Casper Maas
Robot kinematics model fully working
main.cpp@0:3325a6a3a912, 2018-10-30 (annotated)
- Committer:
- cmaas
- Date:
- Tue Oct 30 12:12:13 2018 +0000
- Revision:
- 0:3325a6a3a912
- Child:
- 1:d45695ec7da9
working model of robot kinematics for a robot with 3 motors
Who changed what in which revision?
| User | Revision | Line number | New contents of line |
|---|---|---|---|
| cmaas | 0:3325a6a3a912 | 1 | // EMG naar hoek |
| cmaas | 0:3325a6a3a912 | 2 | //#include <iostream> |
| cmaas | 0:3325a6a3a912 | 3 | //#include <string> |
| cmaas | 0:3325a6a3a912 | 4 | |
| cmaas | 0:3325a6a3a912 | 5 | #include "stdio.h" |
| cmaas | 0:3325a6a3a912 | 6 | #define _USE_MATH_DEFINES |
| cmaas | 0:3325a6a3a912 | 7 | |
| cmaas | 0:3325a6a3a912 | 8 | #include <math.h> |
| cmaas | 0:3325a6a3a912 | 9 | #include "iostream" |
| cmaas | 0:3325a6a3a912 | 10 | #define M_PI 3.14159265358979323846 /* pi */ |
| cmaas | 0:3325a6a3a912 | 11 | |
| cmaas | 0:3325a6a3a912 | 12 | //defining constants |
| cmaas | 0:3325a6a3a912 | 13 | const float la = 0.256; // lengte actieve arm |
| cmaas | 0:3325a6a3a912 | 14 | const float lp = 0.21; // lengte passieve arm |
| cmaas | 0:3325a6a3a912 | 15 | const float rp = 0.052; // straal van midden end effector tot hoekpunt |
| cmaas | 0:3325a6a3a912 | 16 | const float rm = 0.23; // straal van global midden tot motor |
| cmaas | 0:3325a6a3a912 | 17 | const float a = 0.09; // zijde van de driehoek |
| cmaas | 0:3325a6a3a912 | 18 | const float xas = 0.40; // afstand van motor 1 tot motor 3 |
| cmaas | 0:3325a6a3a912 | 19 | const float yas = 0.346; // afstand van xas tot motor 2 |
| cmaas | 0:3325a6a3a912 | 20 | const float thetap = 0; // rotatiehoek van de end effector |
| cmaas | 0:3325a6a3a912 | 21 | |
| cmaas | 0:3325a6a3a912 | 22 | //motor locatie |
| cmaas | 0:3325a6a3a912 | 23 | const int a1x = 0; //x locatie motor 1 |
| cmaas | 0:3325a6a3a912 | 24 | const int a1y = 0; //y locatie motor 1 |
| cmaas | 0:3325a6a3a912 | 25 | const float a2x = (0.5)*xas; // x locatie motor 2 |
| cmaas | 0:3325a6a3a912 | 26 | const float a2y = yas; // y locatie motor 2 |
| cmaas | 0:3325a6a3a912 | 27 | const float a3x = xas; // x locatie motor 3 |
| cmaas | 0:3325a6a3a912 | 28 | const int a3y = 0; // y locatie motor 3 |
| cmaas | 0:3325a6a3a912 | 29 | |
| cmaas | 0:3325a6a3a912 | 30 | // script voor het bepalen van de desired position aan de hand van emg (1/0) |
| cmaas | 0:3325a6a3a912 | 31 | |
| cmaas | 0:3325a6a3a912 | 32 | // Dit moet dus uit EMG script |
| cmaas | 0:3325a6a3a912 | 33 | int EMGxplus; |
| cmaas | 0:3325a6a3a912 | 34 | int EMGxmin ; |
| cmaas | 0:3325a6a3a912 | 35 | int EMGyplus; |
| cmaas | 0:3325a6a3a912 | 36 | int EMGymin ; |
| cmaas | 0:3325a6a3a912 | 37 | |
| cmaas | 0:3325a6a3a912 | 38 | // Dit moet experimenteel geperfectioneerd worden |
| cmaas | 0:3325a6a3a912 | 39 | float tijdstap = 0.05; //nu wss heel langzaam, kan miss omhoog |
| cmaas | 0:3325a6a3a912 | 40 | float v = 0.1; // snelheid kan wss ook hoger |
| cmaas | 0:3325a6a3a912 | 41 | |
| cmaas | 0:3325a6a3a912 | 42 | float px = 0.2; //starting x |
| cmaas | 0:3325a6a3a912 | 43 | float py = 0.155; // starting y |
| cmaas | 0:3325a6a3a912 | 44 | |
| cmaas | 0:3325a6a3a912 | 45 | // limits (since no forward kinematics) |
| cmaas | 0:3325a6a3a912 | 46 | float upperxlim = 0.36; //niet helemaal naar requierments ff kijken of ie groter kan |
| cmaas | 0:3325a6a3a912 | 47 | float lowerxlim = 0.04; |
| cmaas | 0:3325a6a3a912 | 48 | float upperylim = 0.30; |
| cmaas | 0:3325a6a3a912 | 49 | float lowerylim = 0.04; |
| cmaas | 0:3325a6a3a912 | 50 | |
| cmaas | 0:3325a6a3a912 | 51 | // functie x positie |
| cmaas | 0:3325a6a3a912 | 52 | float positionx(int EMGxplus,int EMGxmin) |
| cmaas | 0:3325a6a3a912 | 53 | { |
| cmaas | 0:3325a6a3a912 | 54 | float EMGx = EMGxplus - EMGxmin; |
| cmaas | 0:3325a6a3a912 | 55 | |
| cmaas | 0:3325a6a3a912 | 56 | float verplaatsingx = EMGx * tijdstap * v; |
| cmaas | 0:3325a6a3a912 | 57 | float pxnieuw = px + verplaatsingx; |
| cmaas | 0:3325a6a3a912 | 58 | // x limit |
| cmaas | 0:3325a6a3a912 | 59 | if (pxnieuw <= upperxlim && pxnieuw >= lowerxlim) |
| cmaas | 0:3325a6a3a912 | 60 | { |
| cmaas | 0:3325a6a3a912 | 61 | px = pxnieuw; |
| cmaas | 0:3325a6a3a912 | 62 | } |
| cmaas | 0:3325a6a3a912 | 63 | else |
| cmaas | 0:3325a6a3a912 | 64 | { |
| cmaas | 0:3325a6a3a912 | 65 | if (pxnieuw >= lowerxlim) |
| cmaas | 0:3325a6a3a912 | 66 | { |
| cmaas | 0:3325a6a3a912 | 67 | px = upperxlim; |
| cmaas | 0:3325a6a3a912 | 68 | } |
| cmaas | 0:3325a6a3a912 | 69 | else |
| cmaas | 0:3325a6a3a912 | 70 | { |
| cmaas | 0:3325a6a3a912 | 71 | px = lowerxlim; |
| cmaas | 0:3325a6a3a912 | 72 | } |
| cmaas | 0:3325a6a3a912 | 73 | } |
| cmaas | 0:3325a6a3a912 | 74 | printf("X eindpunt (%f) en verplaatsing: (%f)\n\r",px,verplaatsingx); |
| cmaas | 0:3325a6a3a912 | 75 | return px; |
| cmaas | 0:3325a6a3a912 | 76 | } |
| cmaas | 0:3325a6a3a912 | 77 | |
| cmaas | 0:3325a6a3a912 | 78 | // functie y positie |
| cmaas | 0:3325a6a3a912 | 79 | float positiony(int EMGyplus,int EMGymin) |
| cmaas | 0:3325a6a3a912 | 80 | { |
| cmaas | 0:3325a6a3a912 | 81 | float EMGy = EMGyplus - EMGymin; |
| cmaas | 0:3325a6a3a912 | 82 | |
| cmaas | 0:3325a6a3a912 | 83 | float verplaatsingy = EMGy * tijdstap * v; |
| cmaas | 0:3325a6a3a912 | 84 | float pynieuw = py + verplaatsingy; |
| cmaas | 0:3325a6a3a912 | 85 | |
| cmaas | 0:3325a6a3a912 | 86 | // y limit |
| cmaas | 0:3325a6a3a912 | 87 | if (pynieuw <= upperylim && pynieuw >= lowerylim) |
| cmaas | 0:3325a6a3a912 | 88 | { |
| cmaas | 0:3325a6a3a912 | 89 | py = pynieuw; |
| cmaas | 0:3325a6a3a912 | 90 | } |
| cmaas | 0:3325a6a3a912 | 91 | else |
| cmaas | 0:3325a6a3a912 | 92 | { |
| cmaas | 0:3325a6a3a912 | 93 | if (pynieuw >= lowerylim) |
| cmaas | 0:3325a6a3a912 | 94 | { |
| cmaas | 0:3325a6a3a912 | 95 | py = upperylim; |
| cmaas | 0:3325a6a3a912 | 96 | } |
| cmaas | 0:3325a6a3a912 | 97 | else |
| cmaas | 0:3325a6a3a912 | 98 | { |
| cmaas | 0:3325a6a3a912 | 99 | py = lowerylim; |
| cmaas | 0:3325a6a3a912 | 100 | } |
| cmaas | 0:3325a6a3a912 | 101 | } |
| cmaas | 0:3325a6a3a912 | 102 | printf("Y eindpunt (%f) en verplaatsing: (%f) \n\r",py,verplaatsingy); |
| cmaas | 0:3325a6a3a912 | 103 | return (py); |
| cmaas | 0:3325a6a3a912 | 104 | } |
| cmaas | 0:3325a6a3a912 | 105 | |
| cmaas | 0:3325a6a3a912 | 106 | |
| cmaas | 0:3325a6a3a912 | 107 | // functie berekenen hoeken |
| cmaas | 0:3325a6a3a912 | 108 | // arm 1 |
| cmaas | 0:3325a6a3a912 | 109 | float hoek1(float px, float py) // input: ref x, ref y |
| cmaas | 0:3325a6a3a912 | 110 | { |
| cmaas | 0:3325a6a3a912 | 111 | float c1x = px - rp * cos(thetap +(M_PI/6)); // x locatie hoekpunt end-effector |
| cmaas | 0:3325a6a3a912 | 112 | float c1y = py - rp*sin(thetap+(M_PI/6)); // y locatie hoekpunt end-effector |
| cmaas | 0:3325a6a3a912 | 113 | float alpha1 = atan2((c1y-a1y),(c1x-a1x)); // hoek tussen horizontaal en lijn van motor naar bijbehorende end-effector punt |
| cmaas | 0:3325a6a3a912 | 114 | float psi1 = acos(( pow(la,2)-pow(lp,2)+pow((c1x-a1x),2)+pow((c1y-a1y),2))/(2*la*sqrt(pow ((c1x-a1x),2)+pow((c1y-a1y),2) ))); //Hoek tussen lijn van motor naar bijbehorende end=effector punt en actieve arm |
| cmaas | 0:3325a6a3a912 | 115 | float a1 = alpha1 + psi1; //hoek tussen horizontaal en actieve arm |
| cmaas | 0:3325a6a3a912 | 116 | printf("arm 1 = %f \n\r",a1); |
| cmaas | 0:3325a6a3a912 | 117 | return a1; |
| cmaas | 0:3325a6a3a912 | 118 | } |
| cmaas | 0:3325a6a3a912 | 119 | |
| cmaas | 0:3325a6a3a912 | 120 | // arm 2 |
| cmaas | 0:3325a6a3a912 | 121 | float hoek2(float px, float py) |
| cmaas | 0:3325a6a3a912 | 122 | { |
| cmaas | 0:3325a6a3a912 | 123 | float c2x = px - rp * cos(thetap -(M_PI/2)); |
| cmaas | 0:3325a6a3a912 | 124 | float c2y = py - rp*sin(thetap-(M_PI/2)); |
| cmaas | 0:3325a6a3a912 | 125 | float alpha2 = atan2((c2y-a2y),(c2x-a2x)); |
| cmaas | 0:3325a6a3a912 | 126 | float psi2 = acos(( pow(la,2)-pow(lp,2)+pow((c2x-a2x),2)+pow((c2y-a2y),2))/(2*la*sqrt(pow ((c2x-a2x),2)+pow((c2y-a2y),2) ))); |
| cmaas | 0:3325a6a3a912 | 127 | float a2 = alpha2 + psi2; |
| cmaas | 0:3325a6a3a912 | 128 | printf("arm 2 = %f \n\r",a2); |
| cmaas | 0:3325a6a3a912 | 129 | return a2; |
| cmaas | 0:3325a6a3a912 | 130 | } |
| cmaas | 0:3325a6a3a912 | 131 | |
| cmaas | 0:3325a6a3a912 | 132 | //arm 3 |
| cmaas | 0:3325a6a3a912 | 133 | float hoek3(float px, float py) |
| cmaas | 0:3325a6a3a912 | 134 | { |
| cmaas | 0:3325a6a3a912 | 135 | float c3x = px - rp * cos(thetap +(5*M_PI/6)); |
| cmaas | 0:3325a6a3a912 | 136 | float c3y = py - rp*sin(thetap+(5*M_PI/6)); |
| cmaas | 0:3325a6a3a912 | 137 | float alpha3 = atan2((c3y-a3y),(c3x-a3x)); |
| cmaas | 0:3325a6a3a912 | 138 | float psi3 = acos(( pow(la,2)-pow(lp,2)+pow((c3x-a3x),2)+pow((c3y-a3y),2))/(2*la*sqrt(pow ((c3x-a3x),2)+pow((c3y-a3y),2) ))); |
| cmaas | 0:3325a6a3a912 | 139 | float a3 = alpha3 + psi3; |
| cmaas | 0:3325a6a3a912 | 140 | printf("arm 3 = %f \n\r",a3); |
| cmaas | 0:3325a6a3a912 | 141 | return a3; |
| cmaas | 0:3325a6a3a912 | 142 | } |
| cmaas | 0:3325a6a3a912 | 143 | |
| cmaas | 0:3325a6a3a912 | 144 | |
| cmaas | 0:3325a6a3a912 | 145 | // MAIN |
| cmaas | 0:3325a6a3a912 | 146 | int main() |
| cmaas | 0:3325a6a3a912 | 147 | { |
| cmaas | 0:3325a6a3a912 | 148 | |
| cmaas | 0:3325a6a3a912 | 149 | // berekenen positie |
| cmaas | 0:3325a6a3a912 | 150 | float px = positionx(1,0); // EMG: +x, -x |
| cmaas | 0:3325a6a3a912 | 151 | float py = positiony(1,0); // EMG: +y, -y |
| cmaas | 0:3325a6a3a912 | 152 | printf("positie (%f,%f)\n\r",px,py); |
| cmaas | 0:3325a6a3a912 | 153 | |
| cmaas | 0:3325a6a3a912 | 154 | // berekenen hoeken |
| cmaas | 0:3325a6a3a912 | 155 | float a1 = hoek1(px, py); |
| cmaas | 0:3325a6a3a912 | 156 | float a2 = hoek2(px, py); |
| cmaas | 0:3325a6a3a912 | 157 | float a3 = hoek3(px, py); |
| cmaas | 0:3325a6a3a912 | 158 | |
| cmaas | 0:3325a6a3a912 | 159 | printf("hoek(%f,%f,%f)\n\r",a1,a2,a3); |
| cmaas | 0:3325a6a3a912 | 160 | |
| cmaas | 0:3325a6a3a912 | 161 | return 0; |
| cmaas | 0:3325a6a3a912 | 162 | |
| cmaas | 0:3325a6a3a912 | 163 | } |