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Dependencies:   FastPWM mbed QEI biquadFilter HIDScope MODSERIAL

main.cpp@38:681100ce5fb8, 2018-10-31 (annotated)

Committer:
efvanmarrewijk
Date:
Wed Oct 31 11:14:36 2018 +0000
Revision:
38:681100ce5fb8
Parent:
36:077fe5b3189b 
Motor right moves, because encoder pins are switched in right motor wrt the left motor and the flip motor

Who changed what in which revision?

UserRevisionLine numberNew contents of line
efvanmarrewijk 16:720365110953 1 // Inclusion of libraries
efvanmarrewijk 31:91ad5b188bd9 2 #include "mbed.h"
efvanmarrewijk 31:91ad5b188bd9 3 #include "FastPWM.h"
efvanmarrewijk 31:91ad5b188bd9 4 #include "QEI.h" // Includes library for encoder
efvanmarrewijk 31:91ad5b188bd9 5 #include "MODSERIAL.h"
efvanmarrewijk 31:91ad5b188bd9 6 #include "HIDScope.h"
efvanmarrewijk 31:91ad5b188bd9 7 #include "BiQuad.h"
Ramonwaninge 0:3ea1bbfbeaae 8
efvanmarrewijk 14:e21cb701ccb8 9 // Input
efvanmarrewijk 27:3430dfb4c9fb 10 AnalogIn pot1(A1);
efvanmarrewijk 27:3430dfb4c9fb 11 AnalogIn pot2(A2);
efvanmarrewijk 21:363271dcfe1f 12 InterruptIn button1(D0);
efvanmarrewijk 21:363271dcfe1f 13 InterruptIn button2(D1);
efvanmarrewijk 31:91ad5b188bd9 14 InterruptIn emergencybutton(SW2); //The button SW2 on the K64F is the emergency button: if you press this, everything will abort as soon as possible
efvanmarrewijk 21:363271dcfe1f 15
efvanmarrewijk 32:a5b411833d1e 16 DigitalIn pin8(D8); // Encoder 1 B
efvanmarrewijk 32:a5b411833d1e 17 DigitalIn pin9(D9); // Encoder 1 A
efvanmarrewijk 32:a5b411833d1e 18 DigitalIn pin10(D10); // Encoder 2 B
efvanmarrewijk 32:a5b411833d1e 19 DigitalIn pin11(D11); // Encoder 2 A
efvanmarrewijk 32:a5b411833d1e 20 DigitalIn pin12(D12); // Encoder 3 B
efvanmarrewijk 32:a5b411833d1e 21 DigitalIn pin13(D13); // Encoder 3 A
efvanmarrewijk 9:65c52c1f4a57 22
efvanmarrewijk 14:e21cb701ccb8 23 // Output
efvanmarrewijk 35:ba556f2d0fcc 24 DigitalOut pin2(D2); // Motor 3 direction = motor flip
efvanmarrewijk 35:ba556f2d0fcc 25 FastPWM pin3(D3); // Motor 3 pwm = motor flip
efvanmarrewijk 35:ba556f2d0fcc 26 DigitalOut pin4(D4); // Motor 2 direction = motor right
efvanmarrewijk 35:ba556f2d0fcc 27 FastPWM pin5(D5); // Motor 2 pwm = motor right
efvanmarrewijk 35:ba556f2d0fcc 28 FastPWM pin6(D6); // Motor 1 pwm = motor left
efvanmarrewijk 35:ba556f2d0fcc 29 DigitalOut pin7(D7); // Motor 1 direction = motor left
efvanmarrewijk 26:b48708ed51ff 30
efvanmarrewijk 26:b48708ed51ff 31 DigitalOut greenled(LED_GREEN,1);
efvanmarrewijk 26:b48708ed51ff 32 DigitalOut redled(LED_RED,1);
efvanmarrewijk 26:b48708ed51ff 33 DigitalOut blueled(LED_BLUE,1);
Ramonwaninge 2:d8a552d1d33a 34
efvanmarrewijk 16:720365110953 35 // Utilisation of libraries
efvanmarrewijk 16:720365110953 36 MODSERIAL pc(USBTX, USBRX);
efvanmarrewijk 35:ba556f2d0fcc 37 QEI Encoderl(D9,D8,NC,4200); // Counterclockwise motor rotation is the positive direction
efvanmarrewijk 38:681100ce5fb8 38 QEI Encoderr(D10,D11,NC,4200); // Counterclockwise motor rotation is the positive direction
efvanmarrewijk 35:ba556f2d0fcc 39 QEI Encoderf(D13,D12,NC,4200); // Counterclockwise motor rotation is the positive direction
efvanmarrewijk 20:695140b8db2f 40 Ticker motor;
efvanmarrewijk 24:d255752065d1 41 Ticker encoders;
efvanmarrewijk 9:65c52c1f4a57 42
efvanmarrewijk 16:720365110953 43 // Global variables
efvanmarrewijk 32:a5b411833d1e 44 const float pi = 3.14159265358979f;
efvanmarrewijk 32:a5b411833d1e 45 float u3 = 0.0f; // Normalised variable for the movement of motor 3
efvanmarrewijk 32:a5b411833d1e 46 const float fCountsRad = 4200.0f;
efvanmarrewijk 32:a5b411833d1e 47 const float dt = 0.001f;
efvanmarrewijk 16:720365110953 48
efvanmarrewijk 16:720365110953 49 // Functions
efvanmarrewijk 32:a5b411833d1e 50 void Emergency() // Emgergency, if SW2 on biorobotics is pressed, everything will instantly abort and a red light goes on
efvanmarrewijk 32:a5b411833d1e 51 { greenled = 1; // Red light on
efvanmarrewijk 30:c4a3e868ef04 52 blueled = 1;
efvanmarrewijk 30:c4a3e868ef04 53 redled = 0;
efvanmarrewijk 32:a5b411833d1e 54 pin3 = 0; // All motor forces to zero
efvanmarrewijk 30:c4a3e868ef04 55 pin5 = 0;
efvanmarrewijk 30:c4a3e868ef04 56 pin6 = 0;
efvanmarrewijk 32:a5b411833d1e 57 exit (0); // Abort mission!!
efvanmarrewijk 30:c4a3e868ef04 58 }
efvanmarrewijk 30:c4a3e868ef04 59
efvanmarrewijk 31:91ad5b188bd9 60 // Subfunctions
efvanmarrewijk 35:ba556f2d0fcc 61 int Countslinput() // Gets the counts from encoder 1
efvanmarrewijk 35:ba556f2d0fcc 62 { int countsl;
efvanmarrewijk 35:ba556f2d0fcc 63 countsl = Encoderl.getPulses();
efvanmarrewijk 35:ba556f2d0fcc 64 return countsl;
efvanmarrewijk 27:3430dfb4c9fb 65 }
efvanmarrewijk 35:ba556f2d0fcc 66 int Countsrinput() // Gets the counts from encoder 2
efvanmarrewijk 35:ba556f2d0fcc 67 { int countsr;
efvanmarrewijk 35:ba556f2d0fcc 68 countsr = Encoderr.getPulses();
efvanmarrewijk 35:ba556f2d0fcc 69 return countsr;
efvanmarrewijk 27:3430dfb4c9fb 70 }
efvanmarrewijk 35:ba556f2d0fcc 71 int Countsfinput() // Gets the counts from encoder 3
efvanmarrewijk 35:ba556f2d0fcc 72 { int countsf;
efvanmarrewijk 35:ba556f2d0fcc 73 countsf = Encoderf.getPulses();
efvanmarrewijk 35:ba556f2d0fcc 74 return countsf;
efvanmarrewijk 27:3430dfb4c9fb 75 }
efvanmarrewijk 27:3430dfb4c9fb 76
efvanmarrewijk 32:a5b411833d1e 77 float CurrentAngle(float counts) // Calculates the current angle of the motor (between -2*pi to 2*pi) based on the counts from the encoder
efvanmarrewijk 32:a5b411833d1e 78 { float angle = ((float)counts*2.0f*pi)/fCountsRad;
efvanmarrewijk 32:a5b411833d1e 79 while (angle > 2.0f*pi)
efvanmarrewijk 32:a5b411833d1e 80 { angle = angle-2.0f*pi;
efvanmarrewijk 27:3430dfb4c9fb 81 }
efvanmarrewijk 32:a5b411833d1e 82 while (angle < -2.0f*pi)
efvanmarrewijk 32:a5b411833d1e 83 { angle = angle+2.0f*pi;
efvanmarrewijk 30:c4a3e868ef04 84 }
efvanmarrewijk 30:c4a3e868ef04 85 return angle;
efvanmarrewijk 27:3430dfb4c9fb 86 }
efvanmarrewijk 27:3430dfb4c9fb 87
efvanmarrewijk 32:a5b411833d1e 88 float ErrorCalc(float refvalue,float CurAngle) // Calculates the error of the system, based on the current angle and the reference value
efvanmarrewijk 32:a5b411833d1e 89 { float error = refvalue - CurAngle;
efvanmarrewijk 30:c4a3e868ef04 90 return error;
efvanmarrewijk 30:c4a3e868ef04 91 }
efvanmarrewijk 30:c4a3e868ef04 92
efvanmarrewijk 32:a5b411833d1e 93 float Kpcontr() // Sets the Kp value for the controller dependent on the scaled angle of potmeter 2
efvanmarrewijk 32:a5b411833d1e 94 { float Kp = 20.0f*pot2;
efvanmarrewijk 30:c4a3e868ef04 95 return Kp;
efvanmarrewijk 30:c4a3e868ef04 96 }
efvanmarrewijk 30:c4a3e868ef04 97
efvanmarrewijk 32:a5b411833d1e 98 float Kdcontr() // Sets the Kd value for the controller dependent on the scaled angle of potmeter 1
efvanmarrewijk 32:a5b411833d1e 99 { float Kd = 0.25f*pot1;
efvanmarrewijk 30:c4a3e868ef04 100 return Kd;
efvanmarrewijk 30:c4a3e868ef04 101 }
efvanmarrewijk 31:91ad5b188bd9 102
efvanmarrewijk 32:a5b411833d1e 103 float PIDcontroller(float refvalue,float CurAngle) // PID controller for the motors, based on the reference value and the current angle of the motor
efvanmarrewijk 30:c4a3e868ef04 104 { //float Kp = Kpcontr();
efvanmarrewijk 33:ec07e11676ec 105 float Kp = 10.37f;
efvanmarrewijk 32:a5b411833d1e 106 float Ki = 1.02f;
efvanmarrewijk 33:ec07e11676ec 107 float Kd = 0.0514f;
efvanmarrewijk 30:c4a3e868ef04 108 //float Kd = Kdcontr();
efvanmarrewijk 32:a5b411833d1e 109 float error = ErrorCalc(refvalue,CurAngle);
efvanmarrewijk 30:c4a3e868ef04 110 static float error_integral = 0.0;
efvanmarrewijk 30:c4a3e868ef04 111 static float error_prev = error; // initialization with this value only done once!
efvanmarrewijk 31:91ad5b188bd9 112 static BiQuad PIDfilter(0.0640, 0.1279, 0.0640, -1.1683, 0.4241);
efvanmarrewijk 27:3430dfb4c9fb 113 // Proportional part:
efvanmarrewijk 30:c4a3e868ef04 114 float u_k = Kp * error;
efvanmarrewijk 27:3430dfb4c9fb 115 // Integral part
efvanmarrewijk 27:3430dfb4c9fb 116 error_integral = error_integral + error * dt;
efvanmarrewijk 30:c4a3e868ef04 117 float u_i = Ki * error_integral;
efvanmarrewijk 30:c4a3e868ef04 118 // Derivative part
efvanmarrewijk 30:c4a3e868ef04 119 float error_derivative = (error - error_prev)/dt;
efvanmarrewijk 31:91ad5b188bd9 120 float filtered_error_derivative = PIDfilter.step(error_derivative);
efvanmarrewijk 30:c4a3e868ef04 121 float u_d = Kd * filtered_error_derivative;
efvanmarrewijk 30:c4a3e868ef04 122 error_prev = error;
efvanmarrewijk 27:3430dfb4c9fb 123 // Sum all parts and return it
efvanmarrewijk 30:c4a3e868ef04 124 pc.printf ("Kp = %f Kd = %f",Kp,Kd);
efvanmarrewijk 30:c4a3e868ef04 125 return u_k + u_i + u_d;
efvanmarrewijk 27:3430dfb4c9fb 126 }
efvanmarrewijk 30:c4a3e868ef04 127
efvanmarrewijk 35:ba556f2d0fcc 128 float DesiredAnglel() // Sets the desired angle for the controller dependent on the scaled angle of potmeter 1
efvanmarrewijk 32:a5b411833d1e 129 { float angle = (pot1*2.0f*pi)-pi;
efvanmarrewijk 30:c4a3e868ef04 130 return angle;
efvanmarrewijk 30:c4a3e868ef04 131 }
efvanmarrewijk 35:ba556f2d0fcc 132
efvanmarrewijk 38:681100ce5fb8 133 float* turnr() // main function for movement of motor 1, all above functions with an extra tab are called
efvanmarrewijk 26:b48708ed51ff 134 {
efvanmarrewijk 35:ba556f2d0fcc 135 //float refvalue = pi/4.0f;
efvanmarrewijk 35:ba556f2d0fcc 136 float refvalue = DesiredAnglel(); // different minus sign per motor
efvanmarrewijk 38:681100ce5fb8 137 int counts = Countsrinput(); // different encoder pins per motor
efvanmarrewijk 35:ba556f2d0fcc 138 float currentangle = CurrentAngle(counts); // different minus sign per motor
efvanmarrewijk 35:ba556f2d0fcc 139 float PIDcontrol = PIDcontroller(refvalue,currentangle); // same for every motor
efvanmarrewijk 35:ba556f2d0fcc 140 float error = ErrorCalc(refvalue,currentangle); // same for every motor
efvanmarrewijk 30:c4a3e868ef04 141
efvanmarrewijk 38:681100ce5fb8 142 pin5 = fabs(PIDcontrol); // different pins for every motor
efvanmarrewijk 38:681100ce5fb8 143 pin4 = PIDcontrol > 0.0f; // different pins for every motor
efvanmarrewijk 31:91ad5b188bd9 144 //pin6 = 0.4+0.6*fabs(PIDcontr); //geschaald
efvanmarrewijk 31:91ad5b188bd9 145 //pin6 = fabs(PIDcontr)/pi;
efvanmarrewijk 35:ba556f2d0fcc 146 //pc.printf(" error: %f ref: %f angle: %f \r\n",error,refvalue,currentangle);
efvanmarrewijk 33:ec07e11676ec 147 float* outcome;
efvanmarrewijk 35:ba556f2d0fcc 148 float turninfo[3] = {error, refvalue, currentangle};
efvanmarrewijk 35:ba556f2d0fcc 149 //float ( &fillarr( float (&outcome)[3] ) )[3] { // no decay; argument must be size 3
efvanmarrewijk 35:ba556f2d0fcc 150 outcome = turninfo;
efvanmarrewijk 35:ba556f2d0fcc 151
efvanmarrewijk 35:ba556f2d0fcc 152 return outcome;
efvanmarrewijk 35:ba556f2d0fcc 153 }
efvanmarrewijk 35:ba556f2d0fcc 154
efvanmarrewijk 32:a5b411833d1e 155 float ActualPosition(int counts, int offsetcounts) // After calibration, this function is used to return the counts (and thus the angle of the system) to 0
efvanmarrewijk 32:a5b411833d1e 156 { float MotorPosition = - (counts - offsetcounts) / fCountsRad;
efvanmarrewijk 25:76e9e5597416 157 // minus sign to correct for direction convention
efvanmarrewijk 32:a5b411833d1e 158 return MotorPosition;
efvanmarrewijk 25:76e9e5597416 159 }
efvanmarrewijk 11:3efd6a324f16 160
efvanmarrewijk 16:720365110953 161 // Main program
efvanmarrewijk 11:3efd6a324f16 162 int main()
efvanmarrewijk 18:ca084c362855 163 {
efvanmarrewijk 26:b48708ed51ff 164 pc.baud(115200);
efvanmarrewijk 32:a5b411833d1e 165 pin3.period_us(15); // If you give a period on one pin, c++ gives all pins this period
efvanmarrewijk 31:91ad5b188bd9 166
efvanmarrewijk 33:ec07e11676ec 167 //float motoroutcome1 = motor.attach(turn1,dt);
efvanmarrewijk 33:ec07e11676ec 168
efvanmarrewijk 26:b48708ed51ff 169 emergencybutton.rise(Emergency); //If the button is pressed, stop program
efvanmarrewijk 30:c4a3e868ef04 170 //pin6 = 0.01;
efvanmarrewijk 17:0ae9e8c958f8 171
efvanmarrewijk 16:720365110953 172 while (true)
efvanmarrewijk 25:76e9e5597416 173 {
efvanmarrewijk 38:681100ce5fb8 174 float* motoroutcomel = turnr();
efvanmarrewijk 35:ba556f2d0fcc 175 float motorl1 = motoroutcomel[0];
efvanmarrewijk 35:ba556f2d0fcc 176 float motorl2 = motoroutcomel[1];
efvanmarrewijk 35:ba556f2d0fcc 177 float motorl3 = motoroutcomel[2];
efvanmarrewijk 33:ec07e11676ec 178
efvanmarrewijk 35:ba556f2d0fcc 179 pc.printf(" error1: %f ref1: %f angle1: %f \r\n",motorl1,motorl2,motorl3);
efvanmarrewijk 33:ec07e11676ec 180 wait(dt);
efvanmarrewijk 33:ec07e11676ec 181 //wait(dt*10);
efvanmarrewijk 33:ec07e11676ec 182 //wait(printingfreq); --> still needs to be defined
Ramonwaninge 3:d39285fdd103 183 }
efvanmarrewijk 30:c4a3e868ef04 184 }