Forward Dynamics of Variable Topology Mechanisms – The Case of Constraint Activation

Andreas Müller

Forward Dynamics of Variable Topology Mechanisms – The Case of Constraint Activation

Institute of Robotics

Research output: Chapter in Book/Report/Conference proceeding › Conference proceedings › peer-review

Abstract

Many mechanical systems exhibit changes in their kinematic topology altering the mobility. Ideal contact is the best known cause, but also stiction and controlled locking of parts of a mechanism lead to topology changes. The latter is becoming an important issue in human-machine interaction. Anticipating the dynamic behavior of variable topology mechanisms requires solving a non-smooth dynamic problem. The core challenge is a physically meaningful transition condition at the topology switching events. Such a condition is presented in this paper. Two versions are reported, one using projected motion equations in terms of redundant coordinates, and another one using the Voronets equations in terms of minimal coordinates. Their computational properties are discussed. Results are shown for joint locking of a 3R mechanisms.

Original language	English
Title of host publication	MULTIBODY DYNAMICS 2015, ECCOMAS Thematic Conference
Pages	184-195
Number of pages	12
Publication status	Published - Jun 2015

Fields of science

203015 Mechatronics
203022 Technical mechanics
202 Electrical Engineering, Electronics, Information Engineering
202035 Robotics
203013 Mechanical engineering

JKU Focus areas

Mechatronics and Information Processing

Cite this

@inproceedings{5a782db5b2004ceeb85f338e19a23c4f,

title = "Forward Dynamics of Variable Topology Mechanisms – The Case of Constraint Activation",

abstract = "Many mechanical systems exhibit changes in their kinematic topology altering the mobility. Ideal contact is the best known cause, but also stiction and controlled locking of parts of a mechanism lead to topology changes. The latter is becoming an important issue in human-machine interaction. Anticipating the dynamic behavior of variable topology mechanisms requires solving a non-smooth dynamic problem. The core challenge is a physically meaningful transition condition at the topology switching events. Such a condition is presented in this paper. Two versions are reported, one using projected motion equations in terms of redundant coordinates, and another one using the Voronets equations in terms of minimal coordinates. Their computational properties are discussed. Results are shown for joint locking of a 3R mechanisms.",

author = "Andreas M{\"u}ller",

year = "2015",

month = jun,

language = "English",

pages = "184--195",

booktitle = "MULTIBODY DYNAMICS 2015, ECCOMAS Thematic Conference",

}

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AU - Müller, Andreas

PY - 2015/6

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N2 - Many mechanical systems exhibit changes in their kinematic topology altering the mobility. Ideal contact is the best known cause, but also stiction and controlled locking of parts of a mechanism lead to topology changes. The latter is becoming an important issue in human-machine interaction. Anticipating the dynamic behavior of variable topology mechanisms requires solving a non-smooth dynamic problem. The core challenge is a physically meaningful transition condition at the topology switching events. Such a condition is presented in this paper. Two versions are reported, one using projected motion equations in terms of redundant coordinates, and another one using the Voronets equations in terms of minimal coordinates. Their computational properties are discussed. Results are shown for joint locking of a 3R mechanisms.

AB - Many mechanical systems exhibit changes in their kinematic topology altering the mobility. Ideal contact is the best known cause, but also stiction and controlled locking of parts of a mechanism lead to topology changes. The latter is becoming an important issue in human-machine interaction. Anticipating the dynamic behavior of variable topology mechanisms requires solving a non-smooth dynamic problem. The core challenge is a physically meaningful transition condition at the topology switching events. Such a condition is presented in this paper. Two versions are reported, one using projected motion equations in terms of redundant coordinates, and another one using the Voronets equations in terms of minimal coordinates. Their computational properties are discussed. Results are shown for joint locking of a 3R mechanisms.

M3 - Conference proceedings

SP - 184

EP - 195

BT - MULTIBODY DYNAMICS 2015, ECCOMAS Thematic Conference

ER -