Abstract
Building an accurate and robust energy consumption prediction model is a core mission for the energy management and operation system of a smart building. Prior efforts have explored numerous predictive models in various load prediction scenarios. However, the joint effect of data augmentation and ensemble learning in energy forecasting has not been fully explored. In this paper, we propose a generative adversarial network (GAN)-enhanced ensemble model for energy consumption forecasting in large commercial buildings. The ensemble model aggregates five constituent models with a stacking ensemble method. In addition, we employ a GAN to learn the sample distribution from the original dataset and generate high-quality samples to enhance the training set. The augmented dataset allows a model to be trained with more diverse samples to increase its robustness. A series of experiments are conducted to validate the proposed method with three GAN variants using three performance metrics, including mean absolute error (MAE), root mean square error (RMSE), and coefficient of variation of root mean square error (CVRMSE). Results demonstrate the GAN-enhanced ensemble models are more robust with consistent improvement in reducing the prediction errors. The best ensemble model, enhanced by the Information Maximizing GAN (InfoGAN), outperforms the model without augmentation by decreasing the average error by 1.71, 1.63, and 4.72%, in MAE, RMSE, and CVRMSE respectively, validating its piratical value for building an energy consumption forecasting model in a real-world system.
Highlights
E NERGY is the fuel that drives modern industries to move forward and create value for our societies
Various metrics are used to evaluate the performance of the predictive models, including mean absolute error (MAE), root mean square error (RMSE), and CVRMSE
According to the characteristics of each metric, in this study, the MAE is mainly used to represent the difference between absolute errors, the RMSE is mainly used to identify large errors, and the CVRMSE is mainly used to compare the difference in accuracy between different models
Summary
E NERGY is the fuel that drives modern industries to move forward and create value for our societies. The world has undergone drastic changes due to technological innovation in mobile Internet, 5G, deep learning, and smart cities. These changes facilitate the communication between individuals and organizations, boost manufacturing productivity, and speeds up transportation and logistics; at the same time, the energy consumption and CO2 emissions are increasing remarkably. It is imperative to develop an accurate and robust predictive model for energy consumption forecasting, which is essential for energy planning, optimization, and conservation. The service objectives of predictive models in energy management systems mainly include optimal control [12] and fault detection [13]
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