Probabilistic behavioural modeling in building performance simulation—The Brescia eLUX lab
Probabilistic behavioural modeling in building performance simulation—The Brescia eLUX lab
Occupant's behavioural patterns determine a significant level of uncertainty in building energy performance evaluation. It is difficult to account for this uncertainty in the design phase when operational and occupancy profiles are unknown. The relevant “performance gap” usually encountered between simulated and measured energy performance is clearly connected to biased assumptions in modeling, especially in the initial design phase. A probabilistic modeling approach is proposed to improve simulation reliability and robustness with respect to variability in occupancy patterns. The case study presented is the eLUX lab of the “Smart Campus” of Brescia University in Italy. Occupancy dependent input parameters such as air change rates (i.e. mechanically controlled ventilation) and internal heat gains (i.e. due to people, lighting and appliances) are described by means of probability distributions to obtain probabilistic thermal demand and load profiles as output. Probabilistic results enables a more reliable identification of energy saving strategies (operational and environmental settings) with respect to highly variable operating conditions. Further, simulation data are processed to obtain a weather-adjusted energy demand visualization, suitable for establishing a continuity between modeling in design and operation phases, with calibration purpose. Calibrated energy models can be used for several specific tasks in the operation phase, in particular condition monitoring, fault detection and diagnosis, supervisory control and energy management. For the case study presented, a detailed data acquisition scheme has been designed to enable an effective monitoring activity in the operation phase, aimed at experimenting model-based approaches for the tasks reported. The proposed research is the point-of-departure for a general activity aimed at assessing critically the issues of reliability and robustness of simulation results obtained with conventional modeling approaches, in particular with respect to occupants’ behaviour, exploiting at the same time the possibility of using measured data as a direct feedback to promote behavioural change.
Behavioural learning, Behavioural modeling, Building performance simulation, Energy efficiency, Energy management, Probabilistic modeling, Uncertainty propagation
119-131
Tagliabue, Lavinia Chiara
30e84a7d-5ac8-47fc-9a45-10233778402a
Manfren, Massimiliano
f2b8c02d-cb78-411d-aed1-c4d056365392
Ciribini, Angelo Luigi Camillo
c895dc29-b5a2-4db7-ab68-04a3a6c79704
De Angelis, Enrico
ea55c031-024d-4b1e-a1cb-5a6d97bb1d6a
15 September 2016
Tagliabue, Lavinia Chiara
30e84a7d-5ac8-47fc-9a45-10233778402a
Manfren, Massimiliano
f2b8c02d-cb78-411d-aed1-c4d056365392
Ciribini, Angelo Luigi Camillo
c895dc29-b5a2-4db7-ab68-04a3a6c79704
De Angelis, Enrico
ea55c031-024d-4b1e-a1cb-5a6d97bb1d6a
Tagliabue, Lavinia Chiara, Manfren, Massimiliano, Ciribini, Angelo Luigi Camillo and De Angelis, Enrico
(2016)
Probabilistic behavioural modeling in building performance simulation—The Brescia eLUX lab.
Energy and Buildings, 128, .
(doi:10.1016/j.enbuild.2016.06.083).
Abstract
Occupant's behavioural patterns determine a significant level of uncertainty in building energy performance evaluation. It is difficult to account for this uncertainty in the design phase when operational and occupancy profiles are unknown. The relevant “performance gap” usually encountered between simulated and measured energy performance is clearly connected to biased assumptions in modeling, especially in the initial design phase. A probabilistic modeling approach is proposed to improve simulation reliability and robustness with respect to variability in occupancy patterns. The case study presented is the eLUX lab of the “Smart Campus” of Brescia University in Italy. Occupancy dependent input parameters such as air change rates (i.e. mechanically controlled ventilation) and internal heat gains (i.e. due to people, lighting and appliances) are described by means of probability distributions to obtain probabilistic thermal demand and load profiles as output. Probabilistic results enables a more reliable identification of energy saving strategies (operational and environmental settings) with respect to highly variable operating conditions. Further, simulation data are processed to obtain a weather-adjusted energy demand visualization, suitable for establishing a continuity between modeling in design and operation phases, with calibration purpose. Calibrated energy models can be used for several specific tasks in the operation phase, in particular condition monitoring, fault detection and diagnosis, supervisory control and energy management. For the case study presented, a detailed data acquisition scheme has been designed to enable an effective monitoring activity in the operation phase, aimed at experimenting model-based approaches for the tasks reported. The proposed research is the point-of-departure for a general activity aimed at assessing critically the issues of reliability and robustness of simulation results obtained with conventional modeling approaches, in particular with respect to occupants’ behaviour, exploiting at the same time the possibility of using measured data as a direct feedback to promote behavioural change.
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More information
Accepted/In Press date: 26 June 2016
e-pub ahead of print date: 27 June 2016
Published date: 15 September 2016
Keywords:
Behavioural learning, Behavioural modeling, Building performance simulation, Energy efficiency, Energy management, Probabilistic modeling, Uncertainty propagation
Identifiers
Local EPrints ID: 414103
URI: http://eprints.soton.ac.uk/id/eprint/414103
ISSN: 0378-7788
PURE UUID: 1fc8683e-a305-495e-bc4a-6502822946b6
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Date deposited: 14 Sep 2017 16:31
Last modified: 08 Nov 2024 02:51
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Contributors
Author:
Lavinia Chiara Tagliabue
Author:
Angelo Luigi Camillo Ciribini
Author:
Enrico De Angelis
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