Self-oscillation via locus of a perturbed relay system design (LPRS)

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

doi:10.1007/978-3-319-23303-1_4

Self-oscillation via locus of a perturbed relay system design (LPRS)

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

1 Scopus citations

Abstract

The Poincaré map considered above is a precise tool to find gains of the TRC. The drawback of this approach is in its complexity, which entails extensive computations. This chapter presents an alternative approach—based on the LPRS method, which in the solution of the analysis problem provides exact values of the parameters of self-excited oscillations and a precise solution of the input–output problem, when the plant is linear. Application of this method involved the use of specific computation formulas available within the LPRS method. Unlike other publications on the LPRS method that were focused on analysis, this chapter provides LPRS-based design of self-excited periodic motions. The experiments with inertia wheel pendulum are presented below to illustrate the results of this design.

Original language	English
Title of host publication	Systems and Control
Subtitle of host publication	Foundations and Applications
Publisher	Birkhauser
Pages	53-64
Number of pages	12
Edition	9783319233024
DOIs	https://doi.org/10.1007/978-3-319-23303-1_4
State	Published - 2015

Publication series

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

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10.1007/978-3-319-23303-1_4

Cite this

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abstract = "The Poincar{\'e} map considered above is a precise tool to find gains of the TRC. The drawback of this approach is in its complexity, which entails extensive computations. This chapter presents an alternative approach—based on the LPRS method, which in the solution of the analysis problem provides exact values of the parameters of self-excited oscillations and a precise solution of the input–output problem, when the plant is linear. Application of this method involved the use of specific computation formulas available within the LPRS method. Unlike other publications on the LPRS method that were focused on analysis, this chapter provides LPRS-based design of self-excited periodic motions. The experiments with inertia wheel pendulum are presented below to illustrate the results of this design.",

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Self-oscillation via locus of a perturbed relay system design (LPRS). / Aguilar, Luis T.; Boiko, Igor; Fridman, Leonid et al.
Systems and Control: Foundations and Applications. 9783319233024. ed. Birkhauser, 2015. p. 53-64 (Systems and Control: Foundations and Applications; No. 9783319233024).

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

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T1 - Self-oscillation via locus of a perturbed relay system design (LPRS)

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AU - Fridman, Leonid

AU - Iriarte, Rafael

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Self-oscillation via locus of a perturbed relay system design (LPRS)

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