A general method to stabilize unstable periodic orbits for switched dynamical systems with a periodically moving threshold

Miino, Yuu; Ito, Daisuke; Asahara, Hiroyuki; Kousaka, Takuji; Ueta, Tetsushi

doi:10.1002/cta.2573

Cited by 6 publications

(6 citation statements)

References 37 publications

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“…Moreover, switching techniques find widespread application in various industrial domains, allowing for performance improvements. [5][6][7] Switched systems represent a form of hybrid system that comprises multiple subsystems and employs a switching strategy. The broad utilization of switched systems across various domains such as power electronics, biological systems, robotics, and industrial processes has led to their significant investigation.…”

Section: F I G U R Ementioning

confidence: 99%

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Addressing asymmetric saturation in chaotic Chua's circuit switched system: A combined adaptive sliding mode strategy

Amiri,

Seyed Moosavi,

Forouzanfar

et al. 2024

Adaptive Control & Signal

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SummaryThe purpose of this research is to develop a combined adaptive nonlinear feedback integral sliding mode (CANFISM) for the Chua's switched nonlinear circuit systems. The suggested adaptive composite nonlinear technique is improved to provide a robust controller with enhanced performance in the face of uncertainty and asymmetric saturation. The proposed technique has been theoretically validated, and its closed‐loop exponentially boundedly stable has been demonstrated. Meanwhile, CNF (composite nonlinear feedback) parameters are then determined by employing the linear matrix inequality technique, and the notion of robust tracking is performed and compared in Chua's switched nonlinear circuit systems. This method guarantees robustness against the effects of uncertainty and input asymmetric saturation and decreases chattering. The effectiveness and merits of the suggested technique are then achieved by utilizing two simulation examples of Chua's circuit system.

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Section: F I G U R Ementioning

confidence: 99%

“…It is widely recognized that employing an integral sliding surface instead of a linear sliding surface can improve transient performance. By taking the derivative of (31) with respect to time and considering (5), we arrive at the subsequent dynamic…”

Section: Design Of An Ism Controllermentioning

confidence: 99%

Addressing asymmetric saturation in chaotic Chua's circuit switched system: A combined adaptive sliding mode strategy

Amiri,

Seyed Moosavi,

Forouzanfar

et al. 2024

Adaptive Control & Signal

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“…The steady operation of this system is in the form of periodic orbit and the period of the periodic orbit is the same as that of the external clock signal [19], which is the lowest common multiple of the switching and pulse periods. An unstable and bifurcate periodic orbit has a severe impact on the safety and stability of the system operation [20–21]. Therefore, methods for analyzing the system stability in the multicycle dynamic process need to be studied.…”

Section: Introductionmentioning

confidence: 99%

Stability Analysis of Integrated Power System in Multicycle Dynamic Process

Huang

Wang

Xiao

et al. 2021

IEEJ Transactions Elec Engng

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The integrated power system (IPS) with pulse load involves the dynamic processes of millisecond‐level switching period and second‐level pulse period. The characteristics of this kind of multicycle dynamic process cause much difficulty in analyzing system stability. For this reason, this paper presents a multicycle coupling mathematical model of the IPS with pulse load and proposes an algorithm based on the state variables for analyzing the sensitivity of the preceding switching period which can rapidly and accurately calculate the periodic orbit and stability margin of the system. Considering a little change in the system state variables under small disturbance, this paper uses the pulse‐period average model to simplify the calculation. The simulation analysis shows that the pulse‐period average model has the same stability margin with the multicycle coupling model. The critical pulse power calculated by the above models is 5.5 and 17 kW when the constant power is 20 and 14 kW respectively, which is consistent with the time domain simulation. It may provide technical support for the stability analysis of the IPS with pulse load. © 2021 Institute of Electrical Engineers of Japan. Published by Wiley Periodicals LLC.

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“…Hence, accurate techniques to predict and avoid their occurrence in PV applications is essential in order to maximize the efficiency of the overall system. A variety of different control algorithms for DC‐DC converters have been proposed in the literature to avoid such undesirable behavior 12‐15 …”

Section: Introductionmentioning

confidence: 99%

“…A variety of different control algorithms for DC-DC converters have been proposed in the literature to avoid such undesirable behavior. [12][13][14][15] The typical method for predicting and avoiding fast-scale instabilities in switching circuits is through numerical analysis by discrete-time modeling 16,17 or Floquet theory. 18 Further details of the later approach can be found in Section 3.…”

Section: Introductionmentioning

confidence: 99%

Application of the Filippov Method to PV‐fed DC‐DC converters modeled as hybrid‐DAEs

Hayes

Condon

Giaouris

2020

Engineering Reports

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In this article, a method to study the nonlinear dynamics of a PV-fed boost converter is developed. The model for the solar panel introduces an algebraic constraint into the system and the resulting mathematical model is a set of hybrid differential algebraic equations (DAEs). The behavior of the system is observed to exhibit undesired operation as parameter values vary. Conventional mathematical tools developed to analyze DC-DC converters are not directly applicable to systems modeled as a set of hybrid DAEs. In order to find the monodromy matrix to assess the eigenvalues of the system, we modify the Filippov method to calculate the saltation matrix. The derived formula is general and versatile such that it can be applied to any PV-fed DC-DC converter irrespective of the topology or control algorithm employed. Two case studies are investigated: current mode control and maximum power point tracking. Each case study serves to demonstrate different considerations that must be taken into account when conducting stability analysis of hybrid-DAEs. K E Y W O R D S DC-DC converters, hybrid differential algebraic equations, maximum power point tracking, nonlinear dynamics, photovoltaic, saltation matrix This is an open access article under the terms of the Creative Commons Attribution License, which permits use, distribution and reproduction in any medium, provided the original work is properly cited.

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A general method to stabilize unstable periodic orbits for switched dynamical systems with a periodically moving threshold

Cited by 6 publications

References 37 publications

Addressing asymmetric saturation in chaotic Chua's circuit switched system: A combined adaptive sliding mode strategy

Addressing asymmetric saturation in chaotic Chua's circuit switched system: A combined adaptive sliding mode strategy

Stability Analysis of Integrated Power System in Multicycle Dynamic Process

Application of the Filippov Method to PV‐fed DC‐DC converters modeled as hybrid‐DAEs

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