Nonlinear Kalman Filtering for Force-Controlled Robot Tasks / by Tine Lefebvre, Herman Bruyninckx, Joris Schutter.

Por:

Lefebvre, Tine [autor]

Colaborador(es):

Tipo de material: Texto

TextoSeries Springer Tracts in Advanced Robotics ; 19Editor: Berlin, Heidelberg : Springer Berlin Heidelberg, 2005Descripción: xv, 265 páginas 86 ilustraciones Also available online. recurso en líneaTipo de contenido:

texto

Tipo de medio:

computadora

Tipo de portador:

recurso en línea

ISBN:

9783540315049

Formatos físicos adicionales: Edición impresa:: Sin títuloRecursos en línea:

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Contenidos:

Introduction -- Literature Survey: Autonomous Compliant Motion -- Literature Survey: Bayesian Probability Theory -- Kalman Filters for Nonlinear Systems -- The Non-Minimal State Kalman Filter -- Contact Modelling -- Geometrical Parameter Estimation and CF Recognition -- Experiment: A Cube-In-Corner Assembly -- Task Planning with Active Sensing -- General Conclusions.

Resumen: This monograph focuses on how to achieve more robot autonomy by means of reliable processing skills. "Nonlinear Kalman Filtering for Force-Controlled Robot Tasks " discusses the latest developments in the areas of contact modeling, nonlinear parameter estimation and task plan optimization for improved estimation accuracy. Kalman filtering techniques are applied to identify the contact state based on force sensing between a grasped object and the environment. The potential of this work is to be found not only for industrial robot operation in space, sub-sea or nuclear scenarios, but also for service robots operating in unstructured environments co-habited by humans where autonomous compliant tasks require active sensing.

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Springer eBooks

This monograph focuses on how to achieve more robot autonomy by means of reliable processing skills. "Nonlinear Kalman Filtering for Force-Controlled Robot Tasks " discusses the latest developments in the areas of contact modeling, nonlinear parameter estimation and task plan optimization for improved estimation accuracy. Kalman filtering techniques are applied to identify the contact state based on force sensing between a grasped object and the environment. The potential of this work is to be found not only for industrial robot operation in space, sub-sea or nuclear scenarios, but also for service robots operating in unstructured environments co-habited by humans where autonomous compliant tasks require active sensing.

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