Ben Katz
DRV8323RS Version
Dependencies: mbed-dev-f303 FastPWM3
main.cpp
- Committer:
- benkatz
- Date:
- 2017-03-02
- Revision:
- 20:bf9ea5125d52
- Parent:
- 19:bd10a04eedc2
- Child:
- 22:60276ba87ac6
File content as of revision 20:bf9ea5125d52:
const unsigned int BOARDNUM = 0x2;
//const unsigned int a_id =
const unsigned int TX_ID = 0x0100;
const unsigned int cmd_ID = (BOARDNUM<<8) + 0x7;
#include "CANnucleo.h"
#include "mbed.h"
#include "PositionSensor.h"
#include "structs.h"
#include "foc.h"
#include "hw_setup.h"
#include "math_ops.h"
#include "current_controller_config.h"
#include "hw_config.h"
#include "motor_config.h"
GPIOStruct gpio;
ControllerStruct controller;
COMStruct com;
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);
//sendCMD(TX_ID+b_ID, b1);
//sendCMD(TX_ID+c_ID, c1);
}
Serial pc(PA_2, PA_3);
PositionSensorAM5147 spi(16384, 4.7, NPP); ///1 I really need an eeprom or something to store this....
//PositionSensorEncoder encoder(4096, 0, 21);
int count = 0;
void commutate(void){
count ++;
//pc.printf("%f\n\r", controller.theta_elec);
//Get rotor angle
//spi.GetMechPosition();
controller.i_b = I_SCALE*(float)(controller.adc2_raw - controller.adc2_offset); //Calculate phase currents from ADC readings
controller.i_c = I_SCALE*(float)(controller.adc1_raw - controller.adc1_offset);
controller.i_a = -controller.i_b - controller.i_c;
dq0(controller.theta_elec, controller.i_a, controller.i_b, controller.i_c, &controller.i_d, &controller.i_q); //dq0 transform on currents
///Control Law///
float i_d_error = controller.i_d_ref - controller.i_d;
float i_q_error = controller.i_q_ref - controller.i_q;
float v_d_ff = controller.i_d_ref*R_TOTAL; //feed-forward voltage
float v_q_ff = controller.i_q_ref*R_TOTAL;
controller.d_int += i_d_error;
controller.q_int += i_q_error;
limit_norm(&controller.d_int, &controller.q_int, V_BUS/(K_Q*KI_Q));
//controller.d_int = fminf(fmaxf(controller.d_int, -D_INT_LIM), D_INT_LIM);
//controller.q_int = fminf(fmaxf(controller.q_int, -Q_INT_LIM), Q_INT_LIM);
controller.v_d = K_D*i_d_error + K_D*KI_D*controller.d_int;// + v_d_ff;
controller.v_q = K_Q*i_q_error + K_Q*KI_Q*controller.q_int;// + v_q_ff;
//controller.v_d = 10*v_d_ff;
//controller.v_q = 10*v_q_ff;
limit_norm(&controller.v_d, &controller.v_q, controller.v_bus);
abc(controller.theta_elec, controller.v_d, controller.v_q, &controller.v_u, &controller.v_v, &controller.v_w); //inverse dq0 transform on voltages
svm(controller.v_bus, controller.v_u, controller.v_v, controller.v_w, &controller.dtc_u, &controller.dtc_v, &controller.dtc_w); //space vector modulation
gpio.pwm_u->write(1.0f-controller.dtc_u); //write duty cycles
gpio.pwm_v->write(1.0f-controller.dtc_v);
gpio.pwm_w->write(1.0f-controller.dtc_w);
controller.theta_elec = spi.GetElecPosition();
//TIM1->CCR1 = (int)(controller.dtc_u * 0x8CA);//gpio.pwm_u->write(1.0f-controller.dtc_u); //write duty cycles
//TIM1->CCR2 = (int)(controller.dtc_v * 0x8CA);//gpio.pwm_v->write(1.0f-controller.dtc_v);
//TIM1->CCR3 = (int)(controller.dtc_w * 0x8CA);//gpio.pwm_w->write(1.0f-controller.dtc_w);
//gpio.pwm_u->write(1.0f - .1f); //write duty cycles
//gpio.pwm_v->write(1.0f - .1f);
//gpio.pwm_w->write(1.0f - .15f);
if(count >1000){
controller.i_q_ref = -controller.i_q_ref;
count = 0;
//pc.printf("%f\n\r", controller.theta_elec);
//pc.printf("%f %f %f\n\r", controller.i_a, controller.i_b, controller.i_c);
//pc.printf("%f %f\n\r", controller.i_d, controller.i_q);
//pc.printf("%d %d\n\r", controller.adc1_raw, controller.adc2_raw);
}
}
// Current Sampling IRQ
extern "C" void TIM1_UP_TIM10_IRQHandler(void) {
if (TIM1->SR & TIM_SR_UIF ) {
//toggle = 1;
ADC1->CR2 |= 0x40000000;
//volatile int delay;
//for (delay = 0; delay < 55; delay++);
controller.adc2_raw = ADC2->DR;
controller.adc1_raw = ADC1->DR;
//toggle = 0;
commutate();
}
TIM1->SR = 0x0; // reset the status register
}
int main() {
controller.v_bus = V_BUS;
spi.ZeroPosition();
Init_All_HW(&gpio);
wait(.1);
//TIM1->CR1 |= TIM_CR1_UDIS;
gpio.enable->write(1);
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);
reset_foc(&controller);
TIM1->CR1 ^= TIM_CR1_UDIS; //enable interrupt
gpio.enable->write(1);
//gpio.pwm_u->write(1.0f - .05f); //write duty cycles
//gpio.pwm_v->write(1.0f - .05f);
//gpio.pwm_w->write(1.0f - .1f);
wait(.1);
NVIC_SetPriority(TIM5_IRQn, 2);
//loop.attach(&commutate, .000025);
can.frequency(1000000); // set bit rate to 1Mbps
can.attach(&onMsgReceived); // attach 'CAN receive-complete' interrupt handler
can.filter(0x020 << 25, 0xF0000004, CANAny, 0);
pc.baud(921600);
wait(.01);
pc.printf("HobbyKing Cheetah v1.1\n\r");
pc.printf("ADC1 Offset: %d ADC2 Offset: %d", controller.adc1_offset, controller.adc2_offset);
wait(.01);
controller.i_d_ref = 0;
controller.i_q_ref = 0;
while(1) {
}
}