Optimization of Sampling Designs for Validating Digital Soil Maps
Author | : Yakun Zhang |
Publisher | : |
Total Pages | : |
Release | : 2016 |
Genre | : |
ISBN | : |
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"Meeting food demand for ever increasing global population can be attained through sustainable management of soil resources. This requires a thorough understanding of soil properties and processes and calls for methods to quantify and display spatial variability of soil. Three dimensional digital soil mapping (3D-DSM) with its ability to quantify both the horizontal and the vertical variability has become popular in recent days. The state-of-the-art data mining techniques including 3D regression kriging (RK) has been used to uncover complex soil-landscape relationships but not assessed at small scales. In addition, recent advances in proximal soil sensing allow measurement and prediction of various soil properties simultaneously and rapidly at multiple depths and provide required information for DSM. Furthermore, sampling design (SD) plays a vital role in providing a reliable input for DSM, whereas its effectiveness on 3D-DSM has not been tested. A total of 148 sample locations, identified by six SDs, including grid sampling (GS), grid random sampling (GRS), simple random sampling (SRS), stratified random sampling (StRS), transect sampling (TS), and conditioned Latin hypercube sampling (cLHS), were used to collect vis-NIR spectra data to about 1-m depth in-situ using a commercial soil profiler from a small agricultural farm in Macdonald campus, McGill University. A subset of 32 sample locations were identified to collect soil cores down to 1-m depth and sampled at 10-cm depth intervals. A total of 251 samples were analyzed in laboratory for a range of soil properties. Partial least square regression was used to develop soil-spectral relationship model. Predicted soil and uncertainty maps for soil properties were developed using 3D-DSM with RK from the calibration dataset (103 locations) and assessed using validation dataset (45 locations). Further three regression techniques, including generalized linear model (GLM), regression tree (RT), and random forest (RF) were tested and compared for accuracy and efficiency. Maps developed using sub samples (45 locations) identified by six SDs were further compared with the original map produced by the full dataset (148 locations) and individually validated by the rest 103 locations.The results showed that a good prediction was obtained for soil organic matter (SOM) and water-related soil properties from in-situ vis-NIR spectra, while a fair prediction was obtained for other properties. RF outperformed GLM and RT by quantifying the non-linear soil-landscape relationship, displaying weak spatial structure of regression residuals, and resulting in a more robust prediction model with high accuracy and low uncertainty. The predicted maps clearly presented the soil spatial variability, reflected the interactions among soil properties, and displayed the associated soil forming processes. Among the SDs, StRS with both good spatial and feature space coverage better represented the distribution of original maps and showed a small prediction uncertainty, while cLHS produced higher validation accuracy. SRS resulted in good validation results, while requires further exploration for its robustness. The main contribution of this thesis was to assess and optimize the methods and techniques for 3D-DSM and associated SDs and quantify both the horizontal and vertical variability of multiple soil properties." --