FedRGL: Robust Federated Graph Learning for Label Noise
- URL: http://arxiv.org/abs/2411.18905v1
- Date: Thu, 28 Nov 2024 04:37:04 GMT
- Title: FedRGL: Robust Federated Graph Learning for Label Noise
- Authors: De Li, Haodong Qian, Qiyu Li, Zhou Tan, Zemin Gan, Jinyan Wang, Xianxian Li,
- Abstract summary: Federated Graph Learning (FGL) is a distributed machine learning paradigm based on graph neural networks.
We propose a robust federated graph learning method with label noise, termed FedRGL.
We show that FedRGL outperforms 12 baseline methods across various noise rates, types, and numbers of clients.
- Score: 5.296582539751589
- License:
- Abstract: Federated Graph Learning (FGL) is a distributed machine learning paradigm based on graph neural networks, enabling secure and collaborative modeling of local graph data among clients. However, label noise can degrade the global model's generalization performance. Existing federated label noise learning methods, primarily focused on computer vision, often yield suboptimal results when applied to FGL. To address this, we propose a robust federated graph learning method with label noise, termed FedRGL. FedRGL introduces dual-perspective consistency noise node filtering, leveraging both the global model and subgraph structure under class-aware dynamic thresholds. To enhance client-side training, we incorporate graph contrastive learning, which improves encoder robustness and assigns high-confidence pseudo-labels to noisy nodes. Additionally, we measure model quality via predictive entropy of unlabeled nodes, enabling adaptive robust aggregation of the global model. Comparative experiments on multiple real-world graph datasets show that FedRGL outperforms 12 baseline methods across various noise rates, types, and numbers of clients.
Related papers
- Mixture of Experts Meets Decoupled Message Passing: Towards General and Adaptive Node Classification [4.129489934631072]
Graph neural networks excel at graph representation learning but struggle with heterophilous data and long-range dependencies.
We propose GNNMoE, a universal model architecture for node classification.
We show that GNNMoE performs exceptionally well across various types of graph data, effectively alleviating the over-smoothing issue and global noise.
arXiv Detail & Related papers (2024-12-11T08:35:13Z) - Federated Graph Learning with Structure Proxy Alignment [43.13100155569234]
Federated Graph Learning (FGL) aims to learn graph learning models over graph data distributed in multiple data owners.
We propose FedSpray, a novel FGL framework that learns local class-wise structure proxies in the latent space.
Our goal is to obtain the aligned structure proxies that can serve as reliable, unbiased neighboring information for node classification.
arXiv Detail & Related papers (2024-08-18T07:32:54Z) - Variational Graph Auto-Encoder Based Inductive Learning Method for Semi-Supervised Classification [10.497590357666114]
We propose the Self-Label Augmented VGAE model for inductive graph representation learning.
To leverage the label information for training, our model takes node labels as one-hot encoded inputs and then performs label reconstruction in model training.
Our proposed model archives promise results on node classification with particular superiority under semi-supervised learning settings.
arXiv Detail & Related papers (2024-03-26T08:59:37Z) - Chasing Fairness in Graphs: A GNN Architecture Perspective [73.43111851492593]
We propose textsfFair textsfMessage textsfPassing (FMP) designed within a unified optimization framework for graph neural networks (GNNs)
In FMP, the aggregation is first adopted to utilize neighbors' information and then the bias mitigation step explicitly pushes demographic group node presentation centers together.
Experiments on node classification tasks demonstrate that the proposed FMP outperforms several baselines in terms of fairness and accuracy on three real-world datasets.
arXiv Detail & Related papers (2023-12-19T18:00:15Z) - Combating Bilateral Edge Noise for Robust Link Prediction [56.43882298843564]
We propose an information-theory-guided principle, Robust Graph Information Bottleneck (RGIB), to extract reliable supervision signals and avoid representation collapse.
Two instantiations, RGIB-SSL and RGIB-REP, are explored to leverage the merits of different methodologies.
Experiments on six datasets and three GNNs with diverse noisy scenarios verify the effectiveness of our RGIB instantiations.
arXiv Detail & Related papers (2023-11-02T12:47:49Z) - Optimal Propagation for Graph Neural Networks [51.08426265813481]
We propose a bi-level optimization approach for learning the optimal graph structure.
We also explore a low-rank approximation model for further reducing the time complexity.
arXiv Detail & Related papers (2022-05-06T03:37:00Z) - Noise-robust Graph Learning by Estimating and Leveraging Pairwise
Interactions [123.07967420310796]
This paper bridges the gap by proposing a pairwise framework for noisy node classification on graphs.
PI-GNN relies on the PI as a primary learning proxy in addition to the pointwise learning from the noisy node class labels.
Our proposed framework PI-GNN contributes two novel components: (1) a confidence-aware PI estimation model that adaptively estimates the PI labels, and (2) a decoupled training approach that leverages the estimated PI labels.
arXiv Detail & Related papers (2021-06-14T14:23:08Z) - FedGL: Federated Graph Learning Framework with Global Self-Supervision [22.124339267195822]
FedGL is capable of obtaining a high-quality global graph model while protecting data privacy.
The global self-supervision enables the information of each client to flow and share in a privacy-preserving manner.
arXiv Detail & Related papers (2021-05-07T11:27:23Z) - Unified Robust Training for Graph NeuralNetworks against Label Noise [12.014301020294154]
We propose a new framework, UnionNET, for learning with noisy labels on graphs under a semi-supervised setting.
Our approach provides a unified solution for robustly training GNNs and performing label correction simultaneously.
arXiv Detail & Related papers (2021-03-05T01:17:04Z) - Robust Optimization as Data Augmentation for Large-scale Graphs [117.2376815614148]
We propose FLAG (Free Large-scale Adversarial Augmentation on Graphs), which iteratively augments node features with gradient-based adversarial perturbations during training.
FLAG is a general-purpose approach for graph data, which universally works in node classification, link prediction, and graph classification tasks.
arXiv Detail & Related papers (2020-10-19T21:51:47Z) - Contrastive and Generative Graph Convolutional Networks for Graph-based
Semi-Supervised Learning [64.98816284854067]
Graph-based Semi-Supervised Learning (SSL) aims to transfer the labels of a handful of labeled data to the remaining massive unlabeled data via a graph.
A novel GCN-based SSL algorithm is presented in this paper to enrich the supervision signals by utilizing both data similarities and graph structure.
arXiv Detail & Related papers (2020-09-15T13:59:28Z)
This list is automatically generated from the titles and abstracts of the papers in this site.
This site does not guarantee the quality of this site (including all information) and is not responsible for any consequences.