Canard-induced mixed mode oscillations as a mechanism for the Bonhoeffer-van der Pol circuit under parametric perturbation

IF 0.8 4区工程技术 Q4 ENGINEERING, ELECTRICAL & ELECTRONIC

Circuit World Pub Date : 2021-12-21 DOI:10.1108/cw-07-2020-0132

Yue Yu, Cong Zhang, Zhenyu Chen, Zhengdi Zhang

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引用次数: 2

Abstract

Purpose This paper aims to investigate the singular Hopf bifurcation and mixed mode oscillations (MMOs) in the perturbed Bonhoeffer-van der Pol (BVP) circuit. There is a singular periodic orbit constructed by the switching between the stable focus and large amplitude relaxation cycles. Using a generalized fast/slow analysis, the authors show the generation mechanism of two distinct kinds of MMOs. Design/methodology/approach The parametric modulation can be used to generate complicated dynamics. The BVP circuit is constructed as an example for second-order differential equation with periodic perturbation. Then the authors draw the bifurcation parameter diagram in terms of a containing two attractive regions, i.e. the stable relaxation cycle and the stable focus. The transition mechanism and characteristic features are investigated intensively by one-fast/two-slow analysis combined with bifurcation theory. Findings Periodic perturbation can suppress nonlinear circuit dynamic to a singular periodic orbit. The combination of these small oscillations with the large amplitude oscillations that occur due to canard cycles yields such MMOs. The results connect the theory of the singular Hopf bifurcation enabling easier calculations of where the oscillations occur. Originality/value By treating the perturbation as the second slow variable, the authors obtain that the MMOs are due to the canards in a supercritical case or in a subcritical case. This study can reveal the transition mechanism for multi-time scale characteristics in perturbed circuit. The information gained from such results can be extended to periodically perturbed circuits.

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卡纳德诱导的混合模振荡是参数扰动下邦霍费尔-范德波尔电路的一种机制

目的研究微扰Bonhoeffer-van der Pol (BVP)电路中的Hopf奇异分岔和混合模振荡(MMOs)。通过稳定焦点和大振幅弛豫循环的切换，形成了一个奇异周期轨道。作者通过快速/慢速分析，展示了两种不同类型mmo的生成机制。设计/方法/途径参数调制可用于生成复杂的动力学。构造了具有周期扰动的二阶微分方程的BVP电路。然后绘制了包含稳定松弛循环和稳定焦点两个吸引区域的分岔参数图。采用一快两慢分析方法，结合分岔理论，深入研究了其跃迁机理和特征。发现周期扰动可以抑制非线性电路动态到奇异周期轨道。这些小振荡与鸭式循环引起的大振幅振荡相结合，产生了这样的mmo。结果与奇异Hopf分岔理论相联系，使振荡发生位置的计算更加容易。独创性/价值通过将扰动作为第二个慢变量，作者得出了在超临界情况下或在亚临界情况下，模态偏差是由鸭翼引起的。该研究揭示了微扰电路多时间尺度特性的过渡机制。从这样的结果中获得的信息可以扩展到周期性摄动电路。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Circuit World 工程技术-材料科学：综合

CiteScore

2.60

自引率

0.00%

发文量

审稿时长

>12 weeks

期刊介绍： Circuit World is a platform for state of the art, technical papers and editorials in the areas of electronics circuit, component, assembly, and product design, manufacture, test, and use, including quality, reliability and safety. The journal comprises the multidisciplinary study of the various theories, methodologies, technologies, processes and applications relating to todays and future electronics. Circuit World provides a comprehensive and authoritative information source for research, application and current awareness purposes. Circuit World covers a broad range of topics, including: • Circuit theory, design methodology, analysis and simulation • Digital, analog, microwave and optoelectronic integrated circuits • Semiconductors, passives, connectors and sensors • Electronic packaging of components, assemblies and products • PCB design technologies and processes (controlled impedance, high-speed PCBs, laminates and lamination, laser processes and drilling, moulded interconnect devices, multilayer boards, optical PCBs, single- and double-sided boards, soldering and solderable finishes) • Design for X (including manufacturability, quality, reliability, maintainability, sustainment, safety, reuse, disposal) • Internet of Things (IoT).