Abstract
An important instrument for achieving smart and high-performance buildings is Machine Learning (ML). A lot of research has been done in exploring the ML models for various applications in the built environment such as occupancy prediction. Nevertheless, the research focused mostly on analyzing the feasibility and performance of different supervised ML models but has rarely focused on practical applications and the scalability of those models. In this study, a transfer learning method is proposed as a solution to typical problems in the practical application of ML in buildings. Such problems are scaling a model to a different building, collecting ground truth data necessary for training the supervised model, and assuring the model is robust when conditions change. The practical application examined in this work is a deep learning model used for predicting room occupancy using indoor climate IoT sensors. This work proved that it is possible to significantly reduce the length of ground truth data collection to only two days. The robustness of the transferred model was tested as well, where performance stayed on a similar level if a suitable normalization technique was used. In addition, the proposed methodology was tested with room occupancy level prediction, showing slightly lower performance. Finally, the importance of understanding the performance metrics is crucial for market adoption of ML-based solutions in the built environment. Therefore, in this study, additional analysis was done by presenting the occupancy prediction model performance in understandable ways from the practical perspective.
Highlights
The CO2 emissions of buildings in the European Union are 36% and 28% on the global scale [1,2], while HVAC systems in developed countries are responsible for 50% of building energy consumption alone [3]
To close the research gap, this paper proposes a deep transfer learning methodology for room occupancy prediction
The main goal of the presented study was to explore the scalability of a deep learningbased method for inferring room occupancy information from indoor climate measurements
Summary
The CO2 emissions of buildings in the European Union are 36% and 28% on the global scale [1,2], while HVAC systems in developed countries are responsible for 50% of building energy consumption alone [3]. Many research attempts have been made using advanced technologies in the field of computer science such as Artificial Intelligence (AI), Machine Learning (ML) and the Internet of Things (IoT) in building operations. These technologies are enabling use cases such as model predictive control, system fault detection and diagnosis, occupancy estimation and detection, demand response and more in general they are system integrators of different building subsystems and occupants [4,5]. It is important to minimize the interference with privacy and with work activities in order for office occupants to accept smart technologies, as was found in a recent survey [6]
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