高阶图模型中图网络推理的泛化

Yicheng Fei, Xaq Pitkow
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引用次数: 0

摘要

概率图形模型为描述复杂的统计结构提供了一个强大的工具,在科学和工程领域有许多实际应用,从控制机械臂到理解神经元计算。这些图形模型面临的一个主要挑战是,对于一般图形来说,像边缘化这样的推断是难以处理的。这些推断通常由分布式消息传递算法(如Belief Propagation)来近似,该算法在带有循环的图上并不总是表现良好,对于复杂的连续概率分布也不总是容易指定。这种困难经常出现在包括难以处理的高阶交互的表达图形模型中。在本文中,我们定义了循环因子图神经网络(RF-GNN)来实现对涉及多变量相互作用的图模型的快速近似推理。在多个图形模型族上的实验结果表明,该方法对不同大小的图具有分布外泛化能力,并表明该方法在该领域优于信念传播(BP)。此外,我们在真实世界的低密度奇偶校验数据集上测试了RF-GNN作为基准,以及其他基线模型,包括BP变体和其他GNN方法。总体而言,我们发现RF-GNNs在高噪声水平下优于其他方法。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Generalization of graph network inferences in higher-order graphical models
Abstract Probabilistic graphical models provide a powerful tool to describe complex statistical structure, with many real-world applications in science and engineering from controlling robotic arms to understanding neuronal computations. A major challenge for these graphical models is that inferences such as marginalization are intractable for general graphs. These inferences are often approximated by a distributed message-passing algorithm such as Belief Propagation, which does not always perform well on graphs with cycles, nor can it always be easily specified for complex continuous probability distributions. Such difficulties arise frequently in expressive graphical models that include intractable higher-order interactions. In this paper we define the Recurrent Factor Graph Neural Network (RF-GNN) to achieve fast approximate inference on graphical models that involve many-variable interactions. Experimental results on several families of graphical models demonstrate the out-of-distribution generalization capability of our method to different sized graphs, and indicate the domain in which our method outperforms Belief Propagation (BP). Moreover, we test the RF-GNN on a real-world Low-Density Parity-Check dataset as a benchmark along with other baseline models including BP variants and other GNN methods. Overall we find that RF-GNNs outperform other methods under high noise levels.
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CiteScore
3.40
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