#include "gyro.h" #include "Localisation.h" #include "QEI.h" #include "math.h" #include "Geometrie_robot.h" #include "Robot_config.h" struct position_t position; void Localisation_init(){ position.x_mm = 0; position.y_mm = 0; position.angle_radian = 0; } void Localisation_set(double x_mm, double y_mm, double angle_radian){ position.x_mm = x_mm; position.y_mm = y_mm; position.angle_radian = angle_radian; gyro_set_angle_radian(angle_radian); } void Localisation_set_x(double x_mm){ position.x_mm = x_mm; } void Localisation_set_y(double y_mm){ position.y_mm = y_mm; } void Localisation_set_angle(double angle_radian){ position.angle_radian = angle_radian; } void Localisation_gestion(){ struct t_angle_gyro_double angle_gyro; // Voir http://poivron-robotique.fr/Robot-holonome-localisation-partie-2.html double distance_roue_a_mm = QEI_get_mm(QEI_A_NAME); double distance_roue_b_mm = QEI_get_mm(QEI_B_NAME); double distance_roue_c_mm = QEI_get_mm(QEI_C_NAME); double delta_x_ref_robot, delta_y_ref_robot; double old_orientation_radian = position.angle_radian; delta_x_ref_robot = (distance_roue_a_mm + distance_roue_b_mm - 2 * distance_roue_c_mm) / 3.0; delta_y_ref_robot = (-distance_roue_a_mm + distance_roue_b_mm) * RACINE_DE_3 / 3.0; if(get_position_avec_gyroscope()){ angle_gyro = gyro_get_angle_degres(); position.angle_radian = angle_gyro.rot_z / 180. * M_PI ; }else{ position.angle_radian += - ( distance_roue_a_mm + distance_roue_b_mm + distance_roue_c_mm) / (3 * DISTANCE_ROUES_CENTRE_MM); } // Projection dans le référentiel de la table position.x_mm += delta_x_ref_robot * cos(position.angle_radian) - delta_y_ref_robot * sin(position.angle_radian); position.y_mm += delta_x_ref_robot * sin(position.angle_radian) + delta_y_ref_robot * cos(position.angle_radian); } struct position_t Localisation_get(void){ return position; }