A Field Guide to Federated Optimization
/ Authors
Jianyu Wang, Zachary B. Charles, Zheng Xu, Gauri Joshi, H. B. McMahan, B. A. Y. Arcas, Maruan Al-Shedivat, Galen Andrew, S. Avestimehr, Katharine Daly
and 43 more authors
Deepesh Data, S. Diggavi, Hubert Eichner, Advait Gadhikar, Zachary Garrett, Antonious M. Girgis, Filip Hanzely, Andrew Straiton Hard, Chaoyang He, Samuel Horváth, Zhouyuan Huo, A. Ingerman, Martin Jaggi, T. Javidi, P. Kairouz, Satyen Kale, Sai Praneeth Karimireddy, Jakub Konecný, Sanmi Koyejo, Tian Li, Luyang Liu, M. Mohri, H. Qi, Sashank J. Reddi, Peter Richtárik, K. Singhal, Virginia Smith, M. Soltanolkotabi, Weikang Song, A. Suresh, Sebastian U. Stich, Ameet Talwalkar, Hongyi Wang, Blake E. Woodworth, Shanshan Wu, Felix X. Yu, Honglin Yuan, M. Zaheer, Mi Zhang, Tong Zhang, Chunxiang Zheng, Chen Zhu, Wennan Zhu
/ Abstract
Federated learning and analytics are a distributed approach for collaboratively learning models (or statistics) from decentralized data, motivated by and designed for privacy protection. The distributed learning process can be formulated as solving federated optimization problems, which emphasize communication efficiency, data heterogeneity, compatibility with privacy and system requirements, and other constraints that are not primary considerations in other problem settings. This paper provides recommendations and guidelines on formulating, designing, evaluating and analyzing federated optimization algorithms through concrete examples and practical implementation, with a focus on conducting effective simulations to infer real-world performance. The goal of this work is not to survey the current literature, but to inspire researchers and practitioners to design federated learning algorithms that can be used in various practical applications.
Journal: ArXiv