Intra‐urban nocturnal cooling rates: development and evaluation of the NOCRA model

Intra‐urban nocturnal cooling rates: development and evaluation of the NOCRA model

ABSTRACT A nocturnal cooling rate model (NOCRAM) to simulate nocturnal air temperature at urban sites is presented. The model is designed for urban planners, practitioners and researchers who demand meteorological information for urban planning and research applications. The model is based on the co...

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Bibliographic Details
Published in:Meteorological applications 2016-07, Vol.23 (3), p.339-352
Main Authors: Onomura, Shiho, Holmer, Björn, Lindberg, Fredrik, Thorsson, Sofia
Format: Article
Language:eng
Subjects:
Cooling
empirical modelling
Fysisk geografi
intra-urban heat island
Mean square errors
Meteorologi och atmosfärforskning
Meteorology and Atmospheric Sciences
nocturnal cooling rate
Physical Geography
Temperature
two-phase cooling
urban planning applications
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Summary:ABSTRACT A nocturnal cooling rate model (NOCRAM) to simulate nocturnal air temperature at urban sites is presented. The model is designed for urban planners, practitioners and researchers who demand meteorological information for urban planning and research applications. The model is based on the concept of nocturnal cooling, progressing in two distinct phases, i.e. site‐dependent cooling around sunset and site‐independent cooling from about 1 or 2 h after sunset until sunrise. Cooling rates are usually determined predominantly by prevailing weather conditions (i.e. clearness of the sky and wind speed), followed by maximum daily air temperature and by sky view factors. Second phase cooling is chiefly determined by sky clearness and wind speed. The findings and statistical results from the analysis of observational data during warm months (May–September) from Gothenburg, Sweden, as well as from past studies, were used. The model requires standard meteorological variables (i.e. wind speed, incoming short‐wave radiation, air temperature, relative air humidity, air pressure) at a reference station as well as geometrical information (i.e. the sky view factor of the site and the geographical co‐ordinates of the reference meteorological station). The model simulates the characteristic development of cooling rates in the two phases at open sites and built‐up sites with different sky view factors under a wide range of weather conditions in warm months. Using the modelled cooling rates, nocturnal air temperature is estimated easily with the accuracy of root mean square error (RMSE) ≤1.54 °C and R2 ≥0.78.
ISSN:1350-4827
1469-8080
1469-8080