Beispiel #1
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    def __init__(self, node_name):
        # Initialize the DTROS parent class
        super(StopLineFilterNode, self).__init__(node_name=node_name, node_type=NodeType.PERCEPTION)

        # Initialize the parameters
        self.stop_distance = DTParam("~stop_distance", param_type=ParamType.FLOAT)
        self.min_segs = DTParam("~min_segs", param_type=ParamType.INT)
        self.off_time = DTParam("~off_time", param_type=ParamType.FLOAT)
        self.max_y = DTParam("~max_y", param_type=ParamType.FLOAT)

        ## params
        # self.stop_distance = self.setupParam("~stop_distance", 0.22) # distance from the stop line that we should stop
        # self.min_segs      = self.setupParam("~min_segs", 2) # minimum number of red segments that we should detect to estimate a stop
        # self.off_time      = self.setupParam("~off_time", 2)
        # self.max_y         = self.setupParam("~max_y ", 0.2) # If y value of detected red line is smaller than max_y we will not set at_stop_line true.

        ## state vars
        self.lane_pose = LanePose()

        self.state = "JOYSTICK_CONTROL"
        self.sleep = False

        ## publishers and subscribers
        self.sub_segs = rospy.Subscriber("~segment_list", SegmentList, self.cb_segments)
        self.sub_lane = rospy.Subscriber("~lane_pose", LanePose, self.cb_lane_pose)
        self.sub_mode = rospy.Subscriber("fsm_node/mode", FSMState, self.cb_state_change)
        self.pub_stop_line_reading = rospy.Publisher("~stop_line_reading", StopLineReading, queue_size=1)
        self.pub_at_stop_line = rospy.Publisher("~at_stop_line", BoolStamped, queue_size=1)
Beispiel #2
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    def __init__(self, node_name):

        # Initialize the DTROS parent class
        super(VehicleFilterNode, self).__init__(node_name=node_name,
                                                node_type=NodeType.PERCEPTION)

        # Add the node parameters to the parameters dictionary and load their default values
        self.distance_between_centers = DTParam('~distance_between_centers',
                                                param_type=ParamType.FLOAT)

        self.max_reproj_pixelerror_pose_estimation = DTParam(
            '~max_reproj_pixelerror_pose_estimation',
            param_type=ParamType.FLOAT)

        self.virtual_stop_line_offset = DTParam('~virtual_stop_line_offset',
                                                param_type=ParamType.FLOAT)

        self.bridge = CvBridge()

        # these will be defined on the first call to calc_circle_pattern
        self.last_calc_circle_pattern = None
        self.circlepattern_dist = None
        self.circlepattern = None
        self.state = None
        # subscribers
        self.sub_centers = rospy.Subscriber("~centers",
                                            VehicleCorners,
                                            self.cb_process_centers,
                                            queue_size=1)
        self.sub_info = rospy.Subscriber("~camera_info",
                                         CameraInfo,
                                         self.cb_process_camera_info,
                                         queue_size=1)
        """ TODO: REMOVE AFTER ROAD_ANOMALY NODE CONSTRUCTION"""
        self.sub_state = rospy.Subscriber("~mode", FSMState, self.cbFSMState)
        # publishers
        self.pub_virtual_stop_line = rospy.Publisher("~virtual_stop_line",
                                                     StopLineReading,
                                                     queue_size=1)
        self.pub_visualize = rospy.Publisher("~debug/visualization_marker",
                                             Marker,
                                             queue_size=1)
        self.pub_stopped_flag = rospy.Publisher("~stopped",
                                                BoolStamped,
                                                queue_size=1)
        self.pcm = PinholeCameraModel()
        self.changePattern = rospy.ServiceProxy("~set_pattern", ChangePattern)
        self.log("Initialization completed")
        self.last_led_state = None
Beispiel #3
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    def __init__(self, node_name):
        super().__init__(node_name, node_type=NodeType.PERCEPTION)

        # parameters
        self.publish_freq = DTParam("~publish_freq", -1)

        # utility objects
        self.bridge = CvBridge()
        self.reminder = DTReminder(frequency=self.publish_freq.value)

        # subscribers
        self.sub_img = rospy.Subscriber("~image_in",
                                        CompressedImage,
                                        self.cb_image,
                                        queue_size=1,
                                        buff_size="10MB")

        # publishers
        self.pub_img = rospy.Publisher(
            "~image_out",
            Image,
            queue_size=1,
            dt_topic_type=TopicType.PERCEPTION,
            dt_healthy_freq=self.publish_freq.value,
            dt_help="Raw image",
        )
Beispiel #4
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 def _init_dtparam(name):
     str_topics = []
     param_type = ParamType.STRING if name in str_topics else ParamType.FLOAT
     return DTParam(f'~{name}',
                    param_type=param_type,
                    min_value=-100.0,
                    max_value=100.0)
Beispiel #5
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    def __init__(self, node_name):
        super().__init__(node_name, node_type=NodeType.PERCEPTION)

        # parameters
        self.publish_freq = DTParam("~publish_freq", -1)
        self.alpha = DTParam("~alpha", 0.0)

        # utility objects
        self.jpeg = TurboJPEG()
        self.reminder = DTReminder(frequency=self.publish_freq.value)
        self.camera_model = None
        self.rect_camera_info = None
        self.mapx, self.mapy = None, None

        # subscribers
        self.sub_img = rospy.Subscriber(
            "~image_in",
            CompressedImage,
            self.cb_image,
            queue_size=1,
            buff_size='10MB'
        )
        self.sub_camera_info = rospy.Subscriber(
            "~camera_info_in",
            CameraInfo,
            self.cb_camera_info,
            queue_size=1
        )

        # publishers
        self.pub_img = rospy.Publisher(
            "~image/compressed",
            CompressedImage,
            queue_size=1,
            dt_topic_type=TopicType.PERCEPTION,
            dt_healthy_freq=self.publish_freq.value,
            dt_help="Rectified image (i.e., image with no distortion effects from the lens)."
        )
        self.pub_camera_info = rospy.Publisher(
            "~camera_info",
            CameraInfo,
            queue_size=1,
            dt_topic_type=TopicType.PERCEPTION,
            dt_healthy_freq=self.publish_freq.value,
            dt_help="Camera parameters for the (virtual) rectified camera."
        )
Beispiel #6
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    def __init__(self, node_name):

        # Initialize the DTROS parent class
        super(VehicleDetectionNode,
              self).__init__(node_name=node_name,
                             node_type=NodeType.PERCEPTION)

        # Initialize the parameters
        self.process_frequency = DTParam("~process_frequency",
                                         param_type=ParamType.FLOAT)
        self.circlepattern_dims = DTParam("~circlepattern_dims",
                                          param_type=ParamType.LIST)
        self.blobdetector_min_area = DTParam("~blobdetector_min_area",
                                             param_type=ParamType.FLOAT)
        self.blobdetector_min_dist_between_blobs = DTParam(
            "~blobdetector_min_dist_between_blobs", param_type=ParamType.FLOAT)

        # !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
        #
        self.cbParametersChanged(
        )  # TODO: THIS SHOULD BE FIXED IN THE NEW DTROS!!!!!!!!!!
        #
        # !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!

        self.bridge = CvBridge()

        self.last_stamp = rospy.Time.now()

        # Subscriber
        self.sub_image = rospy.Subscriber("~image",
                                          CompressedImage,
                                          self.cb_image,
                                          queue_size=1)

        # Publishers
        self.pub_centers = rospy.Publisher("~centers",
                                           VehicleCorners,
                                           queue_size=1)
        self.pub_circlepattern_image = rospy.Publisher(
            "~debug/detection_image/compressed", CompressedImage, queue_size=1)
        self.pub_detection_flag = rospy.Publisher("~detection",
                                                  BoolStamped,
                                                  queue_size=1)
        self.log("Initialization completed.")
Beispiel #7
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    def __init__(self, node_name):
        # initialize the DTROS parent class
        super(ColorDetectorNode, self).__init__(node_name=node_name,
                                                node_type=NodeType.PERCEPTION)
        # bridge between opencv and ros
        self.bridge = CvBridge()
        # construct subscriber for images
        self.sub = rospy.Subscriber('~duckie_cam/compressed', CompressedImage,
                                    self.callback)
        # construct publisher for debug images
        self.pub = rospy.Publisher('~debug_images/compressed',
                                   CompressedImage,
                                   queue_size=10)

        self.color = DTParam(
            '~color',
            param_type=ParamType.STRING,
        )
        self.downscale = DTParam('~downscale',
                                 param_type=ParamType.FLOAT,
                                 min_value=0.5,
                                 max_value=1.0)
Beispiel #8
0
 def __init__(self):
     super(AprilTagDetector,
           self).__init__(node_name='apriltag_detector_node',
                          node_type=NodeType.PERCEPTION)
     # get static parameters
     self.family = rospy.get_param('~family', 'tag36h11')
     self.nthreads = rospy.get_param('~nthreads', 1)
     self.quad_decimate = rospy.get_param('~quad_decimate', 1.0)
     self.quad_sigma = rospy.get_param('~quad_sigma', 0.0)
     self.refine_edges = rospy.get_param('~refine_edges', 1)
     self.decode_sharpening = rospy.get_param('~decode_sharpening', 0.25)
     self.tag_size = rospy.get_param('~tag_size', 0.065)
     # dynamic parameter
     self.detection_freq = DTParam('~detection_freq',
                                   default=-1,
                                   param_type=ParamType.INT,
                                   min_value=-1,
                                   max_value=30)
     self._detection_reminder = DTReminder(
         frequency=self.detection_freq.value)
     # camera info
     self._camera_parameters = None
     self._camera_frame = None
     # create detector object
     self._at_detector = Detector(families=self.family,
                                  nthreads=self.nthreads,
                                  quad_decimate=self.quad_decimate,
                                  quad_sigma=self.quad_sigma,
                                  refine_edges=self.refine_edges,
                                  decode_sharpening=self.decode_sharpening)
     # create a CV bridge object
     self._bridge = CvBridge()
     # create subscribers
     self._img_sub = rospy.Subscriber('image_rect', Image, self._img_cb)
     self._cinfo_sub = rospy.Subscriber('camera_info', CameraInfo,
                                        self._cinfo_cb)
     # create publishers
     self._img_pub = rospy.Publisher('tag_detections_image/compressed',
                                     CompressedImage,
                                     queue_size=1,
                                     dt_topic_type=TopicType.VISUALIZATION)
     self._tag_pub = rospy.Publisher('tag_detections',
                                     AprilTagDetectionArray,
                                     queue_size=1,
                                     dt_topic_type=TopicType.PERCEPTION)
     self._img_pub_busy = False
     # create TF broadcaster
     self._tf_bcaster = tf.TransformBroadcaster()
     # spin forever
     rospy.spin()
    def __init__(self, node_name):

        # Initialize the DTROS parent class
        super(LaneControllerNode, self).__init__(node_name=node_name,
                                                 node_type=NodeType.CONTROL)

        # Add the node parameters to the parameters dictionary
        # TODO: MAKE TO WORK WITH NEW DTROS PARAMETERS
        self.params = dict()
        self.params['~v_bar'] = DTParam('~v_bar',
                                        param_type=ParamType.FLOAT,
                                        min_value=0.0,
                                        max_value=5.0)

        # Construct publishers
        self.pub_car_cmd = rospy.Publisher("~car_cmd",
                                           Twist2DStamped,
                                           queue_size=1,
                                           dt_topic_type=TopicType.CONTROL)

        # we will just call the controller at 10Hz to publish constant velocity
        rospy.Timer(rospy.Duration(0.1), self.getControlAction)
        self.log("Initialized!")
    def __init__(self, node_name):

        # Initialize the DTROS parent class
        super(KinematicsNode, self).__init__(node_name=node_name, node_type=NodeType.CONTROL)

        # Get the vehicle name
        self.veh_name = rospy.get_namespace().strip("/")

        # Read parameters from a robot-specific yaml file if such exists
        self.read_params_from_calibration_file()

        # Get static parameters
        self._k = rospy.get_param("~k")
        # Get editable parameters
        self._gain = DTParam("~gain", param_type=ParamType.FLOAT, min_value=0.1, max_value=1.0)
        self._trim = DTParam("~trim", param_type=ParamType.FLOAT, min_value=0.1, max_value=1.0)
        self._limit = DTParam("~limit", param_type=ParamType.FLOAT, min_value=0.1, max_value=1.0)
        self._baseline = DTParam("~baseline", param_type=ParamType.FLOAT, min_value=0.05, max_value=0.2)
        self._radius = DTParam("~radius", param_type=ParamType.FLOAT, min_value=0.01, max_value=0.1)
        self._v_max = DTParam("~v_max", param_type=ParamType.FLOAT, min_value=0.01, max_value=2.0)
        self._omega_max = DTParam("~omega_max", param_type=ParamType.FLOAT, min_value=1.0, max_value=10.0)

        # Prepare the save calibration service
        self.srv_save = rospy.Service("~save_calibration", Empty, self.srv_save_calibration)

        # Setup publishers
        self.pub_wheels_cmd = rospy.Publisher(
            "~wheels_cmd", WheelsCmdStamped, queue_size=1, dt_topic_type=TopicType.CONTROL
        )
        self.pub_velocity = rospy.Publisher(
            "~velocity", Twist2DStamped, queue_size=1, dt_topic_type=TopicType.CONTROL
        )

        # Setup subscribers
        self.sub_car_cmd = rospy.Subscriber("~car_cmd", Twist2DStamped, self.car_cmd_callback)
        # ---
        self.log("Initialized with: \n%s" % self.get_configuration_as_str())
    def __init__(self, node_name):

        # Initialize the DTROS parent class
        super(LaneControllerNode, self).__init__(node_name=node_name,
                                                 node_type=NodeType.PERCEPTION)

        # Add the node parameters to the parameters dictionary
        # TODO: MAKE TO WORK WITH NEW DTROS PARAMETERS
        self.params = dict()
        self.params['~v_bar'] = DTParam('~v_bar',
                                        param_type=ParamType.FLOAT,
                                        min_value=0.0,
                                        max_value=5.0)
        self.params['~k_d'] = DTParam('~k_d',
                                      param_type=ParamType.FLOAT,
                                      min_value=-100.0,
                                      max_value=100.0)
        self.params['~k_theta'] = DTParam('~k_theta',
                                          param_type=ParamType.FLOAT,
                                          min_value=-100.0,
                                          max_value=100.0)
        self.params['~k_Id'] = DTParam('~k_Id',
                                       param_type=ParamType.FLOAT,
                                       min_value=-100.0,
                                       max_value=100.0)
        self.params['~k_Iphi'] = DTParam('~k_Iphi',
                                         param_type=ParamType.FLOAT,
                                         min_value=-100.0,
                                         max_value=100.0)
        self.params['~theta_thres'] = rospy.get_param('~theta_thres', None)
        self.params['~d_thres'] = rospy.get_param('~d_thres', None)
        self.params['~d_offset'] = rospy.get_param('~d_offset', None)
        self.params['~integral_bounds'] = rospy.get_param(
            '~integral_bounds', None)
        self.params['~d_resolution'] = rospy.get_param('~d_resolution', None)
        self.params['~phi_resolution'] = rospy.get_param(
            '~phi_resolution', None)
        self.params['~omega_ff'] = rospy.get_param('~omega_ff', None)
        self.params['~verbose'] = rospy.get_param('~verbose', None)
        self.params['~stop_line_slowdown'] = rospy.get_param(
            '~stop_line_slowdown', None)

        # Need to create controller object before updating parameters, otherwise it will fail
        self.controller = LaneController(self.params)
        # self.updateParameters() # TODO: This needs be replaced by the new DTROS callback when it is implemented

        # Initialize variables
        self.fsm_state = None
        self.wheels_cmd_executed = WheelsCmdStamped()
        self.pose_msg = LanePose()
        self.pose_initialized = False
        self.pose_msg_dict = dict()
        self.last_s = None
        self.stop_line_distance = None
        self.stop_line_detected = False
        self.at_stop_line = False
        self.obstacle_stop_line_distance = None
        self.obstacle_stop_line_detected = False
        self.at_obstacle_stop_line = False

        self.current_pose_source = 'lane_filter'

        # Construct publishers
        self.pub_car_cmd = rospy.Publisher("~car_cmd",
                                           Twist2DStamped,
                                           queue_size=1,
                                           dt_topic_type=TopicType.CONTROL)

        # Construct subscribers
        self.sub_lane_reading = rospy.Subscriber("~lane_pose",
                                                 LanePose,
                                                 self.cbAllPoses,
                                                 "lane_filter",
                                                 queue_size=1)
        self.sub_intersection_navigation_pose = rospy.Subscriber(
            "~intersection_navigation_pose",
            LanePose,
            self.cbAllPoses,
            "intersection_navigation",
            queue_size=1)
        self.sub_wheels_cmd_executed = rospy.Subscriber(
            "~wheels_cmd",
            WheelsCmdStamped,
            self.cbWheelsCmdExecuted,
            queue_size=1)
        self.sub_stop_line = rospy.Subscriber("~stop_line_reading",
                                              StopLineReading,
                                              self.cbStopLineReading,
                                              queue_size=1)
        self.sub_obstacle_stop_line = rospy.Subscriber(
            "~obstacle_distance_reading",
            StopLineReading,
            self.cbObstacleStopLineReading,
            queue_size=1)

        self.log("Initialized!")
Beispiel #12
0
    def __init__(self, node_name):

        # Initialize the DTROS parent class
        super(LaneControllerNode, self).__init__(node_name=node_name,
                                                 node_type=NodeType.CONTROL)

        ## Add the node parameters to the parameters dictionary (1) and
        ## initialize controller (2)
        # 1. get parameters
        self.params = dict()
        self.params["~v_forward"] = DTParam("~v_forward",
                                            default=0.5,
                                            help="forward speed",
                                            param_type=ParamType.FLOAT,
                                            min_value=0.0,
                                            max_value=5.0)
        self.params["~k_theta"] = DTParam("~k_theta",
                                          default=5.0,
                                          help="k_theta's value",
                                          param_type=ParamType.FLOAT,
                                          min_value=-100.0,
                                          max_value=100.0)
        self.params["~k_d"] = DTParam("~k_d",
                                      help="k_d's value",
                                      param_type=ParamType.FLOAT,
                                      min_value=-100.0,
                                      max_value=100.0)
        self.params["~k_dd"] = DTParam("~k_dd",
                                       default=5.0,
                                       help="k_dd's value",
                                       param_type=ParamType.FLOAT,
                                       min_value=-100.0,
                                       max_value=100.0)
        self.params["~k_dtheta"] = DTParam("~k_dtheta",
                                           default=5.0,
                                           help="k_dtheta's value",
                                           param_type=ParamType.FLOAT,
                                           min_value=-100.0,
                                           max_value=100.0)
        self.params["~k_Id"] = DTParam("~k_Id",
                                       default=0.0,
                                       help="k_Id's value",
                                       param_type=ParamType.FLOAT,
                                       min_value=-100.0,
                                       max_value=100.0)
        self.params["~k_Itheta"] = DTParam("~k_Itheta",
                                           default=0.0,
                                           help="k_Id's value",
                                           param_type=ParamType.FLOAT,
                                           min_value=-100.0,
                                           max_value=100.0)
        self.params["~theta_threshold"] = rospy.get_param(
            "~theta_threshold", np.pi / 6)
        self.params["~d_threshold"] = rospy.get_param("~d_threshold", 0.3)
        self.params["~look_ahead_k"] = rospy.get_param("~look_ahead_k", 3.0)
        self.params["~k_d_critically_damped_flag"] = rospy.get_param(
            "~k_d_critically_damped_flag", False)
        self.params["~d_resolution"] = rospy.get_param("~d_resolution", 0.005)
        self.params["~theta_resolution"] = rospy.get_param(
            "~theta_resolution", 0.1)
        self.params["~d_threshold_robust_flag"] = rospy.get_param(
            "~d_threshold_robust_flag", False)

        self.params["~slow_down_multiplier"] = rospy.get_param(
            "~slow_down_multiplier", 0.5)
        self.params["~slow_down_theta_thres"] = rospy.get_param(
            "~slow_down_theta_thres", 0.5)
        self.params["~slow_down_d_thres"] = rospy.get_param(
            "~slow_down_d_thres", 0.5)

        # 2. initialize controller
        self.controller_type = rospy.get_param("~controller_type", None)

        if self.controller_type == "turn_pid":
            self.params["~turning_config"] = rospy.get_param("~turning_config")

        assert self.controller_type in \
               LaneControllerNode.CONTROLLER_LOOKUP.keys()
        self.controller = LaneControllerNode.CONTROLLER_LOOKUP\
                            [self.controller_type](self.params)

        # initialize useful parameters
        self.last_time = None
        self.fsm_state = None
        self.wheels_cmd_executed = WheelsCmdStamped()
        self.at_stop_line = False
        self.at_obstacle_stop_line = False

        # Construct publishers
        self.pub_car_cmd = rospy.Publisher("~car_cmd",
                                           Twist2DStamped,
                                           queue_size=1,
                                           dt_topic_type=TopicType.CONTROL)

        # Construct subscribers
        self.sub_lane_reading = rospy.Subscriber("~lane_pose",
                                                 LanePose,
                                                 self.cbLanePoses,
                                                 queue_size=1)
        self.sub_lane_reading = rospy.Subscriber("~lane_filter",
                                                 LanePose,
                                                 self.cbLaneFilters,
                                                 queue_size=1)
        self.sub_intersection_navigation_pose = rospy.Subscriber(
            "~intersection_navigation_pose",
            LanePose,
            self.cbIntersectionPoses,
            queue_size=1)
        self.sub_wheels_cmd_execute = rospy.Subscriber("~wheels_cmd_executed",
                                                       WheelsCmdStamped,
                                                       self.cbWheelsCmdExecute,
                                                       queue_size=1)
        self.sub_fsm_node = rospy.Subscriber("~fsm_mode",
                                             FSMState,
                                             self.cbMode,
                                             queue_size=1)
        self.sub_stop_line = rospy.Subscriber("~stop_line_reading",
                                              StopLineReading,
                                              self.cbStopLineReading,
                                              queue_size=1)
        self.sub_obstacle_stop_line = rospy.Subscriber(
            "~obstacle_distance_reading",
            StopLineReading,
            self.cbObstacleStopLineReading,
            queue_size=1)

        self.log("Initialized!")
        self.log("Lane controller type = {}.".format(self.controller_type))
        self.log("Slow down multiplier = {}".format(
            self.params["~slow_down_multiplier"]))
        self.log("Slow down theta tres = {}".format(
            self.params["~slow_down_theta_thres"]))
        self.log("Slow down d thres = {}".format(
            self.params["~slow_down_d_thres"]))
 def __init__(self):
     super(AprilTagDetector, self).__init__(
         node_name='apriltag_detector_node',
         node_type=NodeType.PERCEPTION
     )
     # get static parameters
     self.family = rospy.get_param('~family', 'tag36h11')
     self.ndetectors = rospy.get_param('~ndetectors', 1)
     self.nthreads = rospy.get_param('~nthreads', 1)
     self.quad_decimate = rospy.get_param('~quad_decimate', 1.0)
     self.quad_sigma = rospy.get_param('~quad_sigma', 0.0)
     self.refine_edges = rospy.get_param('~refine_edges', 1)
     self.decode_sharpening = rospy.get_param('~decode_sharpening', 0.25)
     self.tag_size = rospy.get_param('~tag_size', 0.065)
     self.rectify_alpha = rospy.get_param('~rectify_alpha', 0.0)
     # dynamic parameter
     self.detection_freq = DTParam(
         '~detection_freq',
         default=-1,
         param_type=ParamType.INT,
         min_value=-1,
         max_value=30
     )
     self._detection_reminder = DTReminder(frequency=self.detection_freq.value)
     # camera info
     self._camera_parameters = None
     self._mapx, self._mapy = None, None
     # create detector object
     self._detectors = [Detector(
         families=self.family,
         nthreads=self.nthreads,
         quad_decimate=self.quad_decimate,
         quad_sigma=self.quad_sigma,
         refine_edges=self.refine_edges,
         decode_sharpening=self.decode_sharpening
     ) for _ in range(self.ndetectors)]
     self._renderer_busy = False
     # create a CV bridge object
     self._jpeg = TurboJPEG()
     # create subscribers
     self._img_sub = rospy.Subscriber(
         '~image',
         CompressedImage,
         self._img_cb,
         queue_size=1,
         buff_size='20MB'
     )
     self._cinfo_sub = rospy.Subscriber(
         '~camera_info',
         CameraInfo,
         self._cinfo_cb,
         queue_size=1
     )
     # create publisher
     self._tag_pub = rospy.Publisher(
         '~detections',
         AprilTagDetectionArray,
         queue_size=1,
         dt_topic_type=TopicType.PERCEPTION,
         dt_help='Tag detections',
     )
     self._img_pub = rospy.Publisher(
         '~detections/image/compressed',
         CompressedImage,
         queue_size=1,
         dt_topic_type=TopicType.VISUALIZATION,
         dt_help='Camera image with tag publishs superimposed',
     )
     # create thread pool
     self._workers = ThreadPoolExecutor(self.ndetectors)
     self._tasks = [None] * self.ndetectors
     # create TF broadcaster
     self._tf_bcaster = tf.TransformBroadcaster()