Multi-Microgrid Energy Trading Strategy Based on Multi-Agent Deep Deterministic Policy Gradient Algorithm

[1] Shafiullah, M., Refat, A. M., Haque, M. E., Chowdhury, D. M. H., Hossain, M. S., Alharbi, A. G., Alam, M. S., Ali, A., & Hossain, S. (2022). Review of recent developments in microgrid energy management strategies. Sustainability, 14, 14794. Search in Google Scholar

[2] Du, C., Du, X., Tong, C., Li, Y., & Zhou, P. (2023). Stability analysis for DFIG-based wind farm grid-connected system under all wind speed conditions. IEEE Transactions on Industry Applications, 59, 2430–2445. Search in Google Scholar

[3] Zhou, X., Pang, C., Zeng, X., Jiang, L., & Chen, Y. (2023). A short-term power prediction method based on temporal convolutional network in virtual power plant photovoltaic system. IEEE Transactions on Instrumentation and Measurement, 72, 1–10. Search in Google Scholar

[4] Liu, Y., Li, P., Xing, Z., Han, X., Fu, Q., & Jiang, Z. (2024). Research on microgrid superconductivity-battery energy storage control strategy based on adaptive dynamic programming. IEEE Transactions on Applied Superconductivity, 34, 1–4. Search in Google Scholar

[5] Wang, J., Chen, L., Tan, Z., Du, E., Liu, N., Ma, J., Sun, M., Li, C., Song, J., … & Lu, X. (2023). Inherent spatiotemporal uncertainty of renewable power in China. Nature Communications, 14, 5379. Search in Google Scholar

[6] An, D., Yang, Q., Li, D., & Wu, Z. (2024). Distributed online incentive scheme for energy trading in multi-microgrid systems. IEEE Transactions on Automation Science and Engineering, 21, 951–964. Search in Google Scholar

[7] Huang, B., & Wang, J. (2023). Applications of physics-informed neural networks in power systems - A review. IEEE Transactions on Power Systems, 38, 572–588. Search in Google Scholar

[8] Li, B., & Roche, R. (2020). Optimal scheduling of multiple multi-energy supply microgrids considering future prediction impacts based on model predictive control. Energy, 197, 117180. Search in Google Scholar

[9] Kunya, A. B., Abubakar, A. S., & Yusuf, S. S. (2023). Review of economic dispatch in multi-area power system: State-of-the-art and future prospective. Electric Power Systems Research, 217, 109089. Search in Google Scholar

[10] El-Sayed, W. T., Awad, A. S. A., Azzouz, M. A., & Shaaban, M. F. (2023). A new economic dispatch for coupled transmission and active distribution networks via hierarchical communication structure. IEEE Systems Journal, 17, 6226–6236. Search in Google Scholar

[11] Yin, L. F., & Cai, Z. J. (2024). Multimodal hierarchical distributed multi-objective moth intelligence algorithm for economic dispatch of power systems. Journal of Cleaner Production, 434, 140130. Search in Google Scholar

[12] Liu, H., Li, J. F., Ge, S. Y., Zhang, P., & Chen, X. Y. (2019). Coordinated scheduling of grid-connected integrated energy microgrid based on multi-agent game and reinforcement learning. Automation of Electric Power Systems, 43, 40–48. Search in Google Scholar

[13] Lin, M. H., Liu, J., Tang, Z., Zeng, P. L., Jiang, B., & Ma, G. J. (2024). Coordinated optimization of mixed microgrid multi-agent game considering multi-energy coupled shared energy storage. Automation of Electric Power Systems, 48, 132–141. Search in Google Scholar

[14] Yang, X., He, H., Zhang, Y., Chen, Y., & Weng, G. (2019). Interactive energy management for enhancing power balances in multi-microgrids. IEEE Transactions on Smart Grid, 10, 6055–6069. Search in Google Scholar

[15] Huang, X. C., Feng, Y., & Ding, Z. H. (2020). Design of multi-time scale trading mechanism and trading strategy optimization for multiple microgrids. Automation of Electric Power Systems, 44, 77–88. Search in Google Scholar

[16] Chen, C. Y., Miao, S. H., Yao, F. X., Wang, Y. S., Wang, J. X., & Wei, W. R. (2023). Hierarchical cooperative dispatching strategy of multi-microgrid and distribution networks based on multi-agent algorithm. Automation of Electric Power Systems, 47, 57–65. Search in Google Scholar

[17] Zhou, Y. B., Xiao, H., Pei, W., & Wang, X. J. (2023). Collaborative optimization operation and strategy evolution of microgrid cluster based on vertical federated learning. Automation of Electric Power Systems, 47, 121–132. Search in Google Scholar

[18] Ju, Y. T., Chen, X., Li, J. W., & Wang, J. (2023). Active and reactive power coordinated optimal dispatch of networked microgrids based on distributed deep reinforcement learning. Automation of Electric Power Systems, 47, 115–125. Search in Google Scholar

[19] Daniel, J. B., Cao, J., & Fan, Z. (2022). Renewable energy integration and microgrid energy trading using multi-agent deep reinforcement learning. Applied Energy, 318, 119151. Search in Google Scholar

[20] Qiu, C., Hu, Y., Chen, Y., & Zeng, B. (2019). Deep deterministic policy gradient (DDPG)-based energy harvesting wireless communications. IEEE Internet of Things Journal, 6, 8577–8588. Search in Google Scholar

[21] Middya, A. I., & Roy, S. (2024). Truthful double auction-based incentive mechanism for participatory sensing systems. Peer-to-Peer Networking and Applications, 17, 2137–2166. Search in Google Scholar

[22] Ausgrid. (n.d.). Home. Retrieved August 27, 2024, from https://www.ausgrid.com.au/ Search in Google Scholar

[23] Elia. (n.d.). Belgian’s electricity system operator. Retrieved August 27, 2024, from https://www.elia.be/ Search in Google Scholar

[24] Australian Energy Market Operator (AEMO). (n.d.). WEM data dashboard. Retrieved August 27, 2024, from https://aemo.com.au/energy-systems/electricity/wholesale-electricity-market-wem/data-wem/data-dashboard/ Search in Google Scholar