FedGPO: Heterogeneity-Aware Global Parameter Optimization for Efficient
Federated Learning
- URL: http://arxiv.org/abs/2211.16669v1
- Date: Wed, 30 Nov 2022 01:22:57 GMT
- Title: FedGPO: Heterogeneity-Aware Global Parameter Optimization for Efficient
Federated Learning
- Authors: Young Geun Kim and Carole-Jean Wu
- Abstract summary: Federated learning (FL) has emerged as a solution to deal with the risk of privacy leaks in machine learning training.
We propose FedGPO to optimize the energy-efficiency of FL use cases while guaranteeing model convergence.
In our experiments, FedGPO improves the model convergence time by 2.4 times, and achieves 3.6 times higher energy efficiency over the baseline settings.
- Score: 11.093360539563657
- License: http://creativecommons.org/licenses/by/4.0/
- Abstract: Federated learning (FL) has emerged as a solution to deal with the risk of
privacy leaks in machine learning training. This approach allows a variety of
mobile devices to collaboratively train a machine learning model without
sharing the raw on-device training data with the cloud. However, efficient edge
deployment of FL is challenging because of the system/data heterogeneity and
runtime variance. This paper optimizes the energy-efficiency of FL use cases
while guaranteeing model convergence, by accounting for the aforementioned
challenges. We propose FedGPO based on a reinforcement learning, which learns
how to identify optimal global parameters (B, E, K) for each FL aggregation
round adapting to the system/data heterogeneity and stochastic runtime
variance. In our experiments, FedGPO improves the model convergence time by 2.4
times, and achieves 3.6 times higher energy efficiency over the baseline
settings, respectively.
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