自适应立体 MCMC

arXiv - STAT - Computation Pub Date : 2024-08-21 DOI:arxiv-2408.11780

Cameron Bell, Krzystof Łatuszyński, Gareth O. Roberts

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引用次数: 0

摘要

为了通过马尔可夫链蒙特卡罗（MCMC）方法解决从重尾高维分布中采样的问题，Yang, Latuszy\'nski, and Roberts (2022) (arXiv:2205. 12112) 引入了立体投影作为工具，将 $\mathbb{R}^d$ 压缩，并将问题转化为从单位球体上的密度 $\mathbb{S}^d$ 中采样。12112）引入了立体投影作为工具，以压缩 $\mathbb{R}^d$ 并将问题转化为从单位球体 $\mathbb{S}^d$ 上的密度中采样。然而，算法效率的提高以及实现的计算成本仍然受到这种转化中使用的参数的显著影响。为了解决这个问题，我们引入了自适应版本的立体随机漫步（SRW）、立体切片采样器（SSS）和立体弹跳粒子采样器（SBPS），它们会在运行过程中自动更新算法参数。自适应设置使我们能够更好地发挥立体投影的威力，即使目标分布既不居中也不均匀。我们提出了一项仿真研究，展示了每种算法在重尾、高维设置下远离均值起始时的鲁棒性，这与汉密尔顿蒙特卡罗（HMC）不同。我们建立了一个新颖的框架，用于证明自适应 MCMC 算法在同时均匀遍历马尔可夫操作者集合（包括连续时间过程）上的收敛性。这个框架使我们能够为我们的自适应立体算法证明 LLN 和 CLT。

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Adaptive Stereographic MCMC

In order to tackle the problem of sampling from heavy tailed, high dimensional distributions via Markov Chain Monte Carlo (MCMC) methods, Yang, Latuszy\'nski, and Roberts (2022) (arXiv:2205.12112) introduces the stereographic projection as a tool to compactify $\mathbb{R}^d$ and transform the problem into sampling from a density on the unit sphere $\mathbb{S}^d$. However, the improvement in algorithmic efficiency, as well as the computational cost of the implementation, are still significantly impacted by the parameters used in this transformation. To address this, we introduce adaptive versions of the Stereographic Random Walk (SRW), the Stereographic Slice Sampler (SSS), and the Stereographic Bouncy Particle Sampler (SBPS), which automatically update the parameters of the algorithms as the run progresses. The adaptive setup allows us to better exploit the power of the stereographic projection, even when the target distribution is neither centered nor homogeneous. We present a simulation study showing each algorithm's robustness to starting far from the mean in heavy tailed, high dimensional settings, as opposed to Hamiltonian Monte Carlo (HMC). We establish a novel framework for proving convergence of adaptive MCMC algorithms over collections of simultaneously uniformly ergodic Markov operators, including continuous time processes. This framework allows us to prove LLNs and a CLT for our adaptive Stereographic algorithms.

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arXiv - STAT - Computation

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