Stability analysis of a time‑delayed Van der Pol-Helmholtz-Duffing oscillatorin fractal space with a non‑perturbative approach

Y. El‐Dib
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Abstract

The time-delayed fractal Van der Pol-Helmholtz-Duffing (VPHD) oscillator is the subject of this paper, which explores its mechanisms and highlights its stability analysis. While time-delayed technologies are currently garnering significant attention, the focus of this research remains crucially relevant. A non-perturbative approach is employed to refine and set the stage for the system under scrutiny. The innovative methodologies introduced yield an equivalent linear differential equation, mirroring the inherent nonlinearities of the system. Notably, the incorporation of quadratic nonlinearity into the frequency formula represents a cutting-edge advancement. The analytical solution's validity is corroborated using a numerical approach. Stability conditions are ascertained through the residual Galerkin method. Intriguingly, it is observed that the delay parameter, in the context of the fractal system, reverses its stabilizing influence, impacting both the amplitude of delayed velocity and position. The analytical solution's precision is underscored by its close alignment with numerical results. Furthermore, the study reveals that fractal characteristics emulate damping behaviors. Given its applicability across diverse nonlinear dynamical systems, this non-perturbative approach emerges as a promising avenue for future research.
用非微扰方法对分形空间中的延时范德波尔-赫尔姆霍兹-杜芬振荡器进行稳定性分析
本文以延时分形范德波尔-赫姆霍兹-杜芬(VPHD)振荡器为主题,探讨了其机理并重点分析了其稳定性。虽然延时技术目前正备受关注,但本研究的重点仍然至关重要。本文采用了非微扰方法来完善和设置所研究的系统。引入的创新方法产生了等效线性微分方程,反映了系统固有的非线性特性。值得注意的是,将二次非线性纳入频率公式代表了一项尖端技术的进步。分析解决方案的有效性通过数值方法得到了证实。通过残差 Galerkin 方法确定了稳定性条件。耐人寻味的是,在分形系统中,延迟参数会反向影响稳定,同时影响延迟速度和位置的振幅。分析解与数值结果的密切吻合凸显了分析解的精确性。此外,该研究还揭示了分形特征对阻尼行为的模拟作用。鉴于其适用于各种非线性动力学系统,这种非微扰方法成为未来研究的一个大有可为的途径。
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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