Abstract
Wide research attention has been paid in the last two decades to the thermal comfort conditions of different outdoor and semi-outdoor urban spaces. Field studies were conducted in a wide range of geographical regions in order to investigate the relationship between the thermal sensation of people and thermal comfort indices. Researchers found that the original threshold values of these indices did not describe precisely the actual thermal sensation patterns of subjects, and they reported neutral temperatures that vary among nations and with time of the year. For that reason, thresholds of some objective indices were rescaled and new thermal comfort categories were defined. This research investigates the outdoor thermal perception patterns of Hungarians regarding the Physiologically Equivalent Temperature (PET) index, based on more than 5800 questionnaires. The surveys were conducted in the city of Szeged on 78 days in spring, summer, and autumn. Various, frequently applied analysis approaches (simple descriptive technique, regression analysis, and probit models) were adopted to reveal seasonal differences in the thermal assessment of people. Thermal sensitivity and neutral temperatures were found to be significantly different, especially between summer and the two transient seasons. Challenges of international comparison are also emphasized, since the results prove that neutral temperatures obtained through different analysis techniques may be considerably different. The outcomes of this study underline the importance of the development of standard measurement and analysis methodologies in order to make future studies comprehensible, hereby facilitating the broadening of the common scientific knowledge about outdoor thermal comfort.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Ali-Toudert F, Mayer H (2006) Numerical study on the effects of aspect ratio and orientation of an urban street canyon on outdoor thermal comfort in hot and dry climate. Build Environ 41:94–108
Ali-Toudert F, Mayer H (2007a) Thermal comfort in an east–west oriented street canyon in Freiburg (Germany) under hot summer conditions. Theor Appl Climatol 87:223–237
Ali-Toudert F, Mayer H (2007b) Effects of asymmetry, galleries, overhanging facades and vegetation on thermal comfort in urban street canyons. Sol Energy 81:742–754
Andrade H, Vieira R (2007) A climatic study of an urban green space: the Gulbenkian park in Lisbon (Portugal). Finisterra 42:27–46
Ballantyne ER, Hill RK, Spencer JW (1977) Probit analysis of thermal sensation assessments. Int J Biometeorol 21:29–43
Becker S, Potchter O, Yaakov Y (2003) Calculated and observed human thermal sensation in an extremely hot and dry climate. Energ Build 35:747–756
Charalampopoulos I, Tsiros I, Chronopoulou-Sereli A, Matzarakis A (2013) Analysis of thermal bioclimate in various urban configurations in Athens, Greece. Urban Ecosyst 16:217–233
Chen L, Ng E (2012) Outdoor thermal comfort and outdoor activities: a review of research in the past decade. Cities 29:118–125
Chen L, Wen Y, Zhang L, Xiang WN (2015) Studies of thermal comfort and space use in an urban park square in cool and cold seasons in Shanghai. Build Environ 94:644–653
Cheng V, Ng E, Chan C, Givoni B (2012) Outdoor thermal comfort study in a sub-tropical climate: a longitudinal study based in Hong Kong. Int J Biometeorol 56:43–56
Cohen P, Potchter O, Matzarakis A (2013) Human thermal perception of Coastal Mediterranean outdoor urban environments. Appl Geogr 37:1–10
Deb C, Ramachandraiah A (2011) A simple technique to classify urban locations with respect to human thermal comfort: proposing the HXG scale. Build Environ 46:1321–1328
Fanger PO (1972) Thermal comfort. McGraw-Hill Book Co, New York
Fröhlich D, Matzarakis A (2013) Modeling of changes in thermal bioclimate: examples based on urban spaces in Freiburg, Germany. Theor Appl Climatol 111:547–558
Gómez F, Pérez Cueva A, Valcuende M, Matzarakis A (2013) Research on ecological design to enhance comfort in open spaces of a city (Valencia, Spain). Utility of the physiological equivalent temperature (PET). Ecol Eng 57:27–39
Gosling SN, Bryce EK, Dixon PG, et al. (2014) A glossary for biometeorology. Int J Biometeorol 58:277–308
Gulyás Á, Unger J, Matzarakis A (2006) Assessment of the microclimatic and human comfort conditions in a complex urban environment: modelling and measurements. Build Environ 41:1713–1722
Holst J, Mayer H (2011) Impacts of street design parameters on human-biometeorological variables. Meteorol Z 20:541–552
Höppe P (1992) Ein neues Verfahren zur Bestimmung der mittleren Strahlungstemperatur im Freien [A new method to determine the mean radiant temperature outdoors]. Wetter und Leben 44:147–151
Höppe P (1999) The physiological equivalent temperature—a universal index for the biometeorological assessment of the thermal environment. Int J Biometeorol 43:71–75
Huttner S, Bruse M, Dostal P (2008) Using ENVI-met to simulate the impact of global warming on the microclimate in central European cities. Ber Meteor Inst Albert-Ludwigs Univ Freiburg 18:307–312
Hwang R-L, Lin T-P (2007) Thermal comfort requirements for occupants of semi-outdoor and outdoor environments in hot-humid regions. Architect Sci Rev 50:357–364
Hwang R-L, Lin T-P, Matzarakis A (2011) Seasonal effects of urban street shading on long-term outdoor thermal comfort. Build Environ 46:863–870
IPCC (2014) Climate Change 2014: synthesis report, 2014. Contribution of Working Groups I, II and III to the Fifth Assessment Report of the Intergovernmental Panel on Climate Change [(Core Writing Team, Pachauri RK, Meyer LA (eds)]. IPCC, Geneva
Johansson E, Emmanuel R (2006) The influence of urban design on outdoor thermal comfort in the hot, humid city of Colombo, Sri Lanka. Int J Biometeorol 51:119–133
Johansson E, Thorsson S, Emmanuel R, Krüger E (2014) Instruments and methods in outdoor thermal comfort studies—the need for standardization. Urban Climate 10:346–366
Kántor N, Unger J (2011) The most problematic variable in the course of human biometeorological comfort assessment—the mean radiant temperature. Cent Eur J Geosci 3:90–100
Kántor N, Unger J, Gulyás Á (2012a) Subjective estimations of thermal environment in recreational urban spaces—Part 2: international comparison. Int J Biometeorol 56:1089–1101
Kántor N, Égerházi LA, Unger J (2012b) Subjective estimation of thermal environment in recreational urban spaces—Part 1: investigations in Szeged, Hungary. Int J Biometeorol 56:1075–1088
Kántor N, Tsai KT, Égerházi L, Lin T-P (2014) Outdoor thermal comfort requirements of Taiwanese and Hungarians in the warm months. Presentation and extended abstract on the 20th International Congress of Biometeorology, 28 September–2 October 2014, Cleveland, Ohio. Paper number: 5C.3
Kántor N (2016) Differences between the evaluation of thermal environment in shaded and sunny position. Hun Geo Bull 65:139–153
Knez I, Thorsson S (2006) Influences of culture and environmental attitude on thermal, emotional and perceptual evaluations of a public square. Int J Biometeorol 50:258–268
Knez I, Thorsson S (2008) Thermal, emotional and perceptual evaluations of a park: cross-cultural and environmental attitude comparisons. Build Environ 43:1483–1490
Kovács A, Unger J, Gál CV, Kántor N (2015) Adjustment of the thermal component of two tourism climatological assessment tools using thermal perception and preference surveys from Hungary. Theor Appl Climatol doi:10.1007/s00704-015-1488-9
Krüger EL, Rossi FA (2011) Effect of personal and microclimatic variables on observed thermal sensation from a field study in southern Brazil. Build Environ 46:690–697
Krüger EL, Drach P, Emmanuel R, Corbella O (2013) Assessment of daytime outdoor comfort levels in and outside the urban area of Glasgow, UK. Int J Biometeorol 57:521–533
Krüzselyi I, Bartholy J, Horányi A, Pieczka I, Pongrácz R, Szabó P, Szépszó G, Torma CS (2011) The future climate characteristics of the Carpathian Basin based on a regional climate model mini-ensemble. Adv Sci Res 6:69–73
Lai D, Guo D, Hou Y, Lin C, Chen Q (2014) Studies of outdoor thermal comfort in northern China. Build Environ 77:110–118
Lenzholzer S (2010) Engrained experience – a comparison of microclimate perception schemata and microclimate measurements in Dutch urban squares. Int J Biometeorol 54:141–150
Lin T-P (2009) Thermal perception, adaptation and attendance in a public square in hot and humid regions. Build Environ 44:2017–2026
Lin T-P, Matzarakis A (2008) Tourism climate and thermal comfort in Sun Moon Lake, Taiwan. Int J Biometeorol 52:281–290
Lin T-P, Matzarakis A, Hwang RL (2010) Shading effect on long-term outdoor thermal comfort. Build Environ 45:213–221
Lin T-P, de Dear R, Hwang R-L (2011) Effect of thermal adaptation on seasonal outdoor thermal comfort. Int J Climatol 31:302–312
Lindner-Cendrowska K (2013) Assessment of bioclimatic conditions in cities for tourism and recreational purposes (a Warsaw case study). Geogr Pol 86:55–66
Mahmoud AHA (2011) Analysis of the microclimatic and human comfort conditions in an urban park in hot and arid regions. Build Environ 46:2641–2656
Matzarakis A, Endler C (2010) Climate change and thermal bioclimate in cities: impacts and options for adaptation in Freiburg, Germany. Int J Biometeorol 54:479–483
Matzarakis A, Mayer H (1996) Another kind of environmental stress: thermal stress. WHO Newsl 18:7–10
Matzarakis A, Mayer H, Iziomon MG (1999) Application of a universal thermal index: physiological equivalent temperature. Int J Biometeorol 43:76–84
Matzarakis A, Rutz F, Mayer H (2007) Modelling radiation fluxes in simple and complex environments—application of the RayMan model. Int J Biometeorol 51:323–334
Matzarakis A, Rutz F, Mayer H (2010) Modelling radiation fluxes in simple and complex environments: basics of the RayMan model. Int J Biometeorol 54:131–139
Mayer H (2008) KLIMES—a joint research project on human thermal comfort in cities. Ber Meteor Inst Albert-Ludwigs Univ Freiburg 17:101–117
Mayer H, Höppe P (1987) Thermal comfort of man in different urban environments. Theor Appl Climatol 38:43–49
Mayer H, Holst J, Dostal P, Imbery F, Schindler D (2008) Human thermal comfort in summer within an urban street canyon in Central Europe. Meteorol Z 17:241–250
Müller N, Kuttler W, Barlag AB (2014) Counteracting urban climate change: adaptation measures and their effect on thermal comfort. Theor Appl Climatol 115:243–257
Nakano J, Tanabe S-I (2004) Thermal comfort and adaptation in semi-outdoor environments. ASHRAE Trans 110:543–553
Ng E, Cheng V (2012) Urban human thermal comfort in hot and humid Hong Kong. Energ Build 55:51–65
Nikolopoulou M, Lykoudis S (2006) Thermal comfort in outdoor urban spaces: analysis across different European countries. Build Environ 41:1455–1470
Nikolopoulou M, Steemers K (2003) Thermal comfort and psychological adaptation as a guide for designing urban spaces. Energ Build 35:95–101
Nikolopoulou M, Baker N, Steemers K (2001) Thermal comfort in outdoor urban spaces: understanding the human parameter. Sol Energy 70:227–235
Pantavou K, Theoharatos G, Santamouris M, Asimakopoulos D (2013) Outdoor thermal sensation of pedestrians in a Mediterranean climate and a comparison with UTCI. Build Environ 66:82–95
Pearlmutter D, Jiao D, Garb Y (2014) The relationship between bioclimatic thermal stress and subjective thermal sensation in pedestrian spaces. Int J Biometeorol 58:2111–2127
Pongrácz R, Bartholy J, Bartha EB (2013) Analysis of projected changes in the occurrence of heat waves in Hungary. Adv Geosci 35:115–122
Rupp RF, Vásquez NG, Lamberts R (2015) A review of human thermal comfort in the built environment. Energ Build 105:178–205
Saaroni H, Pearlmutter D, Hatuka T (2015) Human-biometeorological conditions and thermal perception in a Mediterranean coastal park. Int J Biometeorol 59:1347–1362
Shashua-Bar L, Pearlmutter D, Erell E (2011) The influence of trees and grass on outdoor thermal comfort in a hot-arid environment. Int J Climatol 31:1498–1506
Shashua-Bar L, Tsiros IX, Hoffman M (2012) Passive cooling design options to ameliorate thermal comfort in urban streets of a Mediterranean climate (Athens) under hot summer conditions. Build Environ 57:110–119
Spagnolo J, de Dear R (2003) A field study of thermal comfort in outdoor and semi-outdoor environments in subtropical Sydney Australia. Build Environ 38:721–738
Stathopoulos T, Wu H, Zacharias J (2004) Outdoor human comfort in an urban climate. Build Environ 39:297–305
Streiling S, Matzarakis A (2003) Influence of single and small clusters of trees on the bioclimate of a city: a case study. J Arboric 29:309–316
Thorsson S, Lindqvist M, Lindqvist S (2004) Thermal bioclimatic conditions and patterns of behaviour in an urban park in Göteborg, Sweden. Int J Biometeorol 48:149–156
Tsitoura M, Tsoutsos T, Daras T (2014) Evaluation of comfort conditions in urban open spaces. Application in the island of Crete. Energy Convers Manag 86:250–258
Tung C-H, Chen C-P, Tsai K-T, Kántor N, Hwang R-L, Matzarakis A, Lin T-P (2014) Outdoor thermal comfort characteristics in the hot and humid region from a gender perspective. Int J Biometeorol 58:1927–1939
UNFPA (2011) The state of world population 2011. Report of the United Nations Population Fund. UNFPA, New York
Unger J, Lelovics E, Gál T (2014) Local climate zone mapping using GIS methods in Szeged. Hung Geogr Bull 63:29–41
Xi T, Li Q, Mochida A, Meng Q (2012) Study on the outdoor thermal environment and thermal comfort around campus clusters in subtropical urban areas. Build Environ 52:162–170
Yahia MW, Johansson E (2013) Evaluating the behaviour of different thermal indices by investigating various outdoor urban environments in the hot dry city of Damascus, Syria. Int J Biometeorol 57:615–630
Yang W, Wong NH, Jusuf SK (2013a) Thermal comfort in outdoor urban spaces in Singapore. Build Environ 59:426–435
Yang W, Wong NH, Zhang G (2013b) A comparative analysis of human thermal conditions in outdoor urban spaces in the summer season in Singapore and Changsha, China. Int J Biometeorol 57:895–907
Yin JF, Zheng YF, Wu RJ, Tan JG, Ye DX, Wang W (2012) An analysis of influential factors on outdoor thermal comfort in summer. Int J Biometeorol 56:941–948
Zeng Y, Dong L (2015) Thermal human biometeorological conditions and subjective thermal sensation in pedestrian streets in Chengdu, China. Int J Biometeorol 59:99–108
Author information
Authors and Affiliations
Corresponding author
Appendix
Appendix
Geographical location of the most important outdoor thermal comfort studies related to the present work
Location of the six study areas in the city of Szeged
Photos and the general description of the six study areas
Rights and permissions
About this article
Cite this article
Kántor, N., Kovács, A. & Takács, Á. Seasonal differences in the subjective assessment of outdoor thermal conditions and the impact of analysis techniques on the obtained results. Int J Biometeorol 60, 1615–1635 (2016). https://doi.org/10.1007/s00484-016-1151-x
Received:
Revised:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s00484-016-1151-x