EENX15/EENX15_LQR/EENX15_LQR.ino

#include <Wire.h>


int lastCorrectionTime = 0;
int lastPrintTime = 0;

static int fastTimer = 80;
static int slowTimer = 800;

//lqr stuff
const uint8_t statesNumber = 4;
/** Low pass filter angular Position*/
float angularPositionLP = 0;
/** Zumo's angular position */
float angularPosition = 0;
/** Corrected angular position */
float correctedAngularPosition = 0;
/** Zumo's angular speed */
float angularSpeed = 0;
/** Motor's angular position */
float motorAngularPosition = 0;
/** Motor's angular speed */
float motorAngularSpeed = 0;

/** PWM signal applied to the motor's driver 255 is 100% */
int32_t speed;
int safe_angle;


//gyro stuff
float AccX, AccY, AccZ;
float GyroX, GyroY, GyroZ;
float accAngleX, accAngleY, gyroAngleX, gyroAngleY, gyroAngleZ;
float roll, pitch, yaw;
float AccErrorX, AccErrorY, GyroErrorX, GyroErrorY, GyroErrorZ;
float elapsedTime, currentTime, previousTime;
int gyro_x, gyro_y, gyro_z;
long gyro_x_cal, gyro_y_cal, gyro_z_cal;
boolean set_gyro_angles;

long acc_x, acc_y, acc_z, acc_total_vector;
float angle_roll_acc, angle_pitch_acc;

float angle_pitch, angle_roll;
int angle_pitch_buffer, angle_roll_buffer;
float angle_pitch_output, angle_roll_output;

long loop_timer;
int temp;

//motor stuff
#define encoderA1 2
#define encoderB1 3

#define encoderA2 4
#define encoderB2 7
volatile int countA = 0;
volatile int countAold = 0;
volatile int countB = 0;

const int MotorPinA = 12;
const int MotorSpeedA = 3;
const int MotorBrakeA = 9;

const int MotorPinB = 13;
const int MotorSpeedB = 11;
const int MotorBrakeB = 8;

const int CCW = HIGH;
const int CW = LOW;

volatile byte half_revolutionsA;
volatile byte half_revolutionsB;
unsigned int rpmA;
unsigned int rpmB;
unsigned long timeoldA;
unsigned long timeoldB;
float rpm = 0;
float rps = 0;

void setup() {
  Wire.begin();
  Serial.begin(115200);
  while (!Serial)
    delay(10); // will pause Zero, Leonardo, etc until serial console opens
  
  gyro_setup();
  
  //motor
  pinMode(encoderA1, INPUT_PULLUP);
  pinMode(encoderB1, INPUT_PULLUP);
  pinMode(encoderA2, INPUT_PULLUP);
  pinMode(encoderB2, INPUT_PULLUP);
  attachInterrupt(digitalPinToInterrupt(encoderA1), pulseA, RISING);
  //attachInterrupt(digitalPinToInterrupt(encoderB1), pulseB, RISING);
  
  pinMode(MotorPinA, OUTPUT);
  pinMode(MotorSpeedA, OUTPUT);
  pinMode(MotorBrakeA, OUTPUT);
  
  pinMode(MotorPinB, OUTPUT);
  pinMode(MotorSpeedB, OUTPUT);
  pinMode(MotorBrakeB, OUTPUT);
}
 
void loop() {
  gyro_loop();
  safe_angle = int(round(angle_pitch_output));

  int m = millis();
  
  if (m - lastCorrectionTime >= fastTimer) { //run this code ever 80ms (12.5hz)
    lastCorrectionTime = m;
    getSpeed();
    setSpeed();
  }
  if (m - lastPrintTime >= slowTimer) { //run this code ever 800ms (1.25hz)
    lastPrintTime = m;
    printInfo();
  }
}
void getSpeed() {
  float alpha = 2.0 / (20.0 + 1.0); //alfa aka EMA length. 10 length = 20*20ms=0.2s
  int ticks = countA-countAold;
  float rpm_new = ticks*50*60/56.0; //ticks * 50 hz * 60s / ticks per rotation
  float rps_new = ticks*50/8.91; //ticks * 50hz/ ticks per rad  
  rpm = rpm*(1-alpha)+rpm_new*alpha;
  rps = rps*(1-alpha)+rps_new*alpha;
  countAold = countA;
}
void printInfo(){
  Serial.println("");
  Serial.print("pitch Angle  = "); Serial.println(angle_pitch_output);
  Serial.print("pitch Angle abs = "); Serial.println(abs(safe_angle));
  Serial.print("pitch Angle measured = "); Serial.println(angle_pitch);
  Serial.print("Position: "); Serial.println(countA);
  Serial.print("Full Rotations: "); Serial.println(countA/56.0); //ca. 56 tick per rotation
  Serial.print("Rads rotated: "); Serial.println(countA/8.91); //ca. 56 tick per rotation, 6.26 rads per rotation
  Serial.print("RPM: "); Serial.println(rpm); //ca. 56 tick per rotation
  Serial.print("Rads per second: "); Serial.println(rps); //ca. 56 tick per rotation, 6.26 rads per rotation
  
  //Serial.print("A: "); Serial.println(countA);
  //Serial.print("B: "); Serial.println(countB);
}

void setSpeed(){
  if(abs(safe_angle)<50 ){
    speed = 8*safe_angle;
    if(speed<0){
      digitalWrite(MotorPinB, CW);
      digitalWrite(MotorPinA, CCW);
      speed -= 30;
    }
    else if(speed>0){
      digitalWrite(MotorPinB, CCW);
      digitalWrite(MotorPinA, CW);
      speed += 30;
    }
    else {
      speed = 0;
    }
    speed = abs(speed);
    speed = constrain(speed, 0, 249);
    analogWrite(MotorSpeedB, speed); //Wheel close to connections
    analogWrite(MotorSpeedA, speed); //First experiment wheel
  }
  else{
    speed = 0;
    analogWrite(MotorSpeedB, speed);
    analogWrite(MotorSpeedA, speed);
  } 
}
int directionA(){
  if(digitalRead(encoderA2) ==  HIGH){                             
    return 1;  
  }
  else{
    return -1;
  }
}

int directionB(){
  if(digitalRead(encoderB2) ==  HIGH){                             
    return 1;  
  }
  else{
    return -1;
  }
}

void pulseA(){  
  countA += directionA();
}

void pulseB(){  
  countB += directionB();
}
wire.begin 2021-04-13 21:51:43 +02:00			`#include <Wire.h>`

adding conditions to run things ever x ms 2021-04-14 01:54:01 +02:00
			`int lastCorrectionTime = 0;`
			`int lastPrintTime = 0;`

turn timings into variables 2021-04-14 02:49:29 +02:00			`static int fastTimer = 80;`
			`static int slowTimer = 800;`
add file from last commit to master folder 2021-04-13 20:17:11 +02:00
move gyroscope code into seperate file, add lqr code file 2021-04-13 21:44:53 +02:00			`//lqr stuff`
			`const uint8_t statesNumber = 4;`
			`/** Low pass filter angular Position*/`
			`float angularPositionLP = 0;`
			`/** Zumo's angular position */`
			`float angularPosition = 0;`
			`/** Corrected angular position */`
			`float correctedAngularPosition = 0;`
			`/** Zumo's angular speed */`
			`float angularSpeed = 0;`
			`/** Motor's angular position */`
			`float motorAngularPosition = 0;`
			`/** Motor's angular speed */`
			`float motorAngularSpeed = 0;`
use speed var, set variable for safe angle for simplicity 2021-04-13 22:09:37 +02:00
			`/** PWM signal applied to the motor's driver 255 is 100% */`
move gyroscope code into seperate file, add lqr code file 2021-04-13 21:44:53 +02:00			`int32_t speed;`
use speed var, set variable for safe angle for simplicity 2021-04-13 22:09:37 +02:00			`int safe_angle;`
move gyroscope code into seperate file, add lqr code file 2021-04-13 21:44:53 +02:00

			`//gyro stuff`
add file from last commit to master folder 2021-04-13 20:17:11 +02:00			`float AccX, AccY, AccZ;`
			`float GyroX, GyroY, GyroZ;`
			`float accAngleX, accAngleY, gyroAngleX, gyroAngleY, gyroAngleZ;`
			`float roll, pitch, yaw;`
			`float AccErrorX, AccErrorY, GyroErrorX, GyroErrorY, GyroErrorZ;`
			`float elapsedTime, currentTime, previousTime;`
			`int gyro_x, gyro_y, gyro_z;`
			`long gyro_x_cal, gyro_y_cal, gyro_z_cal;`
			`boolean set_gyro_angles;`

			`long acc_x, acc_y, acc_z, acc_total_vector;`
			`float angle_roll_acc, angle_pitch_acc;`

			`float angle_pitch, angle_roll;`
			`int angle_pitch_buffer, angle_roll_buffer;`
			`float angle_pitch_output, angle_roll_output;`

			`long loop_timer;`
			`int temp;`

			`//motor stuff`
encoder HAL interrupts for position (Net rotations) 2021-04-14 00:20:35 +02:00			`#define encoderA1 2`
			`#define encoderB1 3`

			`#define encoderA2 4`
			`#define encoderB2 7`
			`volatile int countA = 0;`
function for getting RPM, checkpoint. sorta working 2021-04-14 01:55:49 +02:00			`volatile int countAold = 0;`
encoder HAL interrupts for position (Net rotations) 2021-04-14 00:20:35 +02:00			`volatile int countB = 0;`

add file from last commit to master folder 2021-04-13 20:17:11 +02:00			`const int MotorPinA = 12;`
			`const int MotorSpeedA = 3;`
			`const int MotorBrakeA = 9;`

			`const int MotorPinB = 13;`
			`const int MotorSpeedB = 11;`
			`const int MotorBrakeB = 8;`

			`const int CCW = HIGH;`
			`const int CW = LOW;`

			`volatile byte half_revolutionsA;`
			`volatile byte half_revolutionsB;`
			`unsigned int rpmA;`
			`unsigned int rpmB;`
			`unsigned long timeoldA;`
			`unsigned long timeoldB;`
function for getting RPM, checkpoint. sorta working 2021-04-14 01:55:49 +02:00			`float rpm = 0;`
			`float rps = 0;`
add file from last commit to master folder 2021-04-13 20:17:11 +02:00
			`void setup() {`
wire.begin 2021-04-13 21:51:43 +02:00			`Wire.begin();`
add file from last commit to master folder 2021-04-13 20:17:11 +02:00			`Serial.begin(115200);`
			`while (!Serial)`
			`delay(10); // will pause Zero, Leonardo, etc until serial console opens`
move gyroscope code into seperate file, add lqr code file 2021-04-13 21:44:53 +02:00
			`gyro_setup();`
add file from last commit to master folder 2021-04-13 20:17:11 +02:00
			`//motor`
encoder HAL interrupts for position (Net rotations) 2021-04-14 00:20:35 +02:00			`pinMode(encoderA1, INPUT_PULLUP);`
			`pinMode(encoderB1, INPUT_PULLUP);`
			`pinMode(encoderA2, INPUT_PULLUP);`
			`pinMode(encoderB2, INPUT_PULLUP);`
			`attachInterrupt(digitalPinToInterrupt(encoderA1), pulseA, RISING);`
			`//attachInterrupt(digitalPinToInterrupt(encoderB1), pulseB, RISING);`

add file from last commit to master folder 2021-04-13 20:17:11 +02:00			`pinMode(MotorPinA, OUTPUT);`
			`pinMode(MotorSpeedA, OUTPUT);`
			`pinMode(MotorBrakeA, OUTPUT);`

			`pinMode(MotorPinB, OUTPUT);`
			`pinMode(MotorSpeedB, OUTPUT);`
			`pinMode(MotorBrakeB, OUTPUT);`
			`}`
move code between files 2021-04-14 01:52:34 +02:00
add file from last commit to master folder 2021-04-13 20:17:11 +02:00			`void loop() {`
move gyroscope code into seperate file, add lqr code file 2021-04-13 21:44:53 +02:00			`gyro_loop();`
use speed var, set variable for safe angle for simplicity 2021-04-13 22:09:37 +02:00			`safe_angle = int(round(angle_pitch_output));`
move code between files 2021-04-14 01:52:34 +02:00
adding conditions to run things ever x ms 2021-04-14 01:54:01 +02:00			`int m = millis();`

turn timings into variables 2021-04-14 02:49:29 +02:00			`if (m - lastCorrectionTime >= fastTimer) { //run this code ever 80ms (12.5hz)`
adding conditions to run things ever x ms 2021-04-14 01:54:01 +02:00			`lastCorrectionTime = m;`
			`getSpeed();`
			`setSpeed();`
			`}`
turn timings into variables 2021-04-14 02:49:29 +02:00			`if (m - lastPrintTime >= slowTimer) { //run this code ever 800ms (1.25hz)`
adding conditions to run things ever x ms 2021-04-14 01:54:01 +02:00			`lastPrintTime = m;`
			`printInfo();`
			`}`
			`}`
function for getting RPM, checkpoint. sorta working 2021-04-14 01:55:49 +02:00			`void getSpeed() {`
			`float alpha = 2.0 / (20.0 + 1.0); //alfa aka EMA length. 10 length = 20*20ms=0.2s`
			`int ticks = countA-countAold;`
			`float rpm_new = ticks5060/56.0; //ticks * 50 hz * 60s / ticks per rotation`
			`float rps_new = ticks50/8.91; //ticks 50hz/ ticks per rad`
			`rpm = rpm(1-alpha)+rpm_newalpha;`
			`rps = rps(1-alpha)+rps_newalpha;`
			`countAold = countA;`
			`}`
functions to print and set speed 2021-04-14 01:55:14 +02:00			`void printInfo(){`
			`Serial.println("");`
			`Serial.print("pitch Angle = "); Serial.println(angle_pitch_output);`
			`Serial.print("pitch Angle abs = "); Serial.println(abs(safe_angle));`
			`Serial.print("pitch Angle measured = "); Serial.println(angle_pitch);`
			`Serial.print("Position: "); Serial.println(countA);`
			`Serial.print("Full Rotations: "); Serial.println(countA/56.0); //ca. 56 tick per rotation`
			`Serial.print("Rads rotated: "); Serial.println(countA/8.91); //ca. 56 tick per rotation, 6.26 rads per rotation`
			`Serial.print("RPM: "); Serial.println(rpm); //ca. 56 tick per rotation`
			`Serial.print("Rads per second: "); Serial.println(rps); //ca. 56 tick per rotation, 6.26 rads per rotation`
use speed var, set variable for safe angle for simplicity 2021-04-13 22:09:37 +02:00
functions to print and set speed 2021-04-14 01:55:14 +02:00			`//Serial.print("A: "); Serial.println(countA);`
			`//Serial.print("B: "); Serial.println(countB);`
			`}`

			`void setSpeed(){`
redefine speed 2021-04-13 22:29:15 +02:00			`if(abs(safe_angle)<50 ){`
			`speed = 8*safe_angle;`
			`if(speed<0){`
add file from last commit to master folder 2021-04-13 20:17:11 +02:00			`digitalWrite(MotorPinB, CW);`
			`digitalWrite(MotorPinA, CCW);`
redefine speed 2021-04-13 22:29:15 +02:00			`speed -= 30;`
add file from last commit to master folder 2021-04-13 20:17:11 +02:00			`}`
redefine speed 2021-04-13 22:29:15 +02:00			`else if(speed>0){`
add file from last commit to master folder 2021-04-13 20:17:11 +02:00			`digitalWrite(MotorPinB, CCW);`
			`digitalWrite(MotorPinA, CW);`
redefine speed 2021-04-13 22:29:15 +02:00			`speed += 30;`
add file from last commit to master folder 2021-04-13 20:17:11 +02:00			`}`
redefine speed 2021-04-13 22:29:15 +02:00			`else {`
			`speed = 0;`
			`}`
			`speed = abs(speed);`
			`speed = constrain(speed, 0, 249);`
use speed var, set variable for safe angle for simplicity 2021-04-13 22:09:37 +02:00			`analogWrite(MotorSpeedB, speed); //Wheel close to connections`
			`analogWrite(MotorSpeedA, speed); //First experiment wheel`
add file from last commit to master folder 2021-04-13 20:17:11 +02:00			`}`
			`else{`
use speed var, set variable for safe angle for simplicity 2021-04-13 22:09:37 +02:00			`speed = 0;`
			`analogWrite(MotorSpeedB, speed);`
			`analogWrite(MotorSpeedA, speed);`
add file from last commit to master folder 2021-04-13 20:17:11 +02:00			`}`
			`}`
encoder HAL interrupts for position (Net rotations) 2021-04-14 00:20:35 +02:00			`int directionA(){`
			`if(digitalRead(encoderA2) == HIGH){`
			`return 1;`
			`}`
			`else{`
			`return -1;`
			`}`
			`}`
add file from last commit to master folder 2021-04-13 20:17:11 +02:00
encoder HAL interrupts for position (Net rotations) 2021-04-14 00:20:35 +02:00			`int directionB(){`
			`if(digitalRead(encoderB2) == HIGH){`
			`return 1;`
			`}`
			`else{`
			`return -1;`
			`}`
			`}`

			`void pulseA(){`
			`countA += directionA();`
			`}`

			`void pulseB(){`
			`countB += directionB();`
			`}`