def position_api_joint_space_handler(req):
	rospy.loginfo("Inside  PositionAPIJointSpace Service call!")
	'''
	This simple_script_server is a custom library that was created by 
	the Fraunhofer institute.  An action_handle will listen for position
	commands.
	'''
	ah = simple_script_server.action_handle("move", "arm", "home", False, False)
	if False:
		return ah
	else:
		ah.set_active()

	# Form a list of the target joint angles:
	targetJointAngles = [req.joint1, req.joint2, req.joint3, req.joint4, req.joint5, req.joint6]
	rospy.loginfo("Joint Angle saved")
	'''
    Encapsulate the target jointangles into another list (this forms a trajectory)
	'''
	traj = [targetJointAngles]

	# Generate the trajectory message to send to the Powerball:
	traj_msg = JointTrajectory()
	traj_msg.header.stamp = rospy.Time.now() + rospy.Duration(0.5)
	traj_msg.joint_names = ['arm_1_joint', 'arm_2_joint', 'arm_3_joint', 'arm_4_joint', 'arm_5_joint', 'arm_6_joint']
	point_nr = 0

	# Set the target velocities of the target joints.  They are set to 0 to denote stopping at the destinations:
	for point in traj:
		point_nr += 1
		point_msg = JointTrajectoryPoint()
		point_msg.positions = point
		point_msg.velocities = [0] * 6
		point_msg.time_from_start = rospy.Duration(3 * point_nr)
		traj_msg.points.append(point_msg)

	# Send the position control message to the action server node:
	action_server_name = '/arm/joint_trajectory_controller/follow_joint_trajectory'
	rospy.loginfo("Trajectory created")

	client = actionlib.SimpleActionClient(action_server_name, FollowJointTrajectoryAction)
	if not client.wait_for_server(rospy.Duration(5)):
		print("Action server not ready within timeout.  Aborting...")
		ah.set_failed(4)
		#return ah
		return 2
	else:
		print("Action server ready!")
	rospy.loginfo("Creating message")
	client_goal = FollowJointTrajectoryGoal()
	client_goal.trajectory = traj_msg
	client.send_goal(client_goal)
	rospy.loginfo("Sending message to client")
	ah.set_client(client)

	ah.wait_inside()
	# return ah
	return 0
Пример #2
0
def powerball_remote():

	ah = simple_script_server.action_handle("move", "arm", "home", False, False)
	if False:
		return ah
	else: 
		ah.set_active()
	
	# Ask the user to input the desired joint angles:    
	print("Joint 1 is the proximal joint (the base), Joint 6 is the distal joint (the wrist)")
	joint1 = float(input("Please enter the desired angle for Joint 1: "))
	joint2 = float(input("Please enter the desired angle for Joint 2: "))
	joint3 = float(input("Please enter the desired angle for Joint 3: "))
	joint4 = float(input("Please enter the desired angle for Joint 4: "))
	joint5 = float(input("Please enter the desired angle for Joint 5: "))
	joint6 = float(input("Please enter the desired angle for Joint 6: "))

	# This list holds the joint angles:
	jointAngles = [joint1, joint2, joint3, joint4, joint5, joint6]

	# Encapsulate the jointAngles in another list (the trajectory):
	traj = [jointAngles]

	# Generate the trajectory message to send:
	traj_msg = JointTrajectory()
	traj_msg.header.stamp = rospy.Time.now() + rospy.Duration(0.5)		
	traj_msg.joint_names = ['arm_1_joint', 'arm_2_joint', 'arm_3_joint', 'arm_4_joint', 'arm_5_joint', 'arm_6_joint']
	point_nr = 0

	for point in traj:
		point_nr += 1
		point_msg = JointTrajectoryPoint()
		point_msg.positions = point
		point_msg.velocities = [0] * 6
		point_msg.time_from_start = rospy.Duration(3 * point_nr)
		traj_msg.points.append(point_msg)

	# Send the message to the action server:
	action_server_name = '/arm_controller/follow_joint_trajectory'

	client = actionlib.SimpleActionClient(action_server_name, FollowJointTrajectoryAction)
	if not client.wait_for_server(rospy.Duration(5)):
		print("Action server not ready within timeout.  Aborting...")
		ah.set_failed(4)
		return ah
	else:
		print("Action server ready!")



	client_goal = FollowJointTrajectoryGoal()
	client_goal.trajectory = traj_msg
	client.send_goal(client_goal)
	ah.set_client(client)

	ah.wait_inside()
	return ah
Пример #3
0
def position_api_joint_space_handler(req):

	'''
	This simple_script_server is a custom library that was created by 
	the Fraunhofer institute.  An action_handle will listen for position
	commands.
	'''
	ah = simple_script_server.action_handle("move", "arm", "home", False, False)
	if False:
		return ah
	else:
		ah.set_active()

	# Form a list of the target joint angles:
	targetJointAngles = [req.joint1, req.joint2, req.joint3, req.joint4, req.joint5, req.joint6]

	'''
    Encapsulate the target jointangles into another list (this forms a trajectory)
	'''
	traj = [targetJointAngles]

	# Generate the trajectory message to send to the Powerball:
	traj_msg = JointTrajectory()
	traj_msg.header.stamp = rospy.Time.now() + rospy.Duration(0.5)
	traj_msg.joint_names = ['arm_1_joint', 'arm_2_joint', 'arm_3_joint', 'arm_4_joint', 'arm_5_joint', 'arm_6_joint']
	point_nr = 0

	# Set the target velocities of the target joints.  They are set to 0 to denote stopping at the destinations:
	for point in traj:
		point_nr += 1
		point_msg = JointTrajectoryPoint()
		point_msg.positions = point
		point_msg.velocities = [0] * 6
		point_msg.time_from_start = rospy.Duration(3 * point_nr)
		traj_msg.points.append(point_msg)

	# Send the position control message to the action server node:
	action_server_name = '/arm_controller/follow_joint_trajectory'

	client = actionlib.SimpleActionClient(action_server_name, FollowJointTrajectoryAction)
	if not client.wait_for_server(rospy.Duration(5)):
		print("Action server not ready within timeout.  Aborting...")
		ah.set_failed(4)
		return ah
	else:
		print("Action server ready!")

	client_goal = FollowJointTrajectoryGoal()
	client_goal.trajectory = traj_msg
	client.send_goal(client_goal)
	ah.set_client(client)

	ah.wait_inside()
	# return ah
	return 0
Пример #4
0
def position_api_coord_space_quat_handler(req):
	
	global jointStateCallbackEx

	'''
	This simple_script_server is a custom library that was created by
	the Fraunhofer institute.  An action_handle will listen for position commands.
	'''
	ah = simple_script_server.action_handle("move", "arm", "home", False, False)
	if False:
		return ah
	else:
		ah.set_active()
	
	# Get the target (X, Y, Z) coordinates to move to:
	targetCoords = [req.position.x, req.position.y, req.position.z]

	# Get the desired rotation (in quaternion) to move to:
	targetRot = [req.orientation.w, req.orientiation.x, req.orientation.y, req.orientation.z]

	'''
	Currently the Powerball requires a list of the 6 target joint angles to move.
	We can calculate these target joint angles by calling the inverse kinematics
	functions:
	'''

	'''
	First, get a list of the current joint angles.  The joint angles can be
	found from rostopic /joint_states 
	'''
	sub = rospy.Subscriber("/joint_states", JointState, jointStateCallback) 

	while jointStateCallbackEx == False:
		pass

	rospy.Subscriber.unregister(sub)
	jointStateCallbackEx = False

	# We need to convert the quaternion into a 4x4 homogeneous transformation matrix:
	homoMat = quaternion_matrix(targetRot) 
	
	# Insert the desired target joint coordinate into the transformation matrix:
	homoMat[0,3] = req.xCoord
	homoMat[1,3] = req.yCoord
	homoMat[2,3] = req.zCoord    

	'''
	Calculate the inverse kinematics given the target rotation/position and
	the list of current joint angles:
	'''

	targetJointAngles = kf.ikine(homoMat, jointAngles)

	if len(targetJointAngles) != 0:
		# We have a valid solution!  Move the Powerball to this location:
	
		targetJointAngles = targetJointAngles[:6]

		# Encapsulate the targetJointAngles into a trajectory:
		traj = [targetJointAngles] 

		# Generate the trajectory message to send to the Powerball:
		traj_msg = JointTrajectory()
		traj_msg.header.stamp = rospy.Time.now() + rospy.Duration(0.5)
		traj_msg.joint_names = ['arm_1_joint', 'arm_2_joint', 'arm_3_joint', 'arm_4_joint', 'arm_5_joint', 'arm_6_joint']
		point_nr = 0

		# Set the target velocities of the target joints.  They are set to 0 to denote stopping at the destinations:
		for point in traj:
			point_nr += 1
			point_msg = JointTrajectoryPoint()
			point_msg.positions = point
			point_msg.velocities = [0] * 6
			point_msg.time_from_start = rospy.Duration(3 * point_nr)
			traj_msg.points.append(point_msg)

		# Send the position control message to the action server node:
		action_server_name = '/arm_controller/follow_joint_trajectory'
		
		client = actionlib.SimpleActionClient(action_server_name, FollowJointTrajectoryAction)
		if not client.wait_for_server(rospy.Duration(5)):
			print("Action server not ready within timeout.  Aborting...")
			ah.set_failed(4)
			return ah
		else:
			print("Action server ready for Coordinate API Request")
		
		client_goal = FollowJointTrajectoryGoal()
		client_goal.trajectory = traj_msg
		client.send_goal(client_goal)
		ah.set_client(client)

		ah.wait_inside()
	return 0
def position_api_coord_space_quat_handler(req):
	#rospy.loginfo("Inside PostionAPICoordSpaceQuat Service call!")	
	global jointStateCallbackEx
	#global joint_msg_leap
	#joint_msg_leap.name=['arm_1_joint', 'arm_2_joint', 'arm_3_joint', 'arm_4_joint', 'arm_5_joint', 'arm_6_joint','base_joint_gripper_left','base_joint_gripper_right']
	#joint_msg_leap.position=[0.0,0.0,0.0,0.0,0.0,0.0,0.0,0.0]
	#joint_msg_leap.velocity=[0.0,0.0,0.0,0.0,0.0,0.0,0.0,0.0]
	#joint_msg_leap.effort=[0.0,0.0,0.0,0.0,0.0,0.0,0.0,0.0]

	#rospy.loginfo("Inside server_callback!")
	'''
	This simple_script_server is a custom library that was created by
	the Fraunhofer institute.  An action_handle will listen for position commands.
	'''
	ah = simple_script_server.action_handle("move", "arm", "home", False, False)
	if False:
		rospy.loginfo("Action server ready!")
		return ah
	else:
		ah.set_active()
		#rospy.loginfo("ah active!")	
	# Get the target (X, Y, Z) coordinates to move to:
	targetCoords = [req.target.position.x, req.target.position.y, req.target.position.z]
	#rospy.loginfo("TargetCoords read!")
	# Get the desired rotation (in quaternion) to move to:
	targetRot = [req.target.orientation.w, req.target.orientation.x, req.target.orientation.y, req.target.orientation.z]
	#rospy.loginfo("TargetRot read!")
	'''
	Currently the Powerball requires a list of the 6 target joint angles to move.
	We can calculate these target joint angles by calling the inverse kinematics
	functions:
	'''

	'''
	First, get a list of the current joint angles.  The joint angles can be
	found from rostopic /joint_states 
	'''
	sub = rospy.Subscriber("/joint_states", JointState, jointStateCallback,queue_size=1) 
	pub = rospy.Publisher("joint_leap", JointState, queue_size=10) 
	while jointStateCallbackEx == False:
		pass

	rospy.Subscriber.unregister(sub)
	jointStateCallbackEx = False

	# We need to convert the quaternion into a 4x4 homogeneous transformation matrix:
	homoMat = quaternion_matrix(targetRot) 
	
	# Insert the desired target joint coordinate into the transformation matrix:
	homoMat[0,0] = 1
	homoMat[1,0] = 0
	homoMat[2,0] = 0
	homoMat[0,1] = 0
	homoMat[1,1] = 1
	homoMat[2,1] = 0
	homoMat[0,2] = 0
	homoMat[1,2] = 0
	homoMat[2,2] = 1
	homoMat[0,3] = req.target.position.x
	homoMat[1,3] = req.target.position.y
	homoMat[2,3] = req.target.position.z
	#RotxMat=numpy.array([[1,0,0,0],[0,0,1,0],[0,-1,0,0],[0,0,0,1]]) 
	#RotyMat=numpy.array([[0,0,-1,0],[0,1,0,0],[1,0,0,0],[0,0,0,1]])
	#SolMat=numpy.array([[0,0,0,0],[0,0,0,0],[0,0,0,0],[0,0,0,0]])
	#SolMat=RotyMat*RotxMat*homoMat
	'''
	Calculate the inverse kinematics given the target rotation/position and
	the list of current joint angles:
	'''
	#print("homoMat is:  ")
	#print(homoMat)
	#print(SolMat)
	#print(jointAngles)
	try:
		targetJointAngles = kf.ikine(homoMat, jointAngles)
	except ValueError:
		print("ERROR: Position out of Range")
		return 0		
	if len(targetJointAngles) != 0:
		# We have a valid solution!  Move the Powerball to this location: 
		# Code for Simulation 
		#print(targetJointAngles)		
		# Encapsulate the targetJointAngles into a trajectory:
		traj = []
		joint1=targetJointAngles[0]
		joint1=targetJointAngles[0]
		joint2=targetJointAngles[1]
		joint3=targetJointAngles[2]
		joint4=targetJointAngles[3]
		joint5=targetJointAngles[4]
		joint6=targetJointAngles[5]
		traj.append(joint1)
		traj.append(joint2)
		traj.append(joint3)
		traj.append(joint4)
		traj.append(joint5)
		traj.append(joint6)
		#print(traj)
		position = []		 
		# Generate the trajectory message to send to the Powerball:
		# End code simulation
		#Code real robot
		#targetJointAngles = targetJointAngles[:6]

		# Encapsulate the targetJointAngles into a trajectory:
		#traj = [targetJointAngles] 
		traj_msg = JointTrajectory()
		traj_msg.header.stamp = rospy.Time.now() + rospy.Duration(0.5)
		traj_msg.joint_names = ['arm_1_joint', 'arm_2_joint', 'arm_3_joint', 'arm_4_joint', 'arm_5_joint', 'arm_6_joint']
		point_nr = 0

		# Set the target velocities of the target joints.  They are set to 0 to denote stopping at the destinations:
		for point in traj:	
			#print(point)	
			#Position only in simulation
			position.append((point))
			point_nr += 1
			point_msg = JointTrajectoryPoint()
			point_msg.positions = point
			point_msg.velocities = [0] * 6
			point_msg.time_from_start = rospy.Duration(3 * point_nr)
			traj_msg.points.append(point_msg)
		# Send the position control message to the action server node:
		position.append(gripperPos[0]) 
		obj1.position=position
		#rospy.loginfo(obj1.position[0])
		#rospy.loginfo(obj1.position[1])
		#rospy.loginfo(obj1.position[2])
		#rospy.loginfo(obj1.position[3])
		#rospy.loginfo(obj1.position[4])
		#rospy.loginfo(obj1.position[5])
		#rospy.loginfo(obj1.position[6])
		#rospy.loginfo(obj1.position[7])
		resp = PositionAPICoordSpaceQuatResponse()
		resp.ret=1;
		resp.joint1=obj1.position[0]
		resp.joint2=obj1.position[1]
		resp.joint3=obj1.position[2]
		resp.joint4=obj1.position[3]
		resp.joint5=obj1.position[4]
		resp.joint6=obj1.position[5]
		#action_server_name = '/arm/joint_trajectory_controller/follow_joint_trajectory'
		#pub.publish(obj1)
		#client = actionlib.SimpleActionClient(action_server_name, FollowJointTrajectoryAction)
		#if not client.wait_for_server(rospy.Duration(5)):
		#	print("Action server not ready within timeout.  Aborting...")
		#	ah.set_failed(4)
			#return ah
		#	return 0
		#else:
			#print("Action server ready for Coordinate API Request")
		
		#client_goal = FollowJointTrajectoryGoal()
		#client_goal.trajectory = traj_msg
		#client.send_goal(client_goal)
		#ah.set_client(client)

		#ah.wait_inside()
		return resp
Пример #6
0
def position_api_coord_space_quat_handler(req):
	#rospy.loginfo("Inside PostionAPICoordSpaceQuat Service call!")	
	global jointStateCallbackEx
	global gripper
	gripper=0.5	
	'''
	This simple_script_server is a custom library that was created by
	the Fraunhofer institute.  An action_handle will listen for position commands.
	'''
	ah = simple_script_server.action_handle("move", "arm", "home", False, False)
	if False:
		rospy.loginfo("Action server ready!")
		return ah
	else:
		ah.set_active()
		#rospy.loginfo("ah active!")	
	# Get the target (X, Y, Z) coordinates to move to:
	targetCoords = [req.target.position.x, req.target.position.y, req.target.position.z]
	#rospy.loginfo("TargetCoords read!")
	# Get the desired rotation (in quaternion) to move to:
	targetRot = [req.target.orientation.w, req.target.orientation.x, req.target.orientation.y, req.target.orientation.z]
	#rospy.loginfo("TargetRot read!")
	'''
	Currently the Powerball requires a list of the 6 target joint angles to move.
	We can calculate these target joint angles by calling the inverse kinematics
	functions:
	'''

	'''
	First, get a list of the current joint angles.  The joint angles can be
	found from rostopic /joint_states 
	'''
	sub = rospy.Subscriber("/joint_states", JointState, jointStateCallback) 
	pub = rospy.Publisher("joint_leap", JointState, queue_size=10) 
	while jointStateCallbackEx == False:
		pass

	rospy.Subscriber.unregister(sub)
	jointStateCallbackEx = False

	# We need to convert the quaternion into a 4x4 homogeneous transformation matrix:
	homoMat = quaternion_matrix(targetRot) 
	
	# Insert the desired target joint coordinate into the transformation matrix:
	homoMat[0,0] = 1
	homoMat[1,0] = 0
	homoMat[2,0] = 0
	homoMat[0,1] = 0
	homoMat[1,1] = -1
	homoMat[2,1] = 0
	homoMat[0,2] = 0
	homoMat[1,2] = 0
	homoMat[2,2] = -1
	homoMat[0,3] = req.target.position.x
	homoMat[1,3] = req.target.position.y
	homoMat[2,3] = req.target.position.z
	#RotxMat=numpy.array([[1,0,0,0],[0,0,1,0],[0,-1,0,0],[0,0,0,1]]) 
	#RotyMat=numpy.array([[0,0,-1,0],[0,1,0,0],[1,0,0,0],[0,0,0,1]])
	#SolMat=numpy.array([[0,0,0,0],[0,0,0,0],[0,0,0,0],[0,0,0,0]])
	#SolMat=RotyMat*RotxMat*homoMat
	'''
	Calculate the inverse kinematics given the target rotation/position and
	the list of current joint angles:
	'''
	#print("homoMat is:  ")
	#print(homoMat)
	#print(SolMat)
	#print(jointAngles)
	#try:
		#targetJointAngles = kf.ikine(homoMat, jointAngles)
	#except ValueError:
		#print("ERROR: Position out of Range")
		#return 0		
	#if len(targetJointAngles) != 0:
	if len(jointAngles) != 0:		
		# We have a valid solution!  Move the Powerball to this location: 	 
		# Generate the trajectory message to send to the Powerball:
		# End code simulation
		# Code real robot
		#targetJointAngles = targetJointAngles[:6]
		jointAngles.append(req.gripper)
		#trajectory=jointAngles
		#trajectory.append(1.0)
		# Encapsulate the targetJointAngles into a trajectory:
		#traj = [targetJointAngles]
		traj = [jointAngles]
		#traj.append(gripper)
		traj_msg = JointTrajectory()
		traj_msg.header.stamp = rospy.Time.now() + rospy.Duration(0.5)
		traj_msg.joint_names = ['arm_1_joint', 'arm_2_joint', 'arm_3_joint', 'arm_4_joint', 'arm_5_joint', 'arm_6_joint','pg70_finger_left_joint']
		point_nr = 0
		for point in traj:	
			print(point)	
			#Position only in simulation
			#position.append((point))
			point_nr += 1
			print("Point num %d " % point_nr)
			point_msg = JointTrajectoryPoint()
			point_msg.positions = point
			point_msg.velocities = [0.0, 0.0, 0.0 ,0.0, 0.0 ,0.0, 0.1]
			point_msg.time_from_start = rospy.Duration(3 * point_nr)
			traj_msg.points.append(point_msg)
		action_server_name = '/arm/joint_trajectory_controller/follow_joint_trajectory'
		client = actionlib.SimpleActionClient(action_server_name, FollowJointTrajectoryAction)
		if not client.wait_for_server(rospy.Duration(5)):
			print("Action server not ready within timeout.  Aborting...")
			#ah.set_failed(4)
			#return ah
			return 0
		else:
			print("Action server ready for Coordinate API Request")
		client_goal = FollowJointTrajectoryGoal()		
		client_goal.trajectory = traj_msg
		client.send_goal(client_goal)
		print("goal send")
		#ah.set_client(client)	
		#ah.wait_inside()
	return 1
Пример #7
0
def powerball_remote():

    ah = simple_script_server.action_handle("move", "arm", "home", False,
                                            False)
    if False:
        return ah
    else:
        ah.set_active()

    # Ask the user to input the desired joint angles:
    print(
        "Joint 1 is the proximal joint (the base), Joint 6 is the distal joint (the wrist)"
    )
    joint1 = float(input("Please enter the desired angle for Joint 1: "))
    joint2 = float(input("Please enter the desired angle for Joint 2: "))
    joint3 = float(input("Please enter the desired angle for Joint 3: "))
    joint4 = float(input("Please enter the desired angle for Joint 4: "))
    joint5 = float(input("Please enter the desired angle for Joint 5: "))
    joint6 = float(input("Please enter the desired angle for Joint 6: "))

    # This list holds the joint angles:
    jointAngles = [joint1, joint2, joint3, joint4, joint5, joint6]

    # Encapsulate the jointAngles in another list (the trajectory):
    traj = [jointAngles]

    # Generate the trajectory message to send:
    traj_msg = JointTrajectory()
    traj_msg.header.stamp = rospy.Time.now() + rospy.Duration(0.5)
    traj_msg.joint_names = [
        'arm_1_joint', 'arm_2_joint', 'arm_3_joint', 'arm_4_joint',
        'arm_5_joint', 'arm_6_joint'
    ]
    point_nr = 0

    for point in traj:
        point_nr += 1
        point_msg = JointTrajectoryPoint()
        point_msg.positions = point
        point_msg.velocities = [0] * 6
        point_msg.time_from_start = rospy.Duration(3 * point_nr)
        traj_msg.points.append(point_msg)

    # Send the message to the action server:
    action_server_name = '/arm_controller/follow_joint_trajectory'

    client = actionlib.SimpleActionClient(action_server_name,
                                          FollowJointTrajectoryAction)
    if not client.wait_for_server(rospy.Duration(5)):
        print("Action server not ready within timeout.  Aborting...")
        ah.set_failed(4)
        return ah
    else:
        print("Action server ready!")

    client_goal = FollowJointTrajectoryGoal()
    client_goal.trajectory = traj_msg
    client.send_goal(client_goal)
    ah.set_client(client)

    ah.wait_inside()
    return ah