Invariant subspaces for grasping internal forces and non-interacting force-motion control in robotic manipulation

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Invariant subspaces for grasping internal forces and non-interacting force-motion control in robotic manipulation. / Mercorelli, P.
in: Kybernetika, Jahrgang 48, Nr. 6, 01.01.2012, S. 1229-1249.

Publikation: Beiträge in ZeitschriftenZeitschriftenaufsätzeForschungbegutachtet

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@article{d713cf112dee40beb62cde9b7a75e5d3,
title = "Invariant subspaces for grasping internal forces and non-interacting force-motion control in robotic manipulation",
abstract = "This paper presents a parametrization of a feed-forward control based on structures of subspaces for a non-interacting regulation. With advances in technological development, robotics is increasingly being used in many industrial sectors, including medical applications (e. g., micromanipulation of internal tissues or laparoscopy). Typical problems in robotics and general mechanisms may be mathematically formalized and analyzed, resulting in outcomes so general that it is possible to speak of structural properties in robotic manipulation and mechanisms. This work shows an explicit formula for the reachable internal contact forces of a general manipulation system. The main contribution of the paper consists of investigating the design of a feed-forward force-motion control which, together with a feedback structure, realizes a decoupling force-motion control. A generalized linear model is used to perform a careful analysis, resulting in the proposed general geometric structure for the study of mechanisms. In particular, a lemma and a theorem are presented which offer a parametrization of a feed-forward control for a task-oriented choice of input subspaces. The existence of these input subspaces is a necessary condition for the structural non-interaction property. A simulation example in which the subspaces and the control structure are explicitly calculated is shown and widely explicated.",
keywords = "Engineering, Regelungstechnik, Antriebstechnik, Matrices, Internal forces, Manipulators, Subspaces",
author = "P. Mercorelli",
note = "Copyright 2013 Elsevier B.V., All rights reserved.",
year = "2012",
month = jan,
day = "1",
language = "English",
volume = "48",
pages = "1229--1249",
journal = "Kybernetika",
issn = "0023-5954",
publisher = "Academy of Sciences of the Czech Republic",
number = "6",

}

RIS

TY - JOUR

T1 - Invariant subspaces for grasping internal forces and non-interacting force-motion control in robotic manipulation

AU - Mercorelli, P.

N1 - Copyright 2013 Elsevier B.V., All rights reserved.

PY - 2012/1/1

Y1 - 2012/1/1

N2 - This paper presents a parametrization of a feed-forward control based on structures of subspaces for a non-interacting regulation. With advances in technological development, robotics is increasingly being used in many industrial sectors, including medical applications (e. g., micromanipulation of internal tissues or laparoscopy). Typical problems in robotics and general mechanisms may be mathematically formalized and analyzed, resulting in outcomes so general that it is possible to speak of structural properties in robotic manipulation and mechanisms. This work shows an explicit formula for the reachable internal contact forces of a general manipulation system. The main contribution of the paper consists of investigating the design of a feed-forward force-motion control which, together with a feedback structure, realizes a decoupling force-motion control. A generalized linear model is used to perform a careful analysis, resulting in the proposed general geometric structure for the study of mechanisms. In particular, a lemma and a theorem are presented which offer a parametrization of a feed-forward control for a task-oriented choice of input subspaces. The existence of these input subspaces is a necessary condition for the structural non-interaction property. A simulation example in which the subspaces and the control structure are explicitly calculated is shown and widely explicated.

AB - This paper presents a parametrization of a feed-forward control based on structures of subspaces for a non-interacting regulation. With advances in technological development, robotics is increasingly being used in many industrial sectors, including medical applications (e. g., micromanipulation of internal tissues or laparoscopy). Typical problems in robotics and general mechanisms may be mathematically formalized and analyzed, resulting in outcomes so general that it is possible to speak of structural properties in robotic manipulation and mechanisms. This work shows an explicit formula for the reachable internal contact forces of a general manipulation system. The main contribution of the paper consists of investigating the design of a feed-forward force-motion control which, together with a feedback structure, realizes a decoupling force-motion control. A generalized linear model is used to perform a careful analysis, resulting in the proposed general geometric structure for the study of mechanisms. In particular, a lemma and a theorem are presented which offer a parametrization of a feed-forward control for a task-oriented choice of input subspaces. The existence of these input subspaces is a necessary condition for the structural non-interaction property. A simulation example in which the subspaces and the control structure are explicitly calculated is shown and widely explicated.

KW - Engineering

KW - Regelungstechnik

KW - Antriebstechnik

KW - Matrices

KW - Internal forces

KW - Manipulators

KW - Subspaces

UR - http://www.scopus.com/inward/record.url?scp=84871839117&partnerID=8YFLogxK

M3 - Journal articles

AN - SCOPUS:84871839117

VL - 48

SP - 1229

EP - 1249

JO - Kybernetika

JF - Kybernetika

SN - 0023-5954

IS - 6

ER -

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