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Fully data-driven and modular building thermal control with physically consistent modeling

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  • Montazeri, Mina
  • Remlinger, Carl
  • Bejar Haro, Benjamin
  • Heer, Philipp

Abstract

Machine learning has experienced significant growth in the smart building sector, whether for building modeling or energy management. Data-driven approaches leverage available measurements to bypass the slow and costly calibration of physics-based models, offering adaptability, low maintenance and greater flexibility. However, the quality of these models depends on historical data, which may be lacking for newly constructed buildings. This paper introduces a fully data-driven modular approach, from temperature modeling to heating control, that requires few data when transferred from a source to a target building. The controller consists of two modules: a deep reinforcement learning agent that manages the desired room temperature and an action-mapper specific to each room that adjusts heating controls. To adapt the controller to a new room, only the action-mapper is substituted. This approach requires just a few weeks of data and reuses an effective policy with minimal effort. The controller is trained using a neural network-based environment simulator, incorporating physical consistency to ensure accurate states and rewards. Simulations and real-world tests show the modular controller achieves 13 % average energy savings (up to 17 %) compared to traditional transfer learning methods, and 26 % (up to 32 %) compared to rule-based controllers, without compromising comfort.

Suggested Citation

  • Montazeri, Mina & Remlinger, Carl & Bejar Haro, Benjamin & Heer, Philipp, 2025. "Fully data-driven and modular building thermal control with physically consistent modeling," Applied Energy, Elsevier, vol. 390(C).
    • Handle: RePEc:eee:appene:v:390:y:2025:i:c:s0306261925005008
    DOI: 10.1016/j.apenergy.2025.125770
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    References listed on IDEAS

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