Neural Sinkhorn Gradient Flow
CoRR(2024)
摘要
Wasserstein Gradient Flows (WGF) with respect to specific functionals have
been widely used in the machine learning literature. Recently, neural networks
have been adopted to approximate certain intractable parts of the underlying
Wasserstein gradient flow and result in efficient inference procedures. In this
paper, we introduce the Neural Sinkhorn Gradient Flow (NSGF) model, which
parametrizes the time-varying velocity field of the Wasserstein gradient flow
w.r.t. the Sinkhorn divergence to the target distribution starting a given
source distribution. We utilize the velocity field matching training scheme in
NSGF, which only requires samples from the source and target distribution to
compute an empirical velocity field approximation. Our theoretical analyses
show that as the sample size increases to infinity, the mean-field limit of the
empirical approximation converges to the true underlying velocity field. To
further enhance model efficiency on high-dimensional tasks, a two-phase NSGF++
model is devised, which first follows the Sinkhorn flow to approach the image
manifold quickly (≤ 5 NFEs) and then refines the samples along a simple
straight flow. Numerical experiments with synthetic and real-world benchmark
datasets support our theoretical results and demonstrate the effectiveness of
the proposed methods.
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