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Nonlinear Model Reduction by Probabilistic Manifold Decomposition

Jiaming Guo, Dunhui Xiao

2026SIAM Journal on Scientific Computing12 citationsDOIOpen Access PDF

Abstract

This paper presents a novel non-linear model reduction method: Probabilistic Manifold Decomposition (PMD), which provides a powerful framework for constructing non-intrusive reduced-order models (ROMs) by embedding a high-dimensional system into a low-dimensional probabilistic manifold and predicting the dynamics. Through explicit mappings, PMD captures both linearity and non-linearity of the system. A key strength of PMD lies in its predictive capabilities, allowing it to generate stable dynamic states based on embedded representations. The method also offers a mathematically rigorous approach to analyze the convergence of linear feature matrices and low-dimensional probabilistic manifolds, ensuring that sample-based approximations converge to the true data distributions as sample sizes increase. These properties, combined with its computational efficiency, make PMD a versatile tool for applications requiring high accuracy and scalability, such as fluid dynamics simulations and other engineering problems. By preserving the geometric and probabilistic structures of the high-dimensional system, PMD achieves a balance between computational speed, accuracy, and predictive capabilities, positioning itself as a robust alternative to the traditional model reduction method.

Topics & Concepts

Probabilistic logicReduction (mathematics)MathematicsEmbeddingAlgorithmManifold (fluid mechanics)Nonlinear systemDimensionality reductionApplied mathematicsNonlinear dimensionality reductionMathematical optimizationConvergence (economics)Uncertainty quantificationProbabilistic analysis of algorithmsModel order reductionComputer scienceDecompositionDiffusion mapStatistical modelMatrix decompositionLinearityDecomposition method (queueing theory)Feature (linguistics)ComputationTransformation (genetics)Manifold alignmentKey (lock)Fault Detection and Control SystemsGaussian Processes and Bayesian InferenceSimulation and Modeling Applications