With the recent advancement in the field of robotics, Robots have become versatile in size and form and can be programmed to do the most mundane as well as the most sophisticated and specialised tasks.
Inverse kinematics is one of the key techniques in automation and working of robots and deep understanding of the same is required for designing algorithms for strenuous tasks.
The robot use algorithm which uses the concept of Inverse-Kinematics for achieving the basic task of drawing. Hence the simulated robot (Picasso) can draw basic shapes like: circle, square, pentagon and complex figures like: cat, flower etc.
Contributors : Ashwin V , Vishal Menon
This example uses the ROBOTIS OpenManipulator Chain robot to demonstrate the design of manipulator algorithms using MATLAB and Simulink.
This submission depends on files from the following Git repository: https://github.com/ROBOTIS-GIT/open_manipulator.
The startupExample script will attempt to download them, but if there are
any errors there is a pre-imported model of the robot manipulator so you can
still run the examples.
Forward and inverse kinematics are demonstrated using functions available within MATLAB as well as supervisory logic implemented in Stateflow.
Robot geometries are imported to MATLAB using the "importrobot" function and to Simscape Multibody using the "smimport" function. For more information on these functions check the associated documentation pages.
To learn more, refer to these videos:
-
openManipulatorIK.mThis file shows how to import a robot from a URDF description and use the generated rigid body tree representation to implement forward and inverse kinematics algorithms
-
openManipulatorWaypointTracking.slxThis Simulink model uses Simscape Multibody as the environment and shows how to integrate the forward and inverse kinematics algorithms into Simulink to be used with Stateflow supervisory logic to pickup a ball, follow a trajectory, and finally drop the ball.
-
openManipulatorBallTracking.slxThis Simulink model builds on the waypoint tracking model and adds simple perception to track and catch a moving ball using a polynomial extrapolation of the ball trajectory.
-
openManipulatorTorqueCtrlCfg.slxThis Simulink model tests the closed-loop torque controller, in configuration space, using joint position commands (no inverse kinematics or supervisory logic).
-
openManipulatorTorqueCtrlTask.slxThis Simulink model tests the closed-loop torque controller, in task space, using end effector position commands (no supervisory logic).
This submission was last updated and tested using MATLAB R2019b.
The required toolboxes to run all examples are:
- MATLAB
- Simulink
- Robotics System Toolbox
- Simscape
- Simscape Multibody
- Stateflow