Fork and fix for mwork
Dependencies: mbed-dev-f303 FastPWM3 millis
main.cpp
- Committer:
- benkatz
- Date:
- 2017-04-09
- Revision:
- 25:f5741040c4bb
- Parent:
- 24:58c2d7571207
- Child:
- 26:2b865c00d7e9
File content as of revision 25:f5741040c4bb:
/// high-bandwidth 3-phase motor control, for robots /// Written by benkatz, with much inspiration from bayleyw, nkirkby, scolton, David Otten, and others /// Hardware documentation can be found at build-its.blogspot.com /// Written for the STM32F446, but can be implemented on other STM32 MCU's with some further register-diddling #define REST_MODE 0 #define CALIBRATION_MODE 1 #define TORQUE_MODE 2 #define PD_MODE 3 #define SETUP_MODE 4 #define ENCODER_MODE 5 const unsigned int BOARDNUM = 0x2; //const unsigned int a_id = const unsigned int TX_ID = 0x0100; const unsigned int cmd_ID = (BOARDNUM<<8) + 0x7; float __float_reg[64]; int __int_reg[256]; #include "CANnucleo.h" #include "mbed.h" #include "PositionSensor.h" #include "structs.h" #include "foc.h" #include "calibration.h" #include "hw_setup.h" #include "math_ops.h" #include "current_controller_config.h" #include "hw_config.h" #include "motor_config.h" #include "stm32f4xx_flash.h" #include "FlashWriter.h" #include "user_config.h" #include "PreferenceWriter.h" PreferenceWriter prefs(6); GPIOStruct gpio; ControllerStruct controller; COMStruct com; VelocityEstimatorStruct velocity; CANnucleo::CAN can(PB_8, PB_9); // CAN Rx pin name, CAN Tx pin name CANnucleo::CANMessage rxMsg; CANnucleo::CANMessage txMsg; int ledState; int counter = 0; int canCmd = 1000; volatile bool msgAvailable = false; DigitalOut toggle(PA_0); Ticker loop; /** * @brief 'CAN receive-complete' interrup handler. * @note Called on arrival of new CAN message. * Keep it as short as possible. * @param * @retval */ void onMsgReceived() { msgAvailable = true; //printf("ping\n\r"); } void sendCMD(int TX_addr, int val){ txMsg.clear(); //clear Tx message storage txMsg.id = TX_addr; txMsg << val; can.write(txMsg); //wait(.1); } void readCAN(void){ if(msgAvailable) { msgAvailable = false; // reset flag for next use can.read(rxMsg); // read message into Rx message storage // Filtering performed by software: if(rxMsg.id == cmd_ID) { // See comments in CAN.cpp for filtering performed by hardware rxMsg >> canCmd; // extract first data item } } } void cancontroller(void){ //printf("%d\n\r", canCmd); readCAN(); //sendCMD(TX_ID, canCmd); } Serial pc(PA_2, PA_3); PositionSensorAM5147 spi(16384, 0.0, NPP); PositionSensorEncoder encoder(4096, 0, 21); volatile int count = 0; volatile int state = REST_MODE; volatile int state_change; void enter_menu_state(void){ printf("\n\r\n\r\n\r"); printf(" Commands:\n\r"); printf(" t - Torque Mode\n\r"); printf(" p - PD Mode\n\r"); printf(" c - Calibrate Encoder\n\r"); printf(" s - Setup\n\r"); printf(" e - Display Encoder\n\r"); printf(" esc - Exit to Menu\n\r"); state_change = 0; gpio.enable->write(0); } void enter_setup_state(void){ printf("\n\r\n\r Configuration Options \n\r\n\n"); printf(" %-7s %-25s %-5s %-5s %-5s\n\r\n\r", "prefix", "parameter", "min", "max", "current value"); printf(" %-7s %-25s %-5s %-5s %.1f\n\r", "b", "Current Bandwidth (Hz)", "100", "2000", I_BW); printf(" %-7s %-25s %-5s %-5s %-5i\n\r", "i", "CAN ID", "0", "127", CAN_ID); printf(" %-7s %-25s %-5s %-5s %.1f\n\r", "l", "Torque Limit (N-m)", "0.0", "18.0", TORQUE_LIMIT); printf("\n\r To change a value, type 'prefix''value''ENTER'\n\r i.e. 'b1000''ENTER'\n\r\n\r"); state_change = 0; } void enter_torque_mode(void){ controller.i_d_ref = 0; controller.i_q_ref = 1; // Current Setpoints reset_foc(&controller); // Tesets integrators, and other control loop parameters gpio.enable->write(1); // Enable gate drive GPIOC->ODR ^= (1 << 5); // Turn on status LED state_change = 0; } void calibrate(void){ gpio.enable->write(1); // Enable gate drive GPIOC->ODR ^= (1 << 5); // Turn on status LED order_phases(&spi, &gpio, &controller, &prefs); // Check phase ordering calibrate(&spi, &gpio, &controller, &prefs); // Perform calibration procedure GPIOC->ODR ^= (1 << 5); // Turn off status LED wait(.2); gpio.enable->write(0); // Turn off gate drive printf("\n\r Calibration complete. Press 'esc' to return to menu\n\r"); state_change = 0; } void print_encoder(void){ spi.Sample(); wait(.001); printf(" Mechanical Angle: %f Electrical Angle: %f Raw: %d\n\r", spi.GetMechPosition(), spi.GetElecPosition(), spi.GetRawPosition()); wait(.05); } /// Current Sampling Interrupt /// /// This runs at 40 kHz, regardless of of the mode the controller is in /// extern "C" void TIM1_UP_TIM10_IRQHandler(void) { if (TIM1->SR & TIM_SR_UIF ) { //toggle = 1; ///Sample current always /// ADC1->CR2 |= 0x40000000; // Begin sample and conversion //volatile int delay; //for (delay = 0; delay < 55; delay++); controller.adc2_raw = ADC2->DR; // Read ADC1 and ADC2 Data Registers controller.adc1_raw = ADC1->DR; /// /// Check state machine state, and run the appropriate function /// //printf("%d\n\r", state); switch(state){ case REST_MODE: // Do nothing until if(state_change){ enter_menu_state(); } break; case CALIBRATION_MODE: // Run encoder calibration procedure if(state_change){ calibrate(); } break; case TORQUE_MODE: // Run torque control if(state_change){ enter_torque_mode(); } count++; controller.theta_elec = spi.GetElecPosition(); commutate(&controller, &gpio, controller.theta_elec); // Run current loop spi.Sample(); // Sample position sensor if(count > 100){ count = 0; //readCAN(); //controller.i_q_ref = ((float)(canCmd-1000))/100; //pc.printf("%f\n\r ", controller.theta_elec); } break; case PD_MODE: break; case SETUP_MODE: if(state_change){ enter_setup_state(); } break; case ENCODER_MODE: print_encoder(); break; } } TIM1->SR = 0x0; // reset the status register } char cmd_val[8] = {0}; char cmd_id = 0; char char_count = 0; /// Manage state machine with commands from serial terminal or configurator gui /// /// Called when data received over serial /// void serial_interrupt(void){ while(pc.readable()){ char c = pc.getc(); if(c == 27){ state = REST_MODE; state_change = 1; char_count = 0; cmd_id = 0; for(int i = 0; i<8; i++){cmd_val[i] = 0;} } if(state == REST_MODE){ switch (c){ case 'c': state = CALIBRATION_MODE; state_change = 1; break; case 't': state = TORQUE_MODE; state_change = 1; break; case 'e': state = ENCODER_MODE; state_change = 1; break; case 's': state = SETUP_MODE; state_change = 1; break; } } else if(state == SETUP_MODE){ if(c == 13){ switch (cmd_id){ case 'b': I_BW = fmaxf(fminf(atof(cmd_val), 2000.0f), 100.0f); break; case 'i': CAN_ID = atoi(cmd_val); break; case 'l': TORQUE_LIMIT = fmaxf(fminf(atof(cmd_val), 18.0f), 0.0f); break; default: printf("\n\r '%c' Not a valid command prefix\n\r\n\r", cmd_id); break; } if (!prefs.ready()) prefs.open(); prefs.flush(); // Write new prefs to flash prefs.close(); prefs.load(); state_change = 1; char_count = 0; cmd_id = 0; for(int i = 0; i<8; i++){cmd_val[i] = 0;} } else{ if(char_count == 0){cmd_id = c;} else{ cmd_val[char_count-1] = c; } pc.putc(c); char_count++; } } else if (state == ENCODER_MODE){ switch (c){ case 27: state = REST_MODE; state_change = 1; break; } } } } int main() { controller.v_bus = V_BUS; controller.mode = 0; Init_All_HW(&gpio); // Setup PWM, ADC, GPIO wait(.1); //TIM1->CR1 |= TIM_CR1_UDIS; gpio.enable->write(1); // Enable gate drive gpio.pwm_u->write(1.0f); // Write duty cycles gpio.pwm_v->write(1.0f); gpio.pwm_w->write(1.0f); zero_current(&controller.adc1_offset, &controller.adc2_offset); // Measure current sensor zero-offset //gpio.enable->write(0); reset_foc(&controller); // Reset current controller TIM1->CR1 ^= TIM_CR1_UDIS; //enable interrupt wait(.1); NVIC_SetPriority(TIM5_IRQn, 2); // set interrupt priority can.frequency(1000000); // set bit rate to 1Mbps can.attach(&onMsgReceived); // attach 'CAN receive-complete' interrupt handler can.filter(0x020 << 25, 0xF0000004, CANAny, 0); prefs.load(); // Read flash spi.SetElecOffset(E_OFFSET); // Set position sensor offset int lut[128] = {0}; memcpy(&lut, &ENCODER_LUT, sizeof(lut)); spi.WriteLUT(lut); // Set potision sensor nonlinearity lookup table pc.baud(115200); // set serial baud rate wait(.01); pc.printf("\n\r\n\r HobbyKing Cheetah\n\r\n\r"); wait(.01); printf("\n\r Debug Info:\n\r"); printf(" ADC1 Offset: %d ADC2 Offset: %d\n\r", controller.adc1_offset, controller.adc2_offset); printf(" Position Sensor Electrical Offset: %.4f\n\r", E_OFFSET); printf(" CAN ID: %d\n\r", CAN_ID); pc.attach(&serial_interrupt); // attach serial interrupt state_change = 1; while(1) { } }