Dustin Berendsen
/
Angle_control_v3
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Dependencies: Encoder FastPWM MODSERIAL Servo mbed
Fork of
Angle_control_v3
by 
Peter Knoben
main.cpp
- Committer:
- peterknoben
- Date:
- 2017-10-17
- Revision:
- 5:b4ec742aa7d4
- Parent:
- 4:d385669b2f50
- Child:
- 6:6ae6256cf234
File content as of revision 5:b4ec742aa7d4:
#include "mbed.h"
#include "encoder.h"
#include "Servo.h"
#include "FastPWM.h"
Ticker MyControllerTicker1;
Ticker MyControllerTicker2;
const double PI = 3.141592653589793;
const double RAD_PER_PULSE = 0.000749425;
const double CONTROLLER_TS = 0.01;
//Motor1
PwmOut motor1(D5);
DigitalOut motor1DirectionPin(D4);
DigitalIn ENC2A(D12);
DigitalIn ENC2B(D13);
Encoder encoder1(D13,D12);
AnalogIn potmeter1(A3);
const double MOTOR1_KP = 15;
const double MOTOR1_KI = 10;
double m1_err_int = 0;
const double motor1_gain = 2*PI;
//Motor2
PwmOut motor2(D6);
DigitalOut motor2DirectionPin(D7);
DigitalIn ENC1A(D10);
DigitalIn ENC1B(D11);
Encoder encoder2(D10,D11);
AnalogIn potmeter2(A4);
const double MOTOR2_KP = 15;
const double MOTOR2_KI = 10;
double m2_err_int = 0;
const double motor2_gain = 2*PI;
//________________________________________________________________
//Kinematica
//Motor offsets (kinematica implementation)
int max_rangex = 800;
int max_rangey = 500;
int L1 = 450;
int L2 = 490;
float alphaoffset = 10;
float betaoffset = 35;
float x_offset = 0.0;
float y_offset = 0.0;
float getreferencepositionx(double potmeter){
float x_target = potmeter * max_rangex;
return x_target;
}
float getreferencepositiony(double potmeter){
float y_target = potmeter * max_rangey;
return y_target;
}
float getreferenceanglealpha(const double PI){
float x = getreferencepositionx(potmeter1);
float y = getreferencepositiony(potmeter2);
float theta2 = acos((x*x + y*y - L1*L1 - L2*L2)/(2*L1*L2));
float theta1 = asin(L2*sin(theta2)/sqrt(x*x +y*y) + atan(y/x));
float alpha = (05.*PI) - theta1;
return alpha;
}
float getreferenceanglebeta(const double PI){
float x = getreferencepositionx(potmeter1);
float y = getreferencepositiony(potmeter2);
float theta2 = acos((x*x + y*y - L1*L1 - L2*L2)/(2*L1*L2));
float theta1 = asin(L2*sin(theta2)/sqrt(x*x +y*y) + atan(y/x));
float alpha = (05.*PI) - theta1;
float beta = PI - alpha - theta2;
return beta;
}
//________________________________________________________________
//Servo
Servo MyServo(D9);
InterruptIn But1(D8);
int k=0;
double PI_controller(double error, const double Kp, const double Ki, double Ts, double &e_int) {
e_int =+ Ts * error;
return Kp * error + Ki * e_int ;
}
void motor1_control(){
double referenceangle1 = getreferenceanglealpha(PI);
double position1 = RAD_PER_PULSE * encoder1.getPosition();
double magnitude1 = PI_controller(referenceangle1-position1, MOTOR1_KP, MOTOR1_KI, CONTROLLER_TS, m1_err_int) / motor1_gain;
motor1 = fabs(magnitude1);
if (magnitude1 < 0){
motor1DirectionPin = 1;
}
else{
motor1DirectionPin = 0;
}
}
void motor2_control(){
double referenceangle2 = getreferenceanglebeta(PI);
double position2 = RAD_PER_PULSE * encoder2.getPosition();
double magnitude2 = PI_controller(referenceangle2-position2, MOTOR2_KP, MOTOR2_KI, CONTROLLER_TS, m2_err_int) / motor2_gain;
motor2 = fabs(magnitude2);
if (magnitude2 < 0){
motor2DirectionPin = 1;
}
else{
motor2DirectionPin = 0;
}
}
/*void servo_control (){
motor1.period(0.02f);
motor2.period(0.02f);
if (k==0){
MyServo = 0;
k=1;
motor1.period_us(200);
}
else{
MyServo = 2;
k=0;
motor1.period_us(200);
}
}*/
int main(){
//But1.rise(&servo_control);
motor1.period(0.0002f);
motor2.period(0.0002f);
MyControllerTicker1.attach(&motor1_control, CONTROLLER_TS);
MyControllerTicker2.attach(&motor2_control, CONTROLLER_TS);
while(1) {}
}