Abstract
We investigate the approximation of high-dimensional target measures as low-dimensional updates of a dominating reference measure. This approximation class replaces the associated density with the composition of: (i) a feature map that identifies the leading principal components or features of the target measure, relative to the reference, and (ii) a low-dimensional profile function. When the reference measure satisfies a subspace ϕ-Sobolev inequality, we construct a computationally tractable approximation that yields certifiable error guarantees with respect to the Amari α-divergences. Our construction proceeds in two stages. First, for any feature map and any α-divergence, we obtain an analytical expression for the optimal profile function. Second, for linear feature maps, the principal features are obtained from eigenvectors of a matrix involving gradients of the log-density. Neither step requires explicit access to normalizing constants. Notably, by leveraging the ϕ-Sobolev inequalities, we demonstrate that these features universally certify approximation errors across the range of α-divergences . We then propose an application to Bayesian inverse problems and provide an analogous construction with approximation guarantees that hold in expectation over the data. We conclude with an extension of the proposed dimension reduction strategy to nonlinear feature maps.
Funding Statement
ML and YMM acknowledge support from the US Department of Energy, Office of Advanced Scientific Computing Research, under grants DE-SC0023187 and DE-SC0023188, and from the ExxonMobil Technology and Engineering Company. OZ acknowledges support from the ANR JCJC project MODENA (ANR-21-CE46-0006-01).
Acknowledgments
The authors would like to thank the anonymous referees, the associate editor, and the editor-in-chief for many insightful and constructive comments that improved the quality of this paper.
Citation
Matthew T.C. Li. Youssef Marzouk. Olivier Zahm. "Principal feature detection via ϕ-Sobolev inequalities." Bernoulli 30 (4) 2979 - 3003, November 2024. https://doi.org/10.3150/23-BEJ1702
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