This study is part of the requirements consolidation study for the European Copernicus Hyperspectral Imaging Mission for Environment (CHIME). It explores the value added by existing hyperspectral data of similar characteristics to CHIME, namely AVIRIS-NG and PRISMA, for detecting topsoil texture properties. The spatial variability is retrieved using the linear spectral mixture analysis, an image-based algorithm that breaks down the hyperspectral dataset into fractional abundance of spectral classes within each pixel. The fractional abundance of image-based endmembers is broken into categories to find intervals having a spatial relation with texture components in terms of fine (clay and silt) or coarse (sand) abundance. The fraction maps obtained show similar spatial patterns to the USDA soil texture classification, obtained with a geostatistical approach. Specifically, AVIRIS CHIME-like FAM1 > 0.45 presented an agreement of 86% with clay and/or silt higher than 45% which, according to the USDA intervals, correspond to loam-clay loam classes. Similar results are obtained with PRISMA with FAM2 0.20-0.35, overlapping 63% of the kriging-based USDA clay-loam class. The fractional abundance categories showing the highest overlap percentages are correlated with the short-wave infrared spectral range, showing average coefficients of 0.7 where wavelengths are over 1500 nm. From 1700 nm, CHIME-like shows values of 0.8. In conclusion, this exploratory research and results leverage the opportunity of extending the processing chain to a larger number of case studies to better understand the physical relation between the spectral reflectance captured by new spaceborne hyperspectral sensors and the spatial patterns of soil texture classes.
Hyperspectral Mixture Models in the CHIME Mission Implementation for Topsoil Texture Retrieval
Valentini, Emiliana
;Taramelli, Andrea;Marinelli, Chiara;Martin, Laura Piedelobo;Troffa, Stefano;
2023-01-01
Abstract
This study is part of the requirements consolidation study for the European Copernicus Hyperspectral Imaging Mission for Environment (CHIME). It explores the value added by existing hyperspectral data of similar characteristics to CHIME, namely AVIRIS-NG and PRISMA, for detecting topsoil texture properties. The spatial variability is retrieved using the linear spectral mixture analysis, an image-based algorithm that breaks down the hyperspectral dataset into fractional abundance of spectral classes within each pixel. The fractional abundance of image-based endmembers is broken into categories to find intervals having a spatial relation with texture components in terms of fine (clay and silt) or coarse (sand) abundance. The fraction maps obtained show similar spatial patterns to the USDA soil texture classification, obtained with a geostatistical approach. Specifically, AVIRIS CHIME-like FAM1 > 0.45 presented an agreement of 86% with clay and/or silt higher than 45% which, according to the USDA intervals, correspond to loam-clay loam classes. Similar results are obtained with PRISMA with FAM2 0.20-0.35, overlapping 63% of the kriging-based USDA clay-loam class. The fractional abundance categories showing the highest overlap percentages are correlated with the short-wave infrared spectral range, showing average coefficients of 0.7 where wavelengths are over 1500 nm. From 1700 nm, CHIME-like shows values of 0.8. In conclusion, this exploratory research and results leverage the opportunity of extending the processing chain to a larger number of case studies to better understand the physical relation between the spectral reflectance captured by new spaceborne hyperspectral sensors and the spatial patterns of soil texture classes.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.