6533b835fe1ef96bd129ec24

RESEARCH PRODUCT

Compensation of Nonlinear Torsion in Flexible Joint Robots: Comparison of Two Approaches

Michael Ruderman

subject

0209 industrial biotechnologyComputer science020208 electrical & electronic engineeringTorsion (mechanics)Systems and Control (eess.SY)02 engineering and technologyPlanar manipulatorInverse dynamicsNonlinear system020901 industrial engineering & automationControl and Systems EngineeringControl theoryFOS: Electrical engineering electronic engineering information engineering0202 electrical engineering electronic engineering information engineeringTrajectoryComputer Science - Systems and ControlRobotTorqueElectrical and Electronic EngineeringManipulator

description

Flexible joint robots, in particularly those which are equipped with harmonic-drive gears, can feature elasticities with hysteresis. Under heavy loads and large joint torques the hysteresis lost motion can lead to significant errors of tracking and positioning of the robotic links. In this paper, two approaches for compensating the nonlinear joint torsion with hysteresis are described and compared with each other. Both methods assume the measured signals available only on the motor side of joint transmissions. The first approach assumes a rigid-link manipulator model and transforms the desired link trajectory into that of the motor drives by using the inverse dynamics and inverse hysteresis map. The second approach relies on the modeling of motor drives and inverse hysteresis and uses the generalized momenta when predicting the joint torsion. Both methods are discussed in details along with a numerical example of two-link planar manipulator under gravity.

yearjournalcountryeditionlanguage
2015-07-25IEEE Transactions on Industrial Electronics
https://doi.org/10.1109/tie.2016.2574299