GEOTECHNICAL CONDITIONS AND SOIL IMPROVEMENT TECHNIQUES APPLIED IN
Geographic Information Technology Applied to Soil … Information Technology Applied to Soil Mapping...
Transcript of Geographic Information Technology Applied to Soil … Information Technology Applied to Soil Mapping...
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Geographic Information Technology Applied to Soil Mapping
Sabine GrunwaldAssistant Professor GIS & Land ResourcesDistance Education Coordinator
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Conceptual Models of Real World Phenomena
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Conceptual Models of Space
1. Entity (object) model = vector model
2. Continuous fields model = raster model
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1. Geographical Data Model: Object View
basic geographical data primitives (geographical entities):
Point
Line
Area Pixel
Polygon
(Goodchild, 1992)
Voxel
Polyhedrons
Volumes
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Vector Data Model
x1, y1
x2, y2
x3, y3
x4, y4
x5, y5
x6, y6
x7, y7
x8, y8x1, y1
x2, y2
x3, y3
x4, y4
x5, y5
Topology
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Land cover: corn
Conceptual Models of Real World Phenomena
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Tree is represented bypolygon structure in a visual scene with animage stamped on it
Tree is represented aspoint feature with specificattributes (e.g. height, species, age, etc.)
Conceptual Models of Real World Phenomena
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LakeKendrickBonneauMillhopperNorfolkCandlerAredondoApopkaCadillacJonesvilleUrbanWater
Soil map units
N0 3,500 7,000 m
Entity-Based Soil MapAlachuaCounty, FL
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2. Geographical Data Model: Continuous Fields
Attribute valuese.g.
1 23
or:slssl
Raster
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Raster-Based DEM North Florida
111.0
-2.72
Elevations (m)
N30-m pixel resolution
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01 km
1 km
Topographic Models
320.0 - 321.5321.5 - 323.0323.0 - 324.5324.5 - 326.0326.0 - 327.5327.5 - 329.0
> 329.0
Elevation (m)
N(S. Grunwald, 2001)
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Raster-Based Land Cover Model
South Florida, Everglades(Sofia, 2002)
30 m
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Geographic Soil Model
SSURGO Suwannee County, FL
Entity model:Crisp soil classes
Continuous field model(raster)
N
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Geo-Data Modeling
distance
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Statistics vs. Geostatistics
Observations are independentor:no correlation between observations
Autocorrelationmodeled as a functionof distance
distance
corr
elat
ion
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Z x m x x( ) ( ) '( ) ' '? ? ?? ?
Z: value of a random variablex: locationm(x): deterministic function describing the structural
component of Z at x (“deterministic trend”)
?’(x): stochastic, locally varying but spatiallydependent residual from m(x) -the regionalized variable (“autocorrelated errors”)
?’’: residual; a spatially independent noise termhaving zero mean and variance
Geostatistics
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Visualization of Regionalized Variable Theory
(Burrough and McDonnell. 1998. Principles of GIS, Oxford University Press; page 134)
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Experimental Semivariogram
?( ) { ( ) ( )}? hn
z x z x hi ii
n
? ? ???1
22
1
zi: value of attribute zx: locationn: number of pairs of sample points of observations
distance (h)sem
ivar
ianc
e.
. .. .
.?
nugget
sill
range
d1 d2 d3
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Multi-Dimensional Variogram
0 - 900
90 - 1800
180 - 2700
270 - 3600
z
(S. Grunwald, 2001)
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WCA1 (n: 251)
WCA2(n: 280)
WCA3(n: 350)
Holeyland(n: 204)
Water Conservation Areas
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0-10 cm depth
range
sill
nugget
10-20 cm depth
range
sill
nugget
20-30 cm depth
range
sillnugget
30-40 cm depth
range
sillnugget
Total Phosphorus
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Predictions (Ordinary Kriging)WCA2 / Total Phosphorus (TP) / Depth 0–10 cm
217.0 – 349.1349.1 – 424.2424.2 – 466.9466.9 – 491.2491.2 – 533.9533.9 – 609.0609.0 – 741.1741.1 - 973.5973.5 – 1,381.9
1,381.9 – 2,100.3
TP (mg/kg)
N0 10,000 20,000 m
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Prediction Error (Ordinary Kriging) WCA2 / Total Phosphorus (TP) / Depth 0–10 cm
0.27 – 0.330.33 – 0.370.37 – 0.390.39 – 0.400.40 – 0.420.42 – 0.460.46 – 0.520.52 – 0.620.62 – 0.770.77 – 1.0
Prediction standard error
N0 10,000 20,000 m
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Predictions (Ordinary Kriging)WCA2 / Total Phosphorus (TP) / Depth 30–40 cm
0.0 – 68.368.3 – 105.9
105.9 – 126.7126.7 – 138.2138.2 – 159.0159.0 – 196.7196.7 – 264.9 264.9 – 388.6388.6 – 612.6612.6 – 1018.5
TP (mg/kg)
N0 10,000 20,000 m
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Prediction Error (Ordinary Kriging)WCA2 / Total Phosphorus (TP) / Depth 30–40 cm
16.4 – 44.044.0 – 64.064.0 – 78.478.4 – 88.888.8 – 96.396.3 – 101.7
101.7 – 109.2109.2 – 119.6119.6 – 133.9133.9 – 153.9
Prediction standard error
N0 10,000 20,000 m
Link to 3D models
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Conclusion
Geostatistical methods facilitate to describe:
• Changes of physical, chemical, and biologicalsoil properties continuously across landscapes
• Output GIS format: raster or voxel• Variograms describe the spatial variability• Variograms can be used to guide future sampling (targeted, efficient sampling)
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x
y
z
3D Soil-Landscapes
(S. Grunwald, 2001)
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3D Soil-Landscape Model Types
Characteristics: • Continuous • 3-D
Stratigraphic models
Block models
Link to 3D models
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Alachua County, Florida
0 500 1000 mN
TavaresMillhopperMonteochaPomonaLochloosaPlummerWater
Soil Series Elevation (m)707580859095100105
Soil and Topographic Data
(Soil Survey GeographicDatabase, NRCS)
(5-foot contour lines1:24,000, USGS & WMD, 1997)
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Soil ProfilesEntisol
Tavares
A
C1
C2
C3
C4
0
25
50
75
100
125
150
175
200
225
250
cm
A
E1
E2
E3
E4
Bt
Btg
BCg
Millhopper
AE1
E2
Bt1Bt2
Btg
BCg
Cg
Lochloosa
A
Eg1
Eg2
Eg3
PlummerUltisol
AE1
E2
Bh1Bh2BE
E’
Btg1
Btg2
Pomona
A
E
Bh
BC
E’
Btg1
Btg2
Cg
MonteochaSpodosol
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CCgBCgBtgE’BEBCBhBtEgEA
Stratigraphic Model
Elevations range: 70 – 105 mVertical exaggeration factor: 5 (S. Grunwald, 2001)
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3D Scientific VisualizationWCA2; 0-10cm depthTP is represented as heightParameters are represented by color
Ca
Ca
200,000
150,000
100,000
50,000
18,850
Mg
Mg8,000
6,000
4,000
2,000
Fe
Fe1,750
1,500
1,250
1,000
750
500
225Al
Al (mg kg-1)1,500
1,250
1,000
750
500
250
(S. Grunwald, 2001)
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3D Scientific VisualizationWCA2; 0-10cm depthTP is represented as heightParameters are represented by color
Sodium bicarbonate extractable P(“bioavailable P”)
NAHCO3 25
20
15
10
5
0
Hydrochloricacid extractable P(“stable P”)
HCLP1 (mg kg-1)1,250
1,000
750
500
250
0 (S. Grunwald, 2001)
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Conclusions
3D GIT, geostatistics, and SciVisimproves our understanding of the spatial distribution and variabilityof soil-landscape properties
Home page: http://grunwald.ifas.ufl.edu