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Table 2:
Geodetic Controls Required for Regional GIS
Continent Areal Density of Total # of # of controls | New controls
Coverage control pts. Controls available* needed
square km | per 25 needed 2-D 3-D
square km
Africa 22,612,063 1 904,482 7,800 896,682
Asia 17,601,806 1 704,072 596,000 108,072
Australia 7,715,294 1 308,611 44,300 264,311
Europe & 25,179,431 1 1,007,177 2,385,000** 696,088 **
Former
USSR
North 1 861,436 490,000 371,436
America 21,535,902
South 5,917,631 1 236,705 74,800 161,905
America
Total 100562127 4,022,483 3,597,900 2,498,494
Sq. km
* Source: World Cartography, UN Publication.
** Former USSR has only 200,000 control points available and needs an extra 696,088 controls.
Europe has more controls than required.
types of thematic applications.
The information derived from data can be of three types:
€ spatial : locational data
® attribute : non locational data
® temporal : informational changes (i.e. changes in data
due to time changes).
Data collection or digitization can be done in either raster or
vector mode. Most remote sensing data are acquired in
raster mode and are stored in this format. It is less expensive
to process and store data in compressed raster format unless
data are specifically needed in vector format for a particular
application.
The conversion of map data can be done using two main
methods:
e manual digitization - the map is manually traced with
a digitizing cursor. This approach is very time
consuming and labor intensive but it works for almost
all maps.
e electronic scanning - the map or drawing is scanned
electronically and stored as a raster image with no
intelligence. Images of scanned maps are then
generally converted to a vector map and information
from the data base is tied to them, as for example,
soil type or land value. Scanning can be faster than
manual digitization, but works best for clean,
uncluttered maps which do not contain overwritten
data.
After scanning a document one of three main
approaches to raster-vector conversion can be
followed: heads-up digitizing, semi-automatic
vectorization and automatic vectorization. In heads-up
digitizing an operator scans in a map and brings it up
on the screen. S-he then traces the lines off the
screen by using a mouse to follow them. This works
well for a multitude of map types and complexities.
In semi-automatic mode, the computer attempts to
follow lines automatically but stops and waits for
operator intervention when it encounters a problem
area. The operator then examines the problem, makes
a decision and the computer continues. This works
well for relatively clean maps without too much
overwritten text and lines. In fully automatic
vectorization the computer traces all the lines by
itself, often in overnight batch mode. Editing is then
done to clear up any remaining problem areas. This
works only for very clean maps, such as contour
maps, or large scale cadastral plans, but it is rarely
applicable to most local government maps.
The problems of digital data collection in a GIS system are
mainly:
€ The quality of digital data for topographical mapping
€ Interchange of digital information between different
computer aided mapping system (CAMS).
The Quality of Digital Data for Topographical Mapping
Conventional topographical maps are produced within the
accuracy required for a specific scale. Digital map data are
collected for a specific scale, but, due to the fact that these
data are expressed in ground coordinate values without any
permanent accuracy statement attached to them, there is no
way to recognize this fact from the digital map.
