Podrobná bibliografie
| Název: |
Review of Data-Driven Personal Thermal Comfort Modeling and Its Integration into Building Environment Control. |
| Autoři: |
Xue, Wenping, He, Xiaotian, Chen, Guibin, Li, Kangji |
| Zdroj: |
Energies (19961073); Feb2026, Vol. 19 Issue 3, p621, 27p |
| Témata: |
THERMAL comfort, MACHINE learning, TRANSFER of training, BUILT environment, DEEP learning, DATA modeling, USER-centered system design, ENERGY consumption |
| Abstrakt: |
With the increasingly prominent demand for building energy efficiency and occupant-centric design, accurate and reliable personal thermal comfort models (PTCMs) are playing an important role in various residential and energy applications (e.g., building energy-saving design, indoor environmental regulation, and health and well-being improvement). In recent years, data-driven and artificial intelligence (AI) technologies have attracted considerable attention in the field of personal thermal comfort modeling. This study systematically reviews recent progress in data-driven personal thermal comfort modeling, emphasizing contact-based and non-contact data collection ways, correlation analysis of feature data, modeling methods based on machine learning and deep learning. Considering the high cost and limited scale of collection experiments, as well as noise, ambiguity, and individual differences in subjective feedback, special attention is put on the data-efficient thermal comfort modeling in data scarcity scenarios using a transfer learning (TL) strategy. Characteristics and suitable occasions of four transfer methods (model-based, instance-based, feature-based, and ensemble methods) are summarized to provide a deep perspective for practical applications. Furthermore, integration of PTCM into building environment control is summarized from aspects of the integration framework, modeling method, control strategy, actuator, and control effect. Performance of the integrated systems is analyzed in terms of improving personal thermal comfort and promoting building energy efficiency. Finally, several challenges faced by PTCMs and future directions are discussed. [ABSTRACT FROM AUTHOR] |
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| Databáze: |
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