Improved Finite-Particle Convergence Rates for Stein Variational Gradient Descent

arXiv - STAT - Statistics Theory Pub Date : 2024-09-13 DOI:arxiv-2409.08469

Krishnakumar Balasubramanian, Sayan Banerjee, Promit Ghosal

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Abstract

We provide finite-particle convergence rates for the Stein Variational Gradient Descent (SVGD) algorithm in the Kernel Stein Discrepancy ($\mathsf{KSD}$) and Wasserstein-2 metrics. Our key insight is the observation that the time derivative of the relative entropy between the joint density of $N$ particle locations and the $N$-fold product target measure, starting from a regular initial distribution, splits into a dominant `negative part' proportional to $N$ times the expected $\mathsf{KSD}^2$ and a smaller `positive part'. This observation leads to $\mathsf{KSD}$ rates of order $1/\sqrt{N}$, providing a near optimal double exponential improvement over the recent result by~\cite{shi2024finite}. Under mild assumptions on the kernel and potential, these bounds also grow linearly in the dimension $d$. By adding a bilinear component to the kernel, the above approach is used to further obtain Wasserstein-2 convergence. For the case of `bilinear + Mat\'ern' kernels, we derive Wasserstein-2 rates that exhibit a curse-of-dimensionality similar to the i.i.d. setting. We also obtain marginal convergence and long-time propagation of chaos results for the time-averaged particle laws.

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改进斯坦因变分梯度下降的有限粒子收敛速率

我们为核斯坦因差异（$mathsf{KSD}$）和瓦瑟斯坦-2度量中的斯坦因变分梯度下降（SVGD）算法提供了有限粒子收敛率。我们的主要见解是观察到，从正态初始分布开始，N$粒子位置的联合密度与N$折积目标度量之间的相对熵的时间导数会分裂成一个占主导地位的 "负部分"（与预期的$\mathsf{KSD}^2$的N$倍成正比）和一个较小的 "正部分"。这一观察结果使 $\mathsf{KSD}$ 率达到 1/sqrt{N}$ 的数量级，与最近由~\cite{shi2024finite}得出的结果相比，提供了近乎最佳的双指数改进。在内核和势的温和假设下，这些边界在维数$d$上也呈线性增长。通过在内核中加入双线性分量，上述方法被用来进一步获得瓦瑟斯坦-2 收敛性。对于 "双线性 + Mat\'ern' 内核 "的情况，我们得到的 Wasserstein-2 率表现出类似于 i.i.d. 设置的维度诅咒。我们还得到了时间平均粒子定律的边际收敛性和长时间传播的混沌结果。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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arXiv - STAT - Statistics Theory

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