English

Inference via low-dimensional couplings

Methodology 2018-12-18 v4 Computation Machine Learning

Abstract

We investigate the low-dimensional structure of deterministic transformations between random variables, i.e., transport maps between probability measures. In the context of statistics and machine learning, these transformations can be used to couple a tractable "reference" measure (e.g., a standard Gaussian) with a target measure of interest. Direct simulation from the desired measure can then be achieved by pushing forward reference samples through the map. Yet characterizing such a map---e.g., representing and evaluating it---grows challenging in high dimensions. The central contribution of this paper is to establish a link between the Markov properties of the target measure and the existence of low-dimensional couplings, induced by transport maps that are sparse and/or decomposable. Our analysis not only facilitates the construction of transformations in high-dimensional settings, but also suggests new inference methodologies for continuous non-Gaussian graphical models. For instance, in the context of nonlinear state-space models, we describe new variational algorithms for filtering, smoothing, and sequential parameter inference. These algorithms can be understood as the natural generalization---to the non-Gaussian case---of the square-root Rauch-Tung-Striebel Gaussian smoother.

Keywords

Cite

@article{arxiv.1703.06131,
  title  = {Inference via low-dimensional couplings},
  author = {Alessio Spantini and Daniele Bigoni and Youssef Marzouk},
  journal= {arXiv preprint arXiv:1703.06131},
  year   = {2018}
}

Comments

78 pages, 25 figures

R2 v1 2026-06-22T18:49:08.912Z