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Development and validation of a gray box model to predict thermal behavior of occupied office buildings

•Four gray box models are compared on their prediction ability.•Power and temperature prediction fitting exceed 84% in heating and cooling mode.•A novel R6C2 model presents the best results with a validated identification method.•A sensibility analysis allows to validate the R6C2 model architecture....

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Published in:	Energy and buildings 2014-05, Vol.74, p.91-100
Main Authors:	Berthou, Thomas, Stabat, Pascal, Salvazet, Raphael, Marchio, Dominique
Format:	Article
Language:	English
Subjects:	Applied sciences Building technical equipments Buildings Buildings. Public works Commercial building Computation methods. Tables. Charts domain_spi.energ Energy management and energy conservation in building Engineering Sciences Environmental engineering Exact sciences and technology Gray-box models Heating and cooling Load prediction Parameter estimation Sensitivity analysis Structural analysis. Stresses Types of buildings
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cited_by	cdi_FETCH-LOGICAL-c472t-25b90c6dc5fa926a1632793ccf4f8c3fa55afd0f47131e62ffec65f1c334d34f3
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container_title	Energy and buildings
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creator	Berthou, Thomas Stabat, Pascal Salvazet, Raphael Marchio, Dominique
description	•Four gray box models are compared on their prediction ability.•Power and temperature prediction fitting exceed 84% in heating and cooling mode.•A novel R6C2 model presents the best results with a validated identification method.•A sensibility analysis allows to validate the R6C2 model architecture. Due to the development of energy performance contracting and the needs for peak electric demand reduction, the interest for building energy demand prediction is renewed. Gray-box models are a solution for energy demand prediction. However, it is still difficult to find the best level of model complexity and the good practices for the training phase. Since models’ order and parameter identification method have a strong impact on the forecasting precision and are not intuitive, a comparative design approach is used to find the best model architecture and an adequate methodology for improving the training phase. The gray box models are compared on their ability to forecast heating and cooling demands and indoor air temperature. An objective function is proposed aiming to minimize both power and indoor temperature prediction errors. Moreover, for each model, several training period durations are tested. First, this study shows that a R6C2 (second order model) model is adapted to predict the building thermal behavior. Furthermore, the best fits are obtained with two weeks of data for the identification process. Second, a sensitivity analysis using total Sobol index calculation leads to validate the objective function and identify the most important parameters for prediction.
doi_str_mv	10.1016/j.enbuild.2014.01.038
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subjects	Applied sciences Building technical equipments Buildings Buildings. Public works Commercial building Computation methods. Tables. Charts domain_spi.energ Energy management and energy conservation in building Engineering Sciences Environmental engineering Exact sciences and technology Gray-box models Heating and cooling Load prediction Parameter estimation Sensitivity analysis Structural analysis. Stresses Types of buildings
title	Development and validation of a gray box model to predict thermal behavior of occupied office buildings
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