new generation of soil data in slovakia – processing and application jaroslava sobocká rastislav...
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New Generation of Soil Data in Slovakia – Processing and Application
Jaroslava Sobocká Rastislav SkalskýJuraj BalkovičVladimír Hutár
Soil Science and Conservation Reseach Institute Department of Soil Science and Mapping
Soil/ladscape data for Slovakia: in time line
1980 1985 1990 1995 2000 2005
KPP-DB PEU-DB
CMS-P
GFZP
GCHA
DPZ
GDPPS
• KPP-DB – Soil profile database
• CMS-P – Soil Monitoring database
• PEU-DB – Pedo-ecological units database
• GFZP – Regional pedo-geochemical database
• GCHA – Pedo-geochemical atlas database
• GDPPS – Geo-referenced database of agricultural soils
• DPZ – Remote sensing data (auxiliary data)
KPP-DB Soil profile database
Soil profile location (x,y) about 17 000 soil profiles of agricultural soils
Database tables- general soil profile
atributes- genetic soil horizons
attributes – morphological soil physical and chemical properties
Soil profiles distribution within the territory of Slovakia and at regional level
R. Skalský
CMS-P Soil monitoring database Monitoring sites location (x,y),
318 sites on agricultural soils Database tables
– attributes for description of general soil profile properties
– attributes for sequence of soil layers – morphological, chemical, physical properties
– attributes for soil contaminationMonitoring period – provided
data in time series (5 year period sampling/recording frequency)
Soil profiles distribution within the territory of Slovakia
J. Kobza
PEU-DB Pedo-ecological units database pedo-ecological
units (analogue version)Spatial
distribution of topic pedo-ecological units• soil-ecological attributes• soil production or economic attributesSpatial distribution of regional pedo-ecological unitsaccording to soil-ecological attributes
B. Ilavská
GFPP Regional pedo-geochemical database
spatial distribution of soil mapping units polygons
soil profiles localization Tablesgeneral attribute data for soil
profile soil horizon attribute data for
surface and substrate horizon – selected soil physical and chemical properties
soil contamination attributes for surface and substrate horizon – 15 risk elements
Continous raster models (layers) of soil risk elements content at one-dimensional level
pH(H2O)
Soil map 1:50 000
J. Sobocká
GCHA pedo-geochemical atlas database
Soil profile localization (x, y), 5 200 points on both agricultural and forest soils
table - attributes for description of
general properties of soil profile
- soil horizon attribute data for surface and substrate horizon – selected soil physical and chemical properties
- soil contamination attributes for surface and substrate horizon – 36 risk elements
Publication – analogue interpolated maps of risk elements distribution across the Slovakia
J. Čurlík, P. Šefčík
DPZ Remote sensing/auxiliary data
Digital ortophotomaps: covering all territory of Slovakia, valid for 2002/3, scale: 1:10 000
Satelite images: time series from 1999, covering all territory of Slovakia (LANDSAT, SPOT, IRS)
DEM: 30 and 50 m resolution DEM for whole territory of Slovakia
Interpretation example: USLE Based Erosion modelling M. Sviček, O. Rybár
GDPPS - Geo-referenced database of agricultural soils
New-fashioned soil database for Slovakia being built up since 2004
Database representation of General soil survey of agricultural soils of Slovakia (in 1961 – 1970)
Modern database enabling application of wide range of pedometrics procedures
Examples of analogue inputs
R. Skalský
GDPPS -Database structure
• Areal information about soil mapping units distribution
• Soil profiles localization and attribute data related (same as for KPP-DB), possible number of soil profiles represented: about 200 000
R. Skalský
Database aproximation: raster base
• Interpolated rasters, • spatial resolution 250m • applied on soil profile data
• Set of continuous raster layers of soil analytical properties created for discrete depth intervals• Measured soil parameters as well as PTF/stationary models derived ones• Selected regions of Slovakia
GDPPS - Database operability proposal
Soil units polygons
Average soil profile
Expert knowledge based
processing rulesAverage soil attributes
R. Skalský
What are methods used in digital soil/landscape data processing in Slovakia: a short history
1980 1985 1990 1995 2000 2005
PCA, agglomerative cluster analyses
Numerical taxonomy
GIS cartography, Expert interpretation
Geostatistics
Fuzzy k-means
Remote sensing data interpretation
Static/dynamic soil/landscape modelling
First methods and applications
127 soil profile were described by these soil properties (vectors):
Texture, soil structure, stoniness, soil consistence, pH in KCl, carbonate content, humus content, CEC, neoformation presence, depth of top horizons, depth of solum
Type of data: ranking of qualitative data Type of standardization: standard
deviation Similarity coeficient: Manhattan metric Agglomerative strategy: Non-weighted
pair-group method
Juráň, C.: Numerical ordination os soils on the base of General Survey of Agricultural soils, 1984Horváthová, J,: Contribution to the Numerical taxonomy method for soil classification,1985
Problems of clusters validation and interpretation
J. Sobocká
GIS cartography and expert interpretationPolygons as SOTERunit_ID in Slovakia in 1:2.5 million
76 polygons were delineated and described in Slovakia
J. Sobocká
Soil Degradation in Central and Eastern Europe
(SOVEUR)
SOTER database formation and application in maps
J. Sobocká
Various maps producing relating to soil degradation status
SSCRI strategy for creation of regional pedo -geochemical maps - location
Position location of soil description refer to :global coordinates (WGS 84 – latitude B (degree), longitude L (degree) ):national grids (S-JTSK – X (meter) Y (meter))
Satellite images
Topography maps
Orthophotomaps
GPS
V. Hutár
2.49rmsey
3.49rmse
x
4.29
rmsexy
vzdialenosť [m]
-25
-20
-15
-10
-5
0
5
10
15
20
25
-15 -10 -5 0 5 10 15v
X
Y
-40
-30
-20
-10
0
10
20
30
40
1
3601
7201
1080
1
1440
1
1800
1
2160
1
2520
1
dy
dx
vzdialenosť [m]
čas (s)
Reference measurement:GPS position accuracySSRI reference stationSAMPLE ACCURACY – refer to
the mapping method – with regard to map scale – with regard to sample design
V. Hutár
cluster regular random
SSCRI strategy for creation of regional pedogeochemical maps - Sampling strategy
Searching for spatial dependence, analyzing the basic principles in space with regard on accuracy, scale and dimension
directional variogram,direction
60º
anisotropic variation directional variogram,direction
150º
directional variogram, anisotropy 1.6
0 1000 2000 3000 4000 5000 6000 7000 8000 9000 10000 11000 12000
Lag D istance
0
0.0002
0.0004
0.0006
0.0008
0.001
0.0012
Variogram
D irection: 60.0 Tolerance: 36.0Nt
0 1000 2000 3000 4000 5000 6000 7000
Lag D istance
0
0.0002
0.0004
0.0006
0.0008
0.001
0.0012
Variogra
m
D irection : 0 .0 To lerance: 90.0Nt
0 1000 2000 3000 4000 5000 6000 7000 8000 9000 10000 11000 12000
Lag D istance
0
0.0002
0.0004
0.0006
0.0008
0.001
0.0012
0.0014
0.0016
Variogra
m
D irection: 150.0 Tolerance: 36.0Nt
V. Hutár
SSCRI strategy for creation of regional pedo -geochemical maps – geostatistics application
R2 = -0.266
0
10
20
30
40
50
60
0 20 40 60 80
prach (%)
íl (%
)
Analysing the multivariate objects regardinga.) linear methods (PCA) b.) unimodal methods (CA)Non-hierarical classification of multiobjects using fuzzy k-means alghoritm is used to continuously classify the real-world objects
R2 = 0.4009
-10
0
10
20
30
40
50
60
70
80
0 10 20 30 40 50 60
piesok (%)
íl (
%)
100
100 0
0
10 90
20 80
30 70
40 60
50 50
60 40
70 30
80 20
1090
0102030405060708090100
% piesok
% íl
lp lh
sp shssh
ss
spisi ssi
ts
ti
% prach
humus
prach
5b
5c
5d
5e
CaCO3
pH_H20
il
piesok
5a
-1
-0.5
0
0.5
1
1.5
-1.5 -1 -0.5 0 0.5 1 1.5 humus prach CaCO3
pH_H20
il
piesok
-2
-1.5
-1
-0.5
0
0.5
1
1.5
2
2.5
-2 -1 0 1 2 3 4
skupina 5a
skupina 5b
skupina 5c
skupina 5d
skupina 5e
0
500
1000
1500
2000
2500
3000
3500
1.1 1.3 1.5 1.7 1.9
Phi
-dJ/
dphi
triedy_2
triedy_3
triedy_4
triedy_5
V. Hutár
SSCRI strategy for creation of regional pedo -geochemical maps – multivariate analyses, fuzzy k-means
A (A1), B and C limit appointed in the Decree no. 531/1994-540 respecting the absolute value respecting the calculated value for non-standard soil linear gradient analysis were used to findings of statistical
significance of Cox and silt for heavy metals accumulation
V. Hutár
SSCRI strategy for creation of regional pedo -geochemical maps Study case 1: Chvojnicka hilly land
PCA_chv
As
Hg
Mo
Ba
Co
Cr
Cu
Ni
Pb
V
Zn
-0,4
-0,2
0
0,2
0,4
0,6
0,8
1
1,2
-1,2 -1 -0,8 -0,6 -0,4 -0,2 0 0,2
RDA_chv
As
Ba
Hg
Mo
CoCr
Cu
Ni
Pb
VZn
% Cox
% íl
-0,2
0
0,2
0,4
0,6
0,8
1
1,2
-0,2 0 0,2 0,4 0,6 0,8 1 1,2
H.metal Ba Co Cr Cu Mo Ni V Zn
A-limit 8 1 5 39 7 37 10 2
B-limit 2 2
Number of samples with exceeded concentration of risk elements
V. Hutár
A study case 2: Fuzzy-based digital soil mapping in Považsky Inovec Mt.
Point database:
Basic inputs:Numeric profile description• 90 soil profiles• 5 km2
J. Balkovič & G. Čemanová
Genetic horizons [cm]
Soil stratification
Colour:
Features of soil genesis:
others profile data:
Input matrix
Scheme of numericcoding of soil properties:
J.Balkovič & G. Čemanová
Fuzzy k-mean classification (centroids)
J. Balkovič & G. Čemanová
5A 5B 5C
5E5D
Interpolated rasters of membership values
J. Balkovič & G. Čemanová
Digital diffuse soil map obtained by„pixel mixture“ techniqueJuraj Balkovič & Gabriela Čemanová
A study case 3: Digital map of potential water storage in soils (Zahorska lowland)
Inputs (source KPP): Sand content [%] Silt content [%] Clay content [%]
J. Balkovič, T. Orfánus & R. Skalský
Rosetta model for estimation of van Genuchten eq. parameters and validation:
SAND, SILT, CLAY
ROSETTA
PF-curve:Θr, Θs, α, n
Regionally defined PTFKPP-DB
sandy silt
J. Balkovič, T. Orfánus & R. Skalský
ΘFWC – field water capacityΘWP - wilting pointh - soil depth [0.5 m]
W = 1000 (ΘFWC - ΘWP).h [mm]
Potential water storage in soils (up to 50 cm)
J. Balkovič, T. Orfánus & R. Skalský
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