This work is licensed under the Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 International License.
American Society of Heating Refrigerating and Air-Conditioning Engineers. (2010). ANSI/ASHRAE Standard 55, Thermal Environmental Conditions for Human Occupancy is an American National Standard ASHRAE, Atlanta, GA, USA.American Society of Heating Refrigerating and Air-Conditioning Engineers2010ANSI/ASHRAE Standard 55, Thermal Environmental Conditions for Human Occupancy is an American National Standard ASHRAEAtlanta, GA, USASearch in Google Scholar
Appah-Dankyi, J., & Koranteng, C. (2012). A thermal comfort evaluation of a junior high school building in Accra, Ghana. Journal of Construction Project Management and Innovation, 2(2), pp. 403–423.Appah-DankyiJ.KorantengC.2012A thermal comfort evaluation of a junior high school building in Accra, GhanaJournal of Construction Project Management and Innovation22403423Search in Google Scholar
Azizpour, F., Moghimi, S., Salleh, E., Mat, S., Lim, C.H., & Sopian, K. (2013). Thermal comfort assessment of large-scale hospitals in tropical climates: A case study of University Kebangsaan Malaysia Medical Centre (UKMMC). Energy and Buildings, 64, pp. 317–322.AzizpourF.MoghimiS.SallehE.MatS.LimC.H.SopianK.2013Thermal comfort assessment of large-scale hospitals in tropical climates: A case study of University Kebangsaan Malaysia Medical Centre (UKMMC)Energy and Buildings6431732210.1016/j.enbuild.2013.05.033Search in Google Scholar
Calis, G., Alt, B., & Kuru, M. (2015). Thermal comfort and occupant satisfaction of a mosque in a hot and humid climate. In: Congress on Computing in Civil Engineering, Proceedings, 2015-January, pp. 139–147. doi: 10.1061/9780784479247.018.CalisG.AltB.KuruM2015Thermal comfort and occupant satisfaction of a mosque in a hot and humid climateIn:Congress on Computing in Civil Engineering, Proceedings2015-January13914710.1061/9780784479247.018Open DOISearch in Google Scholar
Calis, G., Atalay, S. D., Kuru, M., & Mutlu, N. (2018). Forecasting occupancy for demand driven HVAC operations using time series analysis. Journal of Asian Architecture and Building Engineering, 16(3), 655–660.CalisG.AtalayS. D.KuruM.MutluN2018Forecasting occupancy for demand driven HVAC operations using time series analysisJournal of Asian Architecture and Building Engineering16365566010.3130/jaabe.16.655Search in Google Scholar
Calis, G., & Kuru, M. (2017). Assessing user thermal sensation in the Aegean region against standards. Sustainable Cities and Society, 29, pp. 77–85.CalisG.KuruM.2017Assessing user thermal sensation in the Aegean region against standardsSustainable Cities and Society29778510.1016/j.scs.2016.11.013Search in Google Scholar
Ceria, K., & De Dear, R. (2001). Thermal comfort and behavioural strategies in office buildings located in a hot-arid climate. Journal of Thermal Biology, 26, pp. 409–414.CeriaK.De DearR.2001Thermal comfort and behavioural strategies in office buildings located in a hot-arid climateJournal of Thermal Biology2640941410.1016/S0306-4565(01)00052-3Search in Google Scholar
Chen, M. H., & Dey, D. K. (2003). Variable selection for multivariate logistic regression models. Journal of Statistical Planning and Inference, 111(1–2), pp. 37–55.ChenM. H.DeyD. K.2003Variable selection for multivariate logistic regression modelsJournal of Statistical Planning and Inference1111–2375510.1016/S0378-3758(02)00284-7Search in Google Scholar
Cheung, T., Schiavon, S., Parkinson, T., Li, P., & Brager, G. (2019). Analysis of the accuracy on PMV–PPD model using the ASHRAE global thermal comfort database II. Building and Environment, 153, pp. 205–217.CheungT.SchiavonS.ParkinsonT.LiP.BragerG.2019Analysis of the accuracy on PMV–PPD model using the ASHRAE global thermal comfort database IIBuilding and Environment15320521710.1016/j.buildenv.2019.01.055Search in Google Scholar
Choi, J. H., Aziz, A., & Loftness, V. (2010). Investigation on the impacts of different genders and ages on satisfaction with thermal environments in office buildings. Building and Environment, 45(6), pp. 1529–1535.ChoiJ. H.AzizA.LoftnessV.2010Investigation on the impacts of different genders and ages on satisfaction with thermal environments in office buildingsBuilding and Environment4561529153510.1016/j.buildenv.2010.01.004Search in Google Scholar
Corgnati, S. P., Filippi, M., & Viazzo, S. (2007). Perception of the thermal environment in high school and university classrooms: Subjective preferences and thermal comfort. Building and Environment, 47(2), 951–959.CorgnatiS. P.FilippiM.ViazzoS2007Perception of the thermal environment in high school and university classrooms: Subjective preferences and thermal comfortBuilding and Environment47295195910.1016/j.buildenv.2005.10.027Search in Google Scholar
Daum, D., Haldi, F., & Morel, N. (2011). A personalized measure of thermal comfort for building controls. Building and Environment, 46(1), pp. 3–11.DaumD.HaldiF.MorelN.2011A personalized measure of thermal comfort for building controlsBuilding and Environment46131110.1016/j.buildenv.2010.06.011Search in Google Scholar
Deuble, M. P., & de Dear, R. J. (2014). Is it hot in here or is it just me? Validating the post-occupancy evaluation. Intelligent Buildings International, 6(2), pp. 112–134.DeubleM. P.de DearR. J.2014Is it hot in here or is it just me? Validating the post-occupancy evaluationIntelligent Buildings International6211213410.1080/17508975.2014.883299Search in Google Scholar
Dias, L., Raimondo, D., Paolo, S., Manuel, C., da Silva, G. (2014). Assessment of indoor air quality and thermal comfort in Portuguese secondary classrooms: Methodology and results. Building and Environment, 81, pp. 69–80.DiasL.RaimondoD.PaoloS.ManuelC.da SilvaG.2014Assessment of indoor air quality and thermal comfort in Portuguese secondary classrooms: Methodology and resultsBuilding and Environment81698010.1016/j.buildenv.2014.06.008Search in Google Scholar
Dudzińska, A., & Kotowicz, A. (2015). Features of materials versus thermal comfort in a passive building. Procedia Engineering, 108, pp. 108–115.DudzińskaA.KotowiczA2015Features of materials versus thermal comfort in a passive buildingProcedia Engineering10810811510.1016/j.proeng.2015.06.125Search in Google Scholar
Fagerland, M. W., & Hosmer, D. W. (2012). A generalized Hosmer–Lemeshow goodness-of-fit test for multinomial logistic regression models. Stata Journal, 12(3), pp. 447–453.FagerlandM. W.HosmerD. W.2012A generalized Hosmer–Lemeshow goodness-of-fit test for multinomial logistic regression modelsStata Journal12344745310.1177/1536867X1201200307Search in Google Scholar
Fanger, P. O. (1982). Thermal Comfort. Robert E. Kriege Publishing Company, Malabar, FL, USA.FangerP. O1982Thermal ComfortRobert E. Kriege Publishing CompanyMalabar, FL, USASearch in Google Scholar
Gilani, S. I. U. H., Khan, M. H., & Pao, W. (2015). Thermal comfort analysis of PMV model prediction in air conditioned and naturally ventilated buildings. Energy Procedia, 75, pp. 1373–1379.GilaniS. I. U. H.KhanM. H.PaoW.2015Thermal comfort analysis of PMV model prediction in air conditioned and naturally ventilated buildingsEnergy Procedia751373137910.1016/j.egypro.2015.07.218Search in Google Scholar
Gunay, H. B., Shen, W., Newsham, G., & Ashouri, A. (2018). Modelling and analysis of unsolicited temperature setpoint change requests in office buildings. Building and Environment, 133(February), pp. 203–212.GunayH. B.ShenW.NewshamG.AshouriA.2018Modelling and analysis of unsolicited temperature setpoint change requests in office buildingsBuilding and Environment133February20321210.1016/j.buildenv.2018.02.025Search in Google Scholar
Hosmer, D. W., & Lemeshow, S. (2005). Applied logistic regression. Applied Logistic Regression. doi: 10.1002/0471722146.HosmerD. W.LemeshowS2005Applied logistic regressionApplied Logistic Regression10.1002/0471722146Open DOISearch in Google Scholar
Hoyt, T., Schiavon, S., Piccioli, A., Moon, D., & Steinfeld, K. (2017). CBE Thermal Comfort Tool. Center for the Built Environment, University of California, Berkeley.HoytT.SchiavonS.PiccioliA.MoonD.SteinfeldK2017CBE Thermal Comfort ToolCenter for the Built Environment, University of CaliforniaBerkeleySearch in Google Scholar
International Organization for Standardization. (2012). ISO 16817 Building environment design—Indoor environment—Design process for the visual environment.International Organization for Standardization2012ISO 16817 Building environment design—Indoor environment—Design process for the visual environmentSearch in Google Scholar
International Standardisation Organisation. (2005). ISO 7730, ergonomics of the thermal environment-assessment of the influence of the thermal environment using subjective judgment scales.International Standardisation Organisation2005ISO 7730, ergonomics of the thermal environment-assessment of the influence of the thermal environment using subjective judgment scalesSearch in Google Scholar
Ji, Y., & Wang, Z. (2019). Thermal adaptations and logistic regression analysis of thermal comfort in severe cold area based on two case studies. Energy and Buildings, 205, p. 109560.JiY.WangZ2019Thermal adaptations and logistic regression analysis of thermal comfort in severe cold area based on two case studiesEnergy and Buildings20510956010.1016/j.enbuild.2019.109560Search in Google Scholar
Júlio, J. P., Paiva, A., & Dominguez, C. (2013). Overall aspects for the evaluation of Portuguese dwellings’ quality and sustainability. Organization, Technology & Management in Construction: An International Journal, 5(1), pp. 702–711.JúlioJ. P.PaivaA.DominguezC.2013Overall aspects for the evaluation of Portuguese dwellings’ quality and sustainabilityOrganization, Technology & Management in Construction: An International Journal5170271110.5592/otmcj.2013.1.7Search in Google Scholar
Katafygiotou, M. C., & Serghides, D. K. (2014). Thermal comfort of a typical secondary school building in Cyprus. Sustainable Cities and Society, 13, pp. 303–312.KatafygiotouM. C.SerghidesD. K.2014Thermal comfort of a typical secondary school building in CyprusSustainable Cities and Society1330331210.1016/j.scs.2014.03.004Search in Google Scholar
Kocaman, E., Kuru, M., & Calis, G. (2019). Do thermal comfort standards ensure occupant satisfaction? Learning from occupants’ Thermal complaints, In: Creative Construction Conference 2019, CCC 2019, 29 June – 2 July 2019, Budapest, Hungary, pp. 7–11.KocamanE.KuruM.CalisG2019Do thermal comfort standards ensure occupant satisfaction? Learning from occupants’ Thermal complaintsIn:Creative Construction Conference 2019, CCC 201929 June – 2 July 2019Budapest, Hungary711Search in Google Scholar
Nagano, K., & Mochida, T. (2004). Experiments on thermal environmental design of ceiling radiant cooling for supine human subjects. Building and Environment, 39(3), pp. 267–275.NaganoK.MochidaT.2004Experiments on thermal environmental design of ceiling radiant cooling for supine human subjectsBuilding and Environment39326727510.1016/j.buildenv.2003.08.011Search in Google Scholar
Natarajan, S., Rodriguez, J., & Vellei, M. (2015). A field study of indoor thermal comfort in the subtropical highland climate of Bogota, Colombia. Journal of Building Engineering, 4, pp. 237–246.NatarajanS.RodriguezJ.VelleiM.2015A field study of indoor thermal comfort in the subtropical highland climate of Bogota, ColombiaJournal of Building Engineering423724610.1016/j.jobe.2015.10.003Search in Google Scholar
Panas, A., & Pantouvakis, J.-P. (2010). An empirical framework for the performance-based evaluation of health and safety's contribution to sustainable construction. Organization, Technology & Management in Construction: An International Journal, 2(2), pp. 173–181.PanasA.PantouvakisJ.-P.2010An empirical framework for the performance-based evaluation of health and safety's contribution to sustainable constructionOrganization, Technology & Management in Construction: An International Journal22173181Search in Google Scholar
Shooshtarian, S., & Rajagopalan, P. (2017). Study of thermal satisfaction in an Australian education precinct. Building and Environment, 123, pp. 119–132.ShooshtarianS.RajagopalanP.2017Study of thermal satisfaction in an Australian education precinctBuilding and Environment12311913210.1016/j.buildenv.2017.07.002Search in Google Scholar
Soutullo, S., Enríquez, R., Jiménez, M. J., & Heras, M. R. (2014). Thermal comfort evaluation in a mechanically ventilated office building located in a continental climate. Energy and Buildings, 81, pp. 424–429.SoutulloS.EnríquezR.JiménezM. J.HerasM. R.2014Thermal comfort evaluation in a mechanically ventilated office building located in a continental climateEnergy and Buildings8142442910.1016/j.enbuild.2014.06.049Search in Google Scholar
Tabachnick, B. G., & Fidell, L. S. (2007). Using Multivariate Statistics. Pearson/Allyn & Bacon, Boston.TabachnickB. G.FidellL. S2007Using Multivariate StatisticsPearson/Allyn & BaconBostonSearch in Google Scholar
Trebilcock, M., Soto, J., & Figueroa, R. (2014). Thermal comfort in primary schools : A field study in Chile. In: Proceedings of 8th Windsor Conference: Counting the Cost of Comfort in A Changing World Cumberland Lodge, Windsor, UK, 10–13 April 2014, pp. 421–431.TrebilcockM.SotoJ.FigueroaR2014Thermal comfort in primary schools : A field study in ChileIn:Proceedings of 8th Windsor Conference: Counting the Cost of Comfort in A Changing World Cumberland LodgeWindsor, UK10–13 April 2014421431Search in Google Scholar
Trebilcock, M., Soto-Muñoz, J., Yañez, M., & Figueroa-San Martin, R. (2017). The right to comfort: A field study on adaptive thermal comfort in free-running primary schools in Chile. Building and Environment, 114, pp. 455–469.TrebilcockM.Soto-MuñozJ.YañezM.Figueroa-San MartinR.2017The right to comfort: A field study on adaptive thermal comfort in free-running primary schools in ChileBuilding and Environment11445546910.1016/j.buildenv.2016.12.036Search in Google Scholar