Explicit Density Approximation for Neural Implicit Samplers Using a Bernstein-Based Convex Divergence
Abstract
Rank-based statistical metrics, such as the invariant statistical loss (ISL), have recently emerged as robust and practically effective tools for training implicit generative models. In this work, we introduce dual-ISL, a novel likelihood-free objective for training implicit generative models that interchanges the roles of the target and model distributions in the ISL framework, yielding a convex optimization problem in the space of model densities. We prove that the resulting rank-based discrepancy is i) continuous under weak convergence and with respect to the norm, and ii) convex in its first argument-properties not shared by classical divergences such as KL or Wasserstein distances. Building on this, we develop a theoretical framework that interprets as an -projection of the density ratio onto a Bernstein polynomial basis, from which we derive exact bounds on the truncation error, precise convergence rates, and a closed-form expression for the truncated density approximation. We further extend our analysis to the multivariate setting via random one-dimensional projections, defining a sliced dual-ISL divergence that retains both convexity and continuity. We empirically show that these theoretical advantages translate into practical ones. Specifically, across several benchmarks dual-ISL converges more rapidly, delivers markedly smoother and more stable training, and more effectively prevents mode collapse than classical ISL and other leading implicit generative methods-while also providing an explicit density approximation.
Cite
@article{arxiv.2506.04700,
title = {Explicit Density Approximation for Neural Implicit Samplers Using a Bernstein-Based Convex Divergence},
author = {José Manuel de Frutos and Manuel A. Vázquez and Pablo M. Olmos and Joaquín Míguez},
journal= {arXiv preprint arXiv:2506.04700},
year = {2025}
}