Linear Convergence of Diffusion Models Under the Manifold Hypothesis

Abstract

Score-matching generative models have proven successful at sampling from complex high-dimensional data distributions. In many applications, this distribution is believed to concentrate on a much lower d-dimensional manifold embedded into D-dimensional space; this is known as the manifold hypothesis. The current best-known convergence guarantees are either linear in D or polynomial (superlinear) in d. The latter exploits a novel integration scheme for the backward SDE. We take the best of both worlds and show that the number of steps diffusion models require in order to converge in Kullback-Leibler~(KL) divergence is linear (up to logarithmic terms) in the intrinsic dimension d. Moreover, we show that this linear dependency is sharp.

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