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@ARTICLE{BisognoBernardini_EN_2025,
                      author = {Bisogno Bernardini, Leonardo A. and K{\"{a}}mpf, J{\'{e}}r{\^{o}}me and Desideri, Umberto and Leccese, Francesco and Salvadori, Giacomo},
                    keywords = {digital twins, grey-box RC models, large-scale building facilities, model predictive control (MPC)},
                    projects = {Idiap},
         mainresearchprogram = {Sustainable & Resilient Societies},
                       month = dec,
                       title = {Grey-Box RC Building Models for Intelligent Management of Large-Scale Energy Flexibility: From Mass Modeling to Decentralized Digital Twins},
                     journal = {Energies},
                      volume = {19},
                      number = {1},
                        year = {2025},
                         url = {https://www.mdpi.com/3649858},
                         doi = {10.3390/en19010077},
                    abstract = {Managing complex and large-scale building facilities requires reliable, easily interpretable, and computationally efficient models. Considering the electrical-circuit analogy, lumped-parameter resistance–capacitance (RC) thermal models have emerged as both simulation surrogates and advanced tools for energy management. This review synthesizes recent uses of RC models for building energy management in large facilities and aggregates. A systematic review of the most recent international literature, based on the analysis of 70 peer-reviewed articles, led to the classification of three main areas: (i) the physics and modeling potential of RC models; (ii) the methods for automation, calibration, and scalability; and (iii) applications in model predictive control (MPC), energy flexibility, and digital twins (DTs). The results show that these models achieve an efficient balance between accuracy and simplicity, allowing for real-time deployment in embedded control systems and building-automation platforms. In complex and large-scale situations, a growing integration with machine learning (ML) techniques, semantic frameworks, and stochastic methods within virtual environments is evident. Nonetheless, challenges persist regarding the standardization of performance metrics, input data quality, and real-scale validation. This review provides essential and up-to-date guidance for developing interoperable solutions for complex building energy systems, supporting integrated management across district, urban, and community levels for the future.}
}