Higher-order Taylor approximation of finite motions in mechanisms

J.J. de Jong; A Müller; J. L. Herder

doi:10.1017/S0263574718000462

Higher-order Taylor approximation of finite motions in mechanisms

J.J. de Jong, A Müller, J. L. Herder

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

5 Citations (Scopus)

Abstract

Higher-order derivatives of kinematic mappings give insight into the motion characteristics of complex mechanisms. Screw theory and its associated Lie group theory have been used to find these derivatives of loop closure equations up to an arbitrary order. In this paper, this is extended to the higher-order derivatives of the solution to these loop closure equations to provide an approximation of the finite motion of serial and parallel mechanisms. This recursive algorithm, consisting solely of matrix operations, relies on a simplified representation of the higher-order derivatives of open chains. The method is applied to a serial, a multi-DOF parallel, and an overconstrained mechanism. In all cases, adequate approximation is obtained over a large portion of the workspace.

Original language	English
Pages (from-to)	1190-1201
Journal	Robotica
Volume	37 (2019)
Issue number	7
DOIs	https://doi.org/10.1017/S0263574718000462
Publication status	Published - 2018

Keywords

5-bar mechanism
Bennet linkage
Higher-order kinematics
Screw theory
Taylor approximation

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abstract = "Higher-order derivatives of kinematic mappings give insight into the motion characteristics of complex mechanisms. Screw theory and its associated Lie group theory have been used to find these derivatives of loop closure equations up to an arbitrary order. In this paper, this is extended to the higher-order derivatives of the solution to these loop closure equations to provide an approximation of the finite motion of serial and parallel mechanisms. This recursive algorithm, consisting solely of matrix operations, relies on a simplified representation of the higher-order derivatives of open chains. The method is applied to a serial, a multi-DOF parallel, and an overconstrained mechanism. In all cases, adequate approximation is obtained over a large portion of the workspace.",

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AU - de Jong, J.J.

AU - Müller, A

AU - Herder, J. L.

PY - 2018

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N2 - Higher-order derivatives of kinematic mappings give insight into the motion characteristics of complex mechanisms. Screw theory and its associated Lie group theory have been used to find these derivatives of loop closure equations up to an arbitrary order. In this paper, this is extended to the higher-order derivatives of the solution to these loop closure equations to provide an approximation of the finite motion of serial and parallel mechanisms. This recursive algorithm, consisting solely of matrix operations, relies on a simplified representation of the higher-order derivatives of open chains. The method is applied to a serial, a multi-DOF parallel, and an overconstrained mechanism. In all cases, adequate approximation is obtained over a large portion of the workspace.

AB - Higher-order derivatives of kinematic mappings give insight into the motion characteristics of complex mechanisms. Screw theory and its associated Lie group theory have been used to find these derivatives of loop closure equations up to an arbitrary order. In this paper, this is extended to the higher-order derivatives of the solution to these loop closure equations to provide an approximation of the finite motion of serial and parallel mechanisms. This recursive algorithm, consisting solely of matrix operations, relies on a simplified representation of the higher-order derivatives of open chains. The method is applied to a serial, a multi-DOF parallel, and an overconstrained mechanism. In all cases, adequate approximation is obtained over a large portion of the workspace.

KW - 5-bar mechanism

KW - Bennet linkage

KW - Higher-order kinematics

KW - Screw theory

KW - Taylor approximation

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DO - 10.1017/S0263574718000462

M3 - Article

AN - SCOPUS:85049323944

SN - 0263-5747

VL - 37 (2019)

SP - 1190

EP - 1201

JO - Robotica

JF - Robotica

IS - 7

ER -

Higher-order Taylor approximation of finite motions in mechanisms

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Keywords

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