Abstract
The increasing growth in the energy demand calls for robust actions to design and optimize energy-related assets for efficient and economic energy supply and demand within a smart grid setup. This article proposes a novel integrated machine learning (ML) technique to forecast the heat demand of buildings in a district heating system. The proposed short-term (24h-ahead) heat demand forecasting model is based on the integration of empirical mode decomposition (EMD), imperialistic competitive algorithm (ICA), and support vector machine (SVM). The proposed model also embeds an ML-based feature selection (FS) technique combining binary genetic algorithm and Gaussian process regression to obtain the most important and nonredundant variables that can constitute the input predictor subset to the forecasting model. The model is developed using a two-year (2015–2016) hourly dataset of actual district heat demand obtained from various buildings in the Otaniemi area of Espoo, Finland. Several variables from different domains such as seasonality (calendar), weather, occupancy, and heat demand are used to construct the initial feature space for FS process. Short-term forecasting models are also implemented using the Persistence approach as a reference and other eight ML approaches: artificial neural network (ANN), genetic algorithm combined with ANN (GA-ANN), ICA-ANN, SVM, GA-SVM, ICA-SVM, EMD-GA-ANN, and EMD-ICA-ANN. The performance of the proposed EMD-ICA-SVM-based forecasting model is tested using an out-of-sample one-year (2017) hourly dataset of district heat consumption of various building types. Comparative analysis of the forecasting performance of the models was performed. The obtained results demonstrate that the devised model forecasts the heat demand with improved performance evaluated using various accuracy metrics. Moreover, the devised model achieves outperformed forecasting accuracy enhancement, compared to the other nine evaluated models.
Highlights
T HE RECENT growth of the energy demand has been challenging the energy generation and its delivery
As far as we have investigated, this is the first machine learning (ML)-based approach applying the integrated empirical mode decomposition (EMD)-imperialistic competitive algorithm (ICA)-support vector machine (SVM) model augmented with binary genetic algorithm (BGA)-Gaussian process regression (GPR)-based feature selection (FS) method for energy demand modeling and forecasting
The EMD in the hybrid EMD-ICA-SVM forecasting model is used to extract the important characteristics of the heat demand profile
Summary
T HE RECENT growth of the energy demand has been challenging the energy generation and its delivery. This article can contribute to the field of heat demand modeling and forecasting for small-scale energy systems in general and buildings in particular by making use of data-driven integrated ML models. This has become a major challenge to maintain the performance consistency of forecasting models over different operation scenarios and changing conditions To overcome this problem, we use an ML [hybrid of binary genetic algorithm (BGA) and Gaussian process regression (GPR)] feature selection (FS) methodology to find the most relevant and nonredundant variables to establish the training input data for the proposed heat demand forecasting model. Unlike the prior works on data-driven ML energy demand forecasting, this article employs a feature extraction technique using the empirical mode decomposition (EMD) technique to extract the most relevant features of the target variable (heat demand) for use in the prediction model training.
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