Abstract
An energy-management system requires accurate prediction of the electric load for optimal energy management. However, if the amount of electric load data is insufficient, it is challenging to perform an accurate prediction. To address this issue, we propose a novel electric load forecasting scheme using the electric load data of diverse buildings. We first divide the electric energy consumption data into training and test sets. Then, we construct multivariate random forest (MRF)-based forecasting models according to each building except the target building in the training set and a random forest (RF)-based forecasting model using the limited electric load data of the target building in the test set. In the test set, we compare the electric load of the target building with that of other buildings to select the MRF model that is the most similar to the target building. Then, we predict the electric load of the target building using its input variables via the selected MRF model. We combine the MRF and RF models by considering the different electric load patterns on weekdays and holidays. Experimental results demonstrate that combining the two models can achieve satisfactory prediction performance even if the electric data of only one day are available for the target building.
Highlights
The continuing environmental problems caused by the enormous amount of carbon dioxide produced by the burning of fossil fuels, such as coal and oil, for energy production has resulted in considerable focus on smart grid technologies owing to their effective use of energy [1,2]
We can observe that the proposed SPROUT model significantly outperforms the other models because the p-value in all cases is below the significance level
Building 13 showed that M10 to M12 presented better prediction performance than other models because multiple linear regression (MLR) could predict the building electric energy consumptions better than decision tree (DT) and random forest (RF)
Summary
The continuing environmental problems caused by the enormous amount of carbon dioxide produced by the burning of fossil fuels, such as coal and oil, for energy production has resulted in considerable focus on smart grid technologies owing to their effective use of energy [1,2]. The smart grid can optimize energy use by sharing electric energy production and consumption information with consumers and suppliers in both directions and in real time [4]. An energy management system (EMS) in smart grids requires an optimization algorithm for the advanced operation of an energy storage system (ESS) [7]; it has to plan various strategies by considering consumer-side decision making [8]. Artificial intelligence (AI) technology-based applications are a highly relevant area for smart grid control and management [6,7,8]. Short-term load forecasting (STLF) is a core technology of the EMS [9]; accurate electric load forecasting is required for stable and efficient smart grid operations [10]. From the perspective of a supplier, it is challenging to provide optimal benefits in a cost-effective analysis while storing a large amount of electric energy in the ESS; the smart
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