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Baborska-Narożny, M, Stevenson, F and Grudzińska, M (2017) Overheating in retrofitted flats: Occupant practices, learning and interventions. Building Research & Information, 45(01), 40-59.

Birchmore, R, Davies, K, Etherington, P, Tait, R and Pivac, A (2017) Overheating in Auckland homes: Testing and interventions in full-scale and simulated houses. Building Research & Information, 45(01), 157-75.

Gupta, R, Barnfield, L and Gregg, M (2017) Overheating in care settings: Magnitude, causes, preparedness and remedies. Building Research & Information, 45(01), 83-101.

Lee, W V and Steemers, K (2017) Exposure duration in overheating assessments: A retrofit modelling study. Building Research & Information, 45(01), 60-82.

Mavrogianni, A, Pathan, A, Oikonomou, E, Biddulph, P, Symonds, P and Davies, M (2017) Inhabitant actions and summer overheating risk in London dwellings. Building Research & Information, 45(01), 119-42.

McGill, G, Sharpe, T, Robertson, L, Gupta, R and Mawditt, I (2017) Meta-analysis of indoor temperatures in new-build housing. Building Research & Information, 45(01), 19-39.

Meinke, A, Hawighorst, M, Wagner, A, Trojan, J and Schweiker, M (2017) Comfort-related feedforward information: Occupants' choice of cooling strategy and perceived comfort. Building Research & Information, 45(01), 222-38.

Morgan, C, Foster, J A, Poston, A and Sharpe, T R (2017) Overheating in Scotland: Contributing factors in occupied homes. Building Research & Information, 45(01), 143-56.

Symonds, P, Taylor, J, Mavrogianni, A, Davies, M, Shrubsole, C, Hamilton, I and Chalabi, Z (2017) Overheating in English dwellings: Comparing modelled and monitored large-scale datasets. Building Research & Information, 45(01), 195-208.

• Type: Journal Article
• Keywords: energyplus; occupant behaviour; building information modelling; building performance; overheating; simulation; housing stock; validation; thermal comfort; climate-change; homes; construction & building technology; temperatures; buildings; datasets; he
• ISBN/ISSN: 0961-3218
• URL: https://doi.org/10.1080/09613218.2016.1224675
• Abstract:
  Monitoring and modelling studies of the indoor environment indicate that there are often discrepancies between simulation results and measurements. The availability of large monitoring datasets of domestic buildings allows for more rigorous validation of the performance of building simulation models derived from limited building information, backed by statistical significance tests and goodness-of-fit metrics. These datasets also offer the opportunity to test modelling assumptions. This paper investigates the performance of domestic housing models using EnergyPlus software to predict maximum daily indoor temperatures over the summer of 2011. Monitored maximum daily indoor temperatures from the English Housing Survey's (EHS) Energy Follow-Up Survey (EFUS) for 823 nationally representative dwellings are compared against predictions made by EnergyPlus simulations. Due to lack of information on the characteristics of individual dwellings, the models struggle to predict maximum temperatures in individual dwellings and performance was worse on days when the outdoor maximum temperatures were high. This research indicates that unknown factors such as building characteristics, occupant behaviour and local environment makes the validation of models for individual dwellings a challenging task. The models did, however, provide an improved estimate of temperature exposure when aggregated over dwellings within a particular region.;Monitoring and modelling studies of the indoor environment indicate that there are often discrepancies between simulation results and measurements. The availability of large monitoring datasets of domestic buildings allows for more rigorous validation of the performance of building simulation models derived from limited building information, backed by statistical significance tests and goodness-of-fit metrics. These datasets also offer the opportunity to test modelling assumptions. This paper investigates the performance of domestic housing models using EnergyPlus software to predict maximum daily indoor temperatures over the summer of 2011. Monitored maximum daily indoor temperatures from the English Housing Survey's (EHS) Energy Follow-Up Survey (EFUS) for 823 nationally representative dwellings are compared against predictions made by EnergyPlus simulations. Due to lack of information on the characteristics of individual dwellings, the models struggle to predict maximum temperatures in individual dwellings and performance was worse on days when the outdoor maximum temperatures were high. This research indicates that unknown factors such as building characteristics, occupant behaviour and local environment makes the validation of models for individual dwellings a challenging task. The models did, however, provide an improved estimate of temperature exposure when aggregated over dwellings within a particular region.;  Monitoring and modelling studies of the indoor environment indicate that there are often discrepancies between simulation results and measurements. The availability of large monitoring datasets of domestic buildings allows for more rigorous validation of the performance of building simulation models derived from limited building information, backed by statistical significance tests and goodness-of-fit metrics. These datasets also offer the opportunity to test modelling assumptions. This paper investigates the performance of domestic housing models using EnergyPlus software to predict maximum daily indoor temperatures over the summer of 2011. Monitored maximum daily indoor temperatures from the English Housing Survey's (EHS) Energy Follow-Up Survey (EFUS) for 823 nationally representative dwellings are compared against predictions made by EnergyPlus simulations. Due to lack of information on the characteristics of individual dwellings, the models struggle to predict maximum temperatures in individual dwellings and performance was worse on days when the outdoor maximum temperatures were high. This research indicates that unknown factors such as building characteristics, occupant behaviour and local environment makes the validation of models for individual dwellings a challenging task. The models did, however, provide an improved estimate of temperature exposure when aggregated over dwellings within a particular region.;

Thomas, L E (2017) Combating overheating: Mixed-mode conditioning for workplace comfort. Building Research & Information, 45(01), 176-94.

Vellei, M, Ramallo-González, A P, Coley, D, Lee, J, Gabe-Thomas, E, Lovett, T and Natarajan, S (2017) Overheating in vulnerable and non-vulnerable households. Building Research & Information, 45(01), 102-18.

Zhang, Z, Zhang, Y and Jin, L (2017) Thermal comfort of rural residents in a hot-humid area. Building Research & Information, 45(01), 209-21.