Federated learning increasingly operates in a large-model regime where communication, memory, and computation are all scarce. Typically, non-IID client data induce drift that degrades the stability and performance of local training. Existing remedies such as SCAFFOLD introduce heterogeneity-correction mechanisms to address this challenge, but they incur substantial extra communication and memory overhead. This paper proposes a subspace optimization method for federated learning (SSF), which performs heterogeneity-corrected optimization in a low-dimensional subspace using only projected quantities, while preserving full-dimensional control information through a backfill-style update that retains residual components whenever the active subspace changes. Under standard smoothness and bounded-variance assumptions, SSF attains a non-asymptotic rate of order O(1/T+1/NKT). Experiments show favorable accuracy--efficiency trade-offs under heterogeneous data.
@article{arxiv.2604.25467,
title = {Subspace Optimization for Efficient Federated Learning under Heterogeneous Data},
author = {Shuchen Zhu and Zhengyang Huang and Yuqi Xu and Peijin Li},
journal= {arXiv preprint arXiv:2604.25467},
year = {2026}
}