Infinite-Horizon Graph Filters: Leveraging Power Series to Enhance Sparse Information Aggregation
Abstract: Graph Neural Networks (GNNs) have shown considerable effectiveness in a variety of graph learning tasks, particularly those based on the message-passing approach in recent years. However, their performance is often constrained by a limited receptive field, a challenge that becomes more acute in the presence of sparse graphs. In light of the power series, which possesses infinite expansion capabilities, we propose a novel Graph Power Filter Neural Network (GPFN) that enhances node classification by employing a power series graph filter to augment the receptive field. Concretely, our GPFN designs a new way to build a graph filter with an infinite receptive field based on the convergence power series, which can be analyzed in the spectral and spatial domains. Besides, we theoretically prove that our GPFN is a general framework that can integrate any power series and capture long-range dependencies. Finally, experimental results on three datasets demonstrate the superiority of our GPFN over state-of-the-art baselines.
- Why rumors spread fast in social networks, and how to stop it. In IJCAI, 2023.
- On the spread of viruses on the internet. In SODA, 2005.
- Fluctuation of the largest eigenvalue of a kernel matrix with application in graphon-based random graphs, 2024.
- Adaptive graph encoder for attributed graph embedding. In SIGKDD, 2020.
- Convolutional neural networks on graphs with fast localized spectral filtering. In NeurIPS, 2016.
- Pan Li Eli Chien, Jianhao Peng and Olgica Milenkovic. Adaptive universal generalized pagerank graph neural network. In ICLR, 2021.
- When spatio-temporal meet wavelets: Disentangled traffic forecasting via efficient spectral graph attention networks. In ICDE, 2023.
- Grand+: Scalable graph random neural networks. In WWW, 2022.
- A spatiotemporal analysis of the impact of lockdown and coronavirus on london’s bicycle hire scheme: from response to recovery to a new normal. GIS, 2023.
- Predict then propagate: Graph neural networks meet personalized pagerank. In ICLR, 2022.
- Rethinking spectral graph neural networks with spatially adaptive filtering, 2024.
- Inductive representation learning on large graphs. In NeurIPS, 2017.
- Bernnet: Learning arbitrary graph spectral filters via bernstein approximation. In NeurIPS, 2021.
- Higher-order graph convolutional network with flower-petals laplacians on simplicial complexes, 2023.
- Uncertainty quantification via spatial-temporal tweedie model for zero-inflated and long-tail travel demand prediction. In CIKM, 2023.
- Incomplete graph learning via attribute-structure decoupled variational auto-encoder. In WSDM, 2024.
- Feature overcorrelation in deep graph neural networks: A new perspective. In SIGKDD, 2022.
- Adam: A method for stochastic optimization. In ICLR, 2015.
- Semi-supervised classification with graph convolutional networks. In ICLR, 2016.
- Deepgcns: Can gcns go as deep as cnns? In ICCV, 2019.
- Mining spatio-temporal relations via self-paced graph contrastive learning. In SIGKDD, 2022.
- A generalized neural diffusion framework on graphs. In AAAI, 2024.
- Learning strong graph neural networks with weak information. In SIGKDD, 2023.
- Ulrike Luxburg. A tutorial on spectral clustering, 2007.
- Uncovering the largest community in social networks at scale. In IJCAI, 2023.
- Geometric deep learning on graphs and manifolds using mixture model cnns. In NeurIPS, 2016.
- Bogdan Nica. A Brief Introduction to Spectral Graph Theory. EMS Press, 2018.
- Graph signal processing: Overview, challenges, and applications. IEEE, 2018.
- Pytorch: An imperative style, high-performance deep learning library. In NeurIPS, 2019.
- Next point-of-interest recommendation with auto-correlation enhanced multi-modal transformer network. In SIGIR, 2022.
- Frank Rosenblatt. Principles of neurodynamics. perceptrons and the theory of brain mechanisms. AJP, 1963.
- A survey on oversmoothing in graph neural networks, 2023.
- The emerging field of signal processing on graphs: Extending high-dimensional data analysis to networks and other irregular domains. IEEE Signal Processing Magazine, 2013.
- Graph attention networks. In ICLR, 2018.
- No free lunch theorems for optimization. IEEE Transactions on Evolutionary Computation, 1997.
- Simplifying graph convolutional networks. In ICML, 2019.
- How powerful are graph neural networks? In ICLR, 2019.
- Learning from labeled and unlabeled data with label propagation. Citeseer, 2002.
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