阶约法在非线性动态系统中的应用

IF 0.9 Q4 ACOUSTICS

Sound and Vibration Pub Date : 2020-01-01 DOI:10.32604/sv.2020.09783

N. Wu, Kuan Lu, Yulin Jin, Haopeng Zhang, Yushu Chen

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引用次数: 0

摘要

本文讨论了确定性系统和随机系统的两种不同的降阶方法。首先，介绍了基于高维非线性动力系统的瞬态固有正交分解(T-POD)方法。通过对两端存在基座松动故障的转子-轴承系统进行分析，给出了T-POD法降阶的最优条件。通过与原系统结果的比较，验证了T-POD方法的有效性。其次，将多项式维数分解(PDD)方法应用于考虑不确定刚度的2自由度弹簧系统，研究其幅频响应。用PDD方法得到的数值结果与蒙特卡罗模拟(MCS)方法吻合较好。随着多项式阶数的增加，PDD方法的结果能更好地逼近MCS。同时，将均匀-勒让德多项式与高斯-埃尔米特多项式进行比较，可以在一定程度上消除PDD方法的摄动。

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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The Applications of Order Reduction Methods in Nonlinear Dynamic Systems

Two different order reduction methods of the deterministic and stochastic systems are discussed in this paper. First, the transient proper orthogonal decomposition (T-POD) method is introduced based on the high-dimensional nonlinear dynamic system. The optimal order reduction conditions of the T-POD method are provided by analyzing the rotor-bearing system with pedestal looseness fault at both ends. The efficiency of the T-POD method is verified via comparing with the results of the original system. Second, the polynomial dimensional decomposition (PDD) method is applied to the 2 DOFs spring system considering the uncertain stiffness to study the amplitude-frequency response. The numerical results obtained by the PDD method agree well with the Monte Carlo simulation (MCS) method. The results of the PDD method can approximate to MCS better with the increasing of the polynomial order. Meanwhile, the Uniform-Legendre polynomials can eliminate perturbation of the PDD method to a certain extent via comparing it with the Gaussian-Hermite polynomials.

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来源期刊

Sound and Vibration 物理-工程：机械

CiteScore

1.50

自引率

33.30%

发文量

审稿时长

>12 weeks

期刊介绍： Sound & Vibration is a journal intended for individuals with broad-based interests in noise and vibration, dynamic measurements, structural analysis, computer-aided engineering, machinery reliability, and dynamic testing. The journal strives to publish referred papers reflecting the interests of research and practical engineering on any aspects of sound and vibration. Of particular interest are papers that report analytical, numerical and experimental methods of more relevance to practical applications. Papers are sought that contribute to the following general topics: -broad-based interests in noise and vibration- dynamic measurements- structural analysis- computer-aided engineering- machinery reliability- dynamic testing