bibtype J - Journal Article
ARLID 0508137
utime 20240103222512.2
mtime 20190909235959.9
SCOPUS 85071604891
WOS 000483030700001
DOI 10.1142/S0218127419300246
title (primary) (eng) Lateral Dynamics of Walking-Like Mechanical Systems and Their Chaotic Behavior
specification
page_count 29 s.
media_type P
serial
ARLID cav_un_epca*0256776
ISSN 0218-1274
title International Journal of Bifurcation and Chaos
volume_id 29
publisher
name World Scientific Publishing
keyword Hybrid system
keyword Walking robot
keyword Lateral dynamics
keyword Chaos
author (primary)
ARLID cav_un_auth*0101074
name1 Čelikovský
name2 Sergej
institution UTIA-B
full_dept (cz) Teorie řízení
full_dept (eng) Department of Control Theory
department (cz)
department (eng) TR
full_dept Department of Control Theory
fullinstit Ústav teorie informace a automatizace AV ČR, v. v. i.
author
ARLID cav_un_auth*0215855
name1 Lynnyk
name2 Volodymyr
institution UTIA-B
full_dept (cz) Teorie řízení
full_dept Department of Control Theory
department (cz)
department TR
full_dept Department of Control Theory
fullinstit Ústav teorie informace a automatizace AV ČR, v. v. i.
source
url http://library.utia.cas.cz/separaty/2019/TR/celikovsky-0508137.pdf
source
url https://www.worldscientific.com/doi/10.1142/S0218127419300246
cas_special
project
ARLID cav_un_auth*0347203
project_id GA17-04682S
agency GA ČR
country CZ
abstract (eng) A detailed mathematical analysis of the two-dimensional hybrid model for the lateral dynamics of walking-like mechanical systems (the so-called hybrid inverted pendulum) is presented in this article. The chaotic behavior, when being externally harmonically perturbed, is demonstrated. Two rather exceptional features are analyzed. Firstly, the unperturbed undamped hybrid inverted pendulum behaves inside a certain stability region periodically and its respective frequencies range from zero (close to the boundary of that stability region) to infinity (close to its double support equilibrium). Secondly, the constant lateral forcing less than a certain threshold does not affect the periodic behavior of the hybrid inverted pendulum and preserves its equilibrium at the origin. The latter is due to the hybrid nature of the equilibrium at the origin, which exists only in the Filippov sense. It is actually a trivial example of the so-called pseudo-equilibrium [Kuznetsov et al., 2003]. Nevertheless, such an observation holds only for constant external forcing and even arbitrary small time-varying external forcing may destabilize the origin. As a matter of fact, one can observe many, possibly even infinitely many, distinct chaotic attractors for a single system when the forcing amplitude does not exceed the mentioned threshold. Moreover, some general properties of the hybrid inverted pendulum are characterized through its topological equivalence to the classical pendulum. Extensive numerical experiments demonstrate the chaotic behavior of the harmonically perturbed hybrid inverted pendulum.
result_subspec WOS
RIV BC
FORD0 20000
FORD1 20200
FORD2 20204
reportyear 2020
num_of_auth 2
mrcbC52 4 A hod sml 4ah 4as 20231122144230.0
inst_support RVO:67985556
permalink http://hdl.handle.net/11104/0299379
mrcbC61 1
mrcbC64 1 Department of Control Theory UTIA-B 10100 MATHEMATICS, INTERDISCIPLINARY APPLICATIONS
confidential S
contract
name Copyright Transfer Form
date 20181204
note Copyright Transfer Form
article_num 1930024
mrcbC86 3+4 Article Mathematics Interdisciplinary Applications|Multidisciplinary Sciences
mrcbC91 A
mrcbT16-e MATHEMATICSINTERDISCIPLINARYAPPLICATIONS|MULTIDISCIPLINARYSCIENCES
mrcbT16-j 0.442
mrcbT16-s 0.715
mrcbT16-B 26.689
mrcbT16-D Q3
mrcbT16-E Q2
arlyear 2019
mrcbTft \nSoubory v repozitáři: celikovsky-0508137.pdf, celikovsky-0508137-copyright.pdf
mrcbU14 85071604891 SCOPUS
mrcbU24 PUBMED
mrcbU34 000483030700001 WOS
mrcbU63 cav_un_epca*0256776 International Journal of Bifurcation and Chaos 0218-1274 1793-6551 Roč. 29 č. 9 2019 World Scientific Publishing