General multi-steps variable-coefficient formulation for computing quasi-periodic solutions with multiple base frequencies
Abstract
Quasi-periodic solutions with multiple base frequencies exhibit the feature of -periodicity with respect to each of the hyper-time variables. However, it remains a challenge work, due to the lack of effective solution methods, to solve and track the quasi-periodic solutions with multiple base frequencies until now. In this work, a multi-steps variable-coefficient formulation (m-VCF) is proposed, which provides a unified framework to enable either harmonic balance method (HB) or collocation method (CO) or finite difference method (FD) to solve quasi-periodic solutions with multiple base frequencies. For this purpose, a method of alternating U and S domain (AUS) is also developed to efficiently evaluate the nonlinear force terms. Furthermore, a new robust phase condition is presented for all of the three methods to make them track the quasi-periodic solutions with prior unknown multiple base frequencies, while the stability of the quasi-periodic solutions is assessed by mean of Lyapunov exponents. The feasibility of the constructed methods under the above framework is verified by application to three nonlinear systems.
Cite
@article{arxiv.2505.02021,
title = {General multi-steps variable-coefficient formulation for computing quasi-periodic solutions with multiple base frequencies},
author = {Junqing Wu and Ling Hong and Mingwu Li and Jun Jiang},
journal= {arXiv preprint arXiv:2505.02021},
year = {2025}
}
Comments
23 pages, 15 figures