中文

A Unified Framework for Data-Free One-Step Sampling via Wasserstein Gradient Flows

机器学习 2026-05-19 v1 机器学习

摘要

We develop a unified theoretical framework for data-free one-step sampling from unnormalized target distributions based on Wasserstein gradient flows. For a broad class of standard f-divergence objectives, we show that the induced velocity field admits the universal form V(x)=w(r(x))β(x)\mathbf{V}(x)=w(r(x))\,\beta(x), where β(x)=log(p(x)/q(x))\beta(x)=\nabla \log (p(x)/q(x)) is shared across objectives and ww is determined solely by the choice of divergence. This decomposition shows that standard f-divergence drifts share the same asymptotic target distribution pp and differ primarily in how they redistribute transient repair effort across under-covered regions. To formalize this distinction, we derive a one-step regional-response theory for a soft under-coverage functional and obtain a compression--elasticity identity that links divergence choice to the geometry of mass transport into under-covered regions. We further extend the framework beyond the f-divergence family to the Log-Variance (LV) divergence, analyze how the reference distribution alters the resulting drift structure, and motivate a practical LV-inspired surrogate for data-free training. Based on this theory, we instantiate the framework with a KDE-based implementation and describe a complementary normalizing-flow route, enabling one-step inference after training. Experiments on multimodal Gaussian-mixture benchmarks are consistent with the theoretical predictions and demonstrate effective one-step sampling on these targets.

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引用

@article{arxiv.2605.17808,
  title  = {A Unified Framework for Data-Free One-Step Sampling via Wasserstein Gradient Flows},
  author = {Chenguang Wang and Tianshu Yu},
  journal= {arXiv preprint arXiv:2605.17808},
  year   = {2026}
}