Abstract
Smart grids have recently attracted increasing attention because of their reliability, flexibility, sustainability, and efficiency. A typical smart grid consists of diverse components such as smart meters, energy management systems, energy storage systems, and renewable energy resources. In particular, to make an effective energy management strategy for the energy management system, accurate load forecasting is necessary. Recently, artificial neural network–based load forecasting models with good performance have been proposed. For accurate load forecasting, it is critical to determine effective hyperparameters of neural networks, which is a complex and time-consuming task. Among these parameters, the type of activation function and the number of hidden layers are critical in the performance of neural networks. In this study, we construct diverse artificial neural network–based building electric energy consumption forecasting models using different combinations of the two hyperparameters and compare their performance. Experimental results indicate that neural networks with scaled exponential linear units and five hidden layers exhibit better performance, on average than other forecasting models.
Highlights
Smart grids, which are known to have features including reliability, flexibility, sustainability, and efficiency, have emerged as a solution for numerous current problems, including energy shortage and environmental pollution.[1,2,3] A smart grid is a platform for exchanging real-time power information supported by wired/wireless communication, control, and sensors between suppliers and consumers to enable innovative power management.[1,2] Typical smart grids comprise smart meters, energy management systems (EMSs), energy storage systems (ESSs), and diverse renewable energy resources
We considered rectified linear units (ReLU), Leaky rectified linear unit (LReLU), parametric rectified linear unit (PReLU), exponential linear unit (ELU), and scaled exponential linear unit (SELU) as activation functions, and the number of HLs from 1 to 10
To compare the prediction performance with two hyperparameters for the short-term load forecasting (STLF) model, we considered electric load data collected from five different types of buildings for 2 years, and two performance metrics, CVRMSE and mean absolute percentage error (MAPE)
Summary
Smart grids, which are known to have features including reliability, flexibility, sustainability, and efficiency, have emerged as a solution for numerous current problems, including energy shortage and environmental pollution.[1,2,3] A smart grid is a platform for exchanging real-time power information supported by wired/wireless communication, control, and sensors between suppliers and consumers to enable innovative power management.[1,2] Typical smart grids comprise smart meters, energy management systems (EMSs), energy storage systems (ESSs), and diverse renewable energy resources. International Journal of Distributed Sensor Networks an EMS generates schedules for power generation and ESSs by considering a number of factors, including storage costs and the amount of energy to be used in the future.[4] In order to generate more effective schedules, an EMS requires accurate short-term load forecasting (STLF).[5,6]
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