AFBS:Buffer Gradient Selection in Semi-asynchronous Federated Learning
This addresses performance degradation in federated learning for heterogeneous systems, offering a novel privacy-preserving method that is incremental over existing buffer-based approaches.
The paper tackles gradient staleness in semi-asynchronous federated learning by proposing AFBS, an algorithm that selects high-value gradients from buffers, improving accuracy by up to 4.8% on CIFAR-100 and reducing training time by 75%.
Asynchronous federated learning (AFL) accelerates training by eliminating the need to wait for stragglers, but its asynchronous nature introduces gradient staleness, where outdated gradients degrade performance. Existing solutions address this issue with gradient buffers, forming a semi-asynchronous framework. However, this approach struggles when buffers accumulate numerous stale gradients, as blindly aggregating all gradients can harm training. To address this, we propose AFBS (Asynchronous FL Buffer Selection), the first algorithm to perform gradient selection within buffers while ensuring privacy protection. Specifically, the client sends the random projection encrypted label distribution matrix before training, and the server performs client clustering based on it. During training, server scores and selects gradients within each cluster based on their informational value, discarding low-value gradients to enhance semi-asynchronous federated learning. Extensive experiments in highly heterogeneous system and data environments demonstrate AFBS's superior performance compared to state-of-the-art methods. Notably, on the most challenging task, CIFAR-100, AFBS improves accuracy by up to 4.8% over the previous best algorithm and reduces the time to reach target accuracy by 75%.