A semi-empirical method for estimating complete surface temperature from radiometric surface temperature, a study in Hong Kong city.

The complete surface temperature (T c) in urban areas, defined as the mean temperature of the total active surface area, is an important variable in urban micro-climate research, specifically for assessment of the urban surface energy balance. Since most vertically-oriented building facets are not observed by a nadir-viewing remote imaging radiometer, the radiometric surface temperature (T r) measured at a specific view angle cannot be used with existing heat transfer equations to estimate radiative and convective fluxes in the urban environment. Thus, it is necessary to derive T c for city neighborhoods. This study develops a simple method to estimate T c from T r with the aid of the Temperatures of Urban Facets in 3D (TUF-3D) numerical model, which calculates 3-D sub-facet scale urban surface temperatures for a variety of surface geometries and properties, weather conditions and solar angles. The effects of geometric and meteorological characteristics – e.g., building planar area index (λ p), wall facet area index (F), solar irradiance – on the difference between T c and T r were evaluated using the TUF-3D model. Results showed the effects of geometric and meteorological characteristics on the difference between T c and T r differ between daytime and nighttime. The study then sought to predict the relationship between T r and T c , using λ p , F , and solar irradiance for daytime and only using λ p and F for nighttime. Based on the simulated data from TUF-3D, the resulting relationships achieve a coefficient of determination (r 2 ) of 0.97 and a RMSE of 1.5 K during daytime, with corresponding nighttime values of r 2 = 0.98 and RMSE = 0.69 K. The relationships between T r and T c are evaluated using high resolution airborne thermal images of daytime urban scenes: r 2 = 0.75 and RMSE = 1.09 K on August 6, 2013 at 12:40 pm; and r 2 = 0.86 and RMSE = 1.86K on October 24, 2017 at 11:30 am. The new relationships were also applied to estimate T c from T r in Hong Kong retrieved from Landsat 5 Thematic Mapper (TM) and the Advanced Spaceborne Thermal Emission and Reflection Radiometer (ASTER). In the present climatic context, the difference between T c and T r can reach 10 K during daytime in summer, and 6 K during daytime in winter, with seasonal variation attributable to the variations in shortwave irradiance. The nighttime difference between T c and T r can also reach 2 K in both summer and spring seasons. • Parameterization of complete surface temperature over complex urban areas • Geometric effects on the difference between T r and T c were first evaluated. • Relationships between T r and T c characterized by urban geometry were developed. • Validation with high-spatial-resolution airborne thermal images was undertaken. [ABSTRACT FROM AUTHOR]