Navigate to a given point using the OGM and virtual forces
Dependencies: ISR_Mini-explorer mbed
Fork of VirtualForces by
main.cpp@26:b020cf253059, 2017-04-20 (annotated)
- Committer:
- geotsam
- Date:
- Thu Apr 20 18:54:48 2017 +0000
- Revision:
- 26:b020cf253059
- Parent:
- 25:572c9e9a8809
- Child:
- 27:07bde633af72
shortened go_to_point_with_angle a little bit
Who changed what in which revision?
User | Revision | Line number | New contents of line |
---|---|---|---|
geotsam | 0:8bffb51cc345 | 1 | #include "mbed.h" |
geotsam | 0:8bffb51cc345 | 2 | #include "robot.h" // Initializes the robot. This include should be used in all main.cpp! |
geotsam | 0:8bffb51cc345 | 3 | #include "math.h" |
Ludwigfr | 22:ebb37a249b5f | 4 | |
Ludwigfr | 22:ebb37a249b5f | 5 | using namespace std; |
AurelienBernier | 4:8c56c3ba6e54 | 6 | |
Ludwigfr | 22:ebb37a249b5f | 7 | //fill initialLogValues with the values we already know (here the bordurs) |
Ludwigfr | 22:ebb37a249b5f | 8 | void fill_initial_log_values(); |
Ludwigfr | 22:ebb37a249b5f | 9 | //generate a position randomly and makes the robot go there while updating the map |
Ludwigfr | 22:ebb37a249b5f | 10 | void randomize_and_map(); |
Ludwigfr | 22:ebb37a249b5f | 11 | //go the the given position while updating the map |
Ludwigfr | 22:ebb37a249b5f | 12 | void go_to_point_with_angle(float target_x, float target_y, float target_angle); |
Ludwigfr | 22:ebb37a249b5f | 13 | //Updates sonar values |
geotsam | 24:8f4b820d8de8 | 14 | void update_sonar_values(float leftMm, float frontMm, float rightMm); |
Ludwigfr | 22:ebb37a249b5f | 15 | //function that check if a cell A(x,y) is in the range of the front sonar S(xs,ys) (with an angle depending on the sonar used, front 0, left pi/3, right -pi/3) returns the probability it's occupied/empty [0;1] |
Ludwigfr | 22:ebb37a249b5f | 16 | float compute_probability_t(float x, float y,float xs,float ys, float angleFromSonarPosition, float distanceObstacleDetected); |
Ludwigfr | 22:ebb37a249b5f | 17 | //print the map |
Ludwigfr | 22:ebb37a249b5f | 18 | void print_final_map(); |
Ludwigfr | 25:572c9e9a8809 | 19 | //print the map with the robot marked on it |
Ludwigfr | 25:572c9e9a8809 | 20 | void print_final_map_with_robot_position(); |
geotsam | 0:8bffb51cc345 | 21 | |
Ludwigfr | 22:ebb37a249b5f | 22 | //MATHS heavy functions |
Ludwigfr | 22:ebb37a249b5f | 23 | float dist(float robot_x, float robot_y, float target_x, float target_y); |
Ludwigfr | 22:ebb37a249b5f | 24 | //returns the probability [0,1] that the cell is occupied from the log value lt |
Ludwigfr | 22:ebb37a249b5f | 25 | float log_to_proba(float lt); |
Ludwigfr | 22:ebb37a249b5f | 26 | //returns the log value that the cell is occupied from the probability value [0,1] |
Ludwigfr | 22:ebb37a249b5f | 27 | float proba_to_log(float p); |
Ludwigfr | 22:ebb37a249b5f | 28 | //returns the new log value |
Ludwigfr | 22:ebb37a249b5f | 29 | float compute_log_estimation_lt(float previousLogValue,float currentProbability,float originalLogvalue ); |
Ludwigfr | 22:ebb37a249b5f | 30 | //makes the angle inAngle between 0 and 2pi |
Ludwigfr | 22:ebb37a249b5f | 31 | float rad_angle_check(float inAngle); |
Ludwigfr | 22:ebb37a249b5f | 32 | //returns the angle between the vectors (x,y) and (xs,ys) |
Ludwigfr | 22:ebb37a249b5f | 33 | float compute_angle_between_vectors(float x, float y,float xs,float ys); |
Ludwigfr | 25:572c9e9a8809 | 34 | float robot_center_x_in_orthonormal_x(); |
Ludwigfr | 25:572c9e9a8809 | 35 | float robot_center_y_in_orthonormal_y(); |
Ludwigfr | 25:572c9e9a8809 | 36 | float robot_sonar_front_x_in_orthonormal_x(); |
Ludwigfr | 25:572c9e9a8809 | 37 | float robot_sonar_front_y_in_orthonormal_y(); |
Ludwigfr | 25:572c9e9a8809 | 38 | float robot_sonar_right_x_in_orthonormal_x(); |
Ludwigfr | 25:572c9e9a8809 | 39 | float robot_sonar_right_y_in_orthonormal_y(); |
Ludwigfr | 25:572c9e9a8809 | 40 | float robot_sonar_left_x_in_orthonormal_x(); |
Ludwigfr | 25:572c9e9a8809 | 41 | float robot_sonar_left_y_in_orthonormal_y(); |
Ludwigfr | 25:572c9e9a8809 | 42 | float estimated_width_indice_in_orthonormal_x(int i); |
Ludwigfr | 25:572c9e9a8809 | 43 | float estimated_height_indice_in_orthonormal_y(int j); |
AurelienBernier | 8:109314be5b68 | 44 | |
Ludwigfr | 22:ebb37a249b5f | 45 | const float pi=3.14159; |
Ludwigfr | 22:ebb37a249b5f | 46 | //spec of the sonar |
Ludwigfr | 22:ebb37a249b5f | 47 | //TODO MEASURE THE DISTANCE on X and Y of the robot frame, between each sonar and the center of the robot and add it to calculus in updateSonarValues |
geotsam | 24:8f4b820d8de8 | 48 | const float RANGE_SONAR=50;//cm |
geotsam | 24:8f4b820d8de8 | 49 | const float RANGE_SONAR_MIN=10;//Rmin cm |
geotsam | 24:8f4b820d8de8 | 50 | const float INCERTITUDE_SONAR=10;//cm |
geotsam | 24:8f4b820d8de8 | 51 | const float ANGLE_SONAR=pi/3;//Omega rad |
geotsam | 24:8f4b820d8de8 | 52 | const float SECURITY_DISTANCE=150;//mm |
Ludwigfr | 22:ebb37a249b5f | 53 | |
Ludwigfr | 22:ebb37a249b5f | 54 | //those distance and angle are approximation in need of measurements |
geotsam | 24:8f4b820d8de8 | 55 | const float ANGLE_FRONT_TO_LEFT=10*pi/36;//50 degrees |
geotsam | 24:8f4b820d8de8 | 56 | const float DISTANCE_SONAR_LEFT_X=4; |
geotsam | 24:8f4b820d8de8 | 57 | const float DISTANCE_SONAR_LEFT_Y=4; |
Ludwigfr | 22:ebb37a249b5f | 58 | |
geotsam | 24:8f4b820d8de8 | 59 | const float ANGLE_FRONT_TO_RIGHT=-10*pi/36;//-50 degrees |
geotsam | 24:8f4b820d8de8 | 60 | const float DISTANCE_SONAR_RIGHT_X=-4; |
geotsam | 24:8f4b820d8de8 | 61 | const float DISTANCE_SONAR_RIGHT_Y=4; |
AurelienBernier | 11:e641aa08c92e | 62 | |
Ludwigfr | 22:ebb37a249b5f | 63 | const float ANGLE_FRONT_TO_FRONT=0; |
Ludwigfr | 22:ebb37a249b5f | 64 | const float DISTANCE_SONAR_FRONT_X=0; |
Ludwigfr | 22:ebb37a249b5f | 65 | const float DISTANCE_SONAR_FRONT_Y=5; |
Ludwigfr | 22:ebb37a249b5f | 66 | |
Ludwigfr | 22:ebb37a249b5f | 67 | //TODO adjust the size of the map for computation time (25*25?) |
geotsam | 24:8f4b820d8de8 | 68 | const float WIDTH_ARENA=120;//cm |
geotsam | 24:8f4b820d8de8 | 69 | const float HEIGHT_ARENA=90;//cm |
geotsam | 24:8f4b820d8de8 | 70 | |
geotsam | 24:8f4b820d8de8 | 71 | //const int SIZE_MAP=25; |
geotsam | 24:8f4b820d8de8 | 72 | const int NB_CELL_WIDTH=24; |
geotsam | 24:8f4b820d8de8 | 73 | const int NB_CELL_HEIGHT=18; |
Ludwigfr | 22:ebb37a249b5f | 74 | |
Ludwigfr | 22:ebb37a249b5f | 75 | //position and orientation of the robot when put on the map (ODOMETRY doesn't know those) |
geotsam | 24:8f4b820d8de8 | 76 | const float DEFAULT_X=WIDTH_ARENA/2; |
geotsam | 24:8f4b820d8de8 | 77 | const float DEFAULT_Y=HEIGHT_ARENA/2; |
Ludwigfr | 22:ebb37a249b5f | 78 | const float DEFAULT_THETA=pi/2; |
Ludwigfr | 22:ebb37a249b5f | 79 | |
geotsam | 24:8f4b820d8de8 | 80 | //used to create the map 250 represent the 250cm of the square where the robot is tested |
geotsam | 24:8f4b820d8de8 | 81 | //float sizeCell=250/(float)SIZE_MAP; |
geotsam | 24:8f4b820d8de8 | 82 | float sizeCellX=WIDTH_ARENA/(float)NB_CELL_WIDTH; |
geotsam | 24:8f4b820d8de8 | 83 | float sizeCellY=HEIGHT_ARENA/(float)NB_CELL_HEIGHT; |
geotsam | 24:8f4b820d8de8 | 84 | |
geotsam | 24:8f4b820d8de8 | 85 | float map[NB_CELL_WIDTH][NB_CELL_HEIGHT];//contains the log values for each cell |
geotsam | 24:8f4b820d8de8 | 86 | float initialLogValues[NB_CELL_WIDTH][NB_CELL_HEIGHT]; |
Ludwigfr | 22:ebb37a249b5f | 87 | |
Ludwigfr | 22:ebb37a249b5f | 88 | //Diameter of a wheel and distance between the 2 |
Ludwigfr | 22:ebb37a249b5f | 89 | const float RADIUS_WHEELS=3.25; |
Ludwigfr | 22:ebb37a249b5f | 90 | const float DISTANCE_WHEELS=7.2; |
Ludwigfr | 22:ebb37a249b5f | 91 | |
geotsam | 24:8f4b820d8de8 | 92 | const int MAX_SPEED=500;//TODO TWEAK THE SPEED SO IT DOES NOT FUCK UP |
AurelienBernier | 8:109314be5b68 | 93 | |
geotsam | 24:8f4b820d8de8 | 94 | bool tooClose=false; |
geotsam | 24:8f4b820d8de8 | 95 | bool turnFromObstacle=false; |
AurelienBernier | 8:109314be5b68 | 96 | |
geotsam | 26:b020cf253059 | 97 | float alpha; //angle error |
geotsam | 26:b020cf253059 | 98 | float rho; //distance from target |
geotsam | 26:b020cf253059 | 99 | float beta; |
geotsam | 26:b020cf253059 | 100 | float kRho=12, ka=30, kb=-13; //Kappa values |
geotsam | 26:b020cf253059 | 101 | float linear, angular, angular_left, angular_right; |
geotsam | 26:b020cf253059 | 102 | float dt=0.5; |
geotsam | 26:b020cf253059 | 103 | float temp; |
geotsam | 26:b020cf253059 | 104 | float d2; |
geotsam | 26:b020cf253059 | 105 | Timer t; |
geotsam | 26:b020cf253059 | 106 | |
geotsam | 26:b020cf253059 | 107 | int speed=MAX_SPEED; // Max speed at beggining of movement |
geotsam | 26:b020cf253059 | 108 | |
geotsam | 26:b020cf253059 | 109 | float leftMm; |
geotsam | 26:b020cf253059 | 110 | float frontMm; |
geotsam | 26:b020cf253059 | 111 | float rightMm; |
geotsam | 26:b020cf253059 | 112 | |
geotsam | 0:8bffb51cc345 | 113 | int main(){ |
geotsam | 17:caf393b63e27 | 114 | |
geotsam | 13:41f75c132135 | 115 | i2c1.frequency(100000); |
AurelienBernier | 2:ea61e801e81f | 116 | initRobot(); //Initializing the robot |
geotsam | 0:8bffb51cc345 | 117 | pc.baud(9600); // baud for the pc communication |
geotsam | 0:8bffb51cc345 | 118 | |
Ludwigfr | 22:ebb37a249b5f | 119 | measure_always_on();//TODO check if needed |
geotsam | 24:8f4b820d8de8 | 120 | wait(0.5); |
AurelienBernier | 19:dbc5fbad4975 | 121 | |
Ludwigfr | 22:ebb37a249b5f | 122 | fill_initial_log_values(); |
geotsam | 13:41f75c132135 | 123 | |
geotsam | 24:8f4b820d8de8 | 124 | theta=DEFAULT_THETA; |
geotsam | 24:8f4b820d8de8 | 125 | X=DEFAULT_X; |
geotsam | 24:8f4b820d8de8 | 126 | Y=DEFAULT_Y; |
geotsam | 24:8f4b820d8de8 | 127 | |
geotsam | 24:8f4b820d8de8 | 128 | for (int i = 0; i<20; i++) { |
Ludwigfr | 22:ebb37a249b5f | 129 | randomize_and_map(); |
geotsam | 24:8f4b820d8de8 | 130 | wait(2); |
geotsam | 24:8f4b820d8de8 | 131 | print_final_map(); |
geotsam | 17:caf393b63e27 | 132 | } |
AurelienBernier | 8:109314be5b68 | 133 | |
AurelienBernier | 8:109314be5b68 | 134 | } |
AurelienBernier | 8:109314be5b68 | 135 | |
Ludwigfr | 22:ebb37a249b5f | 136 | //fill initialLogValues with the values we already know (here the bordurs) |
Ludwigfr | 22:ebb37a249b5f | 137 | void fill_initial_log_values(){ |
Ludwigfr | 22:ebb37a249b5f | 138 | //Fill map, we know the border are occupied |
geotsam | 24:8f4b820d8de8 | 139 | for (int i = 0; i<NB_CELL_WIDTH; i++) { |
geotsam | 24:8f4b820d8de8 | 140 | for (int j = 0; j<NB_CELL_HEIGHT; j++) { |
geotsam | 24:8f4b820d8de8 | 141 | if(j==0 || j==NB_CELL_HEIGHT-1 || i==0 || i==NB_CELL_WIDTH-1) |
Ludwigfr | 22:ebb37a249b5f | 142 | initialLogValues[i][j] = proba_to_log(1); |
Ludwigfr | 22:ebb37a249b5f | 143 | else |
Ludwigfr | 22:ebb37a249b5f | 144 | initialLogValues[i][j] = proba_to_log(0.5); |
AurelienBernier | 21:62154d644531 | 145 | } |
Ludwigfr | 22:ebb37a249b5f | 146 | } |
AurelienBernier | 8:109314be5b68 | 147 | } |
AurelienBernier | 8:109314be5b68 | 148 | |
Ludwigfr | 22:ebb37a249b5f | 149 | //generate a position randomly and makes the robot go there while updating the map |
Ludwigfr | 22:ebb37a249b5f | 150 | void randomize_and_map() { |
geotsam | 24:8f4b820d8de8 | 151 | //TODO check that it's aurelien's work |
geotsam | 24:8f4b820d8de8 | 152 | float target_x = (rand()%(int)(WIDTH_ARENA*10))/10;//for decimal precision |
geotsam | 24:8f4b820d8de8 | 153 | float target_y = (rand()%(int)(HEIGHT_ARENA*10))/10; |
Ludwigfr | 22:ebb37a249b5f | 154 | float target_angle = ((float)(rand()%31416)-15708)/10000.0; |
geotsam | 24:8f4b820d8de8 | 155 | |
geotsam | 24:8f4b820d8de8 | 156 | //TODO comment that |
geotsam | 24:8f4b820d8de8 | 157 | //pc.printf("\n\r targ_X=%f", target_x); |
geotsam | 24:8f4b820d8de8 | 158 | //pc.printf("\n\r targ_Y=%f", target_y); |
geotsam | 24:8f4b820d8de8 | 159 | //pc.printf("\n\r targ_Angle=%f", target_angle); |
geotsam | 24:8f4b820d8de8 | 160 | |
Ludwigfr | 22:ebb37a249b5f | 161 | go_to_point_with_angle(target_x, target_y, target_angle); |
AurelienBernier | 19:dbc5fbad4975 | 162 | } |
AurelienBernier | 19:dbc5fbad4975 | 163 | |
Ludwigfr | 22:ebb37a249b5f | 164 | //go the the given position while updating the map |
Ludwigfr | 22:ebb37a249b5f | 165 | //TODO clean this procedure it's ugly as hell and too long |
Ludwigfr | 22:ebb37a249b5f | 166 | void go_to_point_with_angle(float target_x, float target_y, float target_angle) { |
geotsam | 24:8f4b820d8de8 | 167 | if(tooClose){ |
geotsam | 24:8f4b820d8de8 | 168 | target_x=X; |
geotsam | 24:8f4b820d8de8 | 169 | target_y=Y; |
geotsam | 24:8f4b820d8de8 | 170 | target_angle=theta+pi/2; |
geotsam | 24:8f4b820d8de8 | 171 | target_angle = atan(sin(target_angle)/cos(target_angle)); |
geotsam | 24:8f4b820d8de8 | 172 | pc.printf("\n\rShould just turn now, new target_angle=%f\n\r", target_angle); |
geotsam | 24:8f4b820d8de8 | 173 | } |
geotsam | 24:8f4b820d8de8 | 174 | |
geotsam | 24:8f4b820d8de8 | 175 | alpha = atan2((target_y-Y),(target_x-X))-theta; |
geotsam | 24:8f4b820d8de8 | 176 | alpha = atan(sin(alpha)/cos(alpha)); |
geotsam | 24:8f4b820d8de8 | 177 | rho = dist(X, Y, target_x, target_y); |
geotsam | 24:8f4b820d8de8 | 178 | |
geotsam | 24:8f4b820d8de8 | 179 | beta = -alpha-theta+target_angle; |
geotsam | 24:8f4b820d8de8 | 180 | //beta = atan(sin(beta)/cos(beta)); |
geotsam | 24:8f4b820d8de8 | 181 | |
geotsam | 24:8f4b820d8de8 | 182 | do { |
geotsam | 24:8f4b820d8de8 | 183 | //pc.printf("\n\n\r entered while"); |
AurelienBernier | 2:ea61e801e81f | 184 | |
AurelienBernier | 6:afde4b08166b | 185 | //Timer stuff |
AurelienBernier | 6:afde4b08166b | 186 | dt = t.read(); |
AurelienBernier | 6:afde4b08166b | 187 | t.reset(); |
AurelienBernier | 6:afde4b08166b | 188 | t.start(); |
AurelienBernier | 6:afde4b08166b | 189 | |
geotsam | 14:d58f2bdbf42e | 190 | //Updating X,Y and theta with the odometry values |
geotsam | 14:d58f2bdbf42e | 191 | Odometria(); |
geotsam | 24:8f4b820d8de8 | 192 | |
geotsam | 24:8f4b820d8de8 | 193 | leftMm = get_distance_left_sensor(); |
geotsam | 24:8f4b820d8de8 | 194 | frontMm = get_distance_front_sensor(); |
geotsam | 24:8f4b820d8de8 | 195 | rightMm = get_distance_right_sensor(); |
geotsam | 24:8f4b820d8de8 | 196 | |
geotsam | 24:8f4b820d8de8 | 197 | //pc.printf("\n\r leftMm=%f", leftMm); |
geotsam | 24:8f4b820d8de8 | 198 | //pc.printf("\n\r frontMm=%f", frontMm); |
geotsam | 24:8f4b820d8de8 | 199 | //pc.printf("\n\r rightMm=%f", rightMm); |
Ludwigfr | 22:ebb37a249b5f | 200 | |
geotsam | 24:8f4b820d8de8 | 201 | update_sonar_values(leftMm, frontMm, rightMm); |
geotsam | 24:8f4b820d8de8 | 202 | |
geotsam | 24:8f4b820d8de8 | 203 | if ((leftMm < SECURITY_DISTANCE || frontMm < SECURITY_DISTANCE || rightMm < SECURITY_DISTANCE) && turnFromObstacle==false) { |
AurelienBernier | 21:62154d644531 | 204 | tooClose = true; |
geotsam | 24:8f4b820d8de8 | 205 | turnFromObstacle = true; |
geotsam | 24:8f4b820d8de8 | 206 | pc.printf("\n\r TOO CLOSE \n\r"); |
geotsam | 24:8f4b820d8de8 | 207 | leftMotor(1,0); |
geotsam | 24:8f4b820d8de8 | 208 | rightMotor(1,0); |
geotsam | 24:8f4b820d8de8 | 209 | Odometria(); |
geotsam | 24:8f4b820d8de8 | 210 | go_to_point_with_angle(X, Y, rad_angle_check(theta+pi)); |
geotsam | 14:d58f2bdbf42e | 211 | break; |
AurelienBernier | 11:e641aa08c92e | 212 | } |
AurelienBernier | 11:e641aa08c92e | 213 | |
geotsam | 26:b020cf253059 | 214 | compute_angles_and_distance(target_x, target_y, target_angle); //Compute the angles and the distance from target |
geotsam | 26:b020cf253059 | 215 | compute_linear_angular_velocities(); //Using the angles and distance, compute the velocities needed (linear & angular) |
geotsam | 24:8f4b820d8de8 | 216 | |
geotsam | 24:8f4b820d8de8 | 217 | //pc.printf("\n\r X=%f", X); |
geotsam | 24:8f4b820d8de8 | 218 | //pc.printf("\n\r Y=%f", Y); |
geotsam | 24:8f4b820d8de8 | 219 | |
geotsam | 24:8f4b820d8de8 | 220 | pc.printf("\n\r a_r=%f", angular_right); |
geotsam | 24:8f4b820d8de8 | 221 | pc.printf("\n\r a_l=%f", angular_left); |
geotsam | 0:8bffb51cc345 | 222 | |
AurelienBernier | 2:ea61e801e81f | 223 | //Updating motor velocities |
AurelienBernier | 1:f0807d5c5a4b | 224 | leftMotor(1,angular_left); |
AurelienBernier | 1:f0807d5c5a4b | 225 | rightMotor(1,angular_right); |
geotsam | 0:8bffb51cc345 | 226 | |
AurelienBernier | 7:c94070f9af78 | 227 | wait(0.2); |
AurelienBernier | 6:afde4b08166b | 228 | //Timer stuff |
AurelienBernier | 6:afde4b08166b | 229 | t.stop(); |
geotsam | 24:8f4b820d8de8 | 230 | } while(d2>1 && (abs(target_angle-theta)>0.01) && tooClose==false); |
geotsam | 24:8f4b820d8de8 | 231 | |
geotsam | 24:8f4b820d8de8 | 232 | //Stop at the end |
geotsam | 24:8f4b820d8de8 | 233 | leftMotor(1,0); |
geotsam | 24:8f4b820d8de8 | 234 | rightMotor(1,0); |
geotsam | 24:8f4b820d8de8 | 235 | |
geotsam | 24:8f4b820d8de8 | 236 | if(turnFromObstacle){ |
geotsam | 24:8f4b820d8de8 | 237 | turnFromObstacle=false; |
geotsam | 24:8f4b820d8de8 | 238 | tooClose=false; |
geotsam | 24:8f4b820d8de8 | 239 | } |
Ludwigfr | 22:ebb37a249b5f | 240 | } |
Ludwigfr | 22:ebb37a249b5f | 241 | |
Ludwigfr | 22:ebb37a249b5f | 242 | //Updates sonar values |
geotsam | 24:8f4b820d8de8 | 243 | void update_sonar_values(float leftMm, float frontMm, float rightMm){ |
Ludwigfr | 22:ebb37a249b5f | 244 | |
Ludwigfr | 22:ebb37a249b5f | 245 | float currProba; |
Ludwigfr | 25:572c9e9a8809 | 246 | float i_in_orthonormal; |
Ludwigfr | 25:572c9e9a8809 | 247 | float j_in_orthonormal; |
geotsam | 24:8f4b820d8de8 | 248 | for(int i=0;i<NB_CELL_WIDTH;i++){ |
geotsam | 24:8f4b820d8de8 | 249 | for(int j=0;j<NB_CELL_HEIGHT;j++){ |
geotsam | 24:8f4b820d8de8 | 250 | //check if the point A(x,y) in the world frame is within the range of the sonar (which has the coordinates xs, ys in the world frame) |
geotsam | 24:8f4b820d8de8 | 251 | //check that again |
Ludwigfr | 22:ebb37a249b5f | 252 | //compute for front sonar |
Ludwigfr | 25:572c9e9a8809 | 253 | i_in_orthonormal=estimated_width_indice_in_orthonormal_x(i); |
Ludwigfr | 25:572c9e9a8809 | 254 | j_in_orthonormal=estimated_height_indice_in_orthonormal_y(j); |
Ludwigfr | 25:572c9e9a8809 | 255 | |
Ludwigfr | 25:572c9e9a8809 | 256 | currProba=compute_probability_t(i_in_orthonormal,j_in_orthonormal,robot_sonar_front_x_in_orthonormal_x(),robot_sonar_front_y_in_orthonormal_y(),ANGLE_FRONT_TO_FRONT,frontMm/10); |
Ludwigfr | 22:ebb37a249b5f | 257 | map[i][j]=map[i][j]+proba_to_log(currProba)+initialLogValues[i][j];//map is filled as map[0][0] get the data for the point closest to the origin |
Ludwigfr | 22:ebb37a249b5f | 258 | //compute for right sonar |
Ludwigfr | 25:572c9e9a8809 | 259 | currProba=compute_probability_t(i_in_orthonormal,j_in_orthonormal,robot_sonar_right_x_in_orthonormal_x(),robot_sonar_right_y_in_orthonormal_y(),ANGLE_FRONT_TO_RIGHT,rightMm/10); |
Ludwigfr | 22:ebb37a249b5f | 260 | map[i][j]=map[i][j]+proba_to_log(currProba)+initialLogValues[i][j]; |
Ludwigfr | 22:ebb37a249b5f | 261 | //compute for left sonar |
Ludwigfr | 25:572c9e9a8809 | 262 | currProba=compute_probability_t(i_in_orthonormal,j_in_orthonormal,robot_sonar_left_x_in_orthonormal_x(),robot_sonar_left_y_in_orthonormal_y(),ANGLE_FRONT_TO_LEFT,leftMm/10); |
Ludwigfr | 22:ebb37a249b5f | 263 | map[i][j]=map[i][j]+proba_to_log(currProba)+initialLogValues[i][j]; |
Ludwigfr | 22:ebb37a249b5f | 264 | } |
Ludwigfr | 22:ebb37a249b5f | 265 | } |
Ludwigfr | 22:ebb37a249b5f | 266 | } |
Ludwigfr | 22:ebb37a249b5f | 267 | |
Ludwigfr | 25:572c9e9a8809 | 268 | //ODOMETRIA MUST HAVE BEEN CALLED |
Ludwigfr | 22:ebb37a249b5f | 269 | //function that check if a cell A(x,y) is in the range of the front sonar S(xs,ys) (with an angle depending on the sonar used, front 0, left pi/3, right -pi/3) returns the probability it's occupied/empty [0;1] |
Ludwigfr | 22:ebb37a249b5f | 270 | float compute_probability_t(float x, float y,float xs,float ys, float angleFromSonarPosition, float distanceObstacleDetected){ |
Ludwigfr | 22:ebb37a249b5f | 271 | |
Ludwigfr | 22:ebb37a249b5f | 272 | float alpha=compute_angle_between_vectors(x,y,xs,ys);//angle beetween the point and the sonar beam |
geotsam | 24:8f4b820d8de8 | 273 | float alphaBeforeAdjustment=alpha-theta-angleFromSonarPosition; |
Ludwigfr | 22:ebb37a249b5f | 274 | alpha=rad_angle_check(alphaBeforeAdjustment);//TODO I feel you don't need to do that but I m not sure |
Ludwigfr | 22:ebb37a249b5f | 275 | float distancePointToSonar=sqrt(pow(x-xs,2)+pow(y-ys,2)); |
Ludwigfr | 22:ebb37a249b5f | 276 | |
Ludwigfr | 22:ebb37a249b5f | 277 | //check if the distance between the cell and the robot is within the circle of range RADIUS_WHEELS |
Ludwigfr | 22:ebb37a249b5f | 278 | //check if absolute difference between the angles is no more than Omega/2 |
Ludwigfr | 22:ebb37a249b5f | 279 | if( distancePointToSonar < (RANGE_SONAR)&& (alpha <= ANGLE_SONAR/2 || alpha >= rad_angle_check(-ANGLE_SONAR/2))){ |
Ludwigfr | 22:ebb37a249b5f | 280 | if( distancePointToSonar < (distanceObstacleDetected - INCERTITUDE_SONAR)){ |
Ludwigfr | 22:ebb37a249b5f | 281 | //point before obstacle, probably empty |
Ludwigfr | 22:ebb37a249b5f | 282 | /*****************************************************************************/ |
Ludwigfr | 22:ebb37a249b5f | 283 | float Ea=1.f-pow((2*alphaBeforeAdjustment)/ANGLE_SONAR,2); |
Ludwigfr | 22:ebb37a249b5f | 284 | float Er; |
Ludwigfr | 22:ebb37a249b5f | 285 | if(distancePointToSonar < RANGE_SONAR_MIN){ |
Ludwigfr | 22:ebb37a249b5f | 286 | //point before minimum sonar range |
Ludwigfr | 22:ebb37a249b5f | 287 | Er=0.f; |
Ludwigfr | 22:ebb37a249b5f | 288 | }else{ |
Ludwigfr | 22:ebb37a249b5f | 289 | //point after minimum sonar range |
Ludwigfr | 22:ebb37a249b5f | 290 | Er=1.f-pow((distancePointToSonar-RANGE_SONAR_MIN)/(distanceObstacleDetected-INCERTITUDE_SONAR-RANGE_SONAR_MIN),2); |
Ludwigfr | 22:ebb37a249b5f | 291 | } |
Ludwigfr | 22:ebb37a249b5f | 292 | /*****************************************************************************/ |
Ludwigfr | 22:ebb37a249b5f | 293 | return (1.f-Er*Ea)/2.f; |
Ludwigfr | 22:ebb37a249b5f | 294 | }else{ |
Ludwigfr | 22:ebb37a249b5f | 295 | //probably occupied |
Ludwigfr | 22:ebb37a249b5f | 296 | /*****************************************************************************/ |
Ludwigfr | 22:ebb37a249b5f | 297 | float Oa=1.f-pow((2*alphaBeforeAdjustment)/ANGLE_SONAR,2); |
Ludwigfr | 22:ebb37a249b5f | 298 | float Or; |
Ludwigfr | 22:ebb37a249b5f | 299 | if( distancePointToSonar <= (distanceObstacleDetected + INCERTITUDE_SONAR)){ |
Ludwigfr | 22:ebb37a249b5f | 300 | //point between distanceObstacleDetected +- INCERTITUDE_SONAR |
Ludwigfr | 22:ebb37a249b5f | 301 | Or=1-pow((distancePointToSonar-distanceObstacleDetected)/(INCERTITUDE_SONAR),2); |
Ludwigfr | 22:ebb37a249b5f | 302 | }else{ |
Ludwigfr | 22:ebb37a249b5f | 303 | //point after in range of the sonar but after the zone detected |
Ludwigfr | 22:ebb37a249b5f | 304 | Or=0; |
Ludwigfr | 22:ebb37a249b5f | 305 | } |
Ludwigfr | 22:ebb37a249b5f | 306 | /*****************************************************************************/ |
Ludwigfr | 22:ebb37a249b5f | 307 | return (1+Or*Oa)/2; |
Ludwigfr | 22:ebb37a249b5f | 308 | } |
Ludwigfr | 22:ebb37a249b5f | 309 | }else{ |
Ludwigfr | 25:572c9e9a8809 | 310 | //not checked by the sonar |
Ludwigfr | 22:ebb37a249b5f | 311 | return 0.5; |
AurelienBernier | 19:dbc5fbad4975 | 312 | } |
Ludwigfr | 22:ebb37a249b5f | 313 | } |
Ludwigfr | 22:ebb37a249b5f | 314 | |
Ludwigfr | 25:572c9e9a8809 | 315 | void print_final_map() { |
Ludwigfr | 22:ebb37a249b5f | 316 | float currProba; |
geotsam | 24:8f4b820d8de8 | 317 | pc.printf("\n\r"); |
geotsam | 24:8f4b820d8de8 | 318 | for (int y = NB_CELL_HEIGHT -1; y>-1; y--) { |
geotsam | 24:8f4b820d8de8 | 319 | for (int x= 0; x<NB_CELL_WIDTH; x++) { |
geotsam | 24:8f4b820d8de8 | 320 | currProba=log_to_proba(map[x][y]); |
geotsam | 24:8f4b820d8de8 | 321 | if ( currProba < 0.5) { |
geotsam | 24:8f4b820d8de8 | 322 | pc.printf(" 0 "); |
Ludwigfr | 22:ebb37a249b5f | 323 | } else { |
Ludwigfr | 22:ebb37a249b5f | 324 | if(currProba==0.5) |
geotsam | 24:8f4b820d8de8 | 325 | pc.printf(" . "); |
Ludwigfr | 22:ebb37a249b5f | 326 | else |
geotsam | 24:8f4b820d8de8 | 327 | pc.printf(" + "); |
Ludwigfr | 22:ebb37a249b5f | 328 | } |
Ludwigfr | 22:ebb37a249b5f | 329 | } |
geotsam | 24:8f4b820d8de8 | 330 | pc.printf("\n\r"); |
Ludwigfr | 22:ebb37a249b5f | 331 | } |
Ludwigfr | 22:ebb37a249b5f | 332 | } |
Ludwigfr | 22:ebb37a249b5f | 333 | |
Ludwigfr | 25:572c9e9a8809 | 334 | void print_final_map_with_robot_position() { |
geotsam | 24:8f4b820d8de8 | 335 | float currProba; |
Ludwigfr | 25:572c9e9a8809 | 336 | Odometria(); |
Ludwigfr | 25:572c9e9a8809 | 337 | float Xrobot=robot_center_x_in_orthonormal_x(); |
Ludwigfr | 25:572c9e9a8809 | 338 | float Yrobot=robot_center_y_in_orthonormal_y(); |
Ludwigfr | 25:572c9e9a8809 | 339 | |
Ludwigfr | 25:572c9e9a8809 | 340 | float heightIndiceInOrthonormal; |
Ludwigfr | 25:572c9e9a8809 | 341 | float widthIndiceInOrthonormal; |
Ludwigfr | 25:572c9e9a8809 | 342 | |
Ludwigfr | 25:572c9e9a8809 | 343 | float heightMalus=-(3*sizeCellX/2); |
Ludwigfr | 25:572c9e9a8809 | 344 | float heightBonus=sizeCellX/2; |
Ludwigfr | 25:572c9e9a8809 | 345 | |
Ludwigfr | 25:572c9e9a8809 | 346 | float widthMalus=-(3*sizeCellY/2); |
Ludwigfr | 25:572c9e9a8809 | 347 | float widthBonus=sizeCellY/2; |
Ludwigfr | 25:572c9e9a8809 | 348 | |
geotsam | 24:8f4b820d8de8 | 349 | pc.printf("\n\r"); |
geotsam | 24:8f4b820d8de8 | 350 | for (int y = NB_CELL_HEIGHT -1; y>-1; y--) { |
geotsam | 24:8f4b820d8de8 | 351 | for (int x= 0; x<NB_CELL_WIDTH; x++) { |
Ludwigfr | 25:572c9e9a8809 | 352 | heightIndiceInOrthonormal=estimated_height_indice_in_orthonormal_y(y); |
Ludwigfr | 25:572c9e9a8809 | 353 | widthIndiceInOrthonormal=estimated_width_indice_in_orthonormal_x(x); |
Ludwigfr | 25:572c9e9a8809 | 354 | if(Xrobot >= (heightIndiceInOrthonormal+heightMalus) && Xrobot <= (heightIndiceInOrthonormal+heightBonus) && Yrobot >= (widthIndiceInOrthonormal+widthMalus) && Yrobot <= (widthIndiceInOrthonormal+widthBonus)) |
geotsam | 24:8f4b820d8de8 | 355 | pc.printf(" R "); |
Ludwigfr | 25:572c9e9a8809 | 356 | else{ |
Ludwigfr | 25:572c9e9a8809 | 357 | currProba=log_to_proba(map[x][y]); |
Ludwigfr | 25:572c9e9a8809 | 358 | if ( currProba < 0.5) |
Ludwigfr | 25:572c9e9a8809 | 359 | pc.printf(" 0 "); |
Ludwigfr | 25:572c9e9a8809 | 360 | else{ |
Ludwigfr | 25:572c9e9a8809 | 361 | if(currProba==0.5) |
Ludwigfr | 25:572c9e9a8809 | 362 | pc.printf(" . "); |
Ludwigfr | 25:572c9e9a8809 | 363 | else |
Ludwigfr | 25:572c9e9a8809 | 364 | pc.printf(" + "); |
Ludwigfr | 25:572c9e9a8809 | 365 | } |
geotsam | 24:8f4b820d8de8 | 366 | } |
geotsam | 24:8f4b820d8de8 | 367 | } |
geotsam | 24:8f4b820d8de8 | 368 | pc.printf("\n\r"); |
geotsam | 24:8f4b820d8de8 | 369 | } |
geotsam | 24:8f4b820d8de8 | 370 | } |
Ludwigfr | 22:ebb37a249b5f | 371 | |
Ludwigfr | 22:ebb37a249b5f | 372 | |
Ludwigfr | 22:ebb37a249b5f | 373 | //MATHS heavy functions |
Ludwigfr | 22:ebb37a249b5f | 374 | /**********************************************************************/ |
Ludwigfr | 22:ebb37a249b5f | 375 | //Distance computation function |
Ludwigfr | 22:ebb37a249b5f | 376 | float dist(float robot_x, float robot_y, float target_x, float target_y){ |
Ludwigfr | 22:ebb37a249b5f | 377 | return sqrt(pow(target_y-robot_y,2) + pow(target_x-robot_x,2)); |
Ludwigfr | 22:ebb37a249b5f | 378 | } |
Ludwigfr | 22:ebb37a249b5f | 379 | |
geotsam | 24:8f4b820d8de8 | 380 | //returns the probability [0,1] that the cell is occupied from the log valAue lt |
Ludwigfr | 22:ebb37a249b5f | 381 | float log_to_proba(float lt){ |
Ludwigfr | 22:ebb37a249b5f | 382 | return 1-1/(1+exp(lt)); |
Ludwigfr | 22:ebb37a249b5f | 383 | } |
Ludwigfr | 22:ebb37a249b5f | 384 | |
Ludwigfr | 22:ebb37a249b5f | 385 | //returns the log value that the cell is occupied from the probability value [0,1] |
Ludwigfr | 22:ebb37a249b5f | 386 | float proba_to_log(float p){ |
Ludwigfr | 22:ebb37a249b5f | 387 | return log(p/(1-p)); |
Ludwigfr | 22:ebb37a249b5f | 388 | } |
Ludwigfr | 22:ebb37a249b5f | 389 | |
Ludwigfr | 22:ebb37a249b5f | 390 | //returns the new log value |
Ludwigfr | 22:ebb37a249b5f | 391 | float compute_log_estimation_lt(float previousLogValue,float currentProbability,float originalLogvalue ){ |
Ludwigfr | 22:ebb37a249b5f | 392 | return previousLogValue+proba_to_log(currentProbability)-originalLogvalue; |
Ludwigfr | 22:ebb37a249b5f | 393 | } |
Ludwigfr | 22:ebb37a249b5f | 394 | |
Ludwigfr | 22:ebb37a249b5f | 395 | //makes the angle inAngle between 0 and 2pi |
Ludwigfr | 22:ebb37a249b5f | 396 | float rad_angle_check(float inAngle){ |
Ludwigfr | 22:ebb37a249b5f | 397 | //cout<<"before :"<<inAngle; |
Ludwigfr | 22:ebb37a249b5f | 398 | if(inAngle > 0){ |
Ludwigfr | 22:ebb37a249b5f | 399 | while(inAngle > (2*pi)) |
Ludwigfr | 22:ebb37a249b5f | 400 | inAngle-=2*pi; |
Ludwigfr | 22:ebb37a249b5f | 401 | }else{ |
Ludwigfr | 22:ebb37a249b5f | 402 | while(inAngle < 0) |
Ludwigfr | 22:ebb37a249b5f | 403 | inAngle+=2*pi; |
Ludwigfr | 22:ebb37a249b5f | 404 | } |
Ludwigfr | 22:ebb37a249b5f | 405 | //cout<<" after :"<<inAngle<<endl; |
Ludwigfr | 22:ebb37a249b5f | 406 | return inAngle; |
Ludwigfr | 22:ebb37a249b5f | 407 | } |
Ludwigfr | 22:ebb37a249b5f | 408 | |
Ludwigfr | 22:ebb37a249b5f | 409 | //returns the angle between the vectors (x,y) and (xs,ys) |
Ludwigfr | 22:ebb37a249b5f | 410 | float compute_angle_between_vectors(float x, float y,float xs,float ys){ |
Ludwigfr | 22:ebb37a249b5f | 411 | //alpha angle between ->x and ->SA |
Ludwigfr | 22:ebb37a249b5f | 412 | //vector S to A ->SA |
Ludwigfr | 22:ebb37a249b5f | 413 | float vSAx=x-xs; |
Ludwigfr | 22:ebb37a249b5f | 414 | float vSAy=y-ys; |
Ludwigfr | 22:ebb37a249b5f | 415 | //norme SA |
Ludwigfr | 22:ebb37a249b5f | 416 | float normeSA=sqrt(pow(vSAx,2)+pow(vSAy,2)); |
Ludwigfr | 22:ebb37a249b5f | 417 | //vector ->x (1,0) |
Ludwigfr | 22:ebb37a249b5f | 418 | float cosAlpha=1*vSAy/*+0*vSAx*//normeSA;; |
Ludwigfr | 22:ebb37a249b5f | 419 | //vector ->y (0,1) |
Ludwigfr | 22:ebb37a249b5f | 420 | float sinAlpha=/*0*vSAy+*/1*vSAx/normeSA;//+0*vSAx; |
Ludwigfr | 22:ebb37a249b5f | 421 | if (sinAlpha < 0) |
Ludwigfr | 22:ebb37a249b5f | 422 | return -acos(cosAlpha); |
Ludwigfr | 22:ebb37a249b5f | 423 | else |
Ludwigfr | 22:ebb37a249b5f | 424 | return acos(cosAlpha); |
Ludwigfr | 25:572c9e9a8809 | 425 | } |
Ludwigfr | 25:572c9e9a8809 | 426 | |
Ludwigfr | 25:572c9e9a8809 | 427 | float robot_center_x_in_orthonormal_x(){ |
Ludwigfr | 25:572c9e9a8809 | 428 | return Y; |
Ludwigfr | 25:572c9e9a8809 | 429 | } |
Ludwigfr | 25:572c9e9a8809 | 430 | |
Ludwigfr | 25:572c9e9a8809 | 431 | float robot_center_y_in_orthonormal_y(){ |
Ludwigfr | 25:572c9e9a8809 | 432 | return NB_CELL_WIDTH*sizeCellX-X; |
Ludwigfr | 25:572c9e9a8809 | 433 | } |
Ludwigfr | 25:572c9e9a8809 | 434 | |
Ludwigfr | 25:572c9e9a8809 | 435 | float robot_sonar_front_x_in_orthonormal_x(){ |
Ludwigfr | 25:572c9e9a8809 | 436 | return Y+DISTANCE_SONAR_FRONT_Y; |
Ludwigfr | 25:572c9e9a8809 | 437 | } |
Ludwigfr | 25:572c9e9a8809 | 438 | float robot_sonar_front_y_in_orthonormal_y(){ |
Ludwigfr | 25:572c9e9a8809 | 439 | return NB_CELL_WIDTH*sizeCellX-X+DISTANCE_SONAR_FRONT_X; |
Ludwigfr | 25:572c9e9a8809 | 440 | } |
Ludwigfr | 25:572c9e9a8809 | 441 | |
Ludwigfr | 25:572c9e9a8809 | 442 | float robot_sonar_right_x_in_orthonormal_x(){ |
Ludwigfr | 25:572c9e9a8809 | 443 | return Y+DISTANCE_SONAR_RIGHT_Y; |
Ludwigfr | 25:572c9e9a8809 | 444 | } |
Ludwigfr | 25:572c9e9a8809 | 445 | float robot_sonar_right_y_in_orthonormal_y(){ |
Ludwigfr | 25:572c9e9a8809 | 446 | return NB_CELL_WIDTH*sizeCellX-X+DISTANCE_SONAR_RIGHT_X; |
Ludwigfr | 25:572c9e9a8809 | 447 | } |
Ludwigfr | 25:572c9e9a8809 | 448 | |
Ludwigfr | 25:572c9e9a8809 | 449 | float robot_sonar_left_x_in_orthonormal_x(){ |
Ludwigfr | 25:572c9e9a8809 | 450 | return Y+DISTANCE_SONAR_LEFT_Y; |
Ludwigfr | 25:572c9e9a8809 | 451 | } |
Ludwigfr | 25:572c9e9a8809 | 452 | float robot_sonar_left_y_in_orthonormal_y(){ |
Ludwigfr | 25:572c9e9a8809 | 453 | return NB_CELL_WIDTH*sizeCellX-X+DISTANCE_SONAR_LEFT_X; |
Ludwigfr | 25:572c9e9a8809 | 454 | } |
Ludwigfr | 25:572c9e9a8809 | 455 | |
Ludwigfr | 25:572c9e9a8809 | 456 | float estimated_width_indice_in_orthonormal_x(int i){ |
Ludwigfr | 25:572c9e9a8809 | 457 | return sizeCellX/2+i*sizeCellX; |
Ludwigfr | 25:572c9e9a8809 | 458 | } |
Ludwigfr | 25:572c9e9a8809 | 459 | float estimated_height_indice_in_orthonormal_y(int j){ |
Ludwigfr | 25:572c9e9a8809 | 460 | return sizeCellY/2+j*sizeCellY; |
geotsam | 26:b020cf253059 | 461 | } |
geotsam | 26:b020cf253059 | 462 | |
geotsam | 26:b020cf253059 | 463 | void compute_angles_and_distance(float target_x, float target_y, float target_angle){ |
geotsam | 26:b020cf253059 | 464 | alpha = atan2((target_y-Y),(target_x-X))-theta; |
geotsam | 26:b020cf253059 | 465 | alpha = atan(sin(alpha)/cos(alpha)); |
geotsam | 26:b020cf253059 | 466 | rho = dist(X, Y, target_x, target_y); |
geotsam | 26:b020cf253059 | 467 | d2 = rho; |
geotsam | 26:b020cf253059 | 468 | beta = -alpha-theta+target_angle; |
geotsam | 26:b020cf253059 | 469 | |
geotsam | 26:b020cf253059 | 470 | //Computing angle error and distance towards the target value |
geotsam | 26:b020cf253059 | 471 | rho += dt*(-kRho*cos(alpha)*rho); |
geotsam | 26:b020cf253059 | 472 | temp = alpha; |
geotsam | 26:b020cf253059 | 473 | alpha += dt*(kRho*sin(alpha)-ka*alpha-kb*beta); |
geotsam | 26:b020cf253059 | 474 | beta += dt*(-kRho*sin(temp)); |
geotsam | 26:b020cf253059 | 475 | pc.printf("\n\r d2=%f", d2); |
geotsam | 26:b020cf253059 | 476 | pc.printf("\n\r dt=%f", dt); |
geotsam | 26:b020cf253059 | 477 | } |
geotsam | 26:b020cf253059 | 478 | |
geotsam | 26:b020cf253059 | 479 | void compute_linear_angular_velocities(){ |
geotsam | 26:b020cf253059 | 480 | //Computing linear and angular velocities |
geotsam | 26:b020cf253059 | 481 | if(alpha>=-1.5708 && alpha<=1.5708){ |
geotsam | 26:b020cf253059 | 482 | linear=kRho*rho; |
geotsam | 26:b020cf253059 | 483 | angular=ka*alpha+kb*beta; |
geotsam | 26:b020cf253059 | 484 | } |
geotsam | 26:b020cf253059 | 485 | else{ |
geotsam | 26:b020cf253059 | 486 | linear=-kRho*rho; |
geotsam | 26:b020cf253059 | 487 | angular=-ka*alpha-kb*beta; |
geotsam | 26:b020cf253059 | 488 | } |
geotsam | 26:b020cf253059 | 489 | angular_left=(linear-0.5*DISTANCE_WHEELS*angular)/RADIUS_WHEELS; |
geotsam | 26:b020cf253059 | 490 | angular_right=(linear+0.5*DISTANCE_WHEELS*angular)/RADIUS_WHEELS; |
geotsam | 26:b020cf253059 | 491 | |
geotsam | 26:b020cf253059 | 492 | //Slowing down at the end for more precision |
geotsam | 26:b020cf253059 | 493 | // if (d2<25) { |
geotsam | 26:b020cf253059 | 494 | // speed = d2*30; |
geotsam | 26:b020cf253059 | 495 | // } |
geotsam | 26:b020cf253059 | 496 | |
geotsam | 26:b020cf253059 | 497 | //Normalize speed for motors |
geotsam | 26:b020cf253059 | 498 | if(angular_left>angular_right) { |
geotsam | 26:b020cf253059 | 499 | angular_right=speed*angular_right/angular_left; |
geotsam | 26:b020cf253059 | 500 | angular_left=speed; |
geotsam | 26:b020cf253059 | 501 | } else { |
geotsam | 26:b020cf253059 | 502 | angular_left=speed*angular_left/angular_right; |
geotsam | 26:b020cf253059 | 503 | angular_right=speed; |
geotsam | 26:b020cf253059 | 504 | } |
geotsam | 24:8f4b820d8de8 | 505 | } |