Neuro-adaptive control in beating heart surgery based on the viscoelastic tissue model
Subject Areas : Robotic systemsSetareh Rezakhani 1 , Mehdi Aliyari Shoorehdeli 2 , Azam Ghasemi 3
1 - Department of Electrical Engineering, Islamic Azad University, Najafabad Branch
2 - Department of Electrical Engineering, Khajeh Nasirodin Toosi University, Tehran
3 - Islamic Azad University, Najafabad Branch
Keywords: Adaptive controller, motion compensation, force control, neuro, viscoelastic tissue model,
Abstract :
In this paper, the problem of 3D heart motion in beating heart surgery is resolved by proposing a parallel force-motion controller. Motion controller is designed based on neuro-adaptive approach to compensate 3D heart motion and deal with uncertainity in dynamic parameters, while an implicit force control is implemented by considering a viscoelastic tissue model. Stability analysis is proved through Lypanov’s stability theory and Barballet’s lemma. Simulation results, for D2M2 robot, which is done in nominal case and viscoelastic parameter mismatches demonstrate the robust performance of the controller.
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