Abstract
The proliferation of distributed renewable energy resources (RESs) poses major challenges to the operation of microgrids due to uncertainty. Traditional online scheduling approaches relying on accurate forecasts become difficult to implement due to the increase of uncertain RESs. Although several data-driven methods have been proposed recently to overcome the challenge, they generally suffer from a scalability issue due to the limited ability to optimize high-dimensional continuous control variables. To address these issues, we propose a data-driven online scheduling method for microgrid energy optimization based on continuous-control deep reinforcement learning (DRL). We formulate the online scheduling problem as a Markov decision process (MDP). The objective is to minimize the operating cost of the microgrid considering the uncertainty of RESs generation, load demand, and electricity prices. To learn the optimal scheduling strategy, a Gated Recurrent Unit (GRU)-based network is designed to extract temporal features of uncertainty and generate the optimal scheduling decisions in an end-to-end manner. To optimize the policy with high-dimensional and continuous actions, proximal policy optimization (PPO) is employed to train the neural network-based policy in a data-driven fashion. The proposed method does not require any forecasting information on the uncertainty or a prior knowledge of the physical model of the microgrid. Simulation results using realistic power system data of California Independent System Operator (CAISO) demonstrate the effectiveness of the proposed method.
Highlights
We propose a novel online scheduling method for microgrid energy management based on a continuous-control deep reinforcement learning (DRL) algorithm
To validate the effectiveness of the decisions made by the proposed approach, the scheduling results on seven consecutive testing days are presented in Figure 8, which includes the charging/discharging power and state-of-charge (SOC) pattern of the battery, the power output of the distributed generators (DGs), the exchanged power between the microgrid and utility grid, Net load
We proposed a continuous-control DRL-based method for online energy scheduling of a microgrid
Summary
Microgrids have been widely adopted and deployed in modern power systems to improve energy efficiency and power supply security by integrating distributed energy resources [1]. According to statistics by BNResearch [2], there have been 6610 microgrid projects globally representing 31.7 GW of planned and installed power capacity by March. The rapid deployment of microgrids brings many advantageous features, such as reducing long-distance transmission losses, decreasing the cost of the energy mix, and providing a new paradigm of energy infrastructure for future smart cities [3]. Due to some special features in these small, self-governing systems, energy management of microgrids faces several major challenges. Microgrids contain various heterogeneous resources, such as energy storage systems (ESS) and dependent response resources, which cannot be dispatched according to the conventional unit-commitment and economic dispatch methods
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