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Application of Geographical Information System to Understand Spatial Variability of Soil Available Nutrients in Northern Karnataka, India

J. B. Kambale 1 * and H. V. Rudramurthy 2

1 Department of Agricultural Engineering, College of Agriculture Bheemarayanagudi, University of Agricultural sciences, Raichur, 585287 India

2 Department of soil science and Agricultural Chemistry, College of Agriculture Bheemarayanagudi, University of Agricultural sciences, Raichur, 585287 India

DOI: http://dx.doi.org/10.12944/CWE.12.1.20

It is very important to distinguish the spatial variability in soil fertility for site specific nutrient application. To know the status, 25 soil samples were collected from Vandurga Village, Yadgir District, Karnataka, India. Samples were analysed for electrical conductivity (EC), power of hydrogen (pH), organic carbon (OC), Nitrogen (N), Phosphorous (P2O5) and Potassium (K2O). Further, SPSS (ver. 19) was used to execute conventional statistical analysis and ArcGIS to get the information about distribution and spatial variability of soil available nutrients. The analysis results showed that the EC of soil varied from 0.13 to 0.25 dS/m with a mean of 0.18 dS/m. The PH ranged from 6.62 to 8.82 with an average of 7.89. Available OC ranged from 0.14 % to 1.90 % with mean of 0.78 %. Similarly mean values for N, P2O5 and K2O observed 215.3 kg/ha, 31.5 kg/ha, and 513.4 kg/ha, respectively. The SD and CV for EC was 0.031 and 16.69%, respectively, while for pH, OC, N, P2O5 and K2O it was found to be 0.56 and 7.04, 0.39 and 51.16, 100.9 and 46.86, 19.12 and 60.61, 160.88 and 31.33 respectively. Spatial variability maps for various nutrients prepared shows the huge variation in the soil nutrients availability. This variability appeared due to lack of balanced application of fertilizers. It was suggested that an appropriate applications of nutrients necessary for selected land based on soil nutrients.


Soil fertility; Kolmogorov–Smirnov (K-S) test; Dukey data Adequacy test; Inverse Distance Weighted (IDW)

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Kambale J. B, Rudramurthy H. V. Application of Geographical Information System to Understand Spatial Variability of Soil Available Nutrients in Northern Karnataka, India. Curr World Environ 2017;12(1). DOI:http://dx.doi.org/10.12944/CWE.12.1.20

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Kambale J. B, Rudramurthy H. V. Application of Geographical Information System to Understand Spatial Variability of Soil Available Nutrients in Northern Karnataka, India. Curr World Environ 2017;12(1). Available from: http://www.cwejournal.org/?p=16814


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Article Publishing History

Received: 2016-11-28
Accepted: 2017-03-03

Introduction

The conventional method of soil fertility management consider entire fields as a single group of soil and also while calculating requirement of fertilizer as a single field. Recitation of soil spatial variability in the field has a huge difficulty, in the use of latest advanced tools and technologies Viz. Global Positioning Systems (GPS), Geographic Information Systems (GIS) and many others were commenced. Many scientists demonstrated in studies conducted at various locations, GIS is an effective set of tools for to collect, store, retrieve, transform and display spatial data.1 It is also seen that the scientists working in natural resource management groups has extensively used GIS for the production of soil fertility map of an area that helps to understand the soil fertility status spatially and temporally, which will be useful to calculate the site-specific suggestion for application of the appropriate quantity of fertilizers. Technologies like GPS and GIS allow fields to be mapped precisely and to help in understanding the complex spatial relationships between soil fertility factors.2 Noticeably, a prepared soil fertility status map of selected location can help in  guiding the various stakeholders such as the people from farming community, manufacturers  from industrial sectors and  planners in deciding the need of  various  soil available nutrients in a different cropping seasons in the year and making  predictions for  increased  demand based on intensity of crops and cropping pattern.2,3 stated that the soil properties can vary spatially due to a range of factors viz. parent material, topography, climate, vegetation, and land management. It is also revealed that the spatial variability in soil is essential to pinpoint the nutrient limit zones in relation of production area to lessen the use of nutrients. Therefore, the precision agriculture is mainly depends on the management of spatial variability in soil fertility in agriculture and which is a major constraint for food production.4 Therefore, in the present study conventional statistical analysis and ArcGIS tool has been applied to get the information about distribution and spatial variability of soil available nutrients.

Materials and Methods

Study Area

The study carried out in Vandurga Village of Shahapur taluk as geographically lies between 16.64 N to 16.65 N latitude and 76.69 E to 76.70 E longitudes (Fig. 1). The total study area is 40 ha. This village come under the north-east dry zone (Zone-2) of Karnataka and partly irrigated from Krishna River by Shahapur Branch Canal Study area is characterized by undulating to rolling topography and geographically the rock system is granite-genesis complex belongs to Archean period. It’s also enjoys semiarid climates with average annual rainfall 656 mm and minimum temperature of 210C, where maximum temperature is 35 0C.

 Fig. 1. Location of study area and sampling points


Figure 1: Location of study area and sampling points 
Click here to View figure

 

Soil sampling and analysis

A total of 25 soil samples (0-20 cm depth) were collected from farmer's fields randomly 2 km radius. Concurrently, from all the sampling point's global positioning data was recorded by GPS (Trimble Juno-3D) device before sowing of Kharif (onset of south –west monsoon) crops to assess the spatial variability in the soil fertility status. All collected soil samples from different locations were taken for laboratory analysis. Before analysis of soil available nutrients [Electrical conductivity (EC), pH, soil organic carbon (OC), Nitrogen (N), Phosphorous (P2O5) and Potassium (K2O)] all the collected soil samples were air dried and sieved through a 2 mm size brass sieve of BSS(8) and ASTM(10) by following the standard laboratory procedures.5,6,7,8,9 The laboratory analysis was done to know the fertility status of all soil samples for chemical characteristics.

Database preparation

The entire analysed data were further processed using SPSS and ArcGIS. Initially, conventional statistical analysis was performed using SPSS (version 19) and spatial analysis was carried out using ArcMap GIS (version 9.2). The various maps produced in ArcMap GIS are presented in Fig. 1 and 2. The specific distribution of soil available nutrients was evaluated for normality using Kolmogorov–Smirnov (K-S) test.

Results and Discussion

Descriptive statistics

The descriptive statistics values of all analyzed soil samples from study area for various soil available nutrients (EC, pH, OC, N, P2O5 and K2O) are presented in the Table 1. Mean, maximum, minimum, standard deviation (SD) and coefficient of variation (CV) values for all the available soil nutrients have been calculated for 25 locations of the study area. The obtained results were found in close agreement with10 in Mukona, Uganda study area. It was also observed that because of regular application of various nutrients in the past the mean values of N, P, K and OC elevated.

Table 1: Descriptive statistics of soil available nutrients.

Parameters Values

Soil Available Nutrients

EC,dS/m

PH

OC,%

N, kg/ha

P2O,kg/ha

K2P5, kg/ha

Mean

0.18

7.98

0.77

215.31

31.55

513.47

Maximum

0.24

8.82

1.90

527.81

79.62

994.6

Minimum

0.12

6.62

0.14

100.84

7.93

312.6

Median

0.178

8.135

0.701

181.4

24.62

478.0

SD

0.03

0.56

0.39

100.9

19.12

160.88

CV%

16.68

7.04

51.16

46.86

60.60

31.33

 

Test of Distributional Adequacy

The Kolmogorov-Smirnov (K-S) test applied to decide if the analyzed soil samples come from datasets with a specific distribution.11 The applied test is based on the empirical distribution function (ECDF). K-S Test reports has been presented in the Table 2 (a and b). Some outlier’s values were removed as per definition of [12] for OC, N, P2O5, and K2O to achieve the more precise outcome from study. K-S Test found consistent for pH, EC, and OC for normal distribution with 0.49, 0.88 and 0.38 probability, respectively and unlikely consistent for  N, P2O5 and K2O. It is also observed that for log normal distribution K-S test is consistent for all available nutrients evaluated for study area.

Table 2a: Kolmogorov-Smirnov (K-S) test report.

Parameters

95% confidence interval for actual mean

IIIrd Quartile

Ist Quartile

Average Absolute deviation from median

Outliers values as per Jhon Tukey define

pH

7.74 thru 8.21

8.40

7.49

0.43

-

EC

0.17 thru 0.19

0.20

0.17

2.42

-

OC

0.61 thru 0.94

1.01

0.51

0.29

1.91

N

173.7 thru 257.0

101.00

270.00

140.00

528

P2O5

23.66 thru 39.45

39.40

17.80

14.00

79.6

K2O

447.1 thru 579.9

574.00

397.00

115.00

995

 

Table 2b: Kolmogorov-Smirnov (K-S) test report.

items

Normal Distribution

Log Normal Distribution

KS Says

P

mean

SD

KS Says

P

mean

SD

pH

Consistent

0.49

7.93

0.66

Consistent

0.39

7.90

1.09

EC

Consistent

0.88

0.18

3.42

Consistent

0.54

0.17

1.22

OC

Consistent

0.38

0.83

0.45

Consistent

0.30

0.64

2.16

N

Unlikely

0.01

242.8

115.3

Consistent

0.63

203.9

1.57

P2O5

Unlikely

0.01

35.58

20.59

Consistent

0.99

26.64

1.93

K2O

Unlikely

0.01

551.5

183.5

Consistent

0.60

506.8

1.37

 

Spatial variability maps of all soil available nutrients were prepared after interpolation of point values by Inverse Distance Weighted (IDW) method and which is presented in Fig. 2 (i to vi). To classify the spatial variability of soil available nutrients in specific locations in study area spatial variability maps prepared and it clearly shows where management of nutrients is required. Similar results also observed by various scientists viz.13 used interpolation technique of kriging to prepare the landslide susceptibility analysis map of Kota Kinabalu in Malaysia to locate areas prone to landslides.14 reported that the degree of accuracy of kriging technique in the prediction of soil properties and the descriptive  tools of semi variogram to characterize  the spatial patterns of continuous and categorical soil attributes.

Fig.2 Spatial distribution maps of soil available nutrients in study area. 


Figure 2: Spatial distribution maps of
soil available nutrients in study area. 

Click here to View figure

 

Conclusions

In the present study, the spatial variability in soil fertility were analysed for Vandurga Village, Yadgir district of Karnataka. This study showed that huge spatial variability in available nutrients in most of the farmer’s field. Few farmers field found deficient in nutrients availability and some found with adequate. This appeared due to lack of balanced application of nutrients by the farmers. Thus suggesting that, the appropriate nutrients applications needed for based of soil test values. The present study reveals that usefulness of GIS to know the spatial variability of soil available nutrients in the study area as well for spatial interpolation and mapping.

Acknowledgement

Authors would like to thanks to Director of Research, University of Agricultural Sciences, Raichur for supporting this work. Special thanks to unknown reviewer of journal who helped us to improve manuscript.

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