|国家预印本平台
首页|Higher-Order Transverse Discontinuity Mapping in Filippov Systems: Analysis and Experimental Validation using an Electronic Circuit

Higher-Order Transverse Discontinuity Mapping in Filippov Systems: Analysis and Experimental Validation using an Electronic Circuit

Higher-Order Transverse Discontinuity Mapping in Filippov Systems: Analysis and Experimental Validation using an Electronic Circuit

来源:Arxiv_logoArxiv
英文摘要

This paper shows that linearizing the transverse discontinuity mapping (TDM) in Filippov systems can produce inaccurate predictions of the dynamics in impact oscillators operating near a pre-stressed soft barrier. This discrepancy arises from the limitations of the linearized saltation matrix, which inaccurately predicts impacts in the local neighborhood of the discontinuity boundary. To address this issue, a higher-order approximation of the TDM is derived, which accurately captures the onset of impacts and closely matches the results obtained from both numerical simulations and electronic experiments. The proposed higher-order TDM results in a quadratic estimation of flight time for impacts. Geometrically, real-valued impact events are only feasible when the discriminant of this quadratic equation is positive. The differences in the predicted higher-order flight times and mapping estimates become more pronounced for low-velocity impacts close to grazing. Subsequently, a numerical approximation of the higher-order saltation matrix and its consequent Floquet multipliers and Lyapunov exponents for stability analysis is proposed and demonstrated on a pre-stressed, forced, damped, soft impact oscillator. To validate the numerically observed discontinuity-induced bifurcations, an analog electronic circuit is proposed that models a soft mechanical prestressed oscillator. This inductor-less circuit overcomes the limitations of typical LCR-based circuits, which are used to design such oscillators but cannot accommodate low stiffness ratios. The experimentally obtained limit cycles, finger-shaped Poincaré sections, and bifurcation diagrams match the predictions of the higher-order TDM, validating that the proposed circuit accurately models the soft-impact oscillator for both low and high stiffness ratios.

Rohit Chawla、Soumyajit Seth、Aasifa Rounak、Vikram Pakrashi

力学电子电路

Rohit Chawla,Soumyajit Seth,Aasifa Rounak,Vikram Pakrashi.Higher-Order Transverse Discontinuity Mapping in Filippov Systems: Analysis and Experimental Validation using an Electronic Circuit[EB/OL].(2025-06-23)[2025-07-24].https://arxiv.org/abs/2506.18379.点此复制

评论