Hyperspectral inversion of heavy metal content in reclaimed soil from a mining wasteland based on different spectral transformation and modeling methods.

Conventional methods for investigating heavy metal contamination in soil are time consuming and expensive. We explored reflectance spectroscopy as an alternative method for assessing heavy metals. Four spectral transformation methods, first-order differential (FDR), second-order differential (SDR), continuum removal (CR) and continuous wavelet transform (CWT), are used for the original spectral data. Spectral preprocessing effectively eliminated the noise and baseline drifting and also highlighted the locations of the spectral feature bands. Partial least squares regression (PLSR) and radial basis function neural network (RBF) were used to study the hyperspectral inversion of four heavy metals (Cr, As, Ni, Cd). The inversion models of four heavy metals were established in the bands with the highest correlation coefficient. The inversion effects were evaluated by the coefficient of determination (R2), root mean square error (RMSE) and residual predictive deviation (RPD) indexes. The R values of the correlation coefficient were significantly improved after smoothing and spectral transformation compared to the original waveband. The method combining continuous wavelet transform (CWT) with radial basis function neural network (RBF) had the best inversion effect on the four heavy metals. When compared to partial least squares regression (PLSR), the RMSE values were reduced by approximately 2. The CWT-RBF method can be used as a means of inversion of heavy metals in mining wasteland reclaimed land.

[1]  杜培军,et al.  Combined multi-kernel support vector machine and wavelet analysis for hyperspectral remote sensing image classification , 2011 .

[2]  Kun Tan,et al.  Estimation of heavy metal concentrations in reclaimed mining soils using reflectance spectroscopy. , 2014, Guang pu xue yu guang pu fen xi = Guang pu.

[3]  Huang Honghua A method based on wavelet transform for spectral feature extraction , 2006 .

[4]  Jianhui Xi,et al.  Spectral emissivity estimation based on K — means clustering RBF neural network , 2017, 2017 29th Chinese Control And Decision Conference (CCDC).

[5]  J. Castagna,et al.  Spectral decomposition using time-frequency continuous wavelet transforms for fault detection in the Bakken Formation , 2017 .

[6]  Fumin Wang,et al.  Comparison Between Radial Basis Function Neural Network and Regression Model for Estimation of Rice Biophysical Parameters Using Remote Sensing , 2009 .

[7]  J. M. Soriano-Disla,et al.  The Performance of Visible, Near-, and Mid-Infrared Reflectance Spectroscopy for Prediction of Soil Physical, Chemical, and Biological Properties , 2014 .

[8]  Xu Binbin,et al.  Reflectance of soil clay minerals and its application in pedology , 1987 .

[9]  He Ting-ting Research on hyper-spectral remote sensing in heavy metal pollution soil , 2013 .

[10]  Moses Azong Cho,et al.  Model-Based Integrated Methods for Quantitative Estimation of Soil Salinity from Hyperspectral Remote Sensing Data: A Case Study of Selected South African Soils , 2012 .

[11]  Zhou Shi,et al.  Development of a national VNIR soil-spectral library for soil classification and prediction of organic matter concentrations , 2014, Science China Earth Sciences.

[12]  Peijun Du,et al.  Combined multi-kernel support vector machine and wavelet analysis for hyperspectral remote sensing image classif ication , 2011 .

[13]  Bin Li,et al.  Soil mapping via diffuse reflectance spectroscopy based on variable indicators: An ordered predictor selection approach , 2018 .