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RESEARCH PRODUCT
Robust and Decoupled Position and Stiffness Control for Electrically-Driven Articulated Soft Robots
Salvatore PedoneMaja TrumicKosta JovanovicAdriano Fagiolinisubject
Human-Computer InteractionControl and OptimizationSettore ING-INF/04 - AutomaticaArtificial IntelligenceControl and Systems EngineeringMechanical EngineeringBiomedical EngineeringComputer Vision and Pattern RecognitionRobust/adaptive control flexible robotics compliance and impedance control.Computer Science Applicationsdescription
The control of articulated soft robots, i.e. robots with flexible joints and rigid links, presents a challenge due to their in- trinsic elastic elements and nonlinear force-deflection dependency. This letter first proposes a discrete-time delayed unknown input- state observer based on a nominal robot model that reconstructs the total torque disturbance vector, resulting from the imperfect knowledge of the elastic torque characteristic, external torques, and other model uncertainties. Then, it introduces a robust controller, that actively compensates for the estimated uncertainty and allows bounded stability for the tracking of independent link position and joint stiffness reference signals. The convergence of the disturbance estimator and the overall system’s stability in closed loop is proven analytically, while the effectiveness of the proposed control design is first evaluated in simulations with respect to large uncertainty conditions, and then demonstrated through experiments on a real multi-degree-of-freedom articulated soft robot.
| year | journal | country | edition | language |
|---|---|---|---|---|
| 2022-10-01 | IEEE Robotics and Automation Letters |