Analysis and Control of Chaos in the Boost Converter with ZAD, FPIC, and TDAS: Fid-Bau Portal

Fachinformationsdienst BAUdigital

Eine Plattform für die Wissenschaft: Bauingenieurwesen, Architektur und Urbanistik

Analysis and Control of Chaos in the Boost Converter with ZAD, FPIC, and TDAS

Simeón Casanova Trujillo / John E. Candelo-Becerra / Fredy E. Hoyos

This paper presents an analysis and control of chaos in the boost converter controlled with zero average dynamics, fixed-point induced control, and time-delayed autosynchronization techniques. First, the existence of chaos is demonstrated numerically when positive Lyapunov exponents are found in the controlled system, for a range from $k_{1} = - 0.26$ to $k_{1} = 0.4387$ , when $k_{2} = 0.5$ . Additionally, chaos is also found for a range from $k_{1} = - 0.435$ to $k_{1} = 0.26$ , when $k_{2} = - 0.5$ . Subsequently, fixed-point-induced control and time-delayed autosynchronization techniques are used to control the chaos. The results show that both techniques are useful to control the chaos in the boost converter. Furthermore, the fixed-point-induced control technique allows better regulation than the time-delayed autosynchronization technique. Moreover, when only the fixed-point induced control technique is used on the boost converter with a time delay, the results were not good enough to stabilize orbits. The stability is validated by calculating the Lyapunov exponents.

Zugriff

Seitennavigation

Dokumentinformationen

Ähnliche Titel

Exportieren, teilen und zitieren

Analysis and Control of Chaos in the Boost Converter with ZAD, FPIC, and TDAS

Simeón Casanova Trujillo / John E. Candelo-Becerra / Fredy E. Hoyos

This paper presents an analysis and control of chaos in the boost converter controlled with zero average dynamics, fixed-point induced control, and time-delayed autosynchronization techniques. First, the existence of chaos is demonstrated numerically when positive Lyapunov exponents are found in the controlled system, for a range from $k_{1} = - 0.26$ to $k_{1} = 0.4387$ , when $k_{2} = 0.5$ . Additionally, chaos is also found for a range from $k_{1} = - 0.435$ to $k_{1} = 0.26$ , when $k_{2} = - 0.5$ . Subsequently, fixed-point-induced control and time-delayed autosynchronization techniques are used to control the chaos. The results show that both techniques are useful to control the chaos in the boost converter. Furthermore, the fixed-point-induced control technique allows better regulation than the time-delayed autosynchronization technique. Moreover, when only the fixed-point induced control technique is used on the boost converter with a time delay, the results were not good enough to stabilize orbits. The stability is validated by calculating the Lyapunov exponents.

Analysis and Control of Chaos in the Boost Converter with ZAD, FPIC, and TDAS

Simeón Casanova Trujillo / John E. Candelo-Becerra / Fredy E. Hoyos

This paper presents an analysis and control of chaos in the boost converter controlled with zero average dynamics, fixed-point induced control, and time-delayed autosynchronization techniques. First, the existence of chaos is demonstrated numerically when positive Lyapunov exponents are found in the controlled system, for a range from $k_{1} = - 0.26$ to $k_{1} = 0.4387$ , when $k_{2} = 0.5$ . Additionally, chaos is also found for a range from $k_{1} = - 0.435$ to $k_{1} = 0.26$ , when $k_{2} = - 0.5$ . Subsequently, fixed-point-induced control and time-delayed autosynchronization techniques are used to control the chaos. The results show that both techniques are useful to control the chaos in the boost converter. Furthermore, the fixed-point-induced control technique allows better regulation than the time-delayed autosynchronization technique. Moreover, when only the fixed-point induced control technique is used on the boost converter with a time delay, the results were not good enough to stabilize orbits. The stability is validated by calculating the Lyapunov exponents.

Zugriff

Seitennavigation

Dokumentinformationen

Ähnliche Titel

Exportieren, teilen und zitieren

Dokumentinformationen

Titel:

Analysis and Control of Chaos in the Boost Converter with ZAD, FPIC, and TDAS

Beteiligte:

Simeón Casanova Trujillo (Autor:in) / John E. Candelo-Becerra (Autor:in) / Fredy E. Hoyos (Autor:in)

Erschienen in:

Sustainability, Vol 14, Iss 20, p 13170 (2022)

Erscheinungsdatum:

2022

ISSN:

DOI:

https://doi.org/10.3390/su142013170

Medientyp:

Aufsatz (Zeitschrift)

Format:

Elektronische Ressource

Sprache:

Unbekannt

Schlagwörter:

bifurcation diagrams , periodic orbits , boost converter , system stability , biparametric diagram , Environmental effects of industries and plants , TD194-195 , Renewable energy sources , TJ807-830 , Environmental sciences , GE1-350

Metadata by DOAJ is licensed under CC BY-SA 1.0

Ähnliche Titel

Adapting Free, Prior, and Informed Consent (FPIC) to Local Contexts in REDD+: Lessons from Three Experiments in Vietnam

Thuy Thu Pham / Jean-Christophe Castella / Guillaume Lestrelin et al. | DOAJ | 2015

Freier Zugriff

Study of Tracking and Data Acquisition System for the 1990'S. Volume 4: TDAS Space Segment Architecture

R. S. Orr | NTIS | 1984

Modelling and Comparison of Conventional SEPIC Converter with Cascaded Boost–SEPIC Converter

Kumari, Rubi / Pandit, Moumi / Sherpa, K.S. | Springer Verlag | 2021

Analysis of DC DC Boost Converter for Hybrid Power Generating System

S. Kasthuri | BASE | 2018

Freier Zugriff

Study of Control Chaos by Resonant Parametric Perturbation in H Bridge Converter

Jiang, W. / Zhou, Y.F. / Chen, J.N. | British Library Online Contents | 2010