Computer simulation of the inverse dynamics of a three-cable suspension manipulator.

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Title: Computer simulation of the inverse dynamics of a three-cable suspension manipulator.
Authors: Yang, Yinping1 (AUTHOR) yinping.yang@bjut.edu.cn, Betsch, Peter2 (AUTHOR) peter.betsch@kit.edu, Zhang, Wei1,3 (AUTHOR) sandyzhang9@163.com
Source: Multibody System Dynamics. May2026, Vol. 67 Issue 1, p193-219. 27p.
Subjects: Differential-algebraic equations, Constraint algorithms, Robotic trajectory control, Dynamic simulation, Manipulators (Machinery)
Abstract: A three-cable suspension manipulator is an underactuated mechanical system designed to transport a payload precisely within a workspace. This study addresses its inverse dynamics problem using servo constraints, leading to a high-index system of differential-algebraic equations (DAEs). To overcome the numerical challenges, the index reduction by minimal extension method is applied to the servo constraint problem of the differentially flat system. The proposed approach facilitates precise trajectory tracking and serves as a foundation for implementing feedforward and feedback control strategies in future developments. [ABSTRACT FROM AUTHOR]
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Database: Engineering Source
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Abstract:A three-cable suspension manipulator is an underactuated mechanical system designed to transport a payload precisely within a workspace. This study addresses its inverse dynamics problem using servo constraints, leading to a high-index system of differential-algebraic equations (DAEs). To overcome the numerical challenges, the index reduction by minimal extension method is applied to the servo constraint problem of the differentially flat system. The proposed approach facilitates precise trajectory tracking and serves as a foundation for implementing feedforward and feedback control strategies in future developments. [ABSTRACT FROM AUTHOR]
ISSN:13845640
DOI:10.1007/s11044-025-10121-w