LUP Student Papers

Haptic Interface for a Contact Force Controlled Robot

• Mark

Abstract

The use of haptics in teleoperation and robotics can help the human operator to greatly improve the performance. This master thesis presents a haptic interface between a haptic device, a Phantom Premium A, and an industrial robot, an IRB140B, on which a force sensor was mounted. This will enable a human operator controlling the Phantom to get information about the environment surrounding the IRB140B through the sense of touch. An impedance controller is also introduced in order to avoid too large contact forces in the robot-environment interaction and to obtain a good behavior of the Phantom. The haptic interface was achieved by deriving a general mathematical mapping from the states of a haptic device to these of an industrial robot and... (More)

The use of haptics in teleoperation and robotics can help the human operator to greatly improve the performance. This master thesis presents a haptic interface between a haptic device, a Phantom Premium A, and an industrial robot, an IRB140B, on which a force sensor was mounted. This will enable a human operator controlling the Phantom to get information about the environment surrounding the IRB140B through the sense of touch. An impedance controller is also introduced in order to avoid too large contact forces in the robot-environment interaction and to obtain a good behavior of the Phantom. The haptic interface was achieved by deriving a general mathematical mapping from the states of a haptic device to these of an industrial robot and by implementing that mapping for the Phantom and the IRB140B. To handle the Phantom e.g., the force feedback, a C++ program was developed. The program also features a virtual representation of the IRB140B. The impedance controller for the robot-environment interaction was implemented in Matlab's Simulink. That controller was translated into C code and downloaded to the axis computer of the IRB140B. Everything was connected via a TCP/IP network. Tuning the impedance controller resulted in a stable teleoperation system with haptic feedback to the human operator for the materials touched by the IRB140Be (Less)