Robot secondaire

Dependencies:   RoboClaw mbed StepperMotor

Fork of RoboClaw by Simon Emarre

Committer:
Near32
Date:
Tue Jan 26 17:02:41 2016 +0000
Revision:
32:068bd2b2e1f3
Parent:
31:8bcc3a0bfa8a
Child:
33:7f8c29ddee61
Child:
34:e5500418b0e7
odometry::update_odo : change made with required to the queries to roboclaw.

Who changed what in which revision?

UserRevisionLine numberNew contents of line
sype 0:ad9600df4a70 1 #include "Odometry.h"
sype 0:ad9600df4a70 2
sype 0:ad9600df4a70 3 // M1 = Moteur droit, M2 = Moteur gauche
sype 0:ad9600df4a70 4
sype 10:ae3178aa94e9 5 Odometry::Odometry(double diameter_right, double diameter_left, double v, uint16_t quadrature, RoboClaw &rc) : roboclaw(rc)
sype 10:ae3178aa94e9 6 {
sype 0:ad9600df4a70 7 m_v = v;
sype 10:ae3178aa94e9 8 m_distPerTick_left = diameter_left*PI/quadrature;
sype 10:ae3178aa94e9 9 m_distPerTick_right = diameter_right*PI/quadrature;
sype 4:3e6e78d6d3d9 10
sype 3:62e9d715de65 11 roboclaw.ForwardM1(ADR, 0);
sype 3:62e9d715de65 12 roboclaw.ForwardM2(ADR, 0);
sype 10:ae3178aa94e9 13 roboclaw.ResetEnc(ADR);
sype 4:3e6e78d6d3d9 14 // Erreur autorisée sur le déplacement en angle
sype 3:62e9d715de65 15 erreur_ang = 0.01;
sype 4:3e6e78d6d3d9 16
sype 0:ad9600df4a70 17 m_pulses_right = 0;
sype 0:ad9600df4a70 18 m_pulses_left = 0;
sype 10:ae3178aa94e9 19 pos_prog = 0;
sype 2:abdf8c6823a1 20 wait_ms(100);
sype 0:ad9600df4a70 21 }
sype 0:ad9600df4a70 22
sype 10:ae3178aa94e9 23 void Odometry::setPos(double x, double y, double theta)
sype 10:ae3178aa94e9 24 {
sype 0:ad9600df4a70 25 this->x = x;
sype 0:ad9600df4a70 26 this->y = y;
sype 0:ad9600df4a70 27 this->theta = theta;
sype 0:ad9600df4a70 28 }
sype 12:d5e21f71c2a9 29 void Odometry::getEnc()
sype 12:d5e21f71c2a9 30 {
sype 12:d5e21f71c2a9 31 pc.printf("EncM1 : %d\tEncM2 : %d\n\r", roboclaw.ReadEncM1(ADR), roboclaw.ReadEncM2(ADR));
sype 12:d5e21f71c2a9 32 }
sype 0:ad9600df4a70 33
sype 10:ae3178aa94e9 34 void Odometry::setX(double x)
sype 10:ae3178aa94e9 35 {
sype 0:ad9600df4a70 36 this->x = x;
sype 0:ad9600df4a70 37 }
sype 0:ad9600df4a70 38
sype 10:ae3178aa94e9 39 void Odometry::setY(double y)
sype 10:ae3178aa94e9 40 {
sype 0:ad9600df4a70 41 this->y = y;
sype 0:ad9600df4a70 42 }
sype 0:ad9600df4a70 43
sype 10:ae3178aa94e9 44 void Odometry::setTheta(double theta)
sype 10:ae3178aa94e9 45 {
sype 0:ad9600df4a70 46 this->theta = theta;
sype 0:ad9600df4a70 47 }
sype 0:ad9600df4a70 48
sype 10:ae3178aa94e9 49 void Odometry::update_odo(void)
sype 10:ae3178aa94e9 50 {
Near32 32:068bd2b2e1f3 51 int32_t roboclawENCM1 = roboclaw.ReadEncM1(ADR);
Near32 32:068bd2b2e1f3 52 int32_t roboclawENCM2 = roboclaw.ReadEncM2(ADR);
Near32 32:068bd2b2e1f3 53 int32_t delta_right = roboclawENCM1 - m_pulses_right;
Near32 32:068bd2b2e1f3 54 m_pulses_right = roboclawENCM1;
Near32 32:068bd2b2e1f3 55 int32_t delta_left = roboclawENCM2 - m_pulses_left;
Near32 32:068bd2b2e1f3 56 m_pulses_left = roboclawENCM2;
sype 12:d5e21f71c2a9 57
sype 12:d5e21f71c2a9 58 double deltaS = (m_distPerTick_left*delta_left + m_distPerTick_right*delta_right)*C / 2.0f;
sype 12:d5e21f71c2a9 59 double deltaTheta = (m_distPerTick_left*delta_left - m_distPerTick_right*delta_right)*C / m_v;
sype 4:3e6e78d6d3d9 60
sype 12:d5e21f71c2a9 61 /*double R = deltaS/deltaTheta;
sype 10:ae3178aa94e9 62
sype 10:ae3178aa94e9 63 double xO = x - R*sin(theta);
sype 10:ae3178aa94e9 64 double yO = y + R*cos(theta);
sype 4:3e6e78d6d3d9 65
sype 0:ad9600df4a70 66 theta += deltaTheta;
sype 4:3e6e78d6d3d9 67
sype 10:ae3178aa94e9 68 if(deltaTheta == 0) {
sype 10:ae3178aa94e9 69 x = x + deltaS*cos(theta);
sype 10:ae3178aa94e9 70 y = y + deltaS*sin(theta);
sype 10:ae3178aa94e9 71 }
sype 10:ae3178aa94e9 72 else {
sype 10:ae3178aa94e9 73 x = xO + R*sin(theta);
sype 10:ae3178aa94e9 74 y = yO - R*cos(theta);
sype 12:d5e21f71c2a9 75 }*/
sype 10:ae3178aa94e9 76
sype 12:d5e21f71c2a9 77 double dx = deltaS*cos(theta);
sype 10:ae3178aa94e9 78 double dy = deltaS*sin(theta);
sype 10:ae3178aa94e9 79 x += dx;
sype 10:ae3178aa94e9 80 y += dy;
sype 12:d5e21f71c2a9 81 theta += deltaTheta;
sype 4:3e6e78d6d3d9 82
sype 0:ad9600df4a70 83 while(theta > PI) theta -= 2*PI;
sype 0:ad9600df4a70 84 while(theta <= -PI) theta += 2*PI;
sype 0:ad9600df4a70 85 }
sype 0:ad9600df4a70 86
sype 12:d5e21f71c2a9 87 void Odometry::GotoXY(double x_goal, double y_goal)
sype 12:d5e21f71c2a9 88 {
sype 12:d5e21f71c2a9 89 double theta_ = atan2(y_goal-y, x_goal-x);
sype 12:d5e21f71c2a9 90 double dist_ = sqrt(carre(x_goal-x)+carre(y_goal-y));
sype 12:d5e21f71c2a9 91 pc.printf("Dist : %3.2f\tTheta : %3.2f\n\r", dist_, theta_*180/PI);
sype 12:d5e21f71c2a9 92 GotoThet(theta_);
sype 12:d5e21f71c2a9 93 GotoDist(dist_);
sype 12:d5e21f71c2a9 94 }
sype 12:d5e21f71c2a9 95
sype 10:ae3178aa94e9 96 void Odometry::GotoXYT(double x_goal, double y_goal, double theta_goal)
sype 10:ae3178aa94e9 97 {
sype 0:ad9600df4a70 98 double theta_ = atan2(y_goal-y, x_goal-x);
sype 3:62e9d715de65 99 double dist_ = sqrt(carre(x_goal-x)+carre(y_goal-y));
sype 12:d5e21f71c2a9 100 pc.printf("Dist : %3.2f\tTheta : %3.2f\n\r", dist_, theta_*180/PI);
sype 2:abdf8c6823a1 101 GotoThet(theta_);
sype 3:62e9d715de65 102 GotoDist(dist_);
sype 12:d5e21f71c2a9 103 GotoThet(theta_goal);
sype 0:ad9600df4a70 104 }
sype 2:abdf8c6823a1 105
sype 10:ae3178aa94e9 106 void Odometry::GotoThet(double theta_)
sype 10:ae3178aa94e9 107 {
sype 10:ae3178aa94e9 108 led = 0;
sype 10:ae3178aa94e9 109 //pos_prog++;
sype 10:ae3178aa94e9 110 //pc.printf("Theta : %3.2f\n\r", theta_*180/PI);
sype 10:ae3178aa94e9 111 //arrived = false;
sype 10:ae3178aa94e9 112
sype 10:ae3178aa94e9 113 int32_t distance_ticks_left;
sype 10:ae3178aa94e9 114 int32_t distance_ticks_right;
sype 10:ae3178aa94e9 115
sype 10:ae3178aa94e9 116 int32_t pos_initiale_right = m_pulses_right, pos_initiale_left = m_pulses_left;
sype 4:3e6e78d6d3d9 117
sype 4:3e6e78d6d3d9 118 // Le calcul d'erreur est bon (testé), tu peux le vérifier par dessin
sype 3:62e9d715de65 119 double erreur_theta = theta_ - getTheta();
sype 4:3e6e78d6d3d9 120
sype 3:62e9d715de65 121 while(erreur_theta >= PI) erreur_theta -= 2*PI;
sype 12:d5e21f71c2a9 122 while(erreur_theta < -PI) erreur_theta += 2*PI;
sype 12:d5e21f71c2a9 123
sype 12:d5e21f71c2a9 124 pc.printf("ET : %3.2f\n\r", erreur_theta*180/PI);
sype 12:d5e21f71c2a9 125
sype 12:d5e21f71c2a9 126 if(erreur_theta < 0) {
sype 12:d5e21f71c2a9 127 distance_ticks_left = (int32_t) pos_initiale_left + (erreur_theta*m_v/2)/m_distPerTick_left;
sype 12:d5e21f71c2a9 128 distance_ticks_right = (int32_t) pos_initiale_right - (erreur_theta*m_v/2)/m_distPerTick_right;
sype 4:3e6e78d6d3d9 129 } else {
sype 12:d5e21f71c2a9 130 distance_ticks_left = (int32_t) pos_initiale_left + (erreur_theta*m_v/2)/m_distPerTick_left;
sype 12:d5e21f71c2a9 131 distance_ticks_right = (int32_t) pos_initiale_right - (erreur_theta*m_v/2)/m_distPerTick_right;
sype 2:abdf8c6823a1 132 }
sype 10:ae3178aa94e9 133
sype 12:d5e21f71c2a9 134 //pc.printf("TV %3.2f\tTh %3.2f\tET %3.2f\n\r",theta_*180/PI,getTheta()*180/PI,erreur_theta*180/PI);
sype 12:d5e21f71c2a9 135 //pc.printf("X : %3.2f\tY : %3.2f\tTheta : %3.2f\n\r", getX(), getY(), getTheta()*180/PI);
sype 10:ae3178aa94e9 136 //pc.printf("M1 %6d\tM2 %6d\n\r",distance_ticks_right, distance_ticks_left);
sype 10:ae3178aa94e9 137
sype 10:ae3178aa94e9 138 roboclaw.SpeedAccelDeccelPositionM1M2(ADR, accel_angle, vitesse_angle, deccel_angle, distance_ticks_right, accel_angle, vitesse_angle, deccel_angle, distance_ticks_left, 1);
sype 10:ae3178aa94e9 139
sype 10:ae3178aa94e9 140 //pc.printf("IniR:%6d\tDistR:%6d\tIniL:%6d\tDistL:%6d\n\r", pos_initiale_right, distance_ticks_right, pos_initiale_left, distance_ticks_left);
sype 10:ae3178aa94e9 141
sype 10:ae3178aa94e9 142 while((m_pulses_right != distance_ticks_right)&&(m_pulses_left != distance_ticks_left)); //pc.printf("%6d\t%6d\t%6d\t%6d\t%6d\n\r",m_pulses_right - pos_initiale_right, distance_ticks_right, m_pulses_left - pos_initiale_left, distance_ticks_left);
IceTeam 31:8bcc3a0bfa8a 143 wait(0.4);
IceTeam 31:8bcc3a0bfa8a 144 setTheta(theta_);
sype 10:ae3178aa94e9 145 led = 1;
sype 10:ae3178aa94e9 146 //arrived = true;
sype 10:ae3178aa94e9 147 //pc.printf("arrivey %d\n\r",pos_prog);
sype 2:abdf8c6823a1 148 }
sype 2:abdf8c6823a1 149
sype 10:ae3178aa94e9 150 void Odometry::GotoDist(double distance)
sype 10:ae3178aa94e9 151 {
sype 10:ae3178aa94e9 152 led = 0;
sype 10:ae3178aa94e9 153 //pos_prog++;
sype 10:ae3178aa94e9 154 //pc.printf("Dist : %3.2f\n\r", distance);
sype 10:ae3178aa94e9 155 //arrived = false;
sype 10:ae3178aa94e9 156
sype 10:ae3178aa94e9 157 int32_t pos_initiale_right = m_pulses_right, pos_initiale_left = m_pulses_left;
sype 10:ae3178aa94e9 158
sype 10:ae3178aa94e9 159 int32_t distance_ticks_right = (int32_t) distance/m_distPerTick_right + pos_initiale_right;
sype 10:ae3178aa94e9 160 int32_t distance_ticks_left = (int32_t) distance/m_distPerTick_left + pos_initiale_left;
sype 10:ae3178aa94e9 161
sype 10:ae3178aa94e9 162 roboclaw.SpeedAccelDeccelPositionM1M2(ADR, accel_dista, vitesse_dista, deccel_dista, distance_ticks_right, accel_dista, vitesse_dista, deccel_dista, distance_ticks_left, 1);
sype 10:ae3178aa94e9 163
sype 10:ae3178aa94e9 164 //pc.printf("IniR:%6d\tDistR:%6d\tIniL:%6d\tDistL:%6d\n\r", pos_initiale_right, distance_ticks_right, pos_initiale_left, distance_ticks_left);
sype 12:d5e21f71c2a9 165
sype 10:ae3178aa94e9 166 while((m_pulses_right != distance_ticks_right)&&(m_pulses_left != distance_ticks_left)); //pc.printf("PR:%6d\tIR:%6d\tDR:%6d\tPL:%6d\tIL:%6d\tDL:%6d\n\r",m_pulses_right, pos_initiale_right, distance_ticks_right, m_pulses_left, pos_initiale_left, distance_ticks_left);
IceTeam 31:8bcc3a0bfa8a 167 wait(0.4);
sype 10:ae3178aa94e9 168 led = 1;
sype 10:ae3178aa94e9 169 //pc.printf("arrivey %d\n\r",pos_prog);
sype 10:ae3178aa94e9 170 //pc.printf("X : %3.2f\tY : %3.2f\tTheta : %3.2f\n\r", getX(), getY(), getTheta()*180/PI);
sype 2:abdf8c6823a1 171 }