예제 #1
0
def remove_outliers(utm_data, max_speed=15., plot_data=False):

    utm_data_temp = utm_data[:, 3:6].astype(np.float)
    utm_c2 = np.vstack((utm_data_temp[0, :], utm_data_temp))
    diff = utm_data_temp - utm_c2[:-1]

    speed = np.hypot(diff[:, 0], diff[:, 1]) / diff[:, 2]
    utm_data = utm_data[speed < max_speed]

    # import pdb; pdb.set_trace()
    if plot_data:
        utm = utm_data_temp[speed < max_speed]
        # fig = plt.figure()
        # plt.hold(True)
        # plt.xlabel("UTM N", fontsize=20)
        # plt.ylabel("UTM E", fontsize=20)
        # plt.title("Result after removing outliers", fontsize=23)
        #
        # plt.plot(utm_data_temp[:,0], utm_data_temp[:,1], color="blue",
        #          linewidth=1.5, linestyle=":", label='Original data')
        # plt.plot(utm[:,0], utm[:,1], color="red", linewidth=1.5,
        #          label='Outlier filtered data')
        # plt.legend(loc=0)
        #plt.show()
        plotter.path_plot(utm_data_temp[:, 0:2], utm[:, 0:2])
        #fig.savefig("resources/result_removing_outliers.png")
        #plt.close()
    return utm_data[:, 0:5]
예제 #2
0
def main(plots=False):
    gps_data = parse_data()
    times = gps_data[:, 0].reshape((-1, 1))
    geo_coordinates = gps_data[:, 1:3]
    utm_values = utm_geo_convert.geodetic_to_utm(geo_coordinates)
    utm_coordinates = utm_values[:, 3:].astype(np.float)
    sp = simplify_polygons()
    vertices = sp.skimage_rdp(utm_coordinates)
    mask, marker = sp.simplify_lang(10, utm_coordinates,
                                                       step=100)
    simplified = utm_coordinates[mask]

    utm_data = np.hstack((utm_values, times))
    # ex 4.3
    ro = remove_outliers()
    filtered_utm_data = ro.remove_outliers(utm_data,15, plot_data=False)
    # ex. 4.4 - simplify path
    filtered_utm_coordinates = filtered_utm_data[:,3:5].astype(np.float)
    vertices = sp.skimage_rdp(filtered_utm_coordinates)
    wyatt = sp.wyatt(utm_values, 10)
    min_dist_path = sp.minimize_distance_and_angle(filtered_utm_coordinates,
                                                   0.2)
    min_dist_path_angle = sp.minimize_distance_and_angle(
        filtered_utm_coordinates, 0.2, True, 45)

    if(plots):
        plotter.path_plot(filtered_utm_coordinates, vertices, wyatt,
                          min_dist_path, min_dist_path_angle)

    # ex. 4.5 - convert back to geo
    filtered_geo_coordinates = utm_geo_convert.utm_to_geodetic(utm_data)


    # ex 4.7 - fixed wing path cubic hermite spline
    if(plots):
        chs = cubic_hermite_spline();
        splines = chs.get_path(vertices)
        plotter.path_plot(vertices, splines)

    # convert vertices to geodetic_coordinates
    left_side = np.zeros((vertices.shape[0],3)).astype(str)
    left_side[:, 0] = "N"
    left_side[:, 1] = 32
    left_side[:, 2] = "U"
    result = np.hstack((left_side, vertices))
    coordinates_for_planner = utm_geo_convert.utm_to_geodetic(result)
    # import pdb; pdb.set_trace()
    # write to file
    new_left_side = np.zeros((vertices.shape[0],1)).astype(str)
    new_result = np.hstack((new_left_side, coordinates_for_planner))
    new_left_side = np.zeros((vertices.shape[0],1)).astype(str)
    new_left_side[:, 0] = "15"
    new_result = np.hstack((new_result, new_left_side))
    np.savetxt("resources/new_log_wps.log", new_result, "%s", ",")

    return utm_coordinates
예제 #3
0
파일: main.py 프로젝트: donbreum/UAST
def main(plots=False):
    gps_data = parse_data()
    times = gps_data[:, 0].reshape((-1, 1))
    geo_coordinates = gps_data[:, 1:3]
    utm_values = utm_geo_convert.geodetic_to_utm(geo_coordinates)
    utm_coordinates = utm_values[:, 3:].astype(np.float)
    sp = simplify_polygons()
    vertices = sp.skimage_rdp(utm_coordinates)
    mask, marker = sp.simplify_lang(10, utm_coordinates,
                                                       step=100)
    simplified = utm_coordinates[mask]

    utm_data = np.hstack((utm_values, times))
    # ex 4.3
    ro = remove_outliers()
    filtered_utm_data = ro.remove_outliers(utm_data,15, plot_data=False)
    # ex. 4.4 - simplify path
    filtered_utm_coordinates = filtered_utm_data[:,3:5].astype(np.float)
    vertices = sp.skimage_rdp(filtered_utm_coordinates)
    wyatt = sp.wyatt(utm_values, 10)
    min_dist_path = sp.minimize_distance_and_angle(filtered_utm_coordinates,
                                                   0.2)
    min_dist_path_angle = sp.minimize_distance_and_angle(
        filtered_utm_coordinates, 0.2, True, 45)

    if(plots):
        plotter.path_plot(filtered_utm_coordinates, vertices, wyatt,
                          min_dist_path, min_dist_path_angle)
    # import pdb; pdb.set_trace()
    # ex. 4.5 - convert back to geo
    filtered_geo_coordinates = utm_geo_convert.utm_to_geodetic(utm_data)

    # ex 4.7 - fixed wing path cubic hermite spline
    if(plots):
        chs = cubic_hermite_spline();
        splines = chs.get_path(vertices)
        plotter.path_plot(vertices, splines)

    return utm_coordinates
예제 #4
0
def main():
    logger.info("BEGINNING EXECUTION")

    # SIGINT handling:
    # -Create a global flag to check if the execution should keep running.
    # -Whenever SIGINT is received, set the global flag to False.
    global run_program
    run_program = True

    def sigint_handler(signal, frame):
        global run_program
        logger.info("Shutting down")
        run_program = False
        return
    signal.signal(signal.SIGINT, sigint_handler)

    # This exception forces to give the robot_id argument within run command.
    rectangle_path = False
    help_msg = ('Usage: controller.py [-r <robot_id>], [--robotid=<robot_id>], '
                '[--rectangle]')
    try:
        opts, args = getopt.getopt(sys.argv[1:], "hr:",
                                   ["robotid=", "rectangle"])
    except getopt.GetoptError:
        print help_msg
        sys.exit()
    if not opts:
        print help_msg
        sys.exit()
    for opt, arg in opts:
        if opt == '-h':
            print help_msg
            sys.exit()
        if opt in ("-r", "--robotid"):
            robot_id = int(arg)
        if opt == "--rectangle":
            rectangle_path = True
    # Calls the main function
    my_robot = RobotController(robot_id)

    # Open listening sockets
    sockets = init_sockets(robot_id)

    # Until the first pose is not published, the robot instance is not
    # initialized. Keep trying to receive the initial position with a
    # no blocking recv until the instance is initialized or the run flag
    # has been set to False.
    logger.info("Waiting for first position")
    while run_program and not my_robot.init:
        try:
            position = sockets['position'].recv_json(zmq.NOBLOCK)
        except zmq.ZMQError:
            pass
        else:
            logger.debug("Received first position: {}".format(position))
            my_robot.set_speed(position)

    # This function sends 4 rectangle points to the robot path.
    if rectangle_path:
        make_a_rectangle(my_robot)

    # Listen sockets
    listen_sockets(sockets, my_robot)
    # Once the run flag has been set to False, shutdown
    my_robot.on_shutdown()

    if my_robot.QCTracker.path is not None:
        # Print the log output to files and plot it
        script_path = os.path.dirname(os.path.realpath(__file__))
        # A file identifier is generated from the current time value
        file_id = time.strftime('%Y%m%d_%H%M')
        with open('{}/tmp/path_{}.log'.format(script_path, file_id), 'a') as f:
            np.savetxt(f, my_robot.QCTracker.route, fmt='%.2f')
        # Plots the robot ideal path.
        plotter.path_plot(my_robot.QCTracker.path, my_robot.QCTracker.route)

    return