示例#1
0
    def auto_update_lidar_cloud(self, only_nearby_meters=4, fps=2, cb=None):
        ts = None
        while True:
            ts = keep_rps(ts, fps=fps)
            points = self._get_lidar_points()
            if len(points) == 0:
                break

            if cb is not None:
                cb(points, only_nearby_meters=only_nearby_meters)
示例#2
0
    def _capture_frames(self):
        self.cap = cv2.VideoCapture(self._get_csi_gsreamer_str(),
                                    cv2.CAP_GSTREAMER)

        ts = None
        while True:
            ts = keep_rps(ts, fps=self.fps)

            ret, frame = self.cap.read()
            if not ret:
                break
            self.value = frame
示例#3
0
    def start(self):
        previous = None
        ts = None
        while True:
            ts = keep_rps(ts, fps=self.fps)

            current = self._get_current()

            if previous is None:
                self.poses.append({
                    'x': current['odometry_dx'],
                    'y': current['odometry_dy'],
                    'teta': current['teta'],
                })
            else:
                dt = current['ts'] - previous['ts']
                if dt == 0.:
                    continue
                try:
                    current['odometry_dx'], current[
                        'odometry_dy'] = self.odometry.get_dx_dy(
                            dt, current['teta'])
                except Exception as e:
                    self.errors.append('odometry: {}'.format(e))
                    raise

                try:
                    dx, dy, teta = self._get_transformation(
                        dt, current, previous)
                except Exception as e:
                    print('_get_transformation failed with {}'.format(e),
                          file=sys.stderr)
                    raise

                prev_pose = self.poses[-1]
                self.poses.append({
                    'ts': current['ts'],
                    'x': prev_pose['x'] + dx,
                    'y': prev_pose['y'] + dy,
                    'teta': teta,
                })
                self._upgrade_current(current)

            previous = current
示例#4
0
文件: explorer.py 项目: s1l2/ballsbot
    def run(self, save_track_info=False):
        def tracker_run():
            self.tracker.start()

        def detector_run():
            self.detector.start()

        if not self.test_run:
            run_as_thread(tracker_run)
            run_as_thread(detector_run)
            if self.distance_sensors is not None:
                self.distance_sensors.start()

        ts = None
        direction = {'steering': 0., 'throttle': self.STOP}
        steps_with_direction = 0
        keep_for = 0
        while True:
            ts = keep_rps(ts, fps=4)
            prev_direction = direction
            if keep_for <= 0:
                direction, keep_for = self._get_next_move(direction, steps_with_direction)
            keep_for -= 1
            # print('direction: {}, turn: {}, speed {:0.4f}'.format(
            #     direction['throttle'], direction['steering'], self.odometry.get_speed()
            # ))
            self._follow_direction(direction)

            if save_track_info:
                self.track_info.append({
                    'speed': self.cached_speed,
                    'pose': self.cached_pose,
                    'points': self.cached_points,
                    'direction': self.cached_direction,
                    'weights': self.cached_weights,
                })

            if prev_direction == direction:
                steps_with_direction += 1
            else:
                steps_with_direction = 0
示例#5
0
    def update_odometry_cycle(self):
        import RPi.GPIO as GPIO
        GPIO.setmode(GPIO.BCM)  # BCM pin-numbering scheme from Raspberry Pi

        GPIO.setup(ODOMETRY_PRIMARY_PIN, GPIO.IN)
        GPIO.setup(ODOMETRY_SECONDARY_PIN, GPIO.IN)

        detections = self.event_timestamps

        def primary_both(_):
            if GPIO.input(ODOMETRY_PRIMARY_PIN) == GPIO.HIGH:
                detections['primary_rising'] = time()
                detections['any_event'] = detections['primary_rising']
            else:
                ts = time()
                if detections['primary_falling'] is not None:
                    prev_ts = detections['primary_falling']
                    an_interval = ts - prev_ts
                    if 0.05 < an_interval < 2.:
                        self.odometry_last_interval = an_interval
                detections['primary_falling'] = ts
                detections['any_event'] = detections['primary_falling']

        def secondary_both(_):
            if GPIO.input(ODOMETRY_SECONDARY_PIN) == GPIO.HIGH:
                detections['secondary_rising'] = time()
                detections['any_event'] = detections['secondary_rising']
                self.odometry_counter += 1
            else:
                detections['secondary_falling'] = time()
                detections['any_event'] = detections['secondary_falling']

        try:
            GPIO.add_event_detect(ODOMETRY_PRIMARY_PIN,
                                  GPIO.BOTH,
                                  callback=primary_both)
            GPIO.add_event_detect(ODOMETRY_SECONDARY_PIN,
                                  GPIO.BOTH,
                                  callback=secondary_both)

            ts = None
            while True:
                ts = keep_rps(ts, fps=2)
                if detections['any_event'] is None or time(
                ) - detections['any_event'] > 0.5:
                    # reset state if no events (car stopped)
                    self.odometry_last_interval = None
                    self.direction = 0.
                    for k in detections.keys():
                        detections[k] = None
                elif detections['primary_falling'] is not None and detections['secondary_rising'] is not None \
                        and (detections['primary_rising'] is not None or detections['secondary_falling'] is not None):
                    # select events to determine direction
                    select_rising = False
                    if detections['primary_rising'] is not None and detections[
                            'secondary_falling'] is not None:
                        if abs(detections['primary_rising'] - detections['secondary_rising']) < \
                                abs(detections['primary_falling'] - detections['secondary_falling']):
                            select_rising = True
                        else:
                            select_rising = False
                    # determine direction
                    if select_rising and detections[
                            'primary_rising'] is not None:
                        self.direction = 1. if detections[
                            'primary_rising'] < detections[
                                'secondary_rising'] else -1.
                    else:
                        self.direction = 1. if detections[
                            'primary_falling'] < detections[
                                'secondary_falling'] else -1.
        finally:
            GPIO.remove_event_detect(ODOMETRY_PRIMARY_PIN)
            GPIO.remove_event_detect(ODOMETRY_SECONDARY_PIN)
            GPIO.cleanup()