Stabilizing and Enhancing Link Prediction through Deepened Graph Auto-Encoders.

Xinxing Wu, Qiang Cheng
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Abstract

Graph neural networks have been widely used for a variety of learning tasks. Link prediction is a relatively under-studied graph learning task, with current state-of-the-art models based on one- or two-layer shallow graph auto-encoder (GAE) architectures. In this paper, we overcome the limitation of current methods for link prediction of non-Euclidean network data, which can only use shallow GAEs and variational GAEs. Our proposed methods innovatively incorporate standard auto-encoders (AEs) into the architectures of GAEs to capitalize on the intimate coupling of node and edge information in complex network data. Empirically, extensive experiments on various datasets demonstrate the competitive performance of our proposed approach. Theoretically, we prove that our deep extensions can inclusively express multiple polynomial filters with different orders. The codes of this paper are available at https://github.com/xinxingwu-uk/DGAE.

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通过深化图自动编码器稳定并增强链接预测。
图神经网络已被广泛用于各种学习任务。链接预测是一项研究相对较少的图学习任务,目前最先进的模型基于单层或双层浅层图自动编码器(GAE)架构。在本文中,我们克服了目前对非欧几里得网络数据进行链接预测的方法只能使用浅层 GAE 和变异 GAE 的局限性。我们提出的方法创新性地将标准自动编码器(AE)融入到 GAE 的架构中,以利用复杂网络数据中节点和边缘信息的紧密耦合。在各种数据集上进行的大量实验证明了我们提出的方法具有竞争力的性能。从理论上讲,我们证明了我们的深度扩展可以包容地表达多个不同阶数的多项式滤波器。本文代码见 https://github.com/xinxingwu-uk/DGAE。
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