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Environmental Earth Sciences

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01.04.2012 | Original Article

Spatial prediction of soil properties in a watershed scale through maximum likelihood approach

verfasst von: Priyabrata Santra, Bhabani Sankar Das, Debashish Chakravarty

Erschienen in: Environmental Earth Sciences | Ausgabe 7/2012

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Abstract

Surface map of soil properties plays an important role in various applications in a watershed. Ordinary kriging (OK) and regression kriging (RK) are conventionally used to prepare these surface maps but generally need large number of regularly girded soil samples. In this context, REML-EBLUP (REsidual Maximum Likelihood estimation of semivariogram parameters followed by Empirical Best Linear Unbiased Prediction) shown capable but not fully tested in a watershed scale. In this study, REML-EBLUP approach was applied to prepare surface maps of several soil properties in a hilly watershed of Eastern India and the performance was compared with conventionally used spatial interpolation methods: OK and RK. Evaluation of these three spatial interpolation methods through root-mean-squared residuals (RMSR) and mean squared deviation ratio (MSDR) showed better performance of REML-EBLUP over the other methods. Reduction in sample size through random selection of sampling points from full dataset also resulted in better performance of REML-EBLUP over OK and RK approach. The detailed investigation on effect of sample number on performance of spatial interpolation methods concluded that a minimum sampling density of 4/km² may successfully be adopted for spatial prediction of soil properties in a watershed scale using the REML-EBLUP approach.

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Abramowitz M, Stegun IA (1972) Handbook of mathematical functions with formulas, graphs, and mathematical tables. New York, Dover

Basaran M, Erpul G, Ozcan AU, Saygin DS, Kibar M, Bayramin I, Yilman FE (2010) Spatial information of soil hydraulic conductivity and performance of cokriging over kriging in a semiarid basin scale. Environmental Earth Science doi:10.1007/s12665-010-0753-6

Baskan O, Cebel H, Akgul S, Erpul G (2010) Conditional simulation of USLE/RUSLE soil erodibility factor by geostatistics in a Mediterannean catchment, Turkey. Environ Earth Sci 60:1179–1187CrossRef

Baxter SJ, Oliver MA (2005) The spatial prediction of soil mineral N and potentially available N using elevation. Geoderma 128:325–339CrossRef

Bishop TFA, Lark RM (2008) Reply to “Standardized vs. customary ordinary cokriging…” by A. Papritz. Geoderma 146(1–2):397–399CrossRef

Chai X, Shen C, Yuan X, Huang Y (2008) Spatial prediction of soil organic matter in the presence of different external trends with REML-EBLUP. Geoderma 148:159–166CrossRef

Cressie N (1993) Statistics for spatial data. Wiley, New York

Davis BM (1987) Uses and abuses of cross-validation in geostatistics. Math Geol 19:241–248CrossRef

Diggle PJ, Riberio PJ Jr, Christensen OF (2003) An introduction to model-based geostatistics. In: Moller J (ed) Spatial statistics and computational methods. Springer, New York, pp 43–86

Dong J, Yu M, Bian Z, Wang Y, Di C (2011) Geostatistical analysis of heavy metal distribution in reclaimed mine land in Xuzhou, China. Environ Earth Sci 62:127–137CrossRef

Du Y, Delfs JO, Kalbus E, Park CH, Wang W, Kolditz O (2009) A regional hydrological soil model for large-scale applications: Computational concept and application. J Environ Hydrol 17: Paper No. 7, pp 16

Gee GW, Bauder JW (1986) Particle size analysis. In: Klute A (ed) Methods of soil analysis, Part 1, Agronomy Monograph No. 9. ASA and SSSA, Madison, pp 383–412

Goovaerts P (1992) Factorial kriging analysis: a useful tool for exploring the structure of multivariate spatial soil information. J Soil Sci 43:597–619CrossRef

Goovaerts P (1994) Study of spatial relationships between two sets of variables using multivariate geostatistics. Geoderma 62:93–107CrossRef

Goovaerts P (1997) Geostatistics for natural resources evaluation. Applied geostatistics series. Oxford University Press, New York

Goovaerts P (1998) Geostatistical tools for characterizing the spatial variability of microbiological and physico-chemical soil properties. Biol Fertil Soils 27:315–334CrossRef

Goovaerts P (1999) Geostatistical in soil science: state-of-the-art and perspectives. Geoderma 89:1–45CrossRef

Herbst M, Diekkrüger B, Vereecken H (2006) Geostatistical co-regionalisation of soil hydraulic properties in a micro-scale catchment using terrain attributes. Geoderma 132:206–221CrossRef

Iqbal J, Thomasson JA, Jenkins JN, Owens OR, Whisler FD (2005) Spatial variability analysis of soil physical properties of alluvial soils. Soil Sci Soc Am J 69:1338–1350CrossRef

Issaks EH, Srivastava RM (1989) Applied geostatistics. Oxford university press, New York

Juang KW, Chen YS, Lee DY (2004) Using sequential indicator simulation to asses the uncertainty of delineating heavy-metal contaminated soil. Environ Pollut 127:229–238CrossRef

Kerry R, Oliver MA (2007) Comparing sampling needs for semivariograms of soil properties computed by the method of moments and residual maximum likelihood. Geoderma 140:383–396CrossRef

Kitanidis PK (1983) Statistical estimation of polynomial generalized covariance functions and hydrologic applications. Water Resour Res 19:909–921CrossRef

Klute A (1986) Water retention: laboratory methods. In: Klute A (ed) Methods of soil analysis, Part 1, Agronomy Monograph No. 9, 2nd edn. ASA and SSSA, Madison, pp 635–662

Klute A, Dirrksen C (1986) Hydrualic conductivity and diffusivity. In: Klute A (ed) Methods of soil analysis—part 1, physical and mineralogical methods. ASA and SSSA, Madison, pp 687–734

Lark RM (2000) Estimating semivariograms of soil properties by the method of moments and maximum likelihood. Eur J Soil Sci 51:717–728CrossRef

Lark RM, Cullis BR, Welham SJ (2006) On spatial prediction of soil properties in the presence of a spatial trend: the empirical best linear unbiased predictor (E-BLUP) with REML. Eur J Soil Sci 57:787–799CrossRef

Lin YP (2002) Multivariate geostatistical methods to identify and map spatial variations of soil heavy metals. Env Geol 42:1–10CrossRef

Matérn B (1960) Spatial variation. In: Meddelanden fran Statens Skogsforskningsinstitut, 49, No. 5, 2nd edn. 1986, Lecture Notes in Statistics, No. 36. Springer, New York

Matheron G (1965) Les variables regionalisées et leur estimation. Masson, Paris

Minasny B, McBratney AB (2005) The Matérn function as a general model for soil semivariograms. Geoderma 128:192–207CrossRef

Minasny B, McBratney AB (2007) Spatial prediction of soil properties using EBLUP with the Matérn covariance function. Geoderma 140:324–336CrossRef

Odeh IOA, McBratney AB, Chittleborough DJ (1995) Further results on prediction of soil properties from terrain attributes: heterotopic cokriging and regression-kriging. Geoderma 67:215–226CrossRef

Pardo-Igúzquiza E (1998) Inference of spatial indicator covariance parameters by maximum likelihood using MLREML. Comput Geosci 24:453–464CrossRef

Patterson HD, Thompson R (1971) Recovery of inter-block information when block sizes are unequal. Biometrika 58:545–554CrossRef

Rakhmatullaev S, Marache A, Huneau F, Coustumer PL, Bakiev M, Motelica-Heino M (2010) Geostatistical approach for the assessment of the water reservoir capacity in arid regions: a case study of the Akdarya reservoir, Uzbekistan. Environ Earth Sci. doi:10.1007/s12665-010-0711-3

Robinson TP, Metternicht G (2006) Testing the performance of spatial interpolation techniques for mapping soil properties. Comput Electron Agric 50:97–108CrossRef

Santra P, Chopra UK, Chakraborty D (2008) Spatial variability of soil properties in agricultural farm and its application in predicting surface map of hydraulic property. Current Sci 95(7):937–945

Santra P, Das BS, Chakravarty D (2011) Delineation of hydrologically similar units in a watershed based on fuzzy classification of soil hydraulic properties. Hydrol Process 25:64–79CrossRef

Simbahan GC, Dobermann A, Goovaerts P, Ping J, Haddix ML (2006) Fine-resolution mapping of soil organic carbon based on multivariate secondary data. Geoderma 132:471–489CrossRef

Stein ML (1999) Interpolation of spatial data: some theory for kriging. Springer, New YorkCrossRef

Uygur V, Irvem A, Karanlik S, Akis R (2010) Mapping of total nitrogen, available phosphorus and potassium in Amik plain, Turkey. Environ Earth Sci 59:1129–1138CrossRef

van Genuchten MTh (1980) A close-form equation for predicting the hydraulic conductivity of unsaturated soils. Soil Sci Soc Am J 44:892–898CrossRef

Webster R, Oliver MA (1992) Sample adequately to estimate semivariograms of soil properties. J Soil Sci 43:177–192CrossRef

Wu C, Wu J, Luo Y, Zhang H, Teng Y, Degloria SD (2010) Spatial interpolation of severely skewed data with several peak values by the approach integrating kriging and triangular network interpolation. Environ Earth Sci. doi:10.1007/s122665-010-0784-z

Titel: Spatial prediction of soil properties in a watershed scale through maximum likelihood approach
verfasst von: Priyabrata Santra
Bhabani Sankar Das
Debashish Chakravarty
Publikationsdatum: 01.04.2012
Verlag: Springer-Verlag
Erschienen in: Environmental Earth Sciences / Ausgabe 7/2012
Print ISSN: 1866-6280
Elektronische ISSN: 1866-6299
DOI: https://doi.org/10.1007/s12665-011-1185-7

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