A unified force control approach to autonomous underwater manipulation

Yong  Cui; Nilanjan  Sarkar

doi:10.1017/S026357470000309X

Abstract

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A unified force control scheme for an autonomous underwater robotic system is proposed in this paper. This robotic system is composed of a six degree-of-freedom autonomous underwater vehicle (AUV) and a robotic arm that is mounted on the AUV. A unified force control approach, which combines impedance control with hybrid position/force control by means of fuzzy switching to perform autonomous underwater manipulation, is presented in this paper. This controller requires a dynamic model of the underwater vehicle-manipulator system. However, it does not require any model of the environment and therefore will have the potential to be useful in underwater tasks where the environment is generally unknown. The proposed approach combines the advantages of impedance control with hybrid control so that both smooth contact transition and force trajectory tracking can be achieved. In the absence of any functional autonomous underwater vehicle-manipulator system that can be used to verify the proposed controller, extensive computer simulations are performed and the results are presented in the paper.

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A unified force control approach to autonomous underwater manipulation

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This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Article contents

A unified force control approach to autonomous underwater manipulation

Abstract

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