The document discusses various methods of georeferencing, which is assigning accurate locations to spatial information. The most comprehensive method is using latitude and longitude, which defines locations based on angles from the equator and Greenwich Meridian. However, the Earth's curved surface poses issues for technologies that work with flat maps and data. Therefore, map projections are used to translate locations on the spherical Earth onto flat planes or surfaces, though all projections introduce some distortion. Common projections include cylindrical, conic, and the Universal Transverse Mercator system.
2. Georeferencing
‘To georeference’ is the act of assigning
accurate locations to spatial information
Is essential in GIS, since all information must be
linked to the Earth’s surface
The method of georeferencing must be:
Unique, linking information to exactly one
location
Shared, so different users understand the
meaning of a georeference
Persistent through time, so today’s
georeferences are still meaningful tomorrow
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3. Uniqueness
A georeference may be unique only within a
defined domain, not globally
There are many instances of Springfield in the
U.S., but only one in any state
The meaning of a reference to London may
depend on context, since there are smaller
Londons in several parts of the world
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4. Georeferences as Measurements
Some georeferences are metric
They define location using measures of distance
from fixed places
E.g. distance from the Equator or from the Greenwich
Meridian
Others are based on ordering
E.g. street addresses in most parts of the world
order houses along streets
Others are only nominal
Placenames do not involve ordering or
measuring
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5. Metric references
Essential to the making of maps and the display
of mapped information in GIS
Provide the potential for infinitely fine spatial
resolution (provided we have sufficiently
accurate measuring devices)
From measurements of two or three locations it is
possible to compute distances
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6. Georeferencing systems
Place names
Postal addresses and postal codes
Linear referencing systems
Cadastres
Latitude and longitude
Projections and coordinate systems
The Global Positioning System
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7. Place Names
The earliest form of georeferencing
And the most commonly used in everyday
activities
Many names of geographic features are
universally recognized
Others may be understood only by locals
Names work at many different scales
From continents to small villages and
neighborhoods
Names may pass out of use in time
Where was Naples, CA?
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8. Postal Addresses and Postcodes
Every dwelling and office is a potential
destination for mail
Dwellings and offices are arrayed along streets,
and numbered accordingly
Streets have names that are unique within local
areas
Local areas have names that are unique within
larger regions
If these assumptions are true, then a postal
address is a useful georeference
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9. Where do postal addresses fail as
georeferences?
In rural areas
Urban-style addresses have been extended
recently to many rural areas
For natural features
Lakes, mountains, and rivers cannot be
located using postal addresses
When numbering on streets is not
sequential
E.g. in Japan
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10. Postcodes as Georeferences
Defined in many countries
E.g. ZIP codes in the US
Hierarchically structured
The first few characters define large areas
Subsequent characters designate smaller
areas
Coarser spatial resolution than postal address
Useful for mapping
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11. Postcodes in Canada
Forward Sortation Areas (FSA)
The first three characters of the six-character postcode form the FSA
Central part of the Toronto metropolitan region
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12. ZIP code boundaries are a convenient way to summarize data in the US.
The dots on the left have been summarized as a density per square mile
on the right
ZIP Code Boundaries in the US
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13. Linear Referencing
A system for georeferencing positions on a road, street,
rail, or river network
Is closely related to street
address but uses an explicit
measurement of distance
rather then the much less
reliable surrogate of street
address number
Combines the name of the
link with an offset distance
along the link from a fixed point,
most often an intersection
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14. Problem Cases
Transportation authorities - To keep track of pavement
quality, signs, traffic conditions on roads
Police ⚑ To record the locations of accidents
Users of Linear Referencing
Locations in rural areas may be a long way from an
intersection or other suitable zero point
Pairs of streets may intersect more than once
Measurements of distance along streets may be
inaccurate, depending on the measuring device, e.g. a
car odometer
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15. Cadastral Maps
Defined as the map of land ownership in an area,
maintained for the purposes of taxing land, or of
creating a public record of ownership
Parcels of land
Are uniquely identified by number or code (PIN)
Are reasonably persistent through time, but
Very few people know the identification code of their
home parcel, so the use of the cadaster as
georeferencing is thus limited to local officials, with one
major exception
The Public Land Survey System (PLSS) in the US and
similar systems in other countries provide a method of
georeferencing linked to the cadastre (Township,
Range, Section)
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17. The Earth’s shape
The Earth is slightly flattened, such that the
distance between the Poles is about 1 part in 300
less than the diameter at the Equator
The Earth more accurately modeled as an
spheroid (ellipsoid) than a sphere
An spheroid is formed
by rotating an ellipse
about its shorter axis
Ellipsoid allows variable
radii
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18. The History of Ellipsoids
Because the Earth is not shaped precisely as an
ellipsoid, initially each country felt free to adopt
its own as the most accurate approximation to
its own part of the Earth
Without a single standard the maps produced
by different countries using different ellipsoids
could never be made to fit together
Today an international standard has been
adopted known as WGS 84 (the World Geodesic
System of 1984)
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20. Latitude and Longitude
Define the location on Earth’s surface in terms of angles
with respect to well-defined references
The Royal Observatory at Greenwich
The axis of rotation
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21. Latitude and Longitude
Define the location on Earth’s surface in terms of angles
with respect to well-defined references
The Royal Observatory at Greenwich
The axis of rotation
They constitute the most comprehensive system of
georeferencing, and support a range of forms of analysis,
including the calculation of distance between points on
the curved surcace of the Earth
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22. Latitude and Longitude
Define the location on Earth’s surface in terms of angles
with respect to well-defined references
The Royal Observatory at Greenwich
The axis of rotation
They constitute the most comprehensive system of
georeferencing, and support a range of forms of analysis,
including the calculation of distance between points on
the curved surcace of the Earth
Adopted as world standard in 1884
But many technologies for working with
geographic data are inherently flat
(Cartesian)!
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23. Latitude and Longitude
The most comprehensive and powerful method
of georeferencing
Provides potential for very fine spatial resolution
Allows distance to be computed between pairs of
locations
Supports other forms of spatial analysis
Uses a well-defined and fixed reference frame
Based on the Earth’s rotation and center of mass, and
the Greenwich Meridian
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24. Latitude and Longitude
Latitude: is the angular distance, in degrees, minutes, and seconds of a
point north or south of the Equator. Lines of latitude are often referred
to as parallels.
Longitude: is the angular distance, in degrees, minutes, and seconds, of
a point east or west of the Prime (Greenwich) Meridian. Lines of
longitude are often referred to as meridians.
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26. Projections and Coordinates
There are many reasons for wanting to
project the Earth’s surface onto a plane,
rather than deal with the curved surface
The paper used to output GIS maps is flat
Flat maps are scanned and digitized to
create GIS databases
Square and rectangular rasters are flat
The Earth has to be projected to see all of it at
once
It’s much easier to measure distance on a
plane
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27. Distortions
Any projection must distort the Earth in some way
Two types of projections are important in GIS
Conformal property: Shapes of small features are
preserved, or in other words, scales of the projections in x
and y directions are always equal
Equal area property: Shapes are distorted, but areas
measured on the map are always in the same proportion to
areas on the Earth’s surface
Both types of projections will generally distort
distances
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28. Map projections
Azimuthal or planar
- analogous to
touching the Earth with
a sheet of flat paper
Cylindrical - analogous to wrapping a cylinder of paper around the
Earth, projecting the Earth’s features onto it, and then unwrapping the
cylinder
Conical – analogous to wrapping a sheet of paper around the
Earth in a cone
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29. Cylindrical Projections
The cylinder is wrapped
around the Equator
The projection is conformal
• At any point scale is the
same in both directions
• Shape of small features is
preserved
• Features in high latitudes
are significantly enlarged
The Mercator projection is the best-known cylindrical
projection
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30. Conic Projections
Standard Parallels occur
where the cone intersects
the Earth
The Lambert Conformal
Conic projection is
commonly used to map
North America
On this projection lines of
latitude appear as arcs of
circles, and lines of
longitude are straight lines
radiating from the North
Conceptualized as the result of wrapping a cone of
paper around the Earth
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31. The “Unprojected” Projection
A type of cylindrical
projection
Is neither conformal
nor equal area
As latitude increases,
lines of longitude are
much closer
together on the
Earth, but are the
same distance apart
on the projection
Assign latitude to the y axis and longitude to the x axis
Also known as the Plate Carrée or Cylindrical
Equidistant Projection
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32. The Universal Transverse Mercator
(UTM) Projection
A type of cylindrical projection
Implemented as an
internationally standard
coordinate system
Initially devised as a military standard
Uses a system of 60 zones
Maximum distortion is 0.04%
Transverse Mercator because the
cylinder is wrapped around the
Poles, not the Equator
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33. Zones are each six degrees of longitude, numbered as shown at
the top, from W to E
The Universal Transverse Mercator
(UTM) Projection
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34. Implications of the Zone System
UTM coordinates are in meters, making it easy to
make accurate calculations of short distances
between points
Because each zone defines a different projection (60
different projections!) maps will not fit together across
a zone boundary
Zones become a problem at high latitudes
(especially for cities that cross boundaries!)
Jurisdictions that span two zones must make special
arrangements
Use only one of the two projections, and accept the greater-
than-normal distortions in the other zone
Use a third projection spanning the jurisdiction
E.g. CA spans UTM zones 10 and 11
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35. Local Systems:
State Plane Coordinates
All US states have adopted
their own specialized
coordinate systems
Some states use multiple zones
Several different types of
projections are used by the
system
Provides less distortion than
UTM
Used for applications
needing very high
accuracy, such as surveying
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36. Local Systems: The National Grid - UK
It is administered by the
Ordnance Survey of Great
Britain
provides a unique georeference
for every point in England,
Scotland, and Wales
The first designating letter
defines a 500 km square, and
the second defines a 100 km
square
Within each square, two
measurements, called easting
and northing, define a location
with respect to the lower left
corner of the square
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37. Converting Georeferences
GIS applications often require conversion of
projections and ellipsoids
These are standard functions in popular GIS
packages
Street addresses must be converted to
coordinates for mapping and analysis
Using geocoding functions
Placenames can be converted to
coordinates using gazetteers
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38. The Global Positioning System
(GPS)
Allows direct, accurate measurement of
latitude and longitude
Accuracy of 10m from a simple, cheap
unit
Differential GPS capable of sub-meter
accuracy
Sub-centimeter accuracy if observations are
averaged over long periods
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39. What is the Global Positioning
System?
Consists of a system of 24 satellites, each orbiting the
Earth every 12 hours on distinct orbits at a height of 20 200km
and transmitting radio pulses at very precisely timed intervals
Position in a receiver is determined by precise
calculations from:
the satellite signals,
the known positions of the satellites
the velocity of light
Position in the three dimesions (latitude, longitude
and elevation) requires that at least 4 satellites are above
the horizon
Accuracy depends on the number of satellites and their
positions
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40. How does GPS work?
Earth is continuously
circled by 24 GPS
satellites
A GPS receiver listens for signals
which give the satellites’ location
and the exact time of sending.
Trilateration then gives them
your latitude, longitude
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