Stretch ROS driver offers a FollowJointTrajectory
action service for its arm. Within this tutorial we will have a simple FollowJointTrajectory command sent to a Stretch robot to execute.
Begin by running the following command in the terminal in a terminal.
# Terminal 1
roslaunch stretch_core stretch_driver.launch
Switch the mode to position mode using a rosservice call. Then run the stow command node.
# Terminal 2
rosservice call /switch_to_position_mode
cd catkin_ws/src/stretch_tutorials/src/
python stow_command.py
This will send a FollowJointTrajectory
command to stow Stretch's arm.
#!/usr/bin/env python
import rospy
from control_msgs.msg import FollowJointTrajectoryGoal
from trajectory_msgs.msg import JointTrajectoryPoint
import hello_helpers.hello_misc as hm
import time
class StowCommand(hm.HelloNode):
'''
A class that sends a joint trajectory goal to stow the Stretch's arm.
'''
def __init__(self):
hm.HelloNode.__init__(self)
def issue_stow_command(self):
'''
Function that makes an action call and sends stow postion goal.
:param self: The self reference.
'''
stow_point = JointTrajectoryPoint()
stow_point.time_from_start = rospy.Duration(0.000)
stow_point.positions = [0.2, 0.0, 3.4]
trajectory_goal = FollowJointTrajectoryGoal()
trajectory_goal.trajectory.joint_names = ['joint_lift', 'wrist_extension', 'joint_wrist_yaw']
trajectory_goal.trajectory.points = [stow_point]
trajectory_goal.trajectory.header.stamp = rospy.Time(0.0)
trajectory_goal.trajectory.header.frame_id = 'base_link'
self.trajectory_client.send_goal(trajectory_goal)
rospy.loginfo('Sent stow goal = {0}'.format(trajectory_goal))
self.trajectory_client.wait_for_result()
def main(self):
'''
Function that initiates stow_command function.
:param self: The self reference.
'''
hm.HelloNode.main(self, 'stow_command', 'stow_command', wait_for_first_pointcloud=False)
rospy.loginfo('stowing...')
self.issue_stow_command()
time.sleep(2)
if __name__ == '__main__':
try:
node = StowCommand()
node.main()
except KeyboardInterrupt:
rospy.loginfo('interrupt received, so shutting down')
Now let's break the code down.
#!/usr/bin/env python
Every Python ROS Node will have this declaration at the top. The first line makes sure your script is executed as a Python script.
import rospy
from control_msgs.msg import FollowJointTrajectoryGoal
from trajectory_msgs.msg import JointTrajectoryPoint
import hello_helpers.hello_misc as hm
import time
You need to import rospy if you are writing a ROS Node. Import the FollowJointTrajectoryGoal from the control_msgs.msg package to control the Stretch robot. Import JointTrajectoryPoint from the trajectory_msgs package to define robot trajectories. The hello_helpers package consists of a module the provides various Python scripts used across stretch_ros. In this instance we are importing the hello_misc script.
class StowCommand(hm.HelloNode):
def __init__(self):
hm.HelloNode.__init__(self)
The StowCommand
class inherits the HelloNode
class from hm
and is initialized.
def issue_stow_command(self):
stow_point = JointTrajectoryPoint()
stow_point.time_from_start = rospy.Duration(0.000)
stow_point.positions = [0.2, 0.0, 3.4]
The issue_stow_command()
is the name of the function that will stow Stretch's arm. Within the function, we set stow_point as a JointTrajectoryPoint
and provide desired positions (in meters). These are the positions of the lift, wrist extension, and yaw of the wrist, respectively. These are defined in the next set of the code.
trajectory_goal = FollowJointTrajectoryGoal()
trajectory_goal.trajectory.joint_names = ['joint_lift', 'wrist_extension', 'joint_wrist_yaw']
trajectory_goal.trajectory.points = [stow_point]
trajectory_goal.trajectory.header.stamp = rospy.Time(0.0)
trajectory_goal.trajectory.header.frame_id = 'base_link'
Set trajectory_goal as a FollowJointTrajectoryGoal
and define the joint names as a list. Then trajectory_goal.trajectory.points
is defined by the positions set in stow_point. Specify the coordinate frame that we want (base_link) and set the time to be now.
self.trajectory_client.send_goal(trajectory_goal)
rospy.loginfo('Sent stow goal = {0}'.format(trajectory_goal))
self.trajectory_client.wait_for_result()
Make the action call and send the goal. The last line of code waits for the result before it exits the python script.
def main(self):
hm.HelloNode.main(self, 'stow_command', 'stow_command', wait_for_first_pointcloud=False)
rospy.loginfo('stowing...')
self.issue_stow_command()
time.sleep(2)
Create a function, main()
, to do all of the setup for the hm.HelloNode
class and issue the stow command.
if __name__ == '__main__':
try:
node = StowCommand()
node.main()
except KeyboardInterrupt:
rospy.loginfo('interrupt received, so shutting down')
Declare object, node, from the StowCommand()
class. Then run the main()
function.
Begin by running the following command in the terminal in a terminal.
# Terminal 1
roslaunch stretch_core stretch_driver.launch
Switch the mode to position mode using a rosservice call. Then run the multipoint command node.
# Terminal 2
rosservice call /switch_to_position_mode
cd catkin_ws/src/stretch_tutorials/src/
python multipoint_command.py
This will send a list of JointTrajectoryPoint
message types to move Stretch's arm.
#!/usr/bin/env python
import rospy
import time
from control_msgs.msg import FollowJointTrajectoryGoal
from trajectory_msgs.msg import JointTrajectoryPoint
import hello_helpers.hello_misc as hm
class MultiPointCommand(hm.HelloNode):
"""
A class that sends multiple joint trajectory goals to the stretch robot.
"""
def __init__(self):
hm.HelloNode.__init__(self)
def issue_multipoint_command(self):
"""
Function that makes an action call and sends multiple joint trajectory goals
to the joint_lift, wrist_extension, and joint_wrist_yaw.
:param self: The self reference.
"""
point0 = JointTrajectoryPoint()
point0.positions = [0.2, 0.0, 3.4]
point0.velocities = [0.2, 0.2, 2.5]
point0.accelerations = [1.0, 1.0, 3.5]
point1 = JointTrajectoryPoint()
point1.positions = [0.3, 0.1, 2.0]
point2 = JointTrajectoryPoint()
point2.positions = [0.5, 0.2, -1.0]
point3 = JointTrajectoryPoint()
point3.positions = [0.6, 0.3, 0.0]
point4 = JointTrajectoryPoint()
point4.positions = [0.8, 0.2, 1.0]
point5 = JointTrajectoryPoint()
point5.positions = [0.5, 0.1, 0.0]
trajectory_goal = FollowJointTrajectoryGoal()
trajectory_goal.trajectory.joint_names = ['joint_lift', 'wrist_extension', 'joint_wrist_yaw']
trajectory_goal.trajectory.points = [point0, point1, point2, point3, point4, point5]
trajectory_goal.trajectory.header.stamp = rospy.Time(0.0)
trajectory_goal.trajectory.header.frame_id = 'base_link'
self.trajectory_client.send_goal(trajectory_goal)
rospy.loginfo('Sent list of goals = {0}'.format(trajectory_goal))
self.trajectory_client.wait_for_result()
def main(self):
"""
Function that initiates the multipoint_command function.
:param self: The self reference.
"""
hm.HelloNode.main(self, 'multipoint_command', 'multipoint_command', wait_for_first_pointcloud=False)
rospy.loginfo('issuing multipoint command...')
self.issue_multipoint_command()
time.sleep(2)
if __name__ == '__main__':
try:
node = MultiPointCommand()
node.main()
except KeyboardInterrupt:
rospy.loginfo('interrupt received, so shutting down')
Seeing that there are similarities between the multipoint and stow command nodes, we will only breakdown the different components of the multipoint_command node.
point0 = JointTrajectoryPoint()
point0.positions = [0.2, 0.0, 3.4]
Set point0 as a JointTrajectoryPoint
and provide desired positions. These are the positions of the lift, wrist extension, and yaw of the wrist, respectively. The lift and wrist extension positions are expressed in meters, where as the wrist yaw is in radians.
point0.velocities = [0.2, 0.2, 2.5]
Provide desired velocity of the lift (m/s), wrist extension (m/s), and wrist yaw (rad/s) for point0.
point0.accelerations = [1.0, 1.0, 3.5]
Provide desired accelerations of the lift (m/s^2), wrist extension (m/s^2), and wrist yaw (rad/s^2).
IMPORTANT NOTE: The lift and wrist extension can only go up to 0.2 m/s. If you do not provide any velocities or accelerations for the lift or wrist extension, then they go to their default values. However, the Velocity and Acceleration of the wrist yaw will stay the same from the previous value unless updated.
trajectory_goal = FollowJointTrajectoryGoal()
trajectory_goal.trajectory.joint_names = ['joint_lift', 'wrist_extension', 'joint_wrist_yaw']
trajectory_goal.trajectory.points = [point0, point1, point2, point3, point4, point5]
trajectory_goal.trajectory.header.stamp = rospy.Time(0.0)
trajectory_goal.trajectory.header.frame_id = 'base_link'
Set trajectory_goal as a FollowJointTrajectoryGoal
and define the joint names as a list. Then trajectory_goal.trajectory.points
is defined by a list of the 6 points. Specify the coordinate frame that we want (base_link) and set the time to be now.
You can also actuate a single joint for the Stretch. Below are the list of joints and their position limit.
############################# JOINT LIMITS #############################
joint_lift: lower_limit = 0.15, upper_limit = 1.10 # in meters
wrist_extension: lower_limit = 0.00, upper_limit = 0.50 # in meters
joint_wrist_yaw: lower_limit = -1.75, upper_limit = 4.00 # in radians
joint_head_pan: lower_limit = -4.10, upper_limit = 1.60 # in radians
joint_head_tilt: lower_limit = -1.60, upper_limit = 0.40 # in radians
joint_gripper_finger_left: lower_limit = -0.35, upper_limit = 0.165 # in radians
# INCLUDED JOINT IN MANIPULATION MODE
joint_mobile_base_translation: lower_limit = -0.50, upper_limit = 0.50 # in radians
# INCLUDED JOINTS IN POSITION MODE
translate_mobile_base: No lower or upper limit. Defined by a step size in meters
rotate_mobile_base: No lower or upper limit. Defined by a step size in radians
########################################################################
Begin by running the following command in the terminal in a terminal.
# Terminal 1
roslaunch stretch_core stretch_driver.launch
Switch the mode to position mode using a rosservice call. Then run the single joint actuator node.
# Terminal 2
rosservice call /switch_to_position_mode
cd catkin_ws/src/stretch_tutorials/src/
python single_joint_actuator.py
This will send a list of JointTrajectoryPoint
message types to move Stretch's arm.
The joint, joint_gripper_finger_left, is only needed when actuating the gripper.
#!/usr/bin/env python
import rospy
import time
from control_msgs.msg import FollowJointTrajectoryGoal
from trajectory_msgs.msg import JointTrajectoryPoint
import hello_helpers.hello_misc as hm
class SingleJointActuator(hm.HelloNode):
"""
A class that sends multiple joint trajectory goals to a single joint.
"""
def __init__(self):
hm.HelloNode.__init__(self)
def issue_command(self):
"""
Function that makes an action call and sends joint trajectory goals
to a single joint
:param self: The self reference.
"""
trajectory_goal = FollowJointTrajectoryGoal()
trajectory_goal.trajectory.joint_names = ['joint_head_pan']
point0 = JointTrajectoryPoint()
point0.positions = [0.65]
# point1 = JointTrajectoryPoint()
# point1.positions = [0.5]
trajectory_goal.trajectory.points = [point0]#, point1]
trajectory_goal.trajectory.header.stamp = rospy.Time(0.0)
trajectory_goal.trajectory.header.frame_id = 'base_link'
self.trajectory_client.send_goal(trajectory_goal)
rospy.loginfo('Sent goal = {0}'.format(trajectory_goal))
self.trajectory_client.wait_for_result()
def main(self):
"""
Function that initiates the issue_command function.
:param self: The self reference.
"""
hm.HelloNode.main(self, 'issue_command', 'issue_command', wait_for_first_pointcloud=False)
rospy.loginfo('issuing command...')
self.issue_command()
time.sleep(2)
if __name__ == '__main__':
try:
node = SingleJointActuator()
node.main()
except KeyboardInterrupt:
rospy.loginfo('interrupt received, so shutting down')
Since the code is quite similar to the multipoint_command code, we will only review the parts that differ.
Now let's break the code down.
trajectory_goal = FollowJointTrajectoryGoal()
trajectory_goal.trajectory.joint_names = ['joint_head_pan']
Here we only input joint name that we want to actuate. In this instance, we will actuate the joint_head_pan.
point0 = JointTrajectoryPoint()
point0.positions = [0.65]
# point1 = JointTrajectoryPoint()
# point1.positions = [0.5]
Set point0 as a JointTrajectoryPoint
and provide desired position. You also have the option to send multiple point positions rather than one.
trajectory_goal.trajectory.points = [point0]#, point1]
trajectory_goal.trajectory.header.stamp = rospy.Time(0.0)
trajectory_goal.trajectory.header.frame_id = 'base_link'
Set trajectory_goal as a FollowJointTrajectoryGoal
and define the joint names as a list. Then trajectory_goal.trajectory.points
set by your list of points. Specify the coordinate frame that we want (base_link) and set the time to be now.
Next Tutorial: Perception