Prediction of building power consumption using transfer learning-based reference building and simulation dataset

With the advancements in data processing technologies and the increased use of renewable energy systems, the development of microgrid has gained attention. Consequently, a method for machine learning studies has increased for rational building power consumption. Extensive historical data of building...

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Bibliographic Details
Published in:Energy and buildings 2022-03, Vol.258, p.111717, Article 111717
Main Authors: Ahn, Yusun, Kim, Byungseon Sean
Format: Article
Language:English
Subjects:
Accuracy
Building power consumption prediction
Coefficient of variation
Data points
Data processing
Datasets
Distributed generation
Historical account
Long short-term memory
Machine learning
Office buildings
Power consumption
Predictions
Reference building
Renewable energy
Short-term data
Simulation
Simulation dataset
Training
Transfer learning
Transfer learning model
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Summary:With the advancements in data processing technologies and the increased use of renewable energy systems, the development of microgrid has gained attention. Consequently, a method for machine learning studies has increased for rational building power consumption. Extensive historical data of building power consumption are required for a high accuracy prediction; however, in practice, it is difficult to gather such data from existing or new buildings. Therefore, this study proposed a method for using transfer learning based on the simulation dataset of a reference building. The transfer learning long short-term memory (TL-LSTM) model developed in this study trained only on 24 h of office building power consumption data and predicted after 24 h. The accuracy of TL-LSTM was evaluated using various simulation and experimental data, and the factors affecting the performance of TL-LSTM (the number of training data and climate zone) were analyzed. Consequently, compared to the long short-term memory (LSTM) model, the TL-LSTM model demonstrated a higher accuracy with an average coefficient of variation of the root mean square error (CVRMSE) of 4.25% and mean bias error (MBE) of 1.70%. Furthermore, the prediction for the next 24 h was possible when at least 22 training data points were gathered. Finally, when the climate zone was the same for the target and source datasets, high accuracy was demonstrated even if the location of each building was different. Additionally, the source dataset could be replaced with a simulation dataset.
ISSN:0378-7788
1872-6178
DOI:10.1016/j.enbuild.2021.111717