DR-DSGD: A Distributionally Robust Decentralized Learning Algorithm over Graphs
Abstract
In this paper, we propose to solve a regularized distributionally robust learning problem in the decentralized setting, taking into account the data distribution shift. By adding a Kullback-Liebler regularization function to the robust min-max optimization problem, the learning problem can be reduced to a modified robust minimization problem and solved efficiently. Leveraging the newly formulated optimization problem, we propose a robust version of Decentralized Stochastic Gradient Descent (DSGD), coined Distributionally Robust Decentralized Stochastic Gradient Descent (DR-DSGD). Under some mild assumptions and provided that the regularization parameter is larger than one, we theoretically prove that DR-DSGD achieves a convergence rate of , where is the number of devices and is the number of iterations. Simulation results show that our proposed algorithm can improve the worst distribution test accuracy by up to . Moreover, DR-DSGD is more communication-efficient than DSGD since it requires fewer communication rounds (up to times less) to achieve the same worst distribution test accuracy target. Furthermore, the conducted experiments reveal that DR-DSGD results in a fairer performance across devices in terms of test accuracy.
Cite
@article{arxiv.2208.13810,
title = {DR-DSGD: A Distributionally Robust Decentralized Learning Algorithm over Graphs},
author = {Chaouki Ben Issaid and Anis Elgabli and Mehdi Bennis},
journal= {arXiv preprint arXiv:2208.13810},
year = {2022}
}
Comments
Accepted at Transactions on Machine Learning Research (TMLR)