new fork sure
Dependencies: HIDScope MODSERIAL PID QEI biquadFilter mbed
Fork of cpfromralph by
Diff: main.cpp
- Revision:
- 34:6e74f6629a0e
- Parent:
- 33:97e69c32a768
- Child:
- 35:82b432f5aef7
--- a/main.cpp Fri Nov 03 00:25:57 2017 +0000 +++ b/main.cpp Fri Nov 03 01:21:32 2017 +0000 @@ -23,6 +23,7 @@ Ticker max_read1; Ticker max_read3; Ticker Motorcontrol; + //Ticker PIDtimer; HIDScope scope( 4 ); DigitalOut red(LED_RED); DigitalOut blue(LED_BLUE); @@ -103,17 +104,17 @@ // This value also adds a very slight gain to every value // RKI Variables & Constants - float setpoint1; - float setpoint2; + double setpoint1 = 2.35; + double setpoint2 = 0.785; + double x = 10.77; + double y = 15.73; float pi = 3.14159265359; float a = 22.25; //originally 22.25, makes for xinitial=10.766874 // length of arm 1 float b = 26.5; //originally 16.48 makes for yinitial=15.733 // length of arm 2 - float alpha_old = 2.35; //INITIAL ANGLES IN RADIANS - float beta_old = 0.785; + double alpha_old = 2.35; //INITIAL ANGLES IN RADIANS + double beta_old = 0.785; float delta1; float delta2; - float x = 10.77; - float y = 15.73; float diffmotor_a; float diffmotor_b; @@ -369,7 +370,7 @@ // EMG Filtering & Scope // // -void filter() { +void filter(/*double setpoint1, double setpoint2*/) { // Right Biceps emg1 = emg1_in.read(); emg1highfilter = filterhigh1.step(emg1); @@ -515,11 +516,12 @@ green = 0; //MV1 = 0.5; //MV2 = 0; - x = x + 0.5; - float alpha = inversekinematics1(x,y); //calculate alpha and beta for current x,y - float beta = inversekinematics2(x,y); + x = x + 0.2; + double alpha = inversekinematics1(x,y); //calculate alpha and beta for current x,y + double beta = inversekinematics2(x,y); setpoint1 = alpha; setpoint2 = beta; + wait(0.2); } // This part checks for left biceps contractions only else if (maxpart1>MOVAVG_RB && maxpart2<MOVAVG_LB && maxpart3>MOVAVG_LL && maxpart4>MOVAVG_RL){ @@ -528,11 +530,12 @@ green = 1; //MV1 = -0.5; //MV2 = 0; - x = x - 0.5; - float alpha = inversekinematics1(x,y); - float beta = inversekinematics2(x,y); + x = x - 0.2; + double alpha = inversekinematics1(x,y); + double beta = inversekinematics2(x,y); setpoint1 = alpha; setpoint2 = beta; + wait(0.2); } // This part checks for left lower arm contractions only else if (maxpart1>MOVAVG_RB && maxpart2>MOVAVG_LB && maxpart3<MOVAVG_LL && maxpart4>MOVAVG_RL){ @@ -541,11 +544,12 @@ green = 1; //MV1 = 0; //MV2 = 0.5; - y = y + 0.5; - float alpha = inversekinematics1(x,y); - float beta = inversekinematics2(x,y); + y = y + 0.2; + double alpha = inversekinematics1(x,y); + double beta = inversekinematics2(x,y); setpoint1 = alpha; setpoint2 = beta; + wait(0.2); } // This part checks for right lower arm contractions only else if (maxpart1>MOVAVG_RB && maxpart2>MOVAVG_LB && maxpart3>MOVAVG_LL && maxpart4<MOVAVG_RL){ @@ -554,11 +558,12 @@ green = 0; //MV1 = 0; //MV2 = -0.5; - y = y - 0.5; - float alpha = inversekinematics1(x,y); - float beta = inversekinematics2(x,y); + y = y - 0.2; + double alpha = inversekinematics1(x,y); + double beta = inversekinematics2(x,y); setpoint1 = alpha; setpoint2 = beta; + wait(0.2); } /* // This part checks for both lower arm contractions only else if (maxpart1>MOVAVG_RB && maxpart2>MOVAVG_LB && maxpart3<MOVAVG_LL && maxpart4<MOVAVG_RL){ @@ -609,15 +614,16 @@ scope.send(); // send everything to the HID scope } - +/* // PID calculations // // -void PIDcalculation() { +void PIDcalculation1() { //PID calculation for motor 1 + filter(); count1 = Encoder1.getPulses(); - angle1 += (0.0981 * count1); - new_error1 = setpoint1 - alpha_old; + angle1 += (0.000748 * count1); + new_error1 = setpoint1 - angle1; change_error1 = new_error1 - last_error1; total_error1 += new_error1; @@ -631,11 +637,13 @@ pid_term_scaled1 = abs(pid_term1); last_error1 = new_error1; - +} +void PIDcalculation2() { //PID calculation for motor 2 + filter(); count2 = Encoder2.getPulses(); - angle2 += (0.0981 * count2); - new_error2 = setpoint2 - beta_old; + angle2 += (0.000748 * count2); + new_error2 = setpoint2 - angle2; change_error2 = new_error2 - last_error2; total_error2 += new_error2; @@ -650,29 +658,33 @@ last_error2 = new_error2; } - +*/ // Motor control // // // check to see if motor1 needs to be activated -void SetMotor1(float angle1, float setpoint1) { - PIDcalculation(); +void SetMotor1() { + //PIDcalculation1(); + filter(); + angle1 += (0.0981 * count1); if (angle1<setpoint1){ motor1direction = 0; // counterclockwise rotation } else { motor1direction = 1; // clockwise rotation } - if (angle2<setpoint2 || angle2>setpoint2) { - motor2pwm = 0.5; + if (angle1<setpoint1 || angle1>setpoint1) { + motor1pwm = 0.5; } - else if (angle2 == setpoint2){ - motor2pwm = 0; + else if (angle1 == setpoint1){ + motor1pwm = 0; } } // check if motor1 needs to be activated -void SetMotor2(float angle2, float setpoint2) { - PIDcalculation(); +void SetMotor2() { + filter(); + //PIDcalculation2(); + angle2 += (0.0981 * count2); if (angle2<setpoint2){ motor2direction = 0; // counterclockwise rotation } @@ -688,12 +700,8 @@ } void MeasureAndControl(void) { - - // This function measures the potmeter position, extracts a - // reference velocity from it, and controls the motor with - // a simple FeedForward controller. Call this from a Ticker. - SetMotor1(angle1,setpoint1); - SetMotor2(angle2,setpoint2); + SetMotor1(); + SetMotor2(); } @@ -703,5 +711,7 @@ max_read1.attach(&get_max1, 2); // set the frequency of the calibration loop at 0.5Hz max_read3.attach(&get_max3, 2); Motorcontrol.attach(&MeasureAndControl,0.5); + //PIDtimer.attach(&PIDcalculation1, 0.005); + //PIDtimer.attach(&PIDcalculation2, 0.005); while(1) {} } \ No newline at end of file