基于神经网络的性能驱动型时间自适应随机单元承诺

IF 6.5 1区 工程技术 Q1 ENGINEERING, ELECTRICAL & ELECTRONIC
Wenwen Zhang;Gao Qiu;Hongjun Gao;Yaping Li;Shengchun Yang;Jiahao Yan;Wenbo Mao;Junyong Liu
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引用次数: 0

摘要

低效率和电力不平衡风险对老式的固定时间分辨率调度提出了挑战,尤其是在可再生能源大量渗透的情况下。为解决这些问题,最近提出了时间自适应机组承诺(T-UC)。然而,现有的 T-UC 方法都是主观开环的,因此可能离最优还很远。为了进一步改进 T-UC,本文提出了一种基于神经网络(NN)的性能驱动型时间自适应随机 UC(T-SUC)。它首先利用多变量预测的 k-means++ 来解决 SUC 的调度问题。然后,用神经网络对 SUC 的性能进行编码,包括在最细范围内的计算工作量和功率不平衡风险 (PIR)。通过对神经网络的分析,我们可以进一步反馈性能,从而控制调度分辨率。数值研究证明,与最近的 T-UC 竞争对手相比,我们的方法在最精细的日内时间分辨率上减少了 40% 以上的 PIR,而且耗时最快。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Performance-Driven Time-Adaptive Stochastic Unit Commitment Based on Neural Network
The low-efficiency and power imbalance risk have challenged the aging fixed time resolution scheduling, especially when facing largely penetrated renewable energies. Time-adaptive unit commitment (T-UC) is recently advanced to solve the issues. However, existing T-UC methods are subjective open-looped, thus may be still far from optimality. To further improve the T-UC, a performance-driven time-adaptive stochastic UC (T-SUC) based on neural network (NN) is proposed. It firstly leverages k-means++ on multivariate forecasts to settle dispatch resolution for SUC. Then, the SUC performances, involving computing efforts and power imbalance risks (PIRs) at the finest horizon, are encoded by neural network. The analyzing for the NN further allows us to feedback the performances to control dispatch resolution. Numerical studies justify that, compared to recent T-UC rivals, our method reduces over 40% of the PIR on the finest intraday time resolution, with the fastest elapsed time.
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来源期刊
IEEE Transactions on Power Systems
IEEE Transactions on Power Systems 工程技术-工程:电子与电气
CiteScore
15.80
自引率
7.60%
发文量
696
审稿时长
3 months
期刊介绍: The scope of IEEE Transactions on Power Systems covers the education, analysis, operation, planning, and economics of electric generation, transmission, and distribution systems for general industrial, commercial, public, and domestic consumption, including the interaction with multi-energy carriers. The focus of this transactions is the power system from a systems viewpoint instead of components of the system. It has five (5) key areas within its scope with several technical topics within each area. These areas are: (1) Power Engineering Education, (2) Power System Analysis, Computing, and Economics, (3) Power System Dynamic Performance, (4) Power System Operations, and (5) Power System Planning and Implementation.
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