JZUS - Journal of Zhejiang University SCIENCE

Journal of Zhejiang University SCIENCE A

Accepted manuscript available online (unedited version)

Stochastic averaging of quasi partially integrable Hamiltonian systems under fractional Gaussian noise

Author(s): Qiang-feng Lü, Mao-lin Deng, Wei-qiu Zhu
Affiliation(s): Department of Mechanics, Zhejiang University, Hangzhou 310027, China; more
Corresponding email(s): wqzhu@zju.edu.cn
Key Words: Fractional Brownian motion (fBm); Fractional Gaussian noise (fGn); Quasi partially integrable Hamiltonian system; Stochastic averaging method; Stationary response

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Qiang-feng Lü, Mao-lin Deng, Wei-qiu Zhu. Stochastic averaging of quasi partially integrable Hamiltonian systems under fractional Gaussian noise[J]. Journal of Zhejiang University Science A,in press.Frontiers of Information Technology & Electronic Engineering,in press.https://doi.org/10.1631/jzus.A1600541

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author="Qiang-feng Lü, Mao-lin Deng, Wei-qiu Zhu",
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T1 - Stochastic averaging of quasi partially integrable Hamiltonian systems under fractional Gaussian noise
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EP - 717
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PB - Zhejiang University Press & Springer
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doi="https://doi.org/10.1631/jzus.A1600541"

Abstract
Chinese Summary
Academic Network
Reviewer Comment

Abstract: A stochastic averaging method for predicting the response of quasi partially integrable and non-resonant Hamiltonian systems to fractional Gaussian noise (fGn) with the Hurst index 1/2<H<1 is proposed. The averaged stochastic differential equations (SDEs) for the first integrals of the associated Hamiltonian system are derived. The dimension of averaged SDEs is less than that of the original system. The stationary probability density and statistics of the original system are obtained approximately from solving the averaged SDEs numerically. Two systems are worked out to illustrate the proposed stochastic averaging method. It is shown that the results obtained by using the proposed stochastic averaging method and those from digital simulation of original system agree well, and the computational time for the former results is less than that for the latter ones.

Abstract: The traditional stochastic averaging method of quasi Hamiltonian system is based on the theory of diffusion process. An important property of diffusion process is the Markov property. For a long time, many researchers are wondering what the stochastic averaging method would be like if the system response processes is not Markov process. The fractional Brownian motion is known as a non-Markov process. And it is also known that the system response process have to be non-Markov process when the system is excited by fractional Gaussian noise. I value the subject discussed in this manuscript. It is the first time that the stochastic averaging method of quasi Hamiltonian system is developed to the case of non-Markov process.

分数阶高斯噪声激励下拟部分可积哈密顿系统的随机平均法

目的：提出预测分数阶高斯噪声激励下拟部分可积非共振哈密顿系统的稳态响应的方法。
创新点：现有文献中，对于分数阶高斯噪声激励下动态系统响应的研究，多为单自由度或二自由度线性系统，而本文的方法针对的是多自由度强非线性系统，可预测分数阶高斯噪声激励下的多自由度强非线性系统的稳态响应。
方法：1. 根据分数阶布朗运动的顺式积分原理及其随机微分规则，将分数阶高斯噪声激励下的多自由度强非线性系统模型化为分数阶高斯噪声激励下的拟部分可积哈密顿系统。2. 运用随机平均原理进行降维，得到维数更低的分数阶随机微分方程组，由此，原系统可被这组方程近似代替。3. 运用数值方法求解分数阶随机微分方程组，得到原系统的近似稳态响应。
结论：1. 从平均后的分数阶随机微分方程组模拟得到的近似稳态响应与原系统方程模拟得到的稳态响应吻合度较高，说明了此方法的有效性。2. 模拟平均后的分数阶随机微分方程组的时间比模拟原系统方程的时间短很多，说明此方法效率高。

关键词组：分数布朗运动；分数高斯噪声；拟部分可积哈密顿系统；随机平均法；稳态响应

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分数阶高斯噪声激励下拟部分可积哈密顿系统的随机平均法

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