Tobias Berger
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PES 2 - Gruppe 1
source/Positioning.cpp
- Committer:
- cittecla
- Date:
- 2017-05-12
- Revision:
- 120:cdf7a6751f9e
- Parent:
- 118:fbd6d41f6ce8
- Child:
- 121:af16ffc05593
File content as of revision 120:cdf7a6751f9e:
/**
* Positioning function library
* Handels position of the Robot on the map
**/
#include "Positioning.h"
coordinates current_coord; // in degree // Updated
position current_pos; // in degree // Generated from current_coord
float current_heading;
position next_pos;
bool init = false;
Timer t2;
int deg_r = 0;
int deg_l = 0;
float last_dist_r = 0;
float last_dist_l = 0;
float direction_r = 0;
float direction_l = 0;
coordinates get_current_coord()
{
return current_coord;
}
coordinates pos_to_coord(position pos)
{
coordinates coord = {0};
coord.x = pos.x + 0.5f;
coord.y = pos.y + 0.5f;
return coord;
}
position coord_to_pos(coordinates coord)
{
position pos = {0};
pos.x = rint(coord.x -0.5f); //round values
pos.y = rint(coord.y -0.5f);
return pos;
}
position get_current_pos()
{
current_pos = coord_to_pos(current_coord);
return current_pos;
}
position get_next_pos()
{
return next_pos;
}
float get_current_heading()
{
return current_heading;
}
void clamp_heading()
{
while (current_heading >= 360) current_heading -= 360;
while (current_heading < 0) current_heading += 360;
}
void positioning()
{
//printf("positioning...\r\n");
// get wheel_speed
float speed_left = get_speed_left();
float speed_right = get_speed_right();
// calc movement and turning speed
float movement_speed = (speed_left + speed_right) /2.0f ;
float turning_speed = speed_left - speed_right;
// calc heading and coverd distance
current_heading += 360/(2*circle_r*M_PI) * ((2*(float)wheel_r*(float)M_PI)/(2*M_PI) * t2.read() * turning_speed*0.1f);
float distance = (2*(float)wheel_r*(float)M_PI)/(2*M_PI) * t2.read() * movement_speed * 0.1f;
clamp_heading();
t2.reset();
t2.start();
// calc new position
current_coord.x += sin(current_heading/180.0f*(float)M_PI)* distance;
current_coord.y -= cos(current_heading/180.0f*(float)M_PI) * distance;
current_pos = coord_to_pos(current_coord);
}
int initial_positioning()
{
if(init == false) {
printf("initial_positioning init\r\n");
last_dist_r = 100;
last_dist_l = 100;
// deg_r = -50;
// deg_l = 50;
deg_r = 0;
deg_l = 0;
set_servo_position(0,deg_l); //servo sensor left
set_servo_position(2,deg_r); //servo sensor right
current_coord.x = 0;
current_coord.y = 0;
t2.start();
init = true;
} else {
if(t2 > 0.2f) {
t2.reset();
float dist_r = getDistanceIR(0);
float dist_l = getDistanceIR(4);
printf("distances %f || %f\r\n",dist_l, dist_r);
//right
if(dist_r < last_dist_r) {
last_dist_r = dist_r;
deg_r += 3;
set_servo_position(2,deg_r);
} else if(current_coord.y == 0) {
deg_r -= 5; //compensate overturning
//deg_r -= 3; // compensate not straight looking
dist_r *= 100;
float offsetx = 11.5;
float offsety = 11;
current_coord.y = dist_r + sqrt(offsetx*offsetx+offsety*offsety)*cos((90-deg_r-atan(offsety-offsetx))/180.0f*(float)M_PI);
}
//left
if(dist_l < last_dist_l) {
last_dist_l = dist_l;
deg_l -= 5;
set_servo_position(0,deg_l);
} else if(current_coord.x == 0) {
deg_l += 3; //compensate overturning
deg_l -= 3; //compensate not straight looking
dist_r *= 100;
float offsetx = 11.5;
float offsety = 11;
current_coord.x = dist_r + sqrt(offsetx*offsetx+offsety*offsety)*cos((90-fabsf(deg_l)-atan(offsetx-offsety))/180.0f*(float)M_PI);
}
if(current_coord.x != 0 && current_coord.y != 0) {
printf("degs: %d || %d \r\n", deg_l , deg_r);
printf("coords : %f || %f \r\n", current_coord.x, current_coord.y);
current_heading = (360-deg_r + 270-deg_l)/2;
clamp_heading();
printf("heading: %f \r\n", current_heading);
current_coord.x = 20;
current_coord.y = 20;
//finished
return 11;
}
}
}
// not finished
return 17;
}