Flatness-based control of a horizontally moving erected beam with a point mass

Mathias Bachmayer; Heinz Ulbrich; Joachim Rudolph

doi:10.1080/13873954.2010.537517

Flatness-based control of a horizontally moving erected beam with a point mass

Mathias Bachmayer, Heinz Ulbrich, Joachim Rudolph

Chair of Applied Mechanics

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

13 Scopus citations

Abstract

A mechanism consisting of a horizontallymoving cart that carries an erected flexible beam with a point mass - as occurring in placement machines or stacker cranes - is considered. An explicitly parametrized feed-forward control law is designed using a flatness-based approach. Nominally, this control law allows one to perform fast placement motions although avoiding residual oscillations at the arrival. The efficiency of this approach and sensitivity with respect to parametric uncertainties are investigated numerically using both finite element and finite difference models. An experimental set-up is presented and some experimental results demonstrate the usefulness of the approach.

Original language	English
Pages (from-to)	49-69
Number of pages	21
Journal	Mathematical and Computer Modelling of Dynamical Systems
Volume	17
Issue number	1
DOIs	https://doi.org/10.1080/13873954.2010.537517
State	Published - Feb 2011

Keywords

Euler-bernoulli beam
Flatness
Flexible robot
Trajectory tracking

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10.1080/13873954.2010.537517

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abstract = "A mechanism consisting of a horizontallymoving cart that carries an erected flexible beam with a point mass - as occurring in placement machines or stacker cranes - is considered. An explicitly parametrized feed-forward control law is designed using a flatness-based approach. Nominally, this control law allows one to perform fast placement motions although avoiding residual oscillations at the arrival. The efficiency of this approach and sensitivity with respect to parametric uncertainties are investigated numerically using both finite element and finite difference models. An experimental set-up is presented and some experimental results demonstrate the usefulness of the approach.",

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AB - A mechanism consisting of a horizontallymoving cart that carries an erected flexible beam with a point mass - as occurring in placement machines or stacker cranes - is considered. An explicitly parametrized feed-forward control law is designed using a flatness-based approach. Nominally, this control law allows one to perform fast placement motions although avoiding residual oscillations at the arrival. The efficiency of this approach and sensitivity with respect to parametric uncertainties are investigated numerically using both finite element and finite difference models. An experimental set-up is presented and some experimental results demonstrate the usefulness of the approach.

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KW - Trajectory tracking

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Flatness-based control of a horizontally moving erected beam with a point mass

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Keywords

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