%0 Journal Article
%4 sid.inpe.br/mtc-m21b/2017/04.18.13.56
%2 sid.inpe.br/mtc-m21b/2017/04.18.13.56.57
%@doi 10.3390/rs9010042
%@issn 2072-4292
%T Hyperspectral remote sensing for detecting soil salinization using ProSpecTIR-VS aerial imagery and sensor simulation
%D 2017
%8 Jan.
%9 journal article
%A Rocha Neto, Odílio Coimbra da,
%A Teixeira, Adunias dos Santos,
%A Leão, Raimundo Alípio de Oliveira,
%A Moreira, Luis Clenio Jario,
%A Galvão, Lênio Soares,
%@affiliation Universidade Federal do Ceará (UFC)
%@affiliation Universidade Federal do Ceará (UFC)
%@affiliation Universidade Federal do Ceará (UFC)
%@affiliation Universidade Federal do Ceará (UFC)
%@affiliation Instituto Nacional de Pesquisas Espaciais (INPE)
%@electronicmailaddress odilioneto@gmail.com
%@electronicmailaddress adunias@ufc.br
%@electronicmailaddress alipioleao@yahoo.com.br
%@electronicmailaddress cleniojario@gmail.com
%@electronicmailaddress lenio.galvao@inpe.br
%B Remote Sensing
%V 9
%N 1
%P UNSP 42
%K soil salinization, electrical conductivity, reflectance spectroscopy, hyperspectral remote sensing, Extreme Learning Machine (ELM), Ordinary Least Square Regression (OLS), Multilayer Perceptron (MLP), Partial Least Squares Regression (PLSR).
%X Soil salinization due to irrigation affects agricultural productivity in the semi-arid region of Brazil. In this study, the performance of four computational models to estimate electrical conductivity (EC) (soil salinization) was evaluated using laboratory reflectance spectroscopy. To investigate the influence of bandwidth and band positioning on the EC estimates, we simulated the spectral resolution of two hyperspectral sensors (airborne ProSpecTIR-VS and orbital Hyperspectral Infrared Imager (HyspIRI)) and three multispectral instruments (RapidEye/REIS, High Resolution Geometric (HRG)/SPOT-5, and Operational Land Imager (OLI)/Landsat-8)). Principal component analysis (PCA) and the first-order derivative analysis were applied to the data to generate metrics associated with soil brightness and spectral features, respectively. The three sets of data (reflectance, PCA, and derivative) were tested as input variable for Extreme Learning Machine (ELM), Ordinary Least Square regression (OLS), Partial Least Squares Regression (PLSR), and Multilayer Perceptron (MLP). Finally, the laboratory models were inverted to a ProSpecTIR-VS image (400-2500 nm) acquired with 1-m spatial resolution in the northeast of Brazil. The objective was to estimate EC over exposed soils detected using the Normalized Difference Vegetation Index (NDVI). The results showed that the predictive ability of the linear models and ELM was better than that of the MLP, as indicated by higher values of the coefficient of determination (R-2) and ratio of the performance to deviation (RPD), and lower values of the root mean square error (RMSE). Metrics associated with soil brightness (reflectance and PCA scores) were more efficient in detecting changes in the EC produced by soil salinization than metrics related to spectral features (derivative). When applied to the image, the PLSR model with reflectance had an RMSE of 1.22 dS.m(-1) and an RPD of 2.21, and was more suitable for detecting salinization (10-20 dS.m(-1)) in exposed soils (NDVI < 0.30) than the other models. For all computational models, lower values of RMSE and higher values of RPD were observed for the narrowband-simulated sensors compared to the broadband-simulated instruments. The soil EC estimates improved from the RapidEye to the HRG and OLI spectral resolutions, showing the importance of shortwave intervals (SWIR-1 and SWIR-2) in detecting soil salinization when the reflectance of selected bands is used in data modelling.
%@language en
%3 neto.pdf