Romain Ame
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Stressed
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Odometry/Odometry.cpp
- Committer:
- sype
- Date:
- 2015-11-24
- Revision:
- 2:abdf8c6823a1
- Parent:
- 0:ad9600df4a70
- Child:
- 3:62e9d715de65
File content as of revision 2:abdf8c6823a1:
#include "Odometry.h" // M1 = Moteur droit, M2 = Moteur gauche Odometry::Odometry(double diameter_right, double diameter_left, double v, RoboClaw &rc) : roboclaw(rc) { m_v = v; m_distPerTick_left = diameter_left*PI/37400; m_distPerTick_right = diameter_right*PI/37400; erreur_ang = 0.1; m_pulses_right = 0; m_pulses_left = 0; wait_ms(100); } void Odometry::setPos(double x, double y, double theta) { this->x = x; this->y = y; this->theta = theta; } void Odometry::setX(double x) { this->x = x; } void Odometry::setY(double y) { this->y = y; } void Odometry::setTheta(double theta) { this->theta = theta; } void Odometry::update_odo(void) { long delta_right = roboclaw.ReadEncM1(ADR) - m_pulses_right; m_pulses_right = roboclaw.ReadEncM1(ADR); long delta_left = roboclaw.ReadEncM2(ADR) - m_pulses_left; m_pulses_left = roboclaw.ReadEncM2(ADR); double deltaS = (m_distPerTick_left*delta_left + m_distPerTick_right*delta_right) / 2.0f; double deltaTheta = (m_distPerTick_right*delta_right - m_distPerTick_left*delta_left)*C / m_v; double radius = deltaS/deltaTheta; double xO = x - radius*sin(theta); double yO = y + radius*cos(theta); theta += deltaTheta; x = xO + radius*sin(theta); y = yO - radius*cos(theta); while(theta > PI) theta -= 2*PI; while(theta <= -PI) theta += 2*PI; } void Odometry::GotoXYT(double x_goal, double y_goal, double theta_goal) { double theta_ = atan2(y_goal-y, x_goal-x); float distance = sqrt(carre(x_goal-x)+carre(y_goal-y)); GotoThet(theta_); } void Odometry::GotoThet(double theta_) { double distance_ticks_left; double distance_ticks_right; double erreur_theta = theta_-getTheta(); while(erreur_theta > PI) erreur_theta -= 2*PI; while(erreur_theta <= -PI) erreur_theta += 2*PI; if(erreur_theta >= 0) { distance_ticks_left = -(erreur_theta*m_v/2)/m_distPerTick_left; distance_ticks_right = (erreur_theta*m_v/2)/m_distPerTick_right; } else { distance_ticks_left = (erreur_theta*m_v/2)/m_distPerTick_left; distance_ticks_right = -(erreur_theta*m_v/2)/m_distPerTick_right; } pc.printf("T_%3.2f\t T%3.2f\t ET%3.2f\n\r",theta_*180/PI, getTheta()*180/PI, erreur_theta*180/PI); roboclaw.SpeedAccelDeccelPositionM1M2(ADR, 150000, 150000, 150000, (long)distance_ticks_right, 150000, 150000, 150000, (long)distance_ticks_left, 1); while(isArrivedRot(erreur_theta))pc.printf("Theta : %3.2f\n\r",getTheta()*180/PI);; pc.printf("Arrived"); } void Odometry::GotoB(double distance) { double distance_ticks_left = distance/m_distPerTick_left; double distance_ticks_right = distance/m_distPerTick_right; roboclaw.SpeedAccelDeccelPositionM1M2(ADR, 150000, 200000, 150000, (long)distance_ticks_right, 150000, 200000, 150000, (long)distance_ticks_left, 1); } bool Odometry::isArrivedRot(double theta_) { if((abs_d(getTheta())<=abs_d(theta_)+erreur_ang)|(abs_d(getTheta())>=abs_d(theta_)-erreur_ang)) return true; else return false; }