Learning Heterogeneous Performance-Fairness Trade-offs in Federated Learning

• URL: http://arxiv.org/abs/2504.21775v1
• Date: Wed, 30 Apr 2025 16:25:02 GMT
• Title: Learning Heterogeneous Performance-Fairness Trade-offs in Federated Learning
• Authors: Rongguang Ye, Ming Tang,
• Abstract summary: HetPFL comprises Preference Sampling Adaptation (PSA) and Preference-aware Hypernet Fusion (PHF)<n>We prove that HetPFL converges linearly with respect to the number of rounds, under weaker assumptions than existing methods.
• Score: 6.6763659758988885
• License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
• Abstract: Recent methods leverage a hypernet to handle the performance-fairness trade-offs in federated learning. This hypernet maps the clients' preferences between model performance and fairness to preference-specifc models on the trade-off curve, known as local Pareto front. However, existing methods typically adopt a uniform preference sampling distribution to train the hypernet across clients, neglecting the inherent heterogeneity of their local Pareto fronts. Meanwhile, from the perspective of generalization, they do not consider the gap between local and global Pareto fronts on the global dataset. To address these limitations, we propose HetPFL to effectively learn both local and global Pareto fronts. HetPFL comprises Preference Sampling Adaptation (PSA) and Preference-aware Hypernet Fusion (PHF). PSA adaptively determines the optimal preference sampling distribution for each client to accommodate heterogeneous local Pareto fronts. While PHF performs preference-aware fusion of clients' hypernets to ensure the performance of the global Pareto front. We prove that HetPFL converges linearly with respect to the number of rounds, under weaker assumptions than existing methods. Extensive experiments on four datasets show that HetPFL significantly outperforms seven baselines in terms of the quality of learned local and global Pareto fronts.

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