Abstract
This paper proposes a privacy-preserving energy management of a shared energy storage system (SESS) for multiple smart buildings using federated reinforcement learning (FRL). To preserve the privacy of energy scheduling of buildings connected to the SESS, we present a distributed deep reinforcement learning (DRL) framework using the FRL method, which consists of a global server (GS) and local building energy management systems (LBEMSs). In the framework, the LBEMS DRL agents share only a randomly selected part of their trained neural network for energy consumption models with the GS without consumer’s energy consumption data. Using the shared models, the GS executes two processes: (i) construction and broadcast of a global model of energy consumption to the LBEMS agents for retraining their local models and (ii) training of the SESS DRL agent’s energy charging and discharging from and to the utility and buildings. Simulation studies are conducted using one SESS and three smart buildings with solar photovoltaic systems. The results demonstrate that the proposed approach can schedule the charging and discharging of the SESS and an optimal energy consumption of heating, ventilation, and air conditioning systems in smart buildings under heterogeneous building environments while preserving the privacy of buildings’ energy consumption.
Highlights
A shared energy storage system (SESS) is a promising technology to efficiently manage the energy consumption in residential and commercial sectors
(b) Sample an action aSt ESS based on distribution N(μSt ESS, {σtSESS}2) generated by the actor network and the key functions given by state sSt ESS, which includes the inferred energy consumption data for all local building energy management systems (LBEMSs)
It is assumed that a single communication round between the LBEMS and the global server (GS) occured every 150 iterations that are required for the LBEMS training
Summary
A shared energy storage system (SESS) is a promising technology to efficiently manage the energy consumption in residential and commercial sectors. There have been various optimization methods (e.g., robust optimization, stochastic programming, and model predictive control (MPC)) for the energy management of smart residential and commercial buildings while considering their uncertain and dynamic operation characteristics. In FL, local and global neural network models between the local agents and the GS are exchanged without their private local data being shared to preserve consumer data privacy For applying this FL concept to various engineering control problems, federated reinforcement learning (FRL) [31] was proposed wherein the optimal policy for individual agent was calculated as long as ensuring that the data were not shared among agents during the training process. Our recent study [35] developed a privacy-preserving FRL framework to manage the energy consumption of multiple smart homes with DERs. In this study, the DRL agents for home appliances such as air conditioners, washing machines and residential ESS iteratively interact with the GS to build their optimal energy consumption model in multiple homes. To find the optimal policy πθ∗ when the agent executes the that maximizes the action according to policy πθ
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