Generating self-oscillations in furuta pendulum

Luis T. Aguilar; Igor Boiko; Leonid Fridman; Rafael Iriarte

doi:10.1007/978-3-319-23303-1_7

Generating self-oscillations in furuta pendulum

Luis T. Aguilar, Igor Boiko, Leonid Fridman, Rafael Iriarte

Centro de Investigación y Desarrollo de Tecnología Digital (CITEDI)

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

Abstract

This chapter illustrates the DF, Poincaré maps, and LPRS to obtain the desired amplitude and frequency of SO of an experimental Furuta pendulum. The problem becomes more complicated when oscillations are around an open-loop unstable equilibrium point that corresponds to the upright position of the pendulum. Recalling that TRC design requires linear model of the plant, such linearization was made through Taylor expansion around an unstable equilibrium point. The experimental results illustrate motions at several velocities (frequency) and maximum position (amplitude), and then TRC supply, for generic SO of a wide range of frequencies.

Original language	English
Title of host publication	Systems and Control
Subtitle of host publication	Foundations and Applications
Publisher	Birkhauser
Pages	91-98
Number of pages	8
Edition	9783319233024
DOIs	https://doi.org/10.1007/978-3-319-23303-1_7
State	Published - 2015

Publication series

Name	Systems and Control: Foundations and Applications
Number	9783319233024
ISSN (Print)	2324-9749
ISSN (Electronic)	2324-9757

Keywords

Coulomb friction
Describe function
Equilibrium point
Homoclinic orbit
Periodic motion

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10.1007/978-3-319-23303-1_7

Cite this

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abstract = "This chapter illustrates the DF, Poincar{\'e} maps, and LPRS to obtain the desired amplitude and frequency of SO of an experimental Furuta pendulum. The problem becomes more complicated when oscillations are around an open-loop unstable equilibrium point that corresponds to the upright position of the pendulum. Recalling that TRC design requires linear model of the plant, such linearization was made through Taylor expansion around an unstable equilibrium point. The experimental results illustrate motions at several velocities (frequency) and maximum position (amplitude), and then TRC supply, for generic SO of a wide range of frequencies.",

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T1 - Generating self-oscillations in furuta pendulum

AU - Aguilar, Luis T.

AU - Boiko, Igor

AU - Fridman, Leonid

AU - Iriarte, Rafael

N1 - Publisher Copyright: © Springer International Publishing Switzerland 2015.

PY - 2015

Y1 - 2015

N2 - This chapter illustrates the DF, Poincaré maps, and LPRS to obtain the desired amplitude and frequency of SO of an experimental Furuta pendulum. The problem becomes more complicated when oscillations are around an open-loop unstable equilibrium point that corresponds to the upright position of the pendulum. Recalling that TRC design requires linear model of the plant, such linearization was made through Taylor expansion around an unstable equilibrium point. The experimental results illustrate motions at several velocities (frequency) and maximum position (amplitude), and then TRC supply, for generic SO of a wide range of frequencies.

AB - This chapter illustrates the DF, Poincaré maps, and LPRS to obtain the desired amplitude and frequency of SO of an experimental Furuta pendulum. The problem becomes more complicated when oscillations are around an open-loop unstable equilibrium point that corresponds to the upright position of the pendulum. Recalling that TRC design requires linear model of the plant, such linearization was made through Taylor expansion around an unstable equilibrium point. The experimental results illustrate motions at several velocities (frequency) and maximum position (amplitude), and then TRC supply, for generic SO of a wide range of frequencies.

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KW - Describe function

KW - Equilibrium point

KW - Homoclinic orbit

KW - Periodic motion

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T3 - Systems and Control: Foundations and Applications

SP - 91

EP - 98

BT - Systems and Control

PB - Birkhauser

ER -

Generating self-oscillations in furuta pendulum

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