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Energy-Aware Analog Aggregation for Federated Learning with Redundant Data

Yuxuan Sun, Sheng Zhou, Denız Gündüz

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Abstract

Federated learning (FL) enables workers to learn a model collaboratively by using their local data, with the help of a parameter server (PS) for global model aggregation. The high communication cost for periodic model updates and the nonindependent and identically distributed (i.i.d.) data become major bottlenecks for FL. In this work, we consider analog aggregation to scale down the communication cost with respect to the number of workers, and introduce data redundancy to the system to deal with non-i.i.d. data. We propose an online energy-aware dynamic worker scheduling policy, which maximizes the average number of workers scheduled for gradient update at each iteration under a long-term energy constraint, and analyze its performance based on Lyapunov optimization. Experiments using MNIST dataset show that, for non-i.i.d. data, doubling data storage can improve the accuracy by 9.8% under a stringent energy budget, while the proposed policy can achieve close-to-optimal accuracy without violating the energy constraint.

Topics & Concepts

Computer scienceMNIST databaseData aggregatorIndependent and identically distributed random variablesConstraint (computer-aided design)Redundancy (engineering)Federated learningData modelingMathematical optimizationDistributed computingArtificial intelligenceDeep learningDatabaseWireless sensor networkOperating systemStatisticsRandom variableMechanical engineeringComputer networkEngineeringMathematicsPrivacy-Preserving Technologies in DataAge of Information OptimizationAdvanced MIMO Systems Optimization