Spatial analysis Measurements - Points: centroid, clustering, density Lines: Length, sinuosity Polygons: Length, perimeter, area, shape

The Centroid of point data The centroid is the spatial mean. The ‘average’ location of all points. The centroid can also be thought of as the balance point of a set of points.

S S xi yi x = y = n n Centroid The spatial mean is called the centroid. For a set of (x,y) coordinates, the mean center (x,y) is computed using: S xi i=1 i=n n x = S yi i=1 i=n n y =

Point Pattern Analysis There are many ways to quantify the dispersion of points in region. Clustered Regular Random

Applications of Point pattern analysis 1. whether the geographical incidence of disease shows any tendency towards clustering in geographical space? 2. Do cases of disease tend to occur in proximity to other cases? 3. Rural-urban migrants’ spatial clustering in the urban setting Solutions: Spatial Statistics such as Moran's I, Monte carlo simulation

Nang Rong Bangkok 22 source villages and 1085 rural-urban migrants

Results: spatial clustering of migrants at village level

Point density Point Density calculates the density of point features around each output raster cell.

Kernel Function Example The result of applying a 150km-wide kernel to points distributed over California A typical kernel function

(Gatrell et al., 1996)

Kernel Size The smoothness of the resulting field depends on the width of the kernel Wide kernels produce smooth surfaces Narrow kernels produce bumpy surfaces

Kernel Size Kernel width is 16 km instead of 150 km. This shows the S. California part of the database.

Kernel Density in Nicaraguan Health Facilities Objective: assess health accessibility Data Facilities' staffing information GPS receivers to collect latitude and longitude coordinates for every facility Population data from the Nicaragua Census Bureau (the location and population of all communities )

Local peaks for migrant’s locations (intensity surface)

Measuring Linear Objects 1D: Length Vector Distance measurements affected by elevation changes Easily calculated with computer Pythagorean theorem: the difference between x coordinates (longitude), squared + difference between the y coordinates (latitude), squared. Take the square root. The square root is the distance A B A B

Measuring Linear Objects Raster Add up # grid cells, multiply by resolution But what about diagonal or highly sinuous lines? Length possibly underrepresented Take home: Vector best for length calculations!

Measuring Shape: Sinuosity Relating objects to their environment Sinuosity Closer to 1, less sinuous Sometimes want to know about curvature http://forest.mtu.edu/staff/mdhyslop/gis/sinuosity.html

Measuring Polygons 2D: Length, width More dimensionality, more measurements! Orientation, elongation, perimeter, area, shape

Measuring Polygons: Length Vector Calculate lengths of all opposing polygon vertices Compare to see which is longest Ratio of major to minor axes  elongation Angular direction of polygon calculated using spherical geometry Raster  can’t ascertain long axis easily Raster Difficult to determine orientation because grid cell locations are relative

Measuring Polygons: Perimeter Vector Calculate & sum the distance of each line segment making up polygon Raster Identify perimeter cells, sum & multiply by cell resolution Less accurate for complex polygons Take home: Vector best for perimeter calculations!

Measuring Polygons: Areas Vector Simple polygons (e.g., rectangle, triangle, circle)easy calculation Complex polygonsdivide polygon into shapes easily measured with available formulas Often calculated during the digitizing process Perimeter/area ratio: Measure of polygon complexity Perimeter/area ratio smallest for most compact shapes (e.g. circle)

Measuring Polygons: Areas Raster Regions Assign a unique value to each region (recode/reclassify), then count the number of cells for each region & multiply by area Tabulate data to find # grid cells for each attribute Provides measure of proportion of different attribute types

Measuring polygon: Shape Major axis Along longest part of polygon Must divide polygon in two equal parts Minor axis Along shortest part of polygon Must divide the polygon in two equal parts Major axis / Minor axis ratio Values > 1 denote elongated polygon Value = 1 denotes uniform polygon Major axis Minor axis 1.5 2.5 R = 1 3.5 R = 2.33 Graphic: Dr. Jean-Paul Rodrigue, Dept. of Economics & Geography, Hofstra University

Measuring polygon: Shape Area = 25 sqr miles Perimeter = 7 miles CI = 7 / 25 = 0.28 Perimeter = 15 miles CI = 15 / 25 = 0.60 Shape Perimeter to Area Ratio perimeter/area Expression of the geographical complexity of a polygon High ratio  complex Low ratio  simple Graphic: Dr. Jean-Paul Rodrigue, Dept. of Economics & Geography, Hofstra University

Final Project

Introduction Why you wanted to do the project What’s the need, what purpose might the data serve? What features are you planning to map?

Materials & Methods Datasets Source: Where did you obtain it from Scale Projection Use the metadata!

Materials & Methods Notes on Metadata Check the Data Quality Section to determine the data set's fitness-for-use as far as scale and resolution Attribute Accuracy & Horizontal Positional Accuracy can describe the scale/resolution of the data set (either directly or indirectly). Check the Lineage subsection For each contributing source to the data set pertinent information must be included such as the source's title, media (paper, digital), and source scale. Check the Process Steps in the Data Quality section. In well-documented metadata, the Process Steps will describe not only how the data set was created (e.g. from paper maps), but also provide information or links to other documents containing information on how the contributing sources were created, as well.

Materials & Methods Describe your analyses Did you have to query data out of a larger dataset? How did you use that query to generate a separate shapefile for your analysis?

Results & Discussion Present whatever maps and tables you create Discuss their meaning

Conclusions What did you learn from your analysis?