCE_VREF = 3.3f; if (FORCE_VREF < 0.0f) FORCE_VREF = 0.0f; dac_1 = FORCE_VREF / 3.3f; } } else if (SENSING_MODE == 1) { // Pressure Sensor PresA_pulse_sum += pres_A.sen*PRES_SENSOR_A_PULSE_PER_BAR; PresB_pulse_sum += pres_B.sen*PRES_SENSOR_B_PULSE_PER_BAR; if (TMR3_COUNT_TORQUE_NULL % 10 == 0) { float PresA_pluse_mean = PresA_pulse_sum / 10.0f; float PresB_pluse_mean = PresB_pulse_sum / 10.0f; PresA_pulse_sum = 0.0f; PresB_pulse_sum = 0.0f; PRES_A_VREF += VREF_TuningGain * (0.0f - PresA_pluse_mean); if (PRES_A_VREF > 3.3f) PRES_A_VREF = 3.3f; if (PRES_A_VREF < 0.0f) PRES_A_VREF = 0.0f; dac_1 = PRES_A_VREF / 3.3f; PRES_B_VREF += VREF_TuningGain * (0.0f - PresB_pluse_mean); if (PRES_B_VREF > 3.3f) PRES_B_VREF = 3.3f; if (PRES_B_VREF < 0.0f) PRES_B_VREF = 0.0f; dac_2 = PRES_B_VREF / 3.3f; } } TMR3_COUNT_TORQUE_NULL++; } else { if(SENSING_MODE == 0 ) { // Force Sensor (Loadcell) FORCE_pulse_sum = 0.0f; dac_1 = FORCE_VREF / 3.3f; spi_eeprom_write(RID_FORCE_SENSOR_VREF, (int16_t)(FORCE_VREF * 1000.0f)); } else if (SENSING_MODE == 1) { PresA_pulse_sum = 0.0f; PresB_pulse_sum = 0.0f; dac_1 = PRES_A_VREF / 3.3f; dac_2 = PRES_B_VREF / 3.3f; spi_eeprom_write(RID_PRES_A_SENSOR_VREF, (int16_t)(PRES_A_VREF * 1000.0f)); spi_eeprom_write(RID_PRES_B_SENSOR_VREF, (int16_t)(PRES_B_VREF * 1000.0f)); } CONTROL_UTILITY_MODE = MODE_NO_ACT; TMR3_COUNT_TORQUE_NULL = 0; } break; } case MODE_FIND_HOME: { static int cnt_findhome = 0; static int cnt_terminate_findhome = 0; static float FINDHOME_POSITION_pulse = 0.0f; static float FINDHOME_POSITION_pulse_OLD = 0.0f; static float FINDHOME_VELOCITY_pulse = 0.0f; static float REF_POSITION_FINDHOME_INIT = 0.0f; if (FINDHOME_STAGE == FINDHOME_INIT) { REFERENCE_MODE = MODE_REF_FINDHOME; cnt_findhome = 0; cnt_terminate_findhome = 0; pos.ref = pos.sen; vel.ref = 0.0f; REF_POSITION_FINDHOME = pos.ref; FINDHOME_STAGE = FINDHOME_GOTOLIMIT; } else if (FINDHOME_STAGE == FINDHOME_GOTOLIMIT) { int cnt_check_enc = (TMR_FREQ_5k/20); // 5000/20 = 250tic = 50msec if(cnt_findhome%cnt_check_enc == 0) { FINDHOME_POSITION_pulse = pos.sen*ENC_PULSE_PER_POSITION; FINDHOME_VELOCITY_pulse = FINDHOME_POSITION_pulse - FINDHOME_POSITION_pulse_OLD; FINDHOME_POSITION_pulse_OLD = FINDHOME_POSITION_pulse; } cnt_findhome++; if (fabs(FINDHOME_VELOCITY_pulse) <= 1) { cnt_terminate_findhome = cnt_terminate_findhome + 1; } else { cnt_terminate_findhome = 0; } if ((cnt_terminate_findhome < 3*TMR_FREQ_5k) && cnt_findhome < 10*TMR_FREQ_5k) { // wait for 3sec double GOTOHOME_SPEED = 10.0f; // 20mm/s or 20deg/s if (HOMEPOS_OFFSET > 0) { REF_POSITION_FINDHOME = REF_POSITION_FINDHOME + GOTOHOME_SPEED*DT_5k; } else { REF_POSITION_FINDHOME = REF_POSITION_FINDHOME - GOTOHOME_SPEED*DT_5k; } CONTROL_MODE = MODE_JOINT_CONTROL; alpha_trans = 0.0f; } else { ENC_SET((long)((long)HOMEPOS_OFFSET*10)); REF_POSITION_FINDHOME_INIT = (float)((long)HOMEPOS_OFFSET*10); FINDHOME_POSITION_pulse = 0; FINDHOME_POSITION_pulse_OLD = 0; FINDHOME_VELOCITY_pulse = 0; cnt_findhome = 0; cnt_terminate_findhome = 0; pos.ref = 0.0f; FINDHOME_STAGE = FINDHOME_ZEROPOSE; } } else if (FINDHOME_STAGE == FINDHOME_ZEROPOSE) { // int T_move = 2*TMR_FREQ_5k; int T_move = 10000; REF_POSITION_FINDHOME = ((0.0f - REF_POSITION_FINDHOME_INIT)*0.5f*(1.0f - cos(3.14159f * (float)cnt_findhome / (float)T_move)) + (float)REF_POSITION_FINDHOME_INIT)/ENC_PULSE_PER_POSITION; cnt_findhome++; REFERENCE_MODE = MODE_REF_FINDHOME; CONTROL_MODE = MODE_JOINT_CONTROL; alpha_trans = 0.0f; if (cnt_findhome >= T_move) { cnt_findhome = 0; pos.ref = 0.0f; FINDHOME_STAGE = FINDHOME_INIT; CONTROL_UTILITY_MODE = MODE_JOINT_CONTROL; REFERENCE_MODE = MODE_REF_DIRECT; } } break; } case MODE_DDV_POS_VS_PWM_ID: { CONTROL_MODE = MODE_VALVE_OPEN_LOOP; VALVE_ID_timer = VALVE_ID_timer + 1; if(VALVE_ID_timer < TMR_FREQ_5k*1) { Vout.ref = 3000.0f * sin(2.0f*3.14159f*VALVE_ID_timer/TMR_FREQ_5k * 100.0f); } else if(VALVE_ID_timer < TMR_FREQ_5k*2) { Vout.ref = 1000.0f*(ID_index_array[ID_index]); // int R_FET = 1.5f; // int R_Motor = 5.4f; // Vout.ref = Vout.ref + Vout.ref/R_Motor*R_FET*2.0f; } else if(VALVE_ID_timer == TMR_FREQ_5k*2) { VALVE_POS_TMP = 0; data_num = 0; } else if(VALVE_ID_timer < TMR_FREQ_5k*3) { data_num = data_num + 1; VALVE_POS_TMP = VALVE_POS_TMP + valve_pos.sen; } else if(VALVE_ID_timer == TMR_FREQ_5k*3) { Vout.ref = 0.0f; } else { VALVE_POS_AVG[ID_index] = VALVE_POS_TMP / data_num; VALVE_ID_timer = 0; ID_index= ID_index +1; } if(ID_index>=25) { int i; VALVE_POS_AVG_OLD = VALVE_POS_AVG[0]; for(i=0; i<25; i++) { VALVE_POS_VS_PWM[i] = (int16_t) (VALVE_POS_AVG[i]); if(VALVE_POS_AVG[i] > VALVE_POS_AVG_OLD) { VALVE_MAX_POS = VALVE_POS_AVG[i]; VALVE_POS_AVG_OLD = VALVE_MAX_POS; } else if(VALVE_POS_AVG[i] < VALVE_POS_AVG_OLD) { VALVE_MIN_POS = VALVE_POS_AVG[i]; VALVE_POS_AVG_OLD = VALVE_MIN_POS; } } VALVE_ELECTRIC_CENTER = VALVE_POS_VS_PWM[0]; spi_eeprom_write(RID_VALVE_ELECTRIC_CENTER, (int16_t) VALVE_ELECTRIC_CENTER); spi_eeprom_write(RID_VALVE_MAX_POS, (int16_t) VALVE_MAX_POS); spi_eeprom_write(RID_VALVE_MIN_POS, (int16_t) VALVE_MIN_POS); for(int i=0; i<25; i++) { spi_eeprom_write(RID_VALVE_POS_VS_PWM_0 + i, (int16_t) VALVE_POS_VS_PWM[i]); } ID_index = 0; CONTROL_UTILITY_MODE = MODE_NO_ACT; } break; } case MODE_DDV_DEADZONE_AND_CENTER: { CONTROL_MODE = MODE_VALVE_OPEN_LOOP; VALVE_DZ_timer = VALVE_DZ_timer + 1; if(first_check == 0) { if(VALVE_DZ_timer < (int) (1.0f * (float) TMR_FREQ_5k)) { Vout.ref = VALVE_VOLTAGE_LIMIT * 1000.0f; } else if(VALVE_DZ_timer == (int) (1.0f * (float) TMR_FREQ_5k)) { Vout.ref = VALVE_VOLTAGE_LIMIT * 1000.0f; pos_plus_end = pos.sen; } else if(VALVE_DZ_timer < (int) (2.0f * (float) TMR_FREQ_5k)) { Vout.ref = -VALVE_VOLTAGE_LIMIT * 1000.0f; } else if(VALVE_DZ_timer == (int) (2.0f * (float) TMR_FREQ_5k)) { Vout.ref = -VALVE_VOLTAGE_LIMIT * 1000.0f; pos_minus_end = pos.sen; } else if(VALVE_DZ_timer < (int) (3.0f * (float) TMR_FREQ_5k)) { Vout.ref = (float) P_GAIN_JOINT_POSITION * (0.5f * (float) pos_plus_end + 0.5f * (float) pos_minus_end - (float) pos.sen)*(float) 50.0f; } else if(VALVE_DZ_timer < (int) (4.0f * (float) TMR_FREQ_5k)) { Vout.ref = (float) P_GAIN_JOINT_POSITION * (0.5f * (float) pos_plus_end + 0.5f * (float) pos_minus_end - (float) pos.sen)*(float) 50.0f; data_num = data_num + 1; VALVE_POS_TMP = VALVE_POS_TMP + valve_pos.sen; } else if(VALVE_DZ_timer == (int) (4.0f * (float) TMR_FREQ_5k)) { Vout.ref = (float) P_GAIN_JOINT_POSITION * (0.5f * (float) pos_plus_end + 0.5f * (float) pos_minus_end - (float) pos.sen)*(float) 50.0f; DDV_POS_AVG = VALVE_POS_TMP / data_num; START_POS = pos.sen; VALVE_POS_TMP = 0; data_num = 0; } else if(VALVE_DZ_timer < (int) (5.0f * (float) TMR_FREQ_5k)) { valve_pos_raw.ref = DDV_POS_AVG; VALVE_POS_CONTROL(valve_pos_raw.ref); } else if(VALVE_DZ_timer < (int) (6.0f * (float) TMR_FREQ_5k)) { valve_pos_raw.ref = DDV_POS_AVG; VALVE_POS_CONTROL(valve_pos_raw.ref); } else if(VALVE_DZ_timer == (int) (6.0f * (float) TMR_FREQ_5k)) { valve_pos_raw.ref = DDV_POS_AVG; VALVE_POS_CONTROL(valve_pos_raw.ref); FINAL_POS = pos.sen; if((FINAL_POS - START_POS)>1) { DZ_case = 1; } else if((FINAL_POS - START_POS)<-1) { DZ_case = -1; } else { DZ_case = 0; } first_check = 1; DZ_DIRECTION = 1; VALVE_DZ_timer = 0; Ref_Valve_Pos_Old = DDV_POS_AVG; DZ_NUM = 1; DZ_index = 1; } } else { if((DZ_case == -1 && DZ_NUM == 1) | (DZ_case == 1 && DZ_NUM == 1)) { if(VALVE_DZ_timer < (int) (1.0f * (float) TMR_FREQ_5k)) { Vout.ref = (float) P_GAIN_JOINT_POSITION * (0.5f * (float) pos_plus_end + 0.5f * (float) pos_minus_end - (float) pos.sen)*(float) 50.0f; } else if(VALVE_DZ_timer == (int) (1.0f * (float) TMR_FREQ_5k)) { START_POS = pos.sen; } else if(VALVE_DZ_timer < (int) (2.0f * (float) TMR_FREQ_5k)) { // valve_pos_raw.ref = Ref_Valve_Pos_Old - DZ_case * DZ_DIRECTION * 64 / DZ_index; valve_pos_raw.ref = Ref_Valve_Pos_Old - DZ_case * DZ_DIRECTION * 2048 / DZ_index; if(valve_pos_raw.ref <= VALVE_MIN_POS) { valve_pos_raw.ref = VALVE_MIN_POS; } else if(valve_pos_raw.ref >= VALVE_MAX_POS) { valve_pos_raw.ref = VALVE_MAX_POS; } VALVE_POS_CONTROL(valve_pos_raw.ref); } else if(VALVE_DZ_timer == (int) (2.0f * (float) TMR_FREQ_5k)) { Ref_Valve_Pos_Old = valve_pos_raw.ref; FINAL_POS = pos.sen; if((FINAL_POS - START_POS)>1) { DZ_DIRECTION = 1 * DZ_case; } else if((FINAL_POS - START_POS)<-1) { DZ_DIRECTION = -1 * DZ_case; } else { DZ_DIRECTION = 1 * DZ_case; } VALVE_DZ_timer = 0; DZ_index= DZ_index *2; // if(DZ_index >= 128) { if(DZ_index >= 4096) { FIRST_DZ = valve_pos_raw.ref; DZ_NUM = 2; Ref_Valve_Pos_Old = FIRST_DZ; DZ_index = 1; DZ_DIRECTION = 1; } } } else if((DZ_case == -1 && DZ_NUM == 2) | (DZ_case == 1 && DZ_NUM == 2)) { if(VALVE_DZ_timer < (int) (1.0f * (float) TMR_FREQ_5k)) { Vout.ref = (float) P_GAIN_JOINT_POSITION * (0.5f * (float) pos_plus_end + 0.5f * (float) pos_minus_end - (float) pos.sen)*(float) 50.0f; } else if(VALVE_DZ_timer == (int) (1.0f * (float) TMR_FREQ_5k)) { START_POS = pos.sen; } else if(VALVE_DZ_timer < (int) (2.0f * (float) TMR_FREQ_5k)) { // valve_pos_raw.ref = Ref_Valve_Pos_Old - DZ_case * DZ_DIRECTION * 64 / DZ_index; valve_pos_raw.ref = Ref_Valve_Pos_Old - DZ_case * DZ_DIRECTION * 2048 / DZ_index; if(valve_pos_raw.ref <= VALVE_MIN_POS) { valve_pos_raw.ref = VALVE_MIN_POS; } else if(valve_pos_raw.ref >= VALVE_MAX_POS) { valve_pos_raw.ref = VALVE_MAX_POS; } VALVE_POS_CONTROL(valve_pos_raw.ref); } else if(VALVE_DZ_timer == (int) (2.0f * (float) TMR_FREQ_5k)) { Vout.ref = 0.0f; } else if(VALVE_DZ_timer > (int) (2.0f * (float) TMR_FREQ_5k)) { Ref_Valve_Pos_Old = valve_pos_raw.ref; FINAL_POS = pos.sen; if((FINAL_POS - START_POS)>1) { DZ_DIRECTION = 1 * DZ_case; } else if((FINAL_POS - START_POS)<-1) { DZ_DIRECTION = -1 * DZ_case; } else { DZ_DIRECTION = -1 * DZ_case; } VALVE_DZ_timer = 0; DZ_index= DZ_index * 2; // if(DZ_index >= 128) { if(DZ_index >= 4096) { SECOND_DZ = valve_pos_raw.ref; VALVE_CENTER = (int) (0.5f * (float) (FIRST_DZ) + 0.5f * (float) (SECOND_DZ)); first_check = 0; VALVE_DEADZONE_MINUS = (float) FIRST_DZ; VALVE_DEADZONE_PLUS = (float) SECOND_DZ; spi_eeprom_write(RID_VALVE_CNETER, (int16_t) VALVE_CENTER); spi_eeprom_write(RID_VALVE_DEADZONE_PLUS, (int16_t) VALVE_DEADZONE_PLUS); spi_eeprom_write(RID_VALVE_DEADZONE_MINUS, (int16_t) VALVE_DEADZONE_MINUS); CONTROL_UTILITY_MODE = MODE_NO_ACT; DZ_index = 1; } } } else if(DZ_case == 0 && DZ_NUM ==1) { if(VALVE_DZ_timer < (int) (1.0f * (float) TMR_FREQ_5k)) { Vout.ref = (float) P_GAIN_JOINT_POSITION * (0.5f * (float) pos_plus_end + 0.5f * (float) pos_minus_end - (float) pos.sen)*(float) 50.0f; } else if(VALVE_DZ_timer == (int) (1.0f * (float) TMR_FREQ_5k)) { START_POS = pos.sen; } else if(VALVE_DZ_timer < (int) (2.0f * (float) TMR_FREQ_5k)) { // valve_pos_raw.ref = Ref_Valve_Pos_Old - DZ_DIRECTION * 64 / DZ_index; valve_pos_raw.ref = Ref_Valve_Pos_Old - DZ_DIRECTION * 2048 / DZ_index; if(valve_pos_raw.ref <= VALVE_MIN_POS) { valve_pos_raw.ref = VALVE_MIN_POS; } else if(valve_pos_raw.ref >= VALVE_MAX_POS) { valve_pos_raw.ref = VALVE_MAX_POS; } VALVE_POS_CONTROL(valve_pos_raw.ref); } else if(VALVE_DZ_timer == (int) (2.0f * (float) TMR_FREQ_5k)) { Ref_Valve_Pos_Old = valve_pos_raw.ref; FINAL_POS = pos.sen; if((FINAL_POS - START_POS)>1) { DZ_DIRECTION = 1; } else if((FINAL_POS - START_POS)<-1) { DZ_DIRECTION = -1; } else { DZ_DIRECTION = 1; } VALVE_DZ_timer = 0; DZ_index= DZ_index *2; // if(DZ_index >= 128) { if(DZ_index >= 4096) { FIRST_DZ = valve_pos_raw.ref; DZ_NUM = 2; Ref_Valve_Pos_Old = FIRST_DZ; DZ_index = 1; DZ_DIRECTION = 1; } } } else { if(VALVE_DZ_timer < (int) (1.0f * (float) TMR_FREQ_5k)) { Vout.ref = (float) P_GAIN_JOINT_POSITION * (0.5f * (float) pos_plus_end + 0.5f * (float) pos_minus_end - (float) pos.sen)*(float) 50.0f; } else if(VALVE_DZ_timer == (int) (1.0f * (float) TMR_FREQ_5k)) { START_POS = pos.sen; } else if(VALVE_DZ_timer < (int) (2.0f * (float) TMR_FREQ_5k)) { // valve_pos_raw.ref = Ref_Valve_Pos_Old + DZ_DIRECTION * 64 / DZ_index; valve_pos_raw.ref = Ref_Valve_Pos_Old + DZ_DIRECTION * 2048 / DZ_index; if(valve_pos_raw.ref <= VALVE_MIN_POS) { valve_pos_raw.ref = VALVE_MIN_POS; } else if(valve_pos_raw.ref > VALVE_MAX_POS) { valve_pos_raw.ref = VALVE_MAX_POS; } VALVE_POS_CONTROL(valve_pos_raw.ref); } else if(VALVE_DZ_timer == (int) (2.0f * (float) TMR_FREQ_5k)) { Vout.ref = 0.0f; } else if(VALVE_DZ_timer > (int) (2.0f * (float) TMR_FREQ_5k)) { Ref_Valve_Pos_Old = valve_pos_raw.ref; FINAL_POS = pos.sen; if((FINAL_POS - START_POS)>1) { DZ_DIRECTION = -1; } else if((FINAL_POS - START_POS)<-1) { DZ_DIRECTION = 1; } else { DZ_DIRECTION = 1; } VALVE_DZ_timer = 0; DZ_index= DZ_index *2; // if(DZ_index >= 128) { if(DZ_index >= 4096) { SECOND_DZ = valve_pos_raw.ref; VALVE_CENTER = (int) (0.5f * (float) (FIRST_DZ) + 0.5f * (float) (SECOND_DZ)); first_check = 0; VALVE_DEADZONE_MINUS = (float) FIRST_DZ; VALVE_DEADZONE_PLUS = (float) SECOND_DZ; spi_eeprom_write(RID_VALVE_CNETER, (int16_t) VALVE_CENTER); spi_eeprom_write(RID_VALVE_DEADZONE_PLUS, (int16_t) VALVE_DEADZONE_PLUS); spi_eeprom_write(RID_VALVE_DEADZONE_MINUS, (int16_t) VALVE_DEADZONE_MINUS); CONTROL_UTILITY_MODE = MODE_NO_ACT; DZ_index = 1; } } } } break; } case MODE_STEP_TEST: { float valve_pos_ref = 0.0f; if (cnt_step_test < (int) (1.0f * (float) TMR_FREQ_5k)) { valve_pos_ref = 0.0f; } else { valve_pos_ref = 10000.0f; } if(valve_pos_ref >= 0) { valve_pos_raw.ref = (float)VALVE_ELECTRIC_CENTER + (float)valve_pos_ref * ((float)VALVE_MAX_POS-(float)VALVE_ELECTRIC_CENTER)/10000.0f; } else { valve_pos_raw.ref = (float)VALVE_ELECTRIC_CENTER - (float)valve_pos_ref * ((float)VALVE_MIN_POS-(float)VALVE_ELECTRIC_CENTER)/10000.0f; } VALVE_POS_CONTROL_DZ(valve_pos_raw.ref); ref_array[cnt_step_test] = valve_pos_ref; if(valve_pos.sen >= (float) VALVE_ELECTRIC_CENTER) { pos_array[cnt_step_test] = 10000.0f*((float)valve_pos.sen - (float)VALVE_ELECTRIC_CENTER)/((float)VALVE_MAX_POS - (float)VALVE_ELECTRIC_CENTER); } else { pos_array[cnt_step_test] = -10000.0f*((float)valve_pos.sen - (float)VALVE_ELECTRIC_CENTER)/((float)VALVE_MIN_POS - (float)VALVE_ELECTRIC_CENTER); } CONTROL_MODE = MODE_VALVE_OPEN_LOOP; cnt_step_test++; if (cnt_step_test > (int) (2.0f * (float) TMR_FREQ_5k)) { buffer_data_size = cnt_step_test; cnt_step_test = 0; cnt_send_buffer = 0; CONTROL_UTILITY_MODE = MODE_SEND_OVER; CONTROL_MODE = MODE_NO_ACT; } break; } case MODE_SEND_OVER: { CONTROL_UTILITY_MODE = MODE_NO_ACT; CONTROL_MODE = MODE_NO_ACT; break; } case MODE_FREQ_TEST: { float valve_pos_ref = 2500.0f * sin(2.0f * 3.141592f * freq_test_valve_ref * (float) cnt_freq_test * DT_TMR2); if(valve_pos_ref >= 0) { valve_pos_raw.ref = (float)VALVE_ELECTRIC_CENTER + (float)valve_pos_ref * ((float)VALVE_MAX_POS-(float)VALVE_ELECTRIC_CENTER)/10000.0f; } else { valve_pos_raw.ref = (double)VALVE_ELECTRIC_CENTER - (float)valve_pos_ref * ((float)VALVE_MIN_POS-(float)VALVE_ELECTRIC_CENTER)/10000.0f; } VALVE_POS_CONTROL_DZ(valve_pos_raw.ref); ref_array[cnt_freq_test] = valve_pos_ref; // if(value>=(float) VALVE_ELECTRIC_CENTER) { if(valve_pos.sen>=(float) VALVE_ELECTRIC_CENTER) { // pos_array[cnt_freq_test] = 10000.0f*((float)value - (float)VALVE_ELECTRIC_CENTER)/((float)VALVE_MAX_POS - (float)VALVE_ELECTRIC_CENTER); pos_array[cnt_freq_test] = 10000.0f*((float)valve_pos.sen - (float)VALVE_ELECTRIC_CENTER)/((float)VALVE_MAX_POS - (float)VALVE_ELECTRIC_CENTER); } else { // pos_array[cnt_freq_test] = -10000.0f*((float)value - (float)VALVE_ELECTRIC_CENTER)/((float)VALVE_MIN_POS - (float)VALVE_ELECTRIC_CENTER); pos_array[cnt_freq_test] = -10000.0f*((float)valve_pos.sen - (float)VALVE_ELECTRIC_CENTER)/((float)VALVE_MIN_POS - (float)VALVE_ELECTRIC_CENTER); } CONTROL_MODE = MODE_VALVE_OPEN_LOOP; cnt_freq_test++; if (freq_test_valve_ref * (float) cnt_freq_test * DT_TMR2 > 2) { buffer_data_size = cnt_freq_test; cnt_freq_test = 0; cnt_send_buffer = 0; freq_test_valve_ref = freq_test_valve_ref * 1.05f; if (freq_test_valve_ref >= 400) { CONTROL_UTILITY_MODE = MODE_NO_ACT; CONTROL_MODE = MODE_NO_ACT; } CONTROL_MODE = MODE_NO_ACT; CONTROL_UTILITY_MODE = MODE_SEND_OVER; } break; } default: break; } // CONTROL MODE ------------------------------------------------------------ switch (CONTROL_MODE) { case MODE_NO_ACT: { V_out = 0.0f; break; } case MODE_VALVE_POSITION_CONTROL: { if (OPERATING_MODE == 5) { //SW Valve VALVE_POS_CONTROL_DZ(valve_pos.ref); V_out = Vout.ref; } else if (CURRENT_CONTROL_MODE == 0) { //PWM I_REF = valve_pos.ref; } else { I_REF = valve_pos.ref * 0.001f; // Unit : pulse >> mA float I_MAX = 10.0f; // Max : 10mA if (I_REF > I_MAX) { I_REF = I_MAX; } else if (I_REF < -I_MAX) { I_REF = -I_MAX; } } break; } case MODE_JOINT_CONTROL: { float temp_vel_pos = 0.0f; // desired velocity for position control float temp_vel_FT = 0.0f; // desired velocity for force/torque control float temp_vel_ff = 0.0f; // desired velocity for feedforward control float temp_vel = 0.0f; float wn_Pos = 2.0f * PI * 5.0f; // f_cut : 5Hz Position Control pos.err = pos.ref - pos.sen; // Unit : mm or deg vel.err = vel.ref - vel.sen; // Unit : mm/s or deg/s // position control command =============================================================================================================================================== if ((OPERATING_MODE & 0b01) == 0) { // Rotary Mode temp_vel_pos = 0.1f * (P_GAIN_JOINT_POSITION * wn_Pos * pos.err) * PI / 180.0f; // rad/s // L when P-gain = 100, f_cut = 10Hz } else { temp_vel_pos = 0.1f * (P_GAIN_JOINT_POSITION * wn_Pos * pos.err); // mm/s // L when P-gain = 100, f_cut = 10Hz } // torque control command =============================================================================================================================================== float alpha_SpringDamper = 1.0f/(1.0f+TMR_FREQ_5k/(2.0f*PI*30.0f)); K_LPF = (1.0f-alpha_SpringDamper) * K_LPF + alpha_SpringDamper * K_SPRING; D_LPF = (1.0f-alpha_SpringDamper) * D_LPF + alpha_SpringDamper * D_DAMPER; if ((OPERATING_MODE & 0b01) == 0) { // Rotary Mode float torq_ref_act = torq.ref + K_LPF * pos.err + D_LPF * vel.err; // unit : Nm torq.err = torq_ref_act - torq.sen; if (torq.err > 10.0f || torq.err < -10.0f) { torq.err_int += torq.err/((float)TMR_FREQ_5k); } temp_vel_FT = 0.01f * (P_GAIN_JOINT_TORQUE * torq.err + I_GAIN_JOINT_TORQUE * torq.err_int); // Nm >> rad/s } else { float force_ref_act = force.ref + K_LPF * pos.err + D_LPF * vel.err; // unit : N //////////////////////////////////////////////////force_reference_filter//////////////////////////////////////////////////////////////////// // float alpha_torque_ref = 1.0f/(1.0f+TMR_FREQ_5k/(2.0f*PI*1.0f)); // force_ref_filter = (1.0f-alpha_torque_ref) * force_ref_filter + alpha_torque_ref * force_ref_act; //////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////// force.err = force_ref_act - force.sen; if (force.err > 10.0f || force.err < -10.0f) { force.err_int += force.err/((float)TMR_FREQ_5k); } temp_vel_FT = 0.01f * (P_GAIN_JOINT_TORQUE * force.err + I_GAIN_JOINT_TORQUE * force.err_int); // N >> mm/s } // velocity feedforward command ======================================================================================================================================== if ((OPERATING_MODE & 0b01) == 0) { // Rotary Mode temp_vel_ff = 0.01f * (float)VELOCITY_COMP_GAIN * vel.ref * PI / 180.0f; // rad/s } else { temp_vel_ff = 0.01f * (float)VELOCITY_COMP_GAIN * vel.ref; // mm/s } // command integration ================================================================================================================================================= temp_vel = (1.0f - alpha_trans) * temp_vel_pos + alpha_trans * temp_vel_FT + temp_vel_ff; // Position Control + Torque Control + Velocity Feedforward float Qact = 0.0f; // required flow rate float valve_pos_pulse = 0.0f; if( temp_vel > 0.0f ) { Qact = temp_vel * ((float)PISTON_AREA_A * 0.00006f); // mm^3/sec >> LPM if (((OPERATING_MODE&0b110)>>1) == 0 || ((OPERATING_MODE&0b110)>>1) == 1) { //Moog Valve or KNR Valve I_REF = tanh_inv(Qact/(K_v * sqrt(PRES_SUPPLY * alpha3 / (alpha3 + 1.0f))))/C_d; // I_REF = Qact*2.0f; } else { // SW valve valve_pos_pulse = Qact / (C_d * sqrt(PRES_SUPPLY * alpha3 / (alpha3 + 1.0f))); } } else { Qact = temp_vel * ((float)PISTON_AREA_B * 0.00006f); // mm^3/sec >> LPM if (((OPERATING_MODE&0b110)>>1) == 0 || ((OPERATING_MODE&0b110)>>1) == 1) { //Moog Valve or KNR Valve I_REF = tanh_inv(Qact/(K_v * sqrt(PRES_SUPPLY / (alpha3 + 1.0f))))/C_d; // I_REF = Qact*2.0f; } else { // SW valve valve_pos_pulse = Qact / (C_d * sqrt(PRES_SUPPLY / (alpha3 + 1.0f))); } } if (((OPERATING_MODE&0b110)>>1) == 0 || ((OPERATING_MODE&0b110)>>1) == 1) { //Moog Valve or KNR Valve float I_MAX = 10.0f; // Maximum Current : 10mA // Anti-windup for FT if (I_GAIN_JOINT_TORQUE > 0.001f) { float Ka = 2.0f; if (I_REF > I_MAX) { float I_rem = I_REF - I_MAX; I_REF = I_MAX; float temp_vel_rem = K_v * sqrt(PRES_SUPPLY * alpha3 / (alpha3 + 1.0f)) * tanh(C_d*I_rem) / ((double) PISTON_AREA_A * 0.00006f); // Unit : mm/s [linear] / rad/s [rotary] torq.err_int = torq.err_int - Ka * temp_vel_rem * (10000.0f/I_GAIN_JOINT_TORQUE); } else if (I_REF < -I_MAX) { double I_rem = I_REF - (-I_MAX); I_REF = -I_MAX; float temp_vel_rem = K_v * sqrt(PRES_SUPPLY / (alpha3 + 1.0f)) * tanh(C_d*I_rem) / ((double) PISTON_AREA_B * 0.00006f); // Unit : mm/s [linear] / rad/s [rotary] torq.err_int = torq.err_int - Ka * temp_vel_rem * (10000.0f/I_GAIN_JOINT_TORQUE); } } else { if(I_REF > I_MAX) { I_REF = I_MAX; } else if (I_REF < -I_MAX) { I_REF = -I_MAX; } } } else { //SW valve float Valve_pos_MAX = 10000.0f; // Maximum Valve Pos : 10000 // Anti-windup for FT if (I_GAIN_JOINT_TORQUE > 0.001f) { float Ka = 2.0f; if (valve_pos_pulse > Valve_pos_MAX) { float valve_pos_rem = valve_pos_pulse - Valve_pos_MAX; valve_pos_pulse = Valve_pos_MAX; float temp_vel_rem = C_d * valve_pos_rem * sqrt(PRES_SUPPLY * alpha3 / (alpha3 + 1.0f)) / ((double) PISTON_AREA_A * 0.00006f); // Unit : mm/s [linear] / rad/s [rotary] torq.err_int = torq.err_int - Ka * temp_vel_rem * (10000.0f/I_GAIN_JOINT_TORQUE); } else if (valve_pos_pulse < -Valve_pos_MAX) { double valve_pos_rem = valve_pos_pulse - (-Valve_pos_MAX); valve_pos_pulse = -Valve_pos_MAX; float temp_vel_rem = C_d * valve_pos_rem * sqrt(PRES_SUPPLY / (alpha3 + 1.0f)) / ((double) PISTON_AREA_B * 0.00006f); // Unit : mm/s [linear] / rad/s [rotary] torq.err_int = torq.err_int - Ka * temp_vel_rem * (10000.0f/I_GAIN_JOINT_TORQUE); } } else { if(valve_pos_pulse > 10000.0f) { valve_pos_pulse = 10000.0f; } else if(valve_pos_pulse < -10000.0f) { valve_pos_pulse = -10000.0f; } } // float valve_control_deadzone = 5.0f; // if(valve_pos_pulse < valve_control_deadzone && valve_pos_pulse > -valve_control_deadzone) { // valve_pos.ref = ((float) VALVE_DEADZONE_PLUS + (float) VALVE_DEADZONE_MINUS) * 0.5f; // } else if (valve_pos_pulse >= valve_control_deadzone) { // valve_pos.ref = valve_pos_pulse/10000.0f * ((float) VALVE_MAX_POS - (float) VALVE_DEADZONE_PLUS) + (float) VALVE_DEADZONE_PLUS; // } else { // valve_pos.ref = -valve_pos_pulse/10000.0f * ((float) VALVE_MIN_POS - (float) VALVE_DEADZONE_MINUS) + (float) VALVE_DEADZONE_MINUS; // } if (valve_pos_pulse >= 0) { valve_pos.ref = valve_pos_pulse/10000.0f * ((float) VALVE_MAX_POS - (float) VALVE_DEADZONE_PLUS) + (float) VALVE_DEADZONE_PLUS; } else { valve_pos.ref = -valve_pos_pulse/10000.0f * ((float) VALVE_MIN_POS - (float) VALVE_DEADZONE_MINUS) + (float) VALVE_DEADZONE_MINUS; } VALVE_POS_CONTROL_DZ(valve_pos.ref); V_out = Vout.ref; } break; } case MODE_VALVE_OPEN_LOOP: { V_out = (float) Vout.ref; break; } default: break; } if (((OPERATING_MODE&0b110)>>1) == 0 || ((OPERATING_MODE&0b110)>>1) == 1) { //Moog Valve or KNR Valve //////////////////////////////////////////////////////////////////////////// //////////////////////////// CURRENT CONTROL ////////////////////////////// //////////////////////////////////////////////////////////////////////////// if (CURRENT_CONTROL_MODE) { double alpha_update_Iref = 1.0f / (1.0f + 5000.0f / (2.0f * 3.14f * 300.0f)); // f_cutoff : 500Hz I_REF_fil = (1.0f - alpha_update_Iref) * I_REF_fil + alpha_update_Iref*I_REF; if (I_REF_fil > 0.0f) I_REF_fil_DZ = I_REF_fil + (double)VALVE_DEADZONE_PLUS*mA_PER_pulse; // unit: mA else if (I_REF_fil < 0.0f) I_REF_fil_DZ = I_REF_fil + (double)VALVE_DEADZONE_MINUS*mA_PER_pulse; // unit: mA else I_REF_fil_DZ = I_REF_fil + (double)(VALVE_DEADZONE_PLUS+VALVE_DEADZONE_MINUS)/2.0f*mA_PER_pulse; // unit: mA I_ERR = I_REF_fil_DZ - (double)cur.sen; I_ERR_INT = I_ERR_INT + (I_ERR) * 0.0002f; // Moog Valve Current Control Gain double R_model = 500.0f; // ohm double L_model = 1.2f; double w0 = 2.0f * 3.14f * 100.0f; double KP_I = 0.1f * L_model*w0; double KI_I = 0.1f * R_model*w0; // KNR Valve Current Control Gain if (((OPERATING_MODE & 0b110)>>1) == 1) { // KNR Valve R_model = 163.0f; // ohm L_model = 1.0f; w0 = 2.0f * 3.14f * 80.0f; KP_I = 1.0f * L_model*w0; KI_I = 0.08f * R_model*w0; } double FF_gain = 1.0f; VALVE_PWM_RAW = KP_I * 2.0f * I_ERR + KI_I * 2.0f* I_ERR_INT; I_REF_fil_diff = I_REF_fil_DZ - I_REF_fil_old; I_REF_fil_old = I_REF_fil_DZ; // VALVE_PWM_RAW = VALVE_PWM_RAW + FF_gain * (R_model * I_REF_fil + L_model * I_REF_fil_diff * 5000.0f); // Unit : mV VALVE_PWM_RAW = VALVE_PWM_RAW + FF_gain * (R_model * I_REF_fil_DZ); // Unit : mV double V_MAX = VALVE_VOLTAGE_LIMIT*1000.0f; // Maximum Voltage : 12V = 12000mV double Ka = 3.0f / KP_I; if (VALVE_PWM_RAW > V_MAX) { V_rem = VALVE_PWM_RAW - V_MAX; V_rem = Ka*V_rem; VALVE_PWM_RAW = V_MAX; // I_ERR_INT = I_ERR_INT - V_rem * 0.0002f; I_ERR_INT = I_ERR_INT - V_rem; } else if (VALVE_PWM_RAW < -V_MAX) { V_rem = VALVE_PWM_RAW - (-V_MAX); V_rem = Ka*V_rem; VALVE_PWM_RAW = -V_MAX; // I_ERR_INT = I_ERR_INT - V_rem * 0.0002f; I_ERR_INT = I_ERR_INT - V_rem; } } else { VALVE_PWM_RAW = I_REF * mV_PER_mA; } //////////////////////////////////////////////////////////////////////////// ///////////////// Dead Zone Cancellation & Linearization ////////////////// //////////////////////////////////////////////////////////////////////////// // Output Voltage Linearization double CUR_PWM_nonlin = (double)VALVE_PWM_RAW; // Unit : mV double CUR_PWM_lin = PWM_duty_byLT(CUR_PWM_nonlin); // -8000~8000 // Dead Zone Cancellation (Electrical dead-zone) if (CUR_PWM_lin > 0) V_out = (float) (CUR_PWM_lin + 169.0f); else if (CUR_PWM_lin < 0) V_out = (float) (CUR_PWM_lin - 174.0f); else V_out = (float) (CUR_PWM_lin); } else { //////////////////////////sw valve // Output Voltage Linearization & Dead Zone Cancellation (Electrical dead-zone) by SW /////////////Jitter///////////////////// V_out = V_out + 3000.0f*sin(2.0f*3.14159f*500.0f*((float) cnt_jitter)*0.0002f); //4000, 500Hz cnt_jitter++; if(cnt_jitter > 50000000) cnt_jitter = 0; //L6205D if (V_out > 0 ) V_out = 800.0f + V_out*1.1275f; else if (V_out < 0) V_out = -800.0f + V_out*1.1275f; else V_out = 0.0f; } //////////////////////////////////////////////////////////////////// /////////////////// PWM Command /////////////////////////////////// //////////////////////////////////////////////////////////////////// if(DIR_VALVE<0) { V_out = -V_out; } if (V_out >= VALVE_VOLTAGE_LIMIT*1000.0f) { V_out = VALVE_VOLTAGE_LIMIT*1000.0f; } else if(V_out<=-VALVE_VOLTAGE_LIMIT*1000.0f) { V_out = -VALVE_VOLTAGE_LIMIT*1000.0f; } PWM_out= V_out/(SUPPLY_VOLTAGE*1000.0f); // Saturation of output voltage if(PWM_out > 1.0f) PWM_out=1.0f; else if (PWM_out < -1.0f) PWM_out=-1.0f; if (PWM_out>0.0f) { TIM1->CCR1 = (TMR1_COUNT)*(PWM_out); TIM1->CCR2 = (TMR1_COUNT)*(0.0f); } else { TIM1->CCR1 = (TMR1_COUNT)*(0.0f); TIM1->CCR2 = 0.0f -(TMR1_COUNT)*(PWM_out); } //////////////////////////////////////////////////////////////////////////// ////////////////////// Data transmission through CAN ////////////////////// //////////////////////////////////////////////////////////////////////////// // if (TMR2_COUNT_CAN_TX % (int) ((int) TMR_FREQ_5k/CAN_FREQ) == 0) { if (TMR2_COUNT_CAN_TX % (int) ((int) TMR_FREQ_5k/500) == 0) { // Position, Velocity, and Torque (ID:1200) if (flag_data_request[0] == HIGH) { if ((OPERATING_MODE & 0b01) == 0) { // Rotary Actuator CAN_TX_POSITION_FT((int16_t) (pos.sen*200.0f), (int16_t) (vel.sen*20.0f), (int16_t) (torq.sen*TORQUE_SENSOR_PULSE_PER_TORQUE*10.0f)); } else if ((OPERATING_MODE & 0b01) == 1) { // Linear Actuator CAN_TX_POSITION_FT((int16_t) (pos.sen*200.0f), (int16_t) (vel.sen*20.0f), (int16_t) (force.sen*TORQUE_SENSOR_PULSE_PER_TORQUE*10.0f)); } } // Valve Position (ID:1300) if (flag_data_request[1] == HIGH) { if (((OPERATING_MODE&0b110)>>1) == 0 || ((OPERATING_MODE&0b110)>>1) == 1) { //Moog Valve or KNR Valve CAN_TX_PWM((int16_t)(cur.sen/mA_PER_pulse)); } else { float valve_pos_can = 0.0f; if(valve_pos.sen >= VALVE_ELECTRIC_CENTER) { valve_pos_can = 10000.0f*((float)valve_pos.sen-(float)VALVE_ELECTRIC_CENTER)/((float)VALVE_MAX_POS-(float)VALVE_ELECTRIC_CENTER); } else { valve_pos_can = -10000.0f*((float)valve_pos.sen -(float)VALVE_ELECTRIC_CENTER)/((float)VALVE_MIN_POS-(float)VALVE_ELECTRIC_CENTER); } CAN_TX_PWM((int16_t)(valve_pos_can)); } } // Others : SW (ID:1400) if (flag_data_request[2] == HIGH) { CAN_TX_CURRENT((int16_t) valve_pos.sen, (int16_t) valve_pos.ref); } TMR2_COUNT_CAN_TX = 0; } TMR2_COUNT_CAN_TX++; LED = 0; } TIM2->SR = 0x0; // reset the status register }