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Perpendicular_Parking_Simulator.m
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Perpendicular_Parking_Simulator.m
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close all
%% Perpendicular Parking Simulation of Robot
sample_time=0.1
dx_robo=300
dy_robo=150
speed=166
wheel_base=155
turn_radius=260
steer_angle=(atan(wheel_base/turn_radius))
rad2deg(steer_angle)
% Create a figure and plot the initial rectangle
f1=figure;
f1.Position=[50,100,1200,250]
hold on;
r_left_x1=0;
r_left_x2=0;
r_left_x3=5*dx_robo;
r_left_x4=5*dx_robo;
r_left_y1=2*dy_robo;
r_left_y2=2*dy_robo+1.5*dx_robo;
r_left_y3=2*dy_robo;
r_left_y4=2*dy_robo+1.5*dx_robo;
pgon_r_left = polyshape([r_left_x1 r_left_x2 r_left_x4 r_left_x3],[r_left_y1 r_left_y2 r_left_y4 r_left_y3]);
plot(pgon_r_left);
center_line_x1=5*dx_robo;
center_line_x2=5*dx_robo;
center_line_x3=5*dx_robo+1.5*dy_robo;
center_line_x4=5*dx_robo+1.5*dy_robo;
center_line_y1=2*dy_robo+1.6*dx_robo;
center_line_y2=2*dy_robo+1.5*dx_robo;
center_line_y3=2*dy_robo+1.6*dx_robo;
center_line_y4=2*dy_robo+1.5*dx_robo;
pgon_c_line = polyshape([center_line_x1 center_line_x2 center_line_x4 center_line_x3],[center_line_y1 center_line_y2 center_line_y4 center_line_y3]);
plot(pgon_c_line);
r_right_x1=5*dx_robo+1.5*dy_robo;
r_right_x2=5*dx_robo+1.5*dy_robo;
r_right_x3=5*dx_robo+1.5*dy_robo+3*dx_robo;
r_right_x4=5*dx_robo+1.5*dy_robo+3*dx_robo;
r_right_y1=2*dy_robo;
r_right_y2=2*dy_robo+1.5*dx_robo;
r_right_y3=2*dy_robo;
r_right_y4=2*dy_robo+1.5*dx_robo;
pgon_r_right = polyshape([r_right_x1 r_right_x2 r_right_x4 r_right_x3],[r_right_y1 r_right_y2 r_right_y4 r_right_y3]);
plot(pgon_r_right);
%robo_coordinates rear center
x_car=0;
y_car=dy_robo/2;
x1 = x_car; % x-coordinate of top-left corner
y1 = y_car + dy_robo/2; % y-coordinate of top-left corner
x2 = x_car; % x-coordinate of bottom-right corner
y2 = y_car - dy_robo/2; % y-coordinate of bottom-right corner
x3 = x_car+dx_robo; % x-coordinate of bottom-right corner
y3 = y_car + dy_robo/2; % y-coordinate of bottom-right corner
x4 = x_car+dx_robo; % x-coordinate of bottom-right corner
y4 = y_car - dy_robo/2; % y-coordinate of bottom-right corner
% Initialize rectangle plot
pgon_car = polyshape([x1 x2 x4 x3],[y1 y2 y4 y3]);
plot(pgon_car);
title('EV3 Robot Simulator - Perpendicular Parking');
% Draw straight line
x_start = 0;
y_start = 0;
x_end = 6.55*dx_robo;
y_end = dy_robo/2;
num_steps = 100;
straight_line = line([x_start x_end], [y_start+dy_robo/2 y_start+dy_robo/2], 'color', 'g', 'LineWidth', 1.5);
vehicle_speed=166
% Move the rectangle along the straight line
for i = 1:113
% Calculate the x-coordinate for each step
%clf(f1);
axis([-2*dx_robo 11*dx_robo -3*dy_robo 6*dy_robo]);
x_car=x_car+(vehicle_speed*cos(0)*sample_time);
y_car=y_car+(vehicle_speed*sin(0)*sample_time);
x1 = x_car; % x-coordinate of top-left corner
y1 = y_car + dy_robo/2; % y-coordinate of top-left corner
x2 = x_car; % x-coordinate of bottom-right corner
y2 = y_car - dy_robo/2; % y-coordinate of bottom-right corner
x3 = x_car+dx_robo; % x-coordinate of bottom-right corner
y3 = y_car + dy_robo/2; % y-coordinate of bottom-right corner
x4 = x_car+dx_robo; % x-coordinate of bottom-right corner
y4 = y_car - dy_robo/2; % y-coordinate of bottom-right corner
% Initialize rectangle plot
pgon_car = polyshape([x1 x2 x4 x3],[y1 y2 y4 y3]);
pgon_r_left = polyshape([r_left_x1 r_left_x2 r_left_x4 r_left_x3],[r_left_y1 r_left_y2 r_left_y4 r_left_y3]);
pgon_c_line = polyshape([center_line_x1 center_line_x2 center_line_x4 center_line_x3],[center_line_y1 center_line_y2 center_line_y4 center_line_y3]);
pgon_r_right = polyshape([r_right_x1 r_right_x2 r_right_x4 r_right_x3],[r_right_y1 r_right_y2 r_right_y4 r_right_y3]);
plot(pgon_car);
hold on;
%poly1 = rotate(pgon_car,45*i/num_steps,[x_car y_car]);
%poly1.Vertices
%plot(poly1);
hold on;
plot(pgon_r_left);
hold on;
plot(pgon_c_line);
hold on;
plot(pgon_r_right);
hold on;
plot(x_car, y_car, '.')
hold on;
plot(x_car, y_car, '.')
% Update rectangle position
%set(rect, 'Position', [x1_line, y1_line, x2_line, y2_line]);
%poly1 = rotate(rect,45);
%drawnow;
%pause(sample_time/1000);
pause(sample_time/10);
end
% Move the rectangle along the straight line
%arc1
x=x_car;
y=y_car;
theta=0;
speed=76;
for i = 1:53
% Calculate the x-coordinate for each step
i
%clf(f1);
axis([-2*dx_robo 11*dx_robo -2*dy_robo 6*dy_robo]);
del_theta = -speed/wheel_base*tan(steer_angle);
theta=theta+(del_theta*0.1);
rad2deg(theta)
x_car=x_car+(-speed)*cos(theta)*0.1;
y_car=y_car+(-speed)*sin(theta)*0.1;
x1 = x_car; % x-coordinate of top-left corner
y1 = y_car + dy_robo/2; % y-coordinate of top-left corner
x2 = x_car; % x-coordinate of bottom-right corner
y2 = y_car - dy_robo/2; % y-coordinate of bottom-right corner
x3 = x_car+dx_robo; % x-coordinate of bottom-right corner
y3 = y_car + dy_robo/2; % y-coordinate of bottom-right corner
x4 = x_car+dx_robo; % x-coordinate of bottom-right corner
y4 = y_car - dy_robo/2; % y-coordinate of bottom-right corner
% Initialize rectangle plot
pgon_car = polyshape([x1 x2 x4 x3],[y1 y2 y4 y3]);
pgon_r_left = polyshape([r_left_x1 r_left_x2 r_left_x4 r_left_x3],[r_left_y1 r_left_y2 r_left_y4 r_left_y3]);
pgon_c_line = polyshape([center_line_x1 center_line_x2 center_line_x4 center_line_x3],[center_line_y1 center_line_y2 center_line_y4 center_line_y3]);
pgon_r_right = polyshape([r_right_x1 r_right_x2 r_right_x4 r_right_x3],[r_right_y1 r_right_y2 r_right_y4 r_right_y3]);
%plot(pgon_car);
%hold on;
actual_car = rotate(pgon_car,rad2deg(theta),[x_car y_car]);
%actual_car.Vertices
plot(actual_car);
hold on;
plot(pgon_r_left);
hold on;
plot(pgon_c_line);
hold on;
plot(pgon_r_right);
hold on;
plot(x_car, y_car, '.', 'LineWidth', 1);
pause(sample_time);
end
for i = 1:45
% Calculate the x-coordinate for each step
i
%clf(f1);
axis([-02*dx_robo 11*dx_robo -02*dy_robo 6*dy_robo]);
del_theta = -speed/wheel_base*-tan(0);
theta=theta+(del_theta*0.1);
rad2deg(theta)
x_car=x_car+(-speed)*cos(theta)*0.1;
y_car=y_car+(-speed)*sin(theta)*0.1;
x1 = x_car; % x-coordinate of top-left corner
y1 = y_car + dy_robo/2; % y-coordinate of top-left corner
x2 = x_car; % x-coordinate of bottom-right corner
y2 = y_car - dy_robo/2; % y-coordinate of bottom-right corner
x3 = x_car+dx_robo; % x-coordinate of bottom-right corner
y3 = y_car + dy_robo/2; % y-coordinate of bottom-right corner
x4 = x_car+dx_robo; % x-coordinate of bottom-right corner
y4 = y_car - dy_robo/2; % y-coordinate of bottom-right corner
% Initialize rectangle plot
pgon_car = polyshape([x1 x2 x4 x3],[y1 y2 y4 y3]);
pgon_r_left = polyshape([r_left_x1 r_left_x2 r_left_x4 r_left_x3],[r_left_y1 r_left_y2 r_left_y4 r_left_y3]);
pgon_c_line = polyshape([center_line_x1 center_line_x2 center_line_x4 center_line_x3],[center_line_y1 center_line_y2 center_line_y4 center_line_y3]);
pgon_r_right = polyshape([r_right_x1 r_right_x2 r_right_x4 r_right_x3],[r_right_y1 r_right_y2 r_right_y4 r_right_y3]);
%plot(pgon_car);
%hold on;
actual_car = rotate(pgon_car,rad2deg(theta),[x_car y_car]);
%actual_car.Vertices
plot(actual_car);
hold on;
plot(pgon_r_left);
hold on;
plot(pgon_c_line);
hold on;
plot(pgon_r_right);
hold on;
plot(x_car, y_car, '.', 'LineWidth', 1);
pause(sample_time);
end
speed=166;