SPATIAL DEPENDENCE DEGREE AND SAMPLING NEIGHBORHOOD INFLUENCE ON INTERPOLATION PROCESS FOR FERTILIZER PRESCRIPTION MAPS

Amaral, Lucas R. do; Justina, Diego D. Della

doi:10.1590/1809-4430-Eng.Agric.v39nep85-95/2019

Lucas R. do Amaral ^** Corresponding author. University of Campinas, School of Agricultural Engineering/ Campinas - SP, Brazil. E-mail: lucas.amaral@feagri.unicamp.br

University of Campinas, School of Agricultural Engineering/ Campinas - SP, Brazil

http://orcid.org/0000-0001-8071-4449

Diego D. Della Justina

University of Campinas, School of Agricultural Engineering/ Campinas - SP, Brazil

* Corresponding author. University of Campinas, School of Agricultural Engineering/ Campinas - SP, Brazil. E-mail: lucas.amaral@feagri.unicamp.br

Area Editor: Fabio Henrique Rojo Baio

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FIGURE 1
Experimental fields, showing the disposition of the samples according to the datasets (dense and sparse sampling and external validation samples).

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FIGURE 2
Semivariograms obtained with dense (left) and sparse (right) sampling for each field, showing the inconsistency of the lag values and poor model adjustment when the sparse samplings were evaluated.

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FIGURE 3
Comparison among the indices proposed to evaluate the spatial autocorrelation of data (spatial dependence - ISD, DSD and MI) and the performance of the predictions conducted on the external validation set (RPD and R²). The letters above the bars refer to the classification of spatial dependence proposed by the respective indices, as indicated above. The value of the indices were modified for graphical visualization purposes.

ISD: Index of Spatial Dependence - the values were divided by 20 (ISD/20). The letters indicate: P - weak spatial dependence; M - moderate spatial dependence; S - strong spatial dependence, according to Seidel & Oliveira (2016)Seidel EJ, de Oliveira MS (2016) A classification for a geostatistical index of spatial dependence. Revista Brasileira de Ciência do Solo 40:1-10. DOI: https://doi.org/10.1590/18069657rbcs20160007
https://doi.org/10.1590/18069657rbcs2016... .

DSD: Spatial Dependence - the values obtained (in decimal) were subtracted from one (1-DSD); thus, higher values indicate greater spatial dependence (Cambardella et al., 1994Cambardella CA, Moorman TB, Novak JM, Parkin TB, Karlen DL, Turco R, Konopka AE (1994) Field-scale variability of soil properties in Central Iowa soil. Soil Science Society Ambience Journal 58:1501-1511.). The letters indicate: M - moderate spatial dependence; S - strong spatial dependence.

MI: Moran's Index. The letters/symbols indicate presence (*) or absence (^ns) of spatial autocorrelation with 95% confidence.

RPD: Ratio of Percentage Deviation - values divided by two (RPD/2). The letters indicate: VP - very poor model and its use is not recommended; P - poor model, in which only high and low values are distinguishable; M - regular model that allows its use for inferences and correlations, according to Viscarra Rossel et al. (2006)Viscarra Rossel RA, McGlynn RN, McBratney AB (2006) Determining the composition of mineral-organic mixes using UV-Vis-NIR diffuse reflectance spectroscopy. Geoderma 137:70-82. DOI: https://doi.org/10.1016/j.geoderma.2006.07.004
https://doi.org/10.1016/j.geoderma.2006.... .

R²: coefficient of determination.

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FIGURE 4
Potassium fertilizer prescription maps interpolated using KRIG, IDW_p1 and IDW_null for sparse and dense samplings - example of Field 1.

KRIG: Ordinary Kriging with neighborhood search.

IDW_p1: Inverse Distance Weighting with power of 1 (p=1 - IDW[p1]) with neighborhood search.

IDW_null: Inverse Distance Weighting with power of 2 (p=2 - IDW[null]) without neighborhood search.

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TABLE 1
Characteristics of the study sites, samplings performed and soil analysis.

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TABLE 2
Number of samples and sampling density (ha samples^-1) according to the dataset (dense, sparse, and external validation samples) and number of outliers removed in each field.

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TABLE 3
Performance of interpolation methods in predicting potassium fertilizer rates for external validation samples. We used the best sampling neighborhood indicated by the optimization process (kriging and IDW_p1) and the IDW null model (IDW_null). The interpolation methods with the best performance for each dataset are indicated in bold and take into account the coefficient of determination, RMSE (kg ha^-1) and the slope of the relationship between predicted and measured fertilizer rates.

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TABLE 4
The best configuration of sampling neighborhood and interpolation process for each dataset (three fields and two sampling densities) according to cross-validation results. Such configurations were used in all other interpolations carried out in this study (external validation and map preparation).

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(1)

Field	Area (ha)	Number of soil samples¹ 1 Number of samples after removal of outliers;	Subsamples for each sample point² 2 number of soil subsamples collected within 5 m of the center point with an auger;	Sampling density³ 3 Sampling density originally collected. (ha sample^-1)	Sampled depth (cm)	Average potassium soil availability (CV%)
1	115.7	114	6	1.0	0 − 40	1.01 mmol_c/dm³ (79.2%)
2	88.4	95	8	1.0	0 − 20	3.61 mmol_c/dm³ (35.2%)
3	98.6	194	3	0.5	0 − 20	0.9 mmol_c/dm³ (74.7%)

Field	No. of samples in dense sampling	Final sampling density (ha sample^-1)	No. of samples in sparse sampling	Final sampling density (ha sample^-1)	No. of samples in external validation	No. of samples removed as outliers¹ 1 outliers removed according to the criterion of Anselin Local Moran's I (Fu et al., 2016)
1	97	1.19	26	4.13	17	4
2	80	1.11	21	4.02	15	1
3	165	0.60	35	2.99	29	3

Interpolation	R²	RMSE	Slope	R²	RMSE	Slope
	Field 1 - Dense sampling			Field 1 - Sparse sampling
Kriging	0.62	11.15	0.70	0.53	12.38	0.54
IDW_p1	0.63	11.03	0.73	0.54	12.20	0.46
IDW_null	0.60	11.73	0.47	0.46	13.28	0.38
	Field 2 - Dense sampling			Field 2 - Sparse sampling
Kriging	0.62	17.64	0.82	0.44	19.98	0.49
IDW_p1	0.59	18.27	0.71	0.47	18.78	0.57
IDW_null	0.61	17.76	0.46	0.41	20.05	0.47
	Field 3 - Dense sampling			Field 2 - Sparse sampling
Kriging	0.01	16.53	0.04	0.00	19.25	0.04
IDW_p1	0.01	16.58	0.05	0.01	17.55	0.04
IDW_null	0.00	16.12	0.02	0.00	17.56	-0.01

Interpolation	Sampling	Model¹ 1 Model used: kriging = spherical; IDW = inverse distance weighting power equal to 1 (IDWp1).	n.min²	n.max³	R²	RMSE⁴ 4 root mean squared error (mmolc dm-3) between values measured and predicted by interpolation.
Field 1
Kriging	dense	spherical	4	7	0.67	0.46
IDW	dense	power = 1	4	4	0.68	0.46
Kriging	sparse	spherical	4	7	0.23	0.67
IDW	sparse	power = 1	4	4	0.16	0.68
Field 2
Kriging	dense	spherical	4	64	0.35	2.11
IDW	dense	power = 1	4	7	0.36	2.08
Kriging	sparse	spherical	4	7	0.27	2.43
IDW	sparse	power = 1	4	4	0.20	2.42
Field 3
Kriging	dense	spherical	4	58	0.16	0.61
IDW	dense	power = 1	4	13	0.15	0.61
Kriging	sparse	spherical	4	10	0.30	0.48
IDW	sparse	power = 1	4	4	0.20	0.50

[1] * Corresponding author. University of Campinas, School of Agricultural Engineering/ Campinas - SP, Brazil. E-mail: lucas.amaral@feagri.unicamp.br

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SPATIAL DEPENDENCE DEGREE AND SAMPLING NEIGHBORHOOD INFLUENCE ON INTERPOLATION PROCESS FOR FERTILIZER PRESCRIPTION MAPS

ABSTRACT