Regression Model-Based Short-Term Load Forecasting for Load Despatch Centre

Q3 Engineering
Saikat Gochhait, D. Sharma
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引用次数: 0

Abstract

Forecasting load is an integral part of the planning, operation, and control of power systems. This paper is part of a research effort aimed at developing better energy demand forecasting models for load dispatch centers (LDCs) in Indian states as part of an ambitious project utilizing artificial intelligence-based load forecasting models. In this paper, we present a half hourly load forecasting method for the energy management system of the project that will be used at 33 /11 kV and 0.415 kV substations with good accuracy. The paper uses the half-hourly load consumption dataset collected from MSEDCL for Maharashtra from July 1, 2020 through August 31, 2022. This paper evaluates 24 regression model-based half hourly based load forecasting algorithms for ALE PHATA load based on the load consumption dataset and the collected meteorological dataset. The 24 models in MATLAB Regression belong to five types of regression models: Linear Regression, Regression Trees, Support Vector Machines (SVM), Gaussian Process Regression (GPR), Ensemble of Trees, and Neural Networks. As a consequence of their nonparametric kernel-based probabilistic nature, the GPR family of models demonstrates the best load forecasting performance. Least squares estimation was used to determine the regression coefficients. There is a direct correlation between load in an electrical power system and temperature, due point, and seasons, as well as a correlation between load and previous load consumption. Therefore, the input variables are Wet Bulb Temperature at 2 Meters (C), Dew/Frost Point at 2 Meters (C), Temperature at 2 Meters (C), Relative Humidity at 2 Meters (%), Specific Humidity at 2 Meters (g/kg) and Wind Speed at 10 Meters (m/s). The mean absolute percentage error and the R squared are used to validate or verify the accuracy of the model, which is shown in the results section.  Based on this study, two GPR models are recommended for load forecasting, the Rational Quadratic GPR and the Exponential GPR and Exponential GPR as final model.
基于回归模型的负荷调度中心短期负荷预测
负荷预测是电力系统规划、运行和控制的一个组成部分。本文是一项研究工作的一部分,旨在为印度各州的负荷调度中心开发更好的能源需求预测模型,作为利用基于人工智能的负荷预测模型的雄心勃勃的项目的一部分。在本文中,我们为该项目的能源管理系统提出了一种半小时负荷预测方法,该方法将用于33/11 kV和0.415 kV变电站,具有良好的准确性。本文使用了从2020年7月1日至2022年8月31日从马哈拉施特拉邦MSEDCL收集的半小时负荷消耗数据集。本文基于负荷消耗数据集和收集的气象数据集,对ALE PHATA负荷的24种基于回归模型的半小时负荷预测算法进行了评估。MATLAB回归中的24个模型分为五类回归模型:线性回归、回归树、支持向量机、高斯过程回归、树集合和神经网络。由于其基于非参数核的概率性质,GPR模型族表现出最佳的负荷预测性能。最小二乘估计用于确定回归系数。电力系统中的负荷与温度、到期点和季节之间存在直接相关性,负荷与以前的负荷消耗之间也存在相关性。因此,输入变量为2米处的湿球温度(C)、2米处(C)的露点/霜点、2米(C)处的温度、2米的相对湿度(%)、2米处的比湿度(g/kg)和10米处(m/s)的风速。平均绝对百分比误差和R平方用于验证或验证模型的准确性,如结果部分所示。在此研究的基础上,推荐了两种用于负荷预测的GPR模型,即有理二次GPR和指数GPR作为最终模型。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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CiteScore
1.50
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0.00%
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审稿时长
4 weeks
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