class Application: def __init__(self): # ATF code self.atf = ATF() # native app code self.pub_freq = 20.0 # Hz self.br = tf.TransformBroadcaster() rospy.sleep(1) #wait for tf broadcaster to get active (rospy bug?) def execute(self): # small testblock (circle r=0.5, time=3) self.atf.start("testblock_small") self.pub_tf_circle("link1", "link2", radius=1, time=3) self.atf.stop("testblock_small") # large testblock (circle r=1, time=5 self.atf.start("testblock_large") self.pub_tf_circle("link1", "link2", radius=2, time=5) self.atf.stop("testblock_large") self.atf.shutdown() def pub_tf_circle(self, parent_frame_id, child1_frame_id, radius=1, time=1): rate = rospy.Rate(int(self.pub_freq)) for i in range(int(self.pub_freq * time) + 1): t = i / self.pub_freq / time self.br.sendTransform( (-radius * math.cos(2 * math.pi * t) + radius, -radius * math.sin(2 * math.pi * t), 0), tf.transformations.quaternion_from_euler(0, 0, 0), rospy.Time.now(), child1_frame_id, parent_frame_id) rate.sleep()
def __init__(self): self.pub = rospy.Publisher('/gazebo/set_model_state', ModelState, queue_size=1) # gazebo move object publisher self.name = 'box1' # name of object to spawn self.testcases = ['line_passage', # 0 'line_passage_obstacle', # 1 'line_passage_person_moving', # 2 'line_passage_spawn_obstacle', # 3 'narrow_passage_2_cone', # 4 't_passage', # 5 't_passage_obstacle'] # 6 self.rospack = rospkg.RosPack() # get path for ROS package rp = RvizPublisher() # filepath = self.rospack.get_path('msh_bringup') + '/launch/' + self.args.launch + '.launch' if "standalone" == sys.argv[1]: filepath = self.rospack.get_path('msh_bringup') + '/launch/' + sys.argv[2] + '.launch' else: filepath = self.rospack.get_path('msh_bringup') + '/launch/' + self.testcases[4] + '.launch' print '=' * len(filepath) print filepath print '=' * len(filepath) rp.main(filepath, True, False) # 'initialpose' publish del rp rospy.sleep(1) # setup threading daemon to beam object in front of robot self.beam_daemon = threading.Timer(15, self.beam_object, [5.0, -0.5, 0.0, 0.0, 0.0]) self.beam_daemon.setDaemon(True) self.beam_daemon.setName('beam_daemon') self.atf = ATF()
def __init__(self): # ATF code self.atf = ATF() # native app code self.pub_freq = 20.0 # Hz self.br = tf.TransformBroadcaster() rospy.sleep(1) #wait for tf broadcaster to get active (rospy bug?)
class Application: def __init__(self): self.atf = ATF() def execute(self): self.atf.start("testblock_1") rospy.sleep(1) self.atf.stop("testblock_1") self.atf.start("testblock_2") rospy.sleep(1) self.atf.stop("testblock_2") self.atf.shutdown()
class Application: def __init__(self): self.atf = ATF() def execute(self): self.atf.start("testblock_8s") self.atf.start("testblock_3s") rospy.sleep(3) self.atf.stop("testblock_3s") self.atf.start("testblock_5s") rospy.sleep(5) self.atf.stop("testblock_5s") #self.atf.stop("testblock_8s") self.atf.shutdown()
class Application: def __init__(self): self.atf = ATF() def execute(self): # Make sure all hardware is up and running (mainly needed for ensenso) # did not use the ATF wait for topic since this interferes with testing the interface rospy.sleep(30) # ROS Camera test self.atf.start("get_data") rospy.sleep(10) self.atf.stop("get_data") self.atf.shutdown()
class Application: #rospy.Subscriber("/rosout_agg", Log, self.state_transition_cb, queue_size=None) def __init__(self): # initialize the ATF class self.atf = ATF() def state_transition_cb(self, msg): # TODO sm feedback on state change [eg: ERROR, READY, BUSY ...] if 'subscribed to person_of_interest_filter' in msg.msg: self.ready_for_scenario = True def execute(self): # you can call start/pause/purge/stop for each testblock during the execution of your app rospy.sleep(5) #self.atf.start("testblock_all") self.atf.start("testblock_small") # Do something #self.wait_for_robot_ready(); #self.atf.stop("testblock_1") #self.atf.start("testblock_2") # Do something else rospy.sleep(200) self.atf.stop("testblock_small") #self.atf.stop("testblock_all") # finally we'll have to call shutdown() to tell the ATF to stop all recordings and wrap up self.atf.shutdown() def wait_for_robot_ready(self): rospy.loginfo("wait for robot to be ready") r = rospy.Rate(1) while not rospy.is_shutdown(): if self.ready_for_scenario: break r.sleep()
class Application: def __init__(self): self.atf = ATF() moveit_commander.roscpp_initialize(sys.argv) self.group = moveit_commander.MoveGroupCommander("manipulator") def execute(self): # dummy home self.atf.start("initialize") pose_target = geometry_msgs.msg.Pose() pose_target.position.x = 0.732 pose_target.position.y = 0.0 pose_target.position.z = 1.325 pose_target.orientation.w = 1.0 self.group.set_pose_target(pose_target) self.group.go() self.atf.stop("initialize") self.atf.start("full_test") # down self.atf.start("move_down") pose_target2 = geometry_msgs.msg.Pose() pose_target2.position.x = 1.140 pose_target2.position.y = 0.0 pose_target2.position.z = 0.825 pose_target2.orientation.w = 1.0 self.group.set_pose_target(pose_target2) self.group.go() self.atf.stop("move_down") # left self.atf.start("move_left") pose_target3 = geometry_msgs.msg.Pose() pose_target3.position.x = 0.0 pose_target3.position.y = 1.140 pose_target3.position.z = 0.825 pose_target3.orientation.w = 1.0 self.group.set_pose_target(pose_target3) self.group.go() self.atf.stop("move_left") # right self.atf.start("move_right") pose_target4 = geometry_msgs.msg.Pose() pose_target4.position.x = 0.0 pose_target4.position.y = -1.140 pose_target4.position.z = 0.825 pose_target4.orientation.w = 1.0 self.group.set_pose_target(pose_target4) self.group.go() self.atf.stop("move_right") # home self.atf.start("move_up") pose_target5 = geometry_msgs.msg.Pose() pose_target5.position.x = 0.732 pose_target5.position.y = 0.0 pose_target5.position.z = 1.325 pose_target5.orientation.w = 1.0 self.group.set_pose_target(pose_target5) self.group.go() self.atf.stop("move_up") self.atf.stop("full_test") self.atf.shutdown()
def __init__(self): self.atf = ATF()
def __init__(self): self.atf = ATF() moveit_commander.roscpp_initialize(sys.argv) self.group = moveit_commander.MoveGroupCommander("manipulator")
def __init__(self): # initialize the ATF class self.atf = ATF()
def __init__(self): ATF(self.create_test_list()).check_states()
class Application: def __init__(self): self.atf = ATF() self.ptf = PublishTf() def execute(self): self.atf.start("testblock_all") # circle self.atf.start("testblock_circle") self.ptf.pub_circ(radius=1, time=5) self.atf.stop("testblock_circle") # quadrat self.atf.start("testblock_quadrat") self.ptf.pub_quadrat(length=2, time=10) self.atf.stop("testblock_quadrat") self.atf.stop("testblock_all") self.atf.shutdown()
class Application: def __init__(self): self.pub = rospy.Publisher( '/gazebo/set_model_state', ModelState, queue_size=1) # gazebo move object publisher self.name = 'box1' # name of object to spawn self.testcases = [ 'line_passage', # 0 'line_passage_obstacle', # 1 'line_passage_person_moving', # 2 'line_passage_spawn_obstacle', # 3 'narrow_passage_2_cone', # 4 't_passage', # 5 't_passage_obstacle' ] # 6 self.rospack = rospkg.RosPack() # get path for ROS package rp = RvizPublisher() # filepath = self.rospack.get_path('msh_bringup') + '/launch/' + self.args.launch + '.launch' if "standalone" == sys.argv[1]: filepath = self.rospack.get_path( 'msh_bringup') + '/launch/' + sys.argv[2] + '.launch' else: filepath = self.rospack.get_path( 'msh_bringup') + '/launch/' + self.testcases[0] + '.launch' print '=' * len(filepath) print filepath print '=' * len(filepath) rp.main(filepath, True, False) # 'initialpose' publish del rp rospy.sleep(1) # setup threading daemon to beam object in front of robot self.beam_daemon = threading.Timer(15, self.beam_object, [5.0, -0.5, 0.0, 0.0, 0.0]) self.beam_daemon.setDaemon(True) self.beam_daemon.setName('beam_daemon') self.atf = ATF() def execute(self): self.atf.start('testblock_nav') self.beam_daemon.start() # necessary to catch goal published on topic /move_base/goal rospy.sleep(3) # line passage goal sss.move("base", [7.0, 0.0, 0.0]) self.atf.stop('testblock_nav') self.atf.shutdown() def beam_object(self, x, y, roll, pitch, yaw): ''' beams an available object to the desired position :param x: x-Position in [m] :param y: y-Position in [m] :param roll: Euler angle transformation :param pitch: Euler angle transformation :param yaw: Euler angle transformation :return: -- ''' # gazebo takes ModelState as msg type model_state = ModelState() model_state.model_name = self.name model_state.reference_frame = 'world' model_state.pose.position.x = x model_state.pose.position.y = y quaternion = tf.transformations.quaternion_from_euler(roll, pitch, yaw) model_state.pose.orientation.x = quaternion[0] model_state.pose.orientation.y = quaternion[1] model_state.pose.orientation.z = quaternion[2] model_state.pose.orientation.w = quaternion[3] rospy.loginfo('\033[92m' + '----Move Object Gazebo----' + '\033[0m') # publish message self.pub.publish(model_state)
def __init__(self): self.atf = ATF() self.ptf = PublishTf()