Monge-Kantorovich Fitting With Sobolev Budgets

Abstract

Given m < n, we consider the problem of ``best'' approximating an n-d probability measure via an m-d measure such that supp\ has bounded total ``complexity.'' When is concentrated near an m-d set we may interpret this as a manifold learning problem with noisy data. However, we do not restrict our analysis to this case, as the more general formulation has broader applications. We quantify 's performance in approximating via the Monge-Kantorovich (also called Wasserstein) p-cost Wpp(, ), and constrain the complexity by requiring supp\ to be coverable by an f : Rm Rn whose Wk,q Sobolev norm is bounded by ≥ 0. This allows us to reformulate the problem as minimizing a functional Jp(f) under the Sobolev ``budget'' . This problem is closely related to (but distinct from) principal curves with length constraints when m=1, k = 1 and an unsupervised analogue of smoothing splines when k > 1. New challenges arise from the higher-order differentiability condition. We study the ``gradient'' of Jp, which is given by a certain vector field that we call the barycenter field, and use it to prove a nontrivial (almost) strict monotonicity result. We also provide a natural discretization scheme and establish its consistency. We use this scheme as a toy model for a generative learning task, and by analogy, propose novel interpretations for the role regularization plays in improving training.