Design, Kinematics, and Deployment of a Continuum Underwater Vehicle-Manipulator System

Justin Sitler; Long Wang

doi:10.1115/1.4066554

Design, Kinematics, and Deployment of a Continuum Underwater Vehicle-Manipulator System

Justin Sitler, Long Wang

Stevens Institute of Technology

Research output: Contribution to journal › Article › peer-review

Abstract

Underwater vehicle-manipulator systems (UVMSs) are underwater robots equipped with one or more manipulators to perform intervention missions. This article provides the mechanical, electrical, and software design of a novel UVMS equipped with a continuum manipulator, referred to as a continuum-UVMS. A kinematic model for the continuum-UVMS is derived in order to build an algorithm to resolve the robot's redundancy and generate joint space commands. Different methods to optimize the trajectory for specific tasks are proposed using both the weighted least norm solution and the gradient projection method. Kinematic simulation results are analyzed to assess the performance of the proposed algorithm. Finally, the continuum-UVMS is deployed in an experimental demonstration in which both teleoperation and autonomous control are tested for a given reference trajectory.

Original language	English
Article number	051001
Journal	Journal of Mechanisms and Robotics
Volume	17
Issue number	5
DOIs	https://doi.org/10.1115/1.4066554
State	Published - 1 May 2025

Keywords

and control of mechanical systems
continuum robots
kinematics
marine robotics
mechanisms and robots
redundancy resolution

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10.1115/1.4066554

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abstract = "Underwater vehicle-manipulator systems (UVMSs) are underwater robots equipped with one or more manipulators to perform intervention missions. This article provides the mechanical, electrical, and software design of a novel UVMS equipped with a continuum manipulator, referred to as a continuum-UVMS. A kinematic model for the continuum-UVMS is derived in order to build an algorithm to resolve the robot's redundancy and generate joint space commands. Different methods to optimize the trajectory for specific tasks are proposed using both the weighted least norm solution and the gradient projection method. Kinematic simulation results are analyzed to assess the performance of the proposed algorithm. Finally, the continuum-UVMS is deployed in an experimental demonstration in which both teleoperation and autonomous control are tested for a given reference trajectory.",

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Design, Kinematics, and Deployment of a Continuum Underwater Vehicle-Manipulator System

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