电力传输系统中传输功率估计的机器学习方法

V. Kapranov, V. Tugaenko
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引用次数: 0

摘要

目前,预测性机器学习方法被用于生活的许多领域——从交通预测到医疗诊断。近年来,这些方法也出现在大气研究中,首先用于湍流参数的估计,这些任务是定性解决大气光通信问题所必需的。这项工作的目的是展示在不断变化的大气条件下,使用机器学习算法实时估计电力输送系统中的传输功率的可能性和前景。实验数据是在长大气实验装置上历时数月采集的,其中包括气压、温度、风速、湿度、露点、风向、太阳通量等气象参数。数据是在几个地点收集的。从光伏接收器上的电压估计入射辐射的功率。采用最近邻法、梯度增强法和神经网络作为机器学习算法,并在平均绝对误差(MAPE)和决定系数(R2)方面对算法进行比较。分析结果表明,所有模式的预测能力都很好,甚至在简单气象测量的基础上也有使用的潜力。使用传统方法需要更复杂的测量,如闪烁测量法,或使用经验近似。机器学习使得仅使用整体气象参数即可获得结果成为可能,并且在任意条件下显示出良好的准确性。选择R2 0.951、MAPE 0.020的梯度增强模型为最佳模型。该模型的结果使用SHAP方法进行解释,结果对输入数据的依赖性与预期一致。
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A Machine Learning Approach for Transmitted Power Estimation in Power Beaming Systems
Currently, predictive machine learning methods are used in many areas of life — from traffic predictions to medical diagnosis. Recently, these approaches also appeared in atmoposheric studies, first of all, for estimation of turbulence parameters, these tasks are necessary for a qualitative solution of atmospheric optical communication issues. The purpose of this work is to show the possibility and prospects of using machine learning algorithms for estimation transmitted power in power beaming systems in real time under changing atmospheric conditions. Experimental data were collected over several months on long atmospheric experimental setup, among gathered data there are such meteorological parameters as pressure, temperatures, wind speed, humidity, dew point, wind direction, solar flux. The data was collected for several locations. The power of the incident radiation was estimated from the voltage on the photovoltaic receiver. The nearest neighbors method, gradient boosting and neural networks were used as machine learning algorithms, the algorithms were compared with each other in terms of the average absolute error (MAPE) and the coefficient of determination (R2). The analysis of the results showed a good predictive ability of all models and potential of using even on the basis of simple meteorological measurements. The use of traditional methods requires much more complex measurements, such as scintillometry, or empirical approximations are used. Machine learning makes it possible to get results with only integral meteorological parameters and shows good accuracy for arbitrary conditions. Gradient boosting with R2 0.951 and MAPE 0.020 on all data was chosen as the best model. The results of this model was interpreted using the SHAP method, the dependence of the result on the input data is consistent with expectations.
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来源期刊
Radioelektronika, Nanosistemy, Informacionnye Tehnologii
Radioelektronika, Nanosistemy, Informacionnye Tehnologii Materials Science-Materials Science (miscellaneous)
CiteScore
0.60
自引率
0.00%
发文量
38
期刊介绍: Journal “Radioelectronics. Nanosystems. Information Technologies” (abbr RENSIT) publishes original articles, reviews and brief reports, not previously published, on topical problems in radioelectronics (including biomedical) and fundamentals of information, nano- and biotechnologies and adjacent areas of physics and mathematics. The authors of the journal are academicians, corresponding members and foreign members of the Russian Academy of Natural Sciences (RANS) and their colleagues, as well as other russian and foreign authors on the proposal of the members of RANS, which can be obtained by the author before sending articles to the editor or after its arrival on the recommendation of a member of the editorial board or another member of the RANS, who gave the opinion on the article at the request of the editior. The editors will accept articles in both Russian and English languages. Articles are internally peer reviewed (double-blind peer review) by members of the Editorial Board. Some articles undergo external review, if necessary. Designed for researchers, graduate students, physics students of senior courses and teachers. It turns out 2 times a year (that includes 2 rooms)
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