广西师范大学学报(自然科学版) ›› 2026, Vol. 44 ›› Issue (4): 46-55.doi: 10.16088/j.issn.1001-6600.2025072401

• 物理与电子工程 • 上一篇    下一篇

基于TD3算法的电动汽车智能充/放电调度策略

张旭1,2, 刘迪迪1,2*   

  1. 1.广西类脑计算与智能芯片重点实验室(广西师范大学), 广西 桂林 541004;
    2.广西师范大学 电子与信息工程学院/集成电路学院, 广西 桂林 541004
  • 收稿日期:2025-07-24 修回日期:2025-12-30 出版日期:2026-07-05 发布日期:2026-07-01
  • 通讯作者: 刘迪迪(1980—),女,江苏徐州人,广西师范大学教授。E-mail: ldd866@gxnu.edu.cn
  • 基金资助:
    国家自然科学基金(1216200)

Intelligent charging/discharging scheduling strategy for electric vehicles based on TD3 algorithm

Zhang Xu1,2, Liu Didi1,2*   

  1. 1. Guangxi Key Laboratory of Brain-inspired Computing and Intelligent Chips(Guangxi Normal University), Guilin Guangxi 541004, China;
    2. School of Electronics and Information Engineering/School of Integrated Circuits, Guangxi Normal University, Guilin Guangxi 541004, China
  • Received:2025-07-24 Revised:2025-12-30 Online:2026-07-05 Published:2026-07-01

摘要: 伴随电动汽车(electric vehicle, EV)规模化发展,其作为“移动储能单元”不容忽视的调控潜力,正深刻影响电力系统运行范式。在EV入网的背景下,充分考虑EV的可控负荷和移动储能的双重特性,本文构建一个综合EV的充电需求、动态电价、储能时间耦合约束及电池寿命损耗等多重关键因素的EV动态充/放电调度模型。针对EV接入充电时间和初始状态随机性,以及传统强化学习方法在决策变量连续控制场景中的维数灾难与收敛困难问题,本文提出一种基于TD3的智能充/放电控制与优化调度算法,该算法通过智能体与环境持续交互、设计奖励反馈机制,能够根据电价波动做出最佳充/放电决策,并保证在充电结束后达到预期充电量,从而实现对EV充/放电行为的智能控制和优化调度,最小化EV的充电成本。基于真实场景数据进行仿真,结果表明所提算法能够有效适应智能电网中电价的动态变化,有效降低EV用户的充电成本。与DDPG(deep deterministic policy gradient)、DQN(deep Q-network)、PSO(particle swarm optimization)等一系列主流算法相比,本文所提算法将充电成本降低4.41%至24.23%,充分验证了其性能与经济性优势。

关键词: 智能电网, 电动汽车, 车网互动, 充/放电调度, 深度强化学习

Abstract: With the large-scale development of Electric Vehicle (EV), their regulatory potential as "mobile energy storage units" cannot be overlooked, which profoundly influence the operational paradigm of power systems. In the context of EV grid integration, fully considering the dual characteristics of EV as controllable loads and mobile energy storage, a comprehensive dynamic charging/discharging scheduling model for EV is constructed, incorporating multiple key factors such as EV charging demand, dynamic electricity prices, time-coupling constraints of energy storage, and battery degradation. To address the randomness of EV charging start times and initial states, as well as the curse of dimensionality and convergence difficulties of traditional reinforcement learning methods in scenarios with continuous decision variables, an intelligent charging/discharging control and optimal scheduling algorithm based on Twin Delayed Deep Deterministic Policy Gradient (TD3) is proposed. Through continuous interaction between the agent and the environment and the design of a reward feedback mechanism, this algorithm can make optimal charging/discharging decisions based on electricity price fluctuations, ensuring that the expected charging capacity is achieved after the charging process, thereby realizing intelligent control and optimal scheduling of EV charging/discharging behavior to minimize charging costs. Simulations based on real-world scenario data demonstrate that the proposed algorithm effectively adapts to dynamic electricity price changes in smart grids and significantly reduces charging costs for EV users. Compared with a series of mainstream algorithms (such as DDPG, DQN, PSO, etc.), the proposed algorithm reduces charging costs by 4.41% to 24.23%, fully validating its performance and economic advantages.

Key words: smart grid, electric vehicle, vehicle-to-grid, charge/discharge scheduling, deep reinforcement learning

中图分类号:  TM734

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