Energy demand forecasting in seven sectors by an optimization model based on machine learning algorithms

•Energy demand forecasting for seven sectors using six machine learning algorithms.•Proposed mathematical model based on machine learning algorithms.•Increased prediction accuracy indicated by the proposed model.•22-year Energy consumption forecast with high prediction accuracy presented.•Sectors St...

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Bibliographic Details
Published in:Sustainable cities and society 2023-08, Vol.95, p.104623, Article 104623
Main Authors: Emami Javanmard, Majid, Ghaderi, S.F.
Format: Article
Language:English
Subjects:
Energy consumption
Energy demand management
Forecasting
Machine learning
Mathematical Programming
Optimization Model
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Summary:•Energy demand forecasting for seven sectors using six machine learning algorithms.•Proposed mathematical model based on machine learning algorithms.•Increased prediction accuracy indicated by the proposed model.•22-year Energy consumption forecast with high prediction accuracy presented.•Sectors Studied: Residential, Industrial, Commercial, Transport, Public, Agriculture, and other. With the growth of population, many countries face the challenge of supplying energy resources. One approach to managing and planning these resources is to predict energy demand. This study presented an integrated approach by applying six Machine Learning (ML) algorithms (ANN, AR, ARIMA, SARIMA, SARIMAX, and LSTM) and mathematical programming to predict energy demand in Iran up to 2040. The data relating to electricity generation and fuel consumption in power plants, electricity imports and exports, and seven major energy-consuming sectors in Iran (residential, commercial, industrial, transportation, public, agriculture, and others) are collected. The data employed to forecast energy demand in each sector with ML algorithms and prediction accuracy indices evaluated the algorithms' prediction accuracy in every sector. Then, the optimization model for prediction accuracy improvement is introduced. The ML algorithms results are employed as inputs to the integrated model and executed by two PSO and Grey-Wolf Optimizer algorithms for different sectors. The energy demand in these seven sectors until 2040 is predicted, and five prediction accuracy metrics are used to validate the integrated optimization results. The outcomes of the proposed method in all sectors reflect its more accurateness than ML algorithms, such that the MAPE index equals 0.002–0.012 and 0.004–0.013 for the proposed model executed by the PSO and Grey-Wolf Optimizer algorithms. In general, the PSO algorithm indicates a 75.65% growth in the total energy demand of all sectors, and the Grey-Wolf Optimizer algorithm forecasts a 82.94% growth.
ISSN:2210-6707
2210-6715
DOI:10.1016/j.scs.2023.104623