A platform for research: civil engineering, architecture and urbanism
A platform for research: civil engineering, architecture and urbanism
Empirical models on urban surface emissivity retrieval based on different spectral response functions: A field study
https://orcid.org/0000-0002-8674-3862
Abstract Thermal emissivity is a prerequisite for retrieving the land surface temperature (LST) and estimating the land surface budget based on data from remote sensing. Despite the availability of empirical models on emissivity retrieval on the meso-scales, their incompatibility for complex surfaces of the micro-scale leads to errors in emissivity retrieval, thus compromising thermal assessments of urban environments. To minimize such errors, this paper proposed a method to retrieve pixel-scale emissivity on the micro-scale. To measure reflectance spectra and emissivity spectra in the field, a PSR+3500 handheld spectrometer and a 102F portable Fourier transform infrared spectrometer were respectively used. Upon resampling these spectra to spectral response functions (SRF) of drone-derived and satellite-derived sensors, diverse reflectance and emissivity values were obtained to establish empirical models characterizing correlations between the normalized difference vegetation index (NDVI) and emissivity. Then, these models were applied to the low-altitude hyperspectral image from the Nano-Hyperspec imager on a drone. The results show that the model established by the SRF of a thermal camera achieved a root mean square error (RMSE) of 0.0129, and the accuracy of emissivity retrieval was within 0.010. For satellite applications, the model founded by the SRF of Aster was the most accurate for retrieving the emissivity of urban surfaces, with a RMSE of 0.0082 and an average accuracy of 0.003. The model based on SRFs of Landsat 8 registered a RMSE of 0.0155 alongside an average accuracy of 0.012, while that based on Modis registered a RMSE of 0.1210, alongside an average accuracy of 0.007.
Highlights A new method of retrieving emissivity on the micro-scale of urban environment. . Empirical models between NDVI and emissivity based on spectral response functions. The model established by Aster is the most suitable for retrieving emissivity on urban surfaces. This method lays a foundation for precisely assessing the local heat environment by UAV.
Empirical models on urban surface emissivity retrieval based on different spectral response functions: A field study
https://orcid.org/0000-0002-8674-3862
Abstract Thermal emissivity is a prerequisite for retrieving the land surface temperature (LST) and estimating the land surface budget based on data from remote sensing. Despite the availability of empirical models on emissivity retrieval on the meso-scales, their incompatibility for complex surfaces of the micro-scale leads to errors in emissivity retrieval, thus compromising thermal assessments of urban environments. To minimize such errors, this paper proposed a method to retrieve pixel-scale emissivity on the micro-scale. To measure reflectance spectra and emissivity spectra in the field, a PSR+3500 handheld spectrometer and a 102F portable Fourier transform infrared spectrometer were respectively used. Upon resampling these spectra to spectral response functions (SRF) of drone-derived and satellite-derived sensors, diverse reflectance and emissivity values were obtained to establish empirical models characterizing correlations between the normalized difference vegetation index (NDVI) and emissivity. Then, these models were applied to the low-altitude hyperspectral image from the Nano-Hyperspec imager on a drone. The results show that the model established by the SRF of a thermal camera achieved a root mean square error (RMSE) of 0.0129, and the accuracy of emissivity retrieval was within 0.010. For satellite applications, the model founded by the SRF of Aster was the most accurate for retrieving the emissivity of urban surfaces, with a RMSE of 0.0082 and an average accuracy of 0.003. The model based on SRFs of Landsat 8 registered a RMSE of 0.0155 alongside an average accuracy of 0.012, while that based on Modis registered a RMSE of 0.1210, alongside an average accuracy of 0.007.
Highlights A new method of retrieving emissivity on the micro-scale of urban environment. . Empirical models between NDVI and emissivity based on spectral response functions. The model established by Aster is the most suitable for retrieving emissivity on urban surfaces. This method lays a foundation for precisely assessing the local heat environment by UAV.
Empirical models on urban surface emissivity retrieval based on different spectral response functions: A field study
https://orcid.org/0000-0002-8674-3862
Abstract Thermal emissivity is a prerequisite for retrieving the land surface temperature (LST) and estimating the land surface budget based on data from remote sensing. Despite the availability of empirical models on emissivity retrieval on the meso-scales, their incompatibility for complex surfaces of the micro-scale leads to errors in emissivity retrieval, thus compromising thermal assessments of urban environments. To minimize such errors, this paper proposed a method to retrieve pixel-scale emissivity on the micro-scale. To measure reflectance spectra and emissivity spectra in the field, a PSR+3500 handheld spectrometer and a 102F portable Fourier transform infrared spectrometer were respectively used. Upon resampling these spectra to spectral response functions (SRF) of drone-derived and satellite-derived sensors, diverse reflectance and emissivity values were obtained to establish empirical models characterizing correlations between the normalized difference vegetation index (NDVI) and emissivity. Then, these models were applied to the low-altitude hyperspectral image from the Nano-Hyperspec imager on a drone. The results show that the model established by the SRF of a thermal camera achieved a root mean square error (RMSE) of 0.0129, and the accuracy of emissivity retrieval was within 0.010. For satellite applications, the model founded by the SRF of Aster was the most accurate for retrieving the emissivity of urban surfaces, with a RMSE of 0.0082 and an average accuracy of 0.003. The model based on SRFs of Landsat 8 registered a RMSE of 0.0155 alongside an average accuracy of 0.012, while that based on Modis registered a RMSE of 0.1210, alongside an average accuracy of 0.007.
Highlights A new method of retrieving emissivity on the micro-scale of urban environment. . Empirical models between NDVI and emissivity based on spectral response functions. The model established by Aster is the most suitable for retrieving emissivity on urban surfaces. This method lays a foundation for precisely assessing the local heat environment by UAV.
Empirical models on urban surface emissivity retrieval based on different spectral response functions: A field study
Zhong, Xue (author) / Zhao, Lihua (author) / Wang, Jie (author) / Zheng, Haichao (author) / Yan, Junru (author) / Jin, Rong (author) / Ren, Peng (author)
Building and Environment ; 197
2021-04-09
Article (Journal)
Electronic Resource
English
Land surface emissivity retrieval from airborne sensor over urban areas
| Online Contents | 2012
Land Surface Emissivity Retrieval From Different VNIR and TIR Sensors
| Online Contents | 2008
Regression of Surface Spectral Emissivity From Hyperspectral Instruments
| Online Contents | 2008