Intrinsic Dimensionality of Fermi-Pasta-Ulam-Tsingou High-Dimensional Trajectories Through Manifold Learning: A Linear Approach

Abstract

A data-driven approach based on unsupervised machine learning is proposed to infer the intrinsic dimension m of the high-dimensional trajectories of the Fermi-Pasta-Ulam-Tsingou (FPUT) model. Principal component analysis (PCA) is applied to trajectory data consisting of ns = 4,000,000 datapoints, of the FPUT β model with N = 32 coupled oscillators, revealing a critical relationship between m and the model's nonlinear strength. By estimating the intrinsic dimension m using multiple methods (participation ratio, Kaiser rule, and the Kneedle algorithm), it is found that m increases with the model nonlinearity. Interestingly, in the weakly nonlinear regime, for trajectories initialized by exciting the first mode, the participation ratio estimates m = 2, 3, strongly suggesting that quasi-periodic motion on a low-dimensional Riemannian manifold underlies the characteristic energy recurrences observed in the FPUT model.

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