research-article

Polarized Graph Neural Networks

Authors:

Yingxue ZhangAuthors Info & Claims

WWW '22: Proceedings of the ACM Web Conference 2022

Pages 1404 - 1413

https://doi.org/10.1145/3485447.3512187

Published: 25 April 2022 Publication History

Abstract

Despite the recent success of Message-passing Graph Neural Networks (MP-GNNs), the strong inductive bias of homophily limits their ability to generalize to heterophilic graphs and leads to the over-smoothing problem. Most existing works attempt to mitigate this issue in the spirit of emphasizing the contribution from similar neighbors and reducing those from dissimilar ones when performing aggregation, where the dissimilarities are utilized passively and their positive effects are ignored, leading to suboptimal performances. Inspired by the idea of attitude polarization in social psychology, that people tend to be more extreme when exposed to an opposite opinion, we propose Polarized Graph Neural Network (Polar-GNN). Specifically, pairwise similarities and dissimilarities of nodes are firstly modeled with node features and topological structure information. And specially, we assign negative weights for those dissimilar ones. Then nodes aggregate the messages on a hyper-sphere through a polarization operation, which effectively exploits both similarities and dissimilarities. Furthermore, we theoretically demonstrate the validity of the proposed operation. Lastly, an elaborately designed loss function is introduced for the hyper-spherical embedding space. Extensive experiments on real-world datasets verify the effectiveness of our model.

References

[1]

Sami Abu-El-Haija, Bryan Perozzi, Amol Kapoor, Nazanin Alipourfard, Kristina Lerman, Hrayr Harutyunyan, Greg Ver Steeg, and Aram Galstyan. 2019. Mixhop: Higher-order graph convolutional architectures via sparsified neighborhood mixing. In international conference on machine learning. PMLR, 21–29.

[2]

Christopher A Bail, Lisa P Argyle, Taylor W Brown, John P Bumpus, Haohan Chen, MB Fallin Hunzaker, Jaemin Lee, Marcus Mann, Friedolin Merhout, and Alexander Volfovsky. 2018. Exposure to opposing views on social media can increase political polarization. Proceedings of the National Academy of Sciences 115, 37(2018), 9216–9221.

[3]

Deyu Bo, Xiao Wang, Chuan Shi, and Huawei Shen. 2021. Beyond Low-frequency Information in Graph Convolutional Networks. In Proceedings of the AAAI Conference on Artificial Intelligence, Vol. 35. 3950–3957.

[4]

Eli Chien, Jianhao Peng, Pan Li, and Olgica Milenkovic. 2020. Adaptive Universal Generalized PageRank Graph Neural Network. In International Conference on Learning Representations.

[5]

Jiankang Deng, Jia Guo, Niannan Xue, and Stefanos Zafeiriou. 2019. Arcface: Additive angular margin loss for deep face recognition. In Proceedings of the IEEE/CVF Conference on Computer Vision and Pattern Recognition. 4690–4699.

[6]

Kari Edwards and Edward E Smith. 1996. A disconfirmation bias in the evaluation of arguments.Journal of personality and social psychology 71, 1(1996), 5.

[7]

Aditya Grover and Jure Leskovec. 2016. node2vec: Scalable feature learning for networks. In Proceedings of the 22nd ACM SIGKDD international conference on Knowledge discovery and data mining. 855–864.

Digital Library

[8]

William L Hamilton, Rex Ying, and Jure Leskovec. 2017. Inductive representation learning on large graphs. In Proceedings of the 31st International Conference on Neural Information Processing Systems. 1025–1035.

[9]

Kaveh Hassani and Amir Hosein Khasahmadi. 2020. Contrastive multi-view representation learning on graphs. In International Conference on Machine Learning. PMLR, 4116–4126.

[10]

Michael A Hogg and Dominic Abrams. 2007. Intergroup behavior and social identity. The Sage handbook of social psychology: Concise student edition (2007), 335–360.

[11]

Yifan Hou, Jian Zhang, James Cheng, Kaili Ma, Richard TB Ma, Hongzhi Chen, and Ming-Chang Yang. 2019. Measuring and improving the use of graph information in graph neural networks. In International Conference on Learning Representations.

[12]

Yizhu Jiao, Yun Xiong, Jiawei Zhang, Yao Zhang, Tianqi Zhang, and Yangyong Zhu. 2020. Sub-graph contrast for scalable self-supervised graph representation learning. In 2020 IEEE International Conference on Data Mining (ICDM). IEEE, 222–231.

[13]

Dongkwan Kim and Alice Oh. 2020. How to find your friendly neighborhood: Graph attention design with self-supervision. In International Conference on Learning Representations.

[14]

Thomas N. Kipf and Max Welling. 2017. Semi-Supervised Classification with Graph Convolutional Networks. In International Conference on Learning Representations.

[15]

Johannes Klicpera, Aleksandar Bojchevski, and Stephan Günnemann. 2018. Predict then Propagate: Graph Neural Networks meet Personalized PageRank. In International Conference on Learning Representations.

[16]

Jae Kook Lee, Jihyang Choi, Cheonsoo Kim, and Yonghwan Kim. 2014. Social media, network heterogeneity, and opinion polarization. Journal of communication 64, 4 (2014), 702–722.

[17]

Qimai Li, Zhichao Han, and Xiao-Ming Wu. 2018. Deeper insights into graph convolutional networks for semi-supervised learning. In Thirty-Second AAAI conference on artificial intelligence.

[18]

Derek Lim, Xiuyu Li, Felix Hohne, and Ser-Nam Lim. 2021. New Benchmarks for Learning on Non-Homophilous Graphs. arXiv preprint arXiv:2104.01404(2021).

[19]

Meng Liu, Hongyang Gao, and Shuiwang Ji. 2020. Towards deeper graph neural networks. In Proceedings of the 26th ACM SIGKDD International Conference on Knowledge Discovery & Data Mining. 338–348.

Digital Library

[20]

Qingqing Long, Yilun Jin, Yi Wu, and Guojie Song. 2021. Theoretically improving graph neural networks via anonymous walk graph kernels. In Proceedings of the Web Conference 2021. 1204–1214.

Digital Library

[21]

Qingqing Long, Lingjun Xu, Zheng Fang, and Guojie Song. 2021. HGK-GNN: Heterogeneous Graph Kernel based Graph Neural Networks. In Proceedings of the 27th ACM SIGKDD Conference on Knowledge Discovery & Data Mining. 1129–1138.

Digital Library

[22]

Charles G Lord, Lee Ross, and Mark R Lepper. 1979. Biased assimilation and attitude polarization: The effects of prior theories on subsequently considered evidence.Journal of personality and social psychology 37, 11(1979), 2098.

[23]

Miller McPherson, Lynn Smith-Lovin, and James M Cook. 2001. Birds of a feather: Homophily in social networks. Annual review of sociology 27, 1 (2001), 415–444.

[24]

Silvio Micali and Zeyuan Allen Zhu. 2016. Reconstructing markov processes from independent and anonymous experiments. Discrete Applied Mathematics 200 (2016), 108–122.

Digital Library

[25]

Kenta Oono and Taiji Suzuki. 2019. Graph Neural Networks Exponentially Lose Expressive Power for Node Classification. In International Conference on Learning Representations.

[26]

Hongbin Pei, Bingzhe Wei, Kevin Chen-Chuan Chang, Yu Lei, and Bo Yang. 2019. Geom-GCN: Geometric Graph Convolutional Networks. In International Conference on Learning Representations.

[27]

Zhen Peng, Wenbing Huang, Minnan Luo, Qinghua Zheng, Yu Rong, Tingyang Xu, and Junzhou Huang. 2020. Graph representation learning via graphical mutual information maximization. In Proceedings of The Web Conference 2020. 259–270.

Digital Library

[28]

Jiezhong Qiu, Qibin Chen, Yuxiao Dong, Jing Zhang, Hongxia Yang, Ming Ding, Kuansan Wang, and Jie Tang. 2020. Gcc: Graph contrastive coding for graph neural network pre-training. In Proceedings of the 26th ACM SIGKDD International Conference on Knowledge Discovery & Data Mining. 1150–1160.

Digital Library

[29]

Benedek Rozemberczki, Carl Allen, and Rik Sarkar. 2021. Multi-scale attributed node embedding. Journal of Complex Networks 9, 2 (2021), cnab014.

[30]

Oleksandr Shchur, Maximilian Mumme, Aleksandar Bojchevski, and Stephan Günnemann. 2018. Pitfalls of graph neural network evaluation. arXiv preprint arXiv:1811.05868(2018).

[31]

Jian Tang, Meng Qu, Mingzhe Wang, Ming Zhang, Jun Yan, and Qiaozhu Mei. 2015. Line: Large-scale information network embedding. In Proceedings of the 24th international conference on world wide web. 1067–1077.

Digital Library

[32]

Laurens Van der Maaten and Geoffrey Hinton. 2008. Visualizing data using t-SNE.Journal of machine learning research 9, 11 (2008).

[33]

Petar Veličković, Guillem Cucurull, Arantxa Casanova, Adriana Romero, Pietro Liò, and Yoshua Bengio. 2018. Graph Attention Networks. In International Conference on Learning Representations.

[34]

Petar Veličković, William Fedus, William L Hamilton, Pietro Liò, Yoshua Bengio, and R Devon Hjelm. 2018. Deep Graph Infomax. In International Conference on Learning Representations.

[35]

Felix Wu, Amauri Souza, Tianyi Zhang, Christopher Fifty, Tao Yu, and Kilian Weinberger. 2019. Simplifying graph convolutional networks. In International conference on machine learning. PMLR, 6861–6871.

[36]

Liang Yang, Chuan Wang, Junhua Gu, Xiaochun Cao, and Bingxin Niu. 2021. Why Do Attributes Propagate in Graph Convolutional Neural Networks?. In Proceedings of the AAAI Conference on Artificial Intelligence, Vol. 35. 4590–4598.

[37]

Zhilin Yang, William Cohen, and Ruslan Salakhudinov. 2016. Revisiting semi-supervised learning with graph embeddings. In International conference on machine learning. PMLR, 40–48.

[38]

Yuning You, Tianlong Chen, Yongduo Sui, Ting Chen, Zhangyang Wang, and Yang Shen. 2020. Graph contrastive learning with augmentations. Advances in Neural Information Processing Systems 33 (2020), 5812–5823.

[39]

Dingyi Zhang, Yingming Li, and Zhongfei Zhang. 2020. Deep Metric Learning with Spherical Embedding. Advances in Neural Information Processing Systems 33 (2020).

[40]

Jiong Zhu, Yujun Yan, Lingxiao Zhao, Mark Heimann, Leman Akoglu, and Danai Koutra. 2020. Beyond Homophily in Graph Neural Networks: Current Limitations and Effective Designs. Advances in Neural Information Processing Systems 33 (2020).

[41]

Meiqi Zhu, Xiao Wang, Chuan Shi, Houye Ji, and Peng Cui. 2021. Interpreting and unifying graph neural networks with an optimization framework. In Proceedings of the Web Conference 2021. 1215–1226.

Digital Library

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Polarized Graph Neural Networks

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Published In

cover image ACM Conferences

WWW '22: Proceedings of the ACM Web Conference 2022

April 2022

3764 pages

ISBN:9781450390965

DOI:10.1145/3485447

Editors:
Frédérique Laforest
INSA Lyon, France
,
Raphaël Troncy
EURECOM, France
,
Elena Simperl
King’s College London, UK
,
Deepak Agarwal
Pinterest, USA
,
Aristides Gionis
KTH Royal Institute of Technology, Sweden
,
Ivan Herman
W3C / retired
,
Lionel Médini
Université Lyon 1, France

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Published: 25 April 2022

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Khoshraftar SAn A(2024)A Survey on Graph Representation Learning MethodsACM Transactions on Intelligent Systems and Technology10.1145/363351815:1(1-55)Online publication date: 16-Jan-2024
https://dl.acm.org/doi/10.1145/3633518
Long QFang ZFang CChen CWang PZhou YChua TNgo CKa-Wei Lee RKumar RLauw H(2024)Unveiling Delay Effects in Traffic Forecasting: A Perspective from Spatial-Temporal Delay Differential EquationsProceedings of the ACM on Web Conference 202410.1145/3589334.3645688(1035-1044)Online publication date: 13-May-2024
https://dl.acm.org/doi/10.1145/3589334.3645688
Peng TWu WYuan HBao ZPengru ZYu XLin XLiang YPu Y(2024)GraphRARE: Reinforcement Learning Enhanced Graph Neural Network with Relative Entropy2024 IEEE 40th International Conference on Data Engineering (ICDE)10.1109/ICDE60146.2024.00196(2489-2502)Online publication date: 13-May-2024
https://doi.org/10.1109/ICDE60146.2024.00196
Ju WFang ZGu YLiu ZLong QQiao ZQin YShen JSun FXiao ZYang JYuan JZhao YWang YLuo XZhang M(2024)A Comprehensive Survey on Deep Graph Representation LearningNeural Networks10.1016/j.neunet.2024.106207173(106207)Online publication date: May-2024
https://doi.org/10.1016/j.neunet.2024.106207
Ju WZhao YQin YYi SYuan JXiao ZLuo XYan XZhang M(2024)COOLInformation Fusion10.1016/j.inffus.2024.102341107:COnline publication date: 2-Jul-2024
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Wu JChen HCheng MXiong H(2023)CurvAGN: Curvature-based Adaptive Graph Neural Networks for Predicting Protein-Ligand Binding AffinityBMC Bioinformatics10.1186/s12859-023-05503-w24:1Online publication date: 5-Oct-2023
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Guo JDu LBi WFu QMa XChen XHan SZhang DZhang Y(2023)Homophily-oriented Heterogeneous Graph RewiringProceedings of the ACM Web Conference 202310.1145/3543507.3583454(511-522)Online publication date: 30-Apr-2023
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Cheng QShi ZYuan JFitzpatrick PSakurai T(2023)A Novel Environmentally Robust ODDM Detection Approach Using Contrastive LearningIEEE Transactions on Communications10.1109/TCOMM.2023.328295971:9(5274-5286)Online publication date: Sep-2023
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