Example #1
0
 def cbNextGoal(self, msg):
     if not msg.data:
         return
     if self.fsm_state != "LANE_FOLLOWING":
         return
     # Pop next goal on path
     try:
         # If we can pop another goal
         print "pop!"
         self.goal = self.path.pop()
         goal_msg = Pose2DStamped()
         goal_msg.header.stamp = rospy.Time.now()
         goal_msg.x = self.goal[0]
         goal_msg.y = self.goal[1]
         goal_msg.theta = self.goal[2]
         self.pub_goal.publish(goal_msg)
         #self.Rate.sleep()
     except:
         # Cannot pop another goal, reach destination
         # Stop the robot and wait for coordination
         goal_msg = Pose2DStamped()
         goal_msg.header.stamp = rospy.Time.now()
         goal_msg.x = 0.0
         goal_msg.y = 0.0
         goal_msg.theta = 0.0
         self.pub_goal.publish(goal_msg)
         debug = False
         if debug:
             self.path = [(0.0, 0.0, 0.0), (1.0, 0.0, 0.0), (1.0, 1.0, 0.0),
                          (0.0, 1.0, 0.0)]
         else:
             reach_msg = BoolStamped()
             reach_msg.header.stamp = rospy.Time.now()
             reach_msg.data = True
             self.pub_reach_dest.publish(reach_msg)
Example #2
0
    def __init__(self):
        # records the calculated pose of the robot
        self.pose = Pose2DStamped()

        # subscribes to wheels_driver_node/wheels_cmd
        rospy.Subscriber("wheels_driver_node/wheels_cmd", WheelsCmdStamped, self.callback)
        self.pub = rospy.Publisher("lab4_results", Pose2DStamped, queue_size=10)
    def velocity_callback(self, msg_velocity):
        if self.last_pose.header.stamp.to_sec() > 0:  # skip first frame
            delta_t = (msg_velocity.header.stamp -
                       self.last_pose.header.stamp).to_sec()
            [theta_delta, x_delta,
             y_delta] = self.integrate(self.last_theta_dot, self.last_v,
                                       delta_t)
            [theta_res, x_res,
             y_res] = self.propagate(self.last_pose.theta, self.last_pose.x,
                                     self.last_pose.y, theta_delta, x_delta,
                                     y_delta)

            self.last_pose.theta = theta_res
            self.last_pose.x = x_res
            self.last_pose.y = y_res

            # Stuff the new pose into a message and publish
            msg_pose = Pose2DStamped()
            msg_pose.header = msg_velocity.header
            msg_pose.header.frame_id = self.veh_name
            msg_pose.theta = theta_res
            msg_pose.x = x_res
            msg_pose.y = y_res
            self.pub_pose.publish(msg_pose)

        self.last_pose.header.stamp = msg_velocity.header.stamp
        self.last_theta_dot = msg_velocity.omega
        self.last_v = msg_velocity.v
Example #4
0
    def __init__(self, node_name):
        # Initialize the DTROS parent class
        super(VelocityToPoseNode,
              self).__init__(node_name=node_name,
                             node_type=NodeType.LOCALIZATION)

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

        # Keep track of the last known pose
        self.last_pose = Pose2DStamped()
        self.last_theta_dot = 0
        self.last_v = 0

        # Setup the publisher
        self.pub_pose = rospy.Publisher("~pose",
                                        Pose2DStamped,
                                        queue_size=1,
                                        dt_topic_type=TopicType.LOCALIZATION)

        # Setup the subscriber
        self.sub_velocity = rospy.Subscriber("~velocity",
                                             Twist2DStamped,
                                             self.velocity_callback,
                                             queue_size=1)
        # ---
        self.log("Initialized.")
Example #5
0
    def __init__(self):
        self.node_name = 'position_filter_node'

        # Read parameters
        self.veh_name = self.setupParameter("~veh_name", "megaman")

        fi_theta_dot_function = self.setupParameter(
            '~fi_theta_dot_function_param', 'Duty_fi_theta_dot_naive')
        fi_v_function = self.setupParameter('~fi_v_function_param',
                                            'Duty_fi_v_naive')
        theta_dot_weights = matrix(
            self.setupParameter('~theta_dot_weights_param', [-1.0]))
        v_weights = matrix(self.setupParameter('~v_weights_param', [1.0]))

        #Setup the forward kinematics model
        self.fk = Forward_kinematics.Forward_kinematics(
            fi_theta_dot_function, fi_v_function, matrix(theta_dot_weights),
            matrix(v_weights))

        #Setup the publisher and subscriber
        self.sub_velocity = rospy.Subscriber("~velocity", Twist2DStamped,
                                             self.velocityCallback)
        self.pub_pose = rospy.Publisher("~pose", Pose2DStamped, queue_size=1)

        #Keep track of the last known pose
        self.last_pose = Pose2DStamped()
        self.last_theta_dot = 0
        self.last_v = 0

        rospy.loginfo("[%s] has started", self.node_name)
Example #6
0
 def cbSwitch(self, msg):
     self.active = msg.data
     goal_msg = Pose2DStamped()
     goal_msg.header.stamp = rospy.Time.now()
     goal_msg.x = self.goal[0]
     goal_msg.y = self.goal[1]
     goal_msg.theta = self.goal[2]
     self.pub_goal.publish(goal_msg)
    def motion_model_callback(self, msg_velocity):
        """

        This function will use robot velocity information to give a new state
        Performs the calclulation from velocity to pose and publishes a messsage with the result.


        Feel free to modify this however you wish. It's left more-or-less as-is
        from the official duckietown repo

        Args:
            msg_velocity (:obj:`Twist2DStamped`): the current velocity message

        """
        if self.last_pose.header.stamp.to_sec() > 0:  # skip first frame

            dt = (msg_velocity.header.stamp -
                  self.last_pose.header.stamp).to_sec()

            # Integrate the relative movement between the last pose and the current
            theta_delta = self.last_theta_dot * dt
            # to ensure no division by zero for radius calculation:
            if np.abs(self.last_theta_dot) < 0.000001:
                # straight line
                x_delta = self.last_v * dt
                y_delta = 0
            else:
                # arc of circle
                radius = self.last_v / self.last_theta_dot
                x_delta = radius * np.sin(theta_delta)
                y_delta = radius * (1.0 - np.cos(theta_delta))

            # Add to the previous to get absolute pose relative to the starting position
            theta_res = self.last_pose.theta + theta_delta
            x_res = self.last_pose.x + x_delta * np.cos(
                self.last_pose.theta) - y_delta * np.sin(self.last_pose.theta)
            y_res = self.last_pose.y + y_delta * np.cos(
                self.last_pose.theta) + x_delta * np.sin(self.last_pose.theta)

            # Update the stored last pose
            self.last_pose.theta = theta_res
            self.last_pose.x = x_res
            self.last_pose.y = y_res

            # TODO Note how this puts the motion model estimate into a message and publishes the pose.
            # You will also need to publish the pose coming from sensor fusion when you correct
            # the estimates from the motion model
            msg_pose = Pose2DStamped()
            msg_pose.header = msg_velocity.header
            msg_pose.header.frame_id = self.veh_name
            msg_pose.theta = theta_res
            msg_pose.x = x_res
            msg_pose.y = y_res
            self.pub_pose.publish(msg_pose)

        self.last_pose.header.stamp = msg_velocity.header.stamp
        self.last_theta_dot = msg_velocity.omega
        self.last_v = msg_velocity.v
Example #8
0
    def __init__(self, outputDictQueue, logger):

        try:
            # Get the environment variables
            self.ACQ_POSES_UPDATE_RATE = float(os.getenv('ACQ_POSES_UPDATE_RATE', 10)) #Hz
            self.ACQ_ODOMETRY_UPDATE_RATE = float(os.getenv('ACQ_ODOMETRY_UPDATE_RATE', 30)) #Hz
            self.ACQ_STATIONARY_ODOMETRY = bool(int(os.getenv('ACQ_STATIONARY_ODOMETRY', 0)))
            self.ACQ_SOCKET_HOST = os.getenv('ACQ_SOCKET_HOST', '127.0.0.1')
            self.ACQ_SOCKET_PORT = int(os.getenv('ACQ_SOCKET_PORT', 65432))
            self.ACQ_DEVICE_NAME = os.getenv('ACQ_DEVICE_NAME', "watchtower10")
            self.ACQ_TOPIC_RAW = os.getenv('ACQ_TOPIC_RAW', "camera_node/image/raw")
            self.ACQ_TOPIC_CAMERAINFO = os.getenv('ACQ_TOPIC_CAMERAINFO', "camera_node/camera_info")
            self.ACQ_TOPIC_VELOCITY_TO_POSE = os.getenv('ACQ_TOPIC_VELOCITY_TO_POSE', None)
            self.ACQ_TEST_STREAM = bool(int(os.getenv('ACQ_TEST_STREAM', 1)))
            self.ACQ_BEAUTIFY = bool(int(os.getenv('ACQ_BEAUTIFY', 1)))
            self.ACQ_TAG_SIZE = float(os.getenv('ACQ_TAG_SIZE', 0.065))

            # Initialize ROS nodes and subscribe to topics
            rospy.init_node('acquisition_processor', anonymous=True, disable_signals=True)
            self.subscriberRawImage = rospy.Subscriber("/"+self.ACQ_DEVICE_NAME+"/"+self.ACQ_TOPIC_RAW, CompressedImage,
                                                        self.camera_image_callback,  queue_size = 1)
            self.subscriberCameraInfo = rospy.Subscriber("/"+self.ACQ_DEVICE_NAME+"/"+self.ACQ_TOPIC_CAMERAINFO, CameraInfo,
                                                        self.camera_info_callback,  queue_size = 1)

            if self.ACQ_TOPIC_VELOCITY_TO_POSE and self.ACQ_ODOMETRY_UPDATE_RATE>0: #Only if set (probably not for watchtowers)
                self.subscriberCameraInfo = rospy.Subscriber("/"+self.ACQ_DEVICE_NAME+"/"+self.ACQ_TOPIC_VELOCITY_TO_POSE, Pose2DStamped,
                                                            self.odometry_callback,  queue_size = 1)

            # CvBridge is neccessary for the image processing
            self.bridge = CvBridge()

            # Initialize atributes
            self.lastCameraInfo = None
            self.lastCameraImage = None
            self.lastImageProcessed = False

            self.previousOdometry = Pose2DStamped()
            self.previousOdometry.x = 0.0
            self.previousOdometry.y = 0.0
            self.previousOdometry.theta = 0.0

            self.timeLastPub_odometry = rospy.get_time()
            self.timeLastPub_poses = rospy.get_time()

            self.outputDictQueue = outputDictQueue
            self.logger = logger

            dsp_options={"beautify": self.ACQ_BEAUTIFY, "tag_size": self.ACQ_TAG_SIZE}
            self.dsp = deviceSideProcessor(dsp_options, self.logger)

        except Exception as e:
            self.logger.warning("acquisitionProcessor initialization failed: : %s" % str(e))
            raise Exception("acquisitionProcessor initialization failed: : %s" % str(e))
Example #9
0
    def velocity_callback(self, msg_velocity):
        """
        Performs the calclulation from velocity to pose and publishes a messsage with the result.

        Args:
            msg_velocity (:obj:`Twist2DStamped`): the current velocity message

        """
        if self.last_pose.header.stamp.to_sec() > 0:  # skip first frame

            dt = (msg_velocity.header.stamp -
                  self.last_pose.header.stamp).to_sec()

            # Integrate the relative movement between the last pose and the current
            theta_delta = self.last_theta_dot * dt
            # to ensure no division by zero for radius calculation:
            if np.abs(self.last_theta_dot) < 0.000001:
                # straight line
                x_delta = self.last_v * dt
                y_delta = 0
            else:
                # arc of circle
                radius = self.last_v / self.last_theta_dot
                x_delta = radius * np.sin(theta_delta)
                y_delta = radius * (1.0 - np.cos(theta_delta))

            # Add to the previous to get absolute pose relative to the starting position
            theta_res = self.last_pose.theta + theta_delta
            x_res = self.last_pose.x + x_delta * np.cos(
                self.last_pose.theta) - y_delta * np.sin(self.last_pose.theta)
            y_res = self.last_pose.y + y_delta * np.cos(
                self.last_pose.theta) + x_delta * np.sin(self.last_pose.theta)

            # Update the stored last pose
            self.last_pose.theta = theta_res
            self.last_pose.x = x_res
            self.last_pose.y = y_res

            # Stuff the new pose into a message and publish
            msg_pose = Pose2DStamped()
            msg_pose.header = msg_velocity.header
            msg_pose.header.frame_id = self.veh_name
            msg_pose.theta = theta_res
            msg_pose.x = x_res
            msg_pose.y = y_res
            self.pub_pose.publish(msg_pose)

        self.last_pose.header.stamp = msg_velocity.header.stamp
        self.last_theta_dot = msg_velocity.omega
        self.last_v = msg_velocity.v
Example #10
0
 def initial_pose(self):
     distance = self.add_distance / self.count
     x = self.add_x / self.count
     y = self.add_y / self.count
     angle_l = self.add_angle_l / self.count
     self.count = 0
     pose_init_msg = Pose2DStamped()
     pose_init_msg.x = x
     pose_init_msg.y = y
     pose_init_msg.theta = angle_l
     self.pub_pose.publish(pose_init_msg)
     self.needed = False
     ready = BoolStamped()
     ready.header.stamp = rospy.Time.now()
     ready.data = True
     self.pub_detection.publish(ready)
	def detection(self, msg):
           	cv_img = self.bridge.compressed_imgmsg_to_cv2(msg, "bgr8")
                cv_crop = cv_img[np.floor(cv_img.shape[0]*.35):cv_img.shape[0],0:cv_img.shape[1]]
                img_hsv = cv2.cvtColor(cv_crop, cv2.COLOR_BGR2HSV)

                mask = cv2.inRange(img_hsv, self.low_range, self.high_range)

               	params = cv2.SimpleBlobDetector_Params()
               	params.filterByColor = False
               	params.filterByArea = True
               	params.minArea = 120
               	params.filterByInertia = True
		params.minInertiaRatio = 0.7
               	params.filterByConvexity = False
         	params.filterByCircularity = False
               	dectector = cv2.SimpleBlobDetector_create(params)

                keypoints = dectector.detect(mask)

		if len(keypoints) > 0:
			self.count += 1
			if self.time is not None:
				self.time = rospy.get_time()

			if self.count > 3:
				detect_msg = BoolStamped()
				detect_msg.header.stamp = rospy.Time.now()
				detect_msg.data = True
				pose_msg = Pose2DStamped()
				pose_msg.header.stamp = rospy.Time.now()
				pose_msg.x = keypoints[0].pt[0]
				pose_msg.y = keypoints[0].pt[1]
				pose_msg.theta = 0
				if (pose_msg.x > 30 and pose_msg.y < 110) and self.detect:
					self.duckie_detected.publish(detect_msg)
					self.duckie_pose.publish(pose_msg)
					self.detect = False

		if self.time is not None:
			if (rospy.get_time() - self.time) > 1:
				self.count = 0

                img_keypoints = cv2.drawKeypoints(cv_crop, keypoints, cv_crop, color=(0,0,255), flags=cv2.DRAW_MATCHES_FLAGS_DRAW_RICH_KEYPOINTS)
		img_keypoints_out = self.bridge.cv2_to_imgmsg(cv_crop, "bgr8")
		img_mask_out = self.bridge.cv2_to_imgmsg(mask, "mono8")
		self.detection_image.publish(img_keypoints_out)
		self.mask.publish(img_mask_out)
    def __init__(self):
        # Get node name and vehicle name
        self.node_name = rospy.get_name()
        self.veh_name = self.node_name.split("/")[1]

        # Keep track of the last known pose
        self.last_pose = Pose2DStamped()
        self.last_theta_dot = 0
        self.last_v = 0

        # Setup the publisher and subscriber
        self.sub_velocity = rospy.Subscriber("~velocity",
                                             Twist2DStamped,
                                             self.velocity_callback,
                                             queue_size=1)
        self.pub_pose = rospy.Publisher("~pose", Pose2DStamped, queue_size=1)
        rospy.loginfo("[%s] Initialized.", self.node_name)
    def __init__(self):

        #dimensions of image used by detection node
        self.IMAGE_WIDTH = 256.0
        self.IMAGE_HEIGHT = 67.0

        #cmd velocities
        self.omega = 8.0
        self.v = 0.5

        self.steering_enabled = False
        self.last_start = BoolStamped()
        self.last_pose = Pose2DStamped()

        #subscribers
        rospy.Subscriber("remote_steering_start", BoolStamped, self.start_steering_cb)
        rospy.Subscriber("pose", Pose2DStamped, self.pose_cb)

        #publishsers
        self.pub_done = rospy.Publisher("remote_steering_complete", BoolStamped, queue_size=1)
        self.pub_car_cmd = rospy.Publisher("lane_controller_node/car_cmd", Twist2DStamped, queue_size=1)
    def __init__(self, node_name):
        # Initialize the DTROS parent class
        super(SensorFusionNode, self).__init__(node_name=node_name,
                                               node_type=NodeType.LOCALIZATION)

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

        # Keep track of the last known pose
        self.last_pose = Pose2DStamped()
        self.last_theta_dot = 0
        self.last_v = 0

        # TODO Feel free to use a flag like this to set which type of filter you're currently using.
        # You can also define these as parameters in the launch file for this node if you're feeling fancy
        # (or if this was a system you wanted to use in the real world), but a hardcoded flag works just as well
        # for a class project like this.
        self.FUSION_TYPE = "EKF"

        # Setup the publisher
        self.pub_pose = rospy.Publisher("~pose",
                                        Pose2DStamped,
                                        queue_size=1,
                                        dt_topic_type=TopicType.LOCALIZATION)

        # Setup the subscriber to the motion of the robot
        self.sub_velocity = rospy.Subscriber(
            f"/{self.veh_name}/kinematics_node/velocity",
            Twist2DStamped,
            self.motion_model_callback,
            queue_size=1)

        # Setup the subscriber for when sensor readings come in
        self.sub_sensor = rospy.Subscriber(f"/{self.veh_name}/detected_tags",
                                           Int32MultiArray,
                                           self.sensor_fusion_callback,
                                           queue_size=1)

        # ---
        self.log("Initialized.")
Example #15
0
    def set_task(self):
        path_msg = Pose2DList()
        move_msg = String()

        # Publish move message
        move_msg.data = self.current_task['move']
        self.pub_set_move.publish(move_msg)

        # Publish path messgae
        data_list = []
        for i in range(len(self.current_task['path'])):
            # ith position
            data = self.current_task['path'][i]
            ith_pose = Pose2DStamped()
            ith_pose.header.stamp = rospy.Time.now()
            ith_pose.x = data[0]
            ith_pose.y = data[1]
            ith_pose.theta = data[2]
            data_list.append(ith_pose)
        path_msg.data_list = data_list
        self.pub_set_path.publish(path_msg)

        rospy.loginfo("[%s] set move and path to planners" %(self.node_name))
#!/usr/bin/env python

import rospy
import math
import csv
import sys
from duckietown_msgs.msg import Twist2DStamped, Pose2DStamped
from wifianalyzer_teamgrapes import wifiutils as wu

lastLinVel = 0.0
lastAngVel = 0.0
oldPose = Pose2DStamped()
f = open('./heatmapdata.csv', 'wt')
writer = csv.writer(f)


# integrates the linear and angular velocities to calculate displacement
def integrate(theta_dot, v, dt):
    # change in theta
    theta_delta = theta_dot * dt

    # if the angular velocity is very small
    # assume we are moving in a straight line
    if abs(theta_dot) < 0.00001:
        x_delta = v * dt
        y_delta = 0
    else:
        # otherwise we are moving along the arc of a circle
        r = v / theta_dot
        x_delta = r * math.sin(theta_delta)
        y_delta = r * (1.0 - math.cos(theta_delta))
Example #17
0
 def __init__(self, *args):
     super(TestPositionFilterNode, self).__init__(*args)
     self.pose = Pose2DStamped()
     self.pose_prev = Pose2DStamped()
     self.msg_received = False
Example #18
0
rospy.init_node("nav_home")
rospack = rospkg.RosPack()
path = rospack.get_path('ank_ris')

steering_pub = rospy.Publisher('/lead/joy', Joy, queue_size=10, latch=True)
while steering_pub.get_num_connections() < 1 and not rospy.is_shutdown():
    pass

command = Joy()
i = 0
while i < 8:
    command.axes.append(0)
    i += 1

home = Pose2DStamped()
current_pose = Pose2DStamped()
return_home = False
new_home = True
lin_speed = 0.5
ang_speed = 1
full_circle = 25
full_circle_time = 2


def triggerOdom():
    command.axes[3] = 0.1
    steering_pub.publish(command)
    rospy.sleep(0.3)
    command.axes[3] = 0
    steering_pub.publish(command)