Scalable and Adaptive Graph Neural Networks with Self-Label-Enhanced Training

IF 7.5 1区计算机科学 Q1 COMPUTER SCIENCE, ARTIFICIAL INTELLIGENCE

Pattern Recognition Pub Date : 2024-11-23 DOI:10.1016/j.patcog.2024.111210

Chuxiong Sun , Jie Hu , Hongming Gu , Jinpeng Chen , Wei Liang , Mingchuan Yang

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引用次数: 0

Abstract

Although GNNs have achieved success in semi-supervised graph learning tasks, common GNNs suffer from expensive message passing during each epoch and the exponentially growing receptive field occupying too much memory, especially on large graphs. Neighbor sampling techniques can reduce GNNs’ memory footprints, but they encounter either redundant computation or incomplete edges. Some simplified GNNs decouple graph convolutions and feature transformations to reduce computation in training. However, only a part of them can scale to large graphs without neighbor sampling techniques, which can be concluded as decoupled GNNs. Nevertheless, they either only utilize the last convolution output or simply add multi-hop features with uniform weights, which limits their expressiveness. In this paper, we refine the pipeline of decoupled GNNs and propose Scalable and Adaptive Graph Neural Networks (SAGN), which effectively leverages multi-hop information with a scalable attention mechanism. Moreover, we generalize the input of decoupled GNNs to view another classical technique, label propagation, as a special case of decoupled GNNs and propose decoupled label trick (DecLT) to incorporate label information into decoupled GNNs. Furthermore, by incorporating self-training technique, we further propose the Self-Label-Enhanced (SLE) training framework, leveraging pseudo labels to simultaneously augment the training set and improve label propagation. Extensive experiments show that SAGN outperforms other baselines, and that DecLT and SLE can consistently and significantly improve all types of models on semi-supervised node classification tasks. Many top-ranked models on Open Graph Benchmark (OGB) leaderboard adopt our methods as the main backbone.

查看原文本刊更多论文

采用自标签增强训练的可扩展自适应图神经网络

虽然 GNNs 在半监督图学习任务中取得了成功，但普通 GNNs 在每个历时中的信息传递都很昂贵，而且指数级增长的感受野占用了太多内存，尤其是在大型图中。邻域采样技术可以减少 GNN 的内存占用，但会遇到冗余计算或边缘不完整的问题。一些简化的 GNN 将图卷积和特征变换解耦，以减少训练中的计算量。然而，其中只有一部分可以在不使用邻居采样技术的情况下扩展到大型图，这可以归结为解耦 GNN。不过，它们要么只利用最后的卷积输出，要么只是简单地添加权重统一的多跳特征，这限制了它们的表现力。在本文中，我们完善了去耦合 GNN 的管道，并提出了可扩展和自适应图神经网络（SAGN），它通过可扩展的关注机制有效利用了多跳信息。此外，我们对去耦合 GNN 的输入进行了概括，将另一种经典技术--标签传播视为去耦合 GNN 的特例，并提出了去耦合标签技巧（DecLT），将标签信息纳入去耦合 GNN。此外，通过结合自我训练技术，我们进一步提出了自我标签增强（Self-Label-Enhanced，SLE）训练框架，利用伪标签同时增强训练集和改进标签传播。广泛的实验表明，SAGN 的表现优于其他基线，而且 DecLT 和 SLE 可以在半监督节点分类任务中持续、显著地改进所有类型的模型。在开放图基准（Open Graph Benchmark，OGB）排行榜上，许多排名靠前的模型都采用了我们的方法作为主干。

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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来源期刊

Pattern Recognition 工程技术-工程：电子与电气

CiteScore

14.40

自引率

16.20%

发文量

683

审稿时长

5.6 months

期刊介绍： The field of Pattern Recognition is both mature and rapidly evolving, playing a crucial role in various related fields such as computer vision, image processing, text analysis, and neural networks. It closely intersects with machine learning and is being applied in emerging areas like biometrics, bioinformatics, multimedia data analysis, and data science. The journal Pattern Recognition, established half a century ago during the early days of computer science, has since grown significantly in scope and influence.