Adversarial Federated Consensus Learning for Surface Defect Classification Under Data Heterogeneity in IIoT
- URL: http://arxiv.org/abs/2409.15711v2
- Date: Fri, 1 Nov 2024 03:17:03 GMT
- Title: Adversarial Federated Consensus Learning for Surface Defect Classification Under Data Heterogeneity in IIoT
- Authors: Jixuan Cui, Jun Li, Zhen Mei, Yiyang Ni, Wen Chen, Zengxiang Li,
- Abstract summary: It's difficult to collect and centralize sufficient training data from various entities in Industrial Internet of Things (IIoT)
Federated learning (FL) provides a solution by enabling collaborative global model training across clients.
We propose a novel personalized FL approach, named Adversarial Federated Consensus Learning (AFedCL)
- Score: 8.48069043458347
- License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
- Abstract: The challenge of data scarcity hinders the application of deep learning in industrial surface defect classification (SDC), as it's difficult to collect and centralize sufficient training data from various entities in Industrial Internet of Things (IIoT) due to privacy concerns. Federated learning (FL) provides a solution by enabling collaborative global model training across clients while maintaining privacy. However, performance may suffer due to data heterogeneity-discrepancies in data distributions among clients. In this paper, we propose a novel personalized FL (PFL) approach, named Adversarial Federated Consensus Learning (AFedCL), for the challenge of data heterogeneity across different clients in SDC. First, we develop a dynamic consensus construction strategy to mitigate the performance degradation caused by data heterogeneity. Through adversarial training, local models from different clients utilize the global model as a bridge to achieve distribution alignment, alleviating the problem of global knowledge forgetting. Complementing this strategy, we propose a consensus-aware aggregation mechanism. It assigns aggregation weights to different clients based on their efficacy in global knowledge learning, thereby enhancing the global model's generalization capabilities. Finally, we design an adaptive feature fusion module to further enhance global knowledge utilization efficiency. Personalized fusion weights are gradually adjusted for each client to optimally balance global and local features. Compared with state-of-the-art FL methods like FedALA, the proposed AFedCL method achieves an accuracy increase of up to 5.67% on three SDC datasets.
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