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Ripley K

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Ripley K Fisher et al. Density Mapping Kernel, Radius = 20 CellSize = 2x2m Mean = 0.0088 S.D. = 0.0038 Simple, Radius = 20 CellSize = 2x2m Mean = 0.0083 S.D. = 0 ... – PowerPoint PPT presentation

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Title: Ripley K


1
Ripley K Fisher et al.
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Ripley K - Issues
  • Assumes the process is homogeneous (stationary
    random field).
  • Ripley K was is very sensitive to study area
    size.
  • Riley K is influenced by study area shape, the
    expected L(d) assumes a simple geometry.
  • Ripley K has strong basis near the edge/boundary.
    You should use a boundary correction method, and
    if your study area is not a simple shape you
    should use study are polygon.
  • Weighting points

4
Boundary Correction Methods
  • Boundary Correction Methods
  • RIPLEY EDGE CORRECTION FORMULA
  • SIMULATE OUTER BOUNDARY VALUES
  • REDUCE ANALYSIS AREA
  • Study Area Method
  • MINIMUM ENCLOSING RECTANGLE
  • USER PROVIDED STUDY AREA

5
Pottery Survey PointsRandom
6
NND Test
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Minimum Enclosing RectangleRipley Correction
Formula
8
Used Survey Shapefile
9
Reduce Analysis AreaUsed Shapefile
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Weighted Points
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WeightedReduce Analysis Area - Shapefile
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High-Low Clustering (Getis-Ord)
13
Point Transformations
  • In many situations we collect point
    measurements of an entity we wish to study, but
    prefer/need to have an area (i.e. polygon) or
    field (e.g. raster) representation to relate the
    measurements to other information or have
    information at locations not measured to make
    decisions.

14
Four Basic Types of Methods
  • Point to Area Transformations (Deterministic)
  • Delineate areas and assign the point
    measurement(s) to the area. An Area is related to
    one or more points
  • Points are usually weighted.
  • Density Mapping point to field (Deterministic)
  • A field element (e.g. a raster cell) is assigned
    a value based on sampling the surrounding
    neighborhood and computing the density of
    observations around the element. Density is the
    quantity per area.
  • Points can weighted or un-weighted.

15
Four Basic Types of Methods
  • Interpolation Methods point to field
    (Deterministic)
  • A field element is assigned a value based on a
    mathematical transformation that predicts what
    the value should be at the field element location
    based on known point observations.
  • Points must be weighted.
  • Local Interpolation Methods
  • Uses a sub-sample of point observations to
    develop the mathematical equation and make the
    prediction.
  • Global Interpolation Methods
  • Uses all the point observations to develop the
    mathematical equation. Regression and trend
    analysis are examples.
  • Stochastic Modeling field generation
    (Stochastic)
  • Use point observations to understand the
    statistical properties of an entity and to
    develop a model that generates a field of values
    that retain the statistical properties of the
    entity.

16
Point to Area Transformations
Data
Rasterization
Voronmoi Polygons
Zone of Influence
Irregular Polygons
Zone/Vornomoi
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Point to Area Transformation Methods
  • Voronmoi (Thiessen) Polygons
  • The most commonly used.
  • Based on the concept of Nearest Neighbor.
  • Creates (usually) unequal size areas around each
    point. The areas are assigned the value of the
    origin point.
  • Depending on the distribution of points the range
    in sizes can be relatively large, but the entire
    analysis area is covered.

18
Thiessen Polygons
  • The Thiessen polygons are constructed as follows
    All points are triangulated into a triangulated
    irregular network (TIN) that meets the Delaunay
    criterion. The perpendicular bisectors for each
    triangle edge are generated, forming the edges of
    the Thiessen polygons. The location at which the
    bisectors intersect determine the locations of
    the Thiessen polygon vertices.

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Point to Area Transformation Methods
  • Irregular Shaped Polygons
  • Based on modeling or analysis, sometimes using
    additional data.
  • Watershed Delineation
  • Need outlet point and surface representation
    (e.g. DEM).
  • Model flow across surface to outlet point.
  • All areas that flow to outlet point are in
    watershed.
  • Minimum Convex Polygons (MCP)
  • Minimum area around all selected points.
  • Can create MCP that contain a percentage of the
    points.

21
Minimum Convex Polygon
Hawth's Analysis Tools is an extension for ESRI's
ArcGIS http//spatialecology.com
22
Density Mapping
  • Also referred to as Intensity.
  • Point to field ? raster data structure
  • Calculates the density of points in a
    neighborhood around each output grid cell.
    Neighbor is usually larger then the cell.
  • Points can be weighted (using a numeric
    attribute) or un-weighted (all points 1).
  • Units of density are quantity per unit area.
  • Good for when the density of points is small
    relative to the desired cell size.
  • Two methods Simple and Kernel.

23
Simple Density Mapping
  • The density is calculated using the number of
    points that fall within the neighborhood of each
    output grid cell, divided by the area of the
    neighborhood. For a circle neighborhood the
    equation is
  • n
  • D(s) ? (si / ? ?2) hi lt ?
  • i1
  • where
  • D(s) density (intensity) at point s (grid
    cell center)
  • si observation point i (equals 1 or a
    quantity)
  • ? radius of circle neighborhood
  • hi Euclidean distance between point and cell
    center.
  • n number of observations points within the
  • neighborhood

24
Simple Density Mapping
  • Rough surfaces, all points have the same weight
    within search radius regardless of distance.
  • No assumptions regarding the kernal method type.
  • Called Point Density in ArcMap.
  • Can use different neighborhood shapes
  • Circle (most common)
  • Rectangle
  • Wedge
  • Annulus

25
Kernel Density Mapping
  • A kernel function is used to fit a smoothly
    tapered surface to each point, and the density is
    calculated from these surfaces where they overlap
    the center of the output grid cell. This gives a
    smoother output grid, while maintaining the same
    general values for density. A circular
    neighborhood is always used with the KERNEL
    option.

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Kernel Density Function
  • There are several commonly used kernel functions
  • Gaussian
  • Quadratic (in ESRI)
  • Uniform
  • Triangle

28
Kernel Density Mapping
  • ArcGIS uses a quadratic kernel function where
  • n
  • D (s) ? si (3/??2) 1 (hi2/?2)2 hi lt ?
  • i1
  • D(s) 0 otherwise
  • where ? radius of circle neighborhood
  • hi distance between the point s and the
    observation point si
  • n number of observation points
  • D(s) density (intensity) at point s (grid
    cell center)
  • si observation point i (equals 1 or a
    quantity)

29
Kernel Weights Quadratic Function
30
Kernel Density Mapping
  • Assume ? 10m si 1 with 5 points
  • If hi 0 D(si) si (3/??2) 1.0000 0.0095
  • If hi 2 D(si) si (3/??2) 0.9216 0.0088
  • If hi 5 D(si) si (3/??2) 0.5625 0.0054
  • If hi 7 D(si) si (3/??2) 0.2601 0.0025
  • If hi 9 D(si) si (3/??2) 0.0361 0.0003
  • D(S) 0.0265 units per square meter
  • If all points hi 9 D(S) 0.0015 units per sq.
    m.
  • D(S)simple 5 / ??2 5 /314.159 m2
  • 0.0159 units per sq. m.

31
Kernel Density Mapping
  • Factors that influence surface characteristics
  • Method Simple would have a rougher looking
    surface, but typically less variance.
  • Neighborhood Size the greater the number of
    points used to compute density the less variance
    in the surface.
  • Cell Size the larger the cell the rougher,
    greater potential relative change per cell.
  • You can made a surface to smooth and loss the
    natural variance of the surface, areas with high
    and low density.
  • You should experiment, what creates the best
    surface for you. Some use the search distance
    where variance starts to become stable.

32
Density Mapping
Kernel, Radius 10 CellSize 5x5m Mean
0.0094 S.D. 0.0073
Kernel, Radius 20 CellSize 5x5m Mean
0.0088 S.D. 0.0038
33
Density Mapping
Kernel, Radius 20 CellSize 2x2m Mean
0.0088 S.D. 0.0038
Kernel, Radius 20 CellSize 5x5m Mean
0.0088 S.D. 0.0038
34
Density Mapping
Kernel, Radius 20 CellSize 2x2m Mean
0.0088 S.D. 0.0038
Simple, Radius 20 CellSize 2x2m Mean
0.0083 S.D. 0.0031
35
Density Mapping
Patchy
Trend
36
Density surface using bivariate normal density
kernel
This figure is a display of the location points
(shown in yellow) within the selected 50, 75, and
90 probability polygons.
37
  • Here is a kernel density map of the cholera
    deaths (kernel size 1.0
  • cellsize 0.0025) with density contours
    overlaid.   The density of
  • cholera deaths derived from this map is 36.8 at
    the Broad Street pump,
  • versus 2.4 at Carnaby Street, 1.9 at Rupert
    Street, 0.8 at Marlborough
  • Mews, 0.2 at Bridle Street, 0.1 at Newman Street
    and zero at all other
  • pumps.  A simple density analysis with no
    smoothing yielded a similar
  • map with discrete edge segments.

38
Interpolation
  • Global Interpolation Methods
  • Trend Analysis (Global Polynomials)
  • Regression (spatial and non-spatial)

39
Interpolation
  • Trend Analysis
  • Surface is approximated by a polynomial
  • Value (z) at any point (x,y) on the surface is
    given by an equation in powers of x and y.
  • Linear equation (1 degree) describes a tilted
    plane surface
  • z a bx cy
  • Quadratic equation (2 degree describes a simple
    hill or valley
  • z a bx cy dx2 exy fy2

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Interpolation
  • Trend Analysis
  • In general, any cross-section of a surface of
    degree n can have at most n-1 alternating maxima
    and minima.
  • Assumes the general trend of the surface is
    independent of random errors found at each sample
    point.
  • Good at addressing non-stationary cases.
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