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UNITED NATIONS SECRETARIAT
ESA/STAT/AC.98/14
Department of
Economic and Social Affairs 03 September 2004
Statistics Division
English
only
United Nations Expert Group Meeting to Review Critical
Issues Relevant to the Planning of the 2010 Round of Population and Housing
Censuses
15-17 September 2004
New
York
Integration of
GPS, Digital Imagery and GIS with Census Mapping*
By United Nations
Statistics Division
DESA
* This document is being reproduced without
formal editing.
https://unstats.un.org/unsd/demographic/meetings/egm/CensusEGM04/docs/AC98_14.pdf
2
INRODUCTION
1.
The recent technological developments, including new high-resolution sensors,
global
positioning systems (GPS), geographical information systems (GIS),
Internet and World
Wide Web services, are revolutionizing cartography,
surveying and mapping in
fundamental ways: geographic data is easily
collected and combined with a variety of other
data in order to create
relevant information for spatial analysis and decision making.
Geographic
information, in its digital form, is indeed exchanged more rapidly,
duplicated
without alteration, and easily disseminated to
end-users.
2. For
the past decade, the United Nations Statistics Division (UNSD) has
been
promoting the development of geographical information systems for
population and
demographic statistics in developing countries through
technical cooperation projects
supported by the United Nations Fund for
Population Activities (UNFPA), training
workshops, and technical
publications. However, the statistical community in developing
countries has
been slow to adopt the use of GIS, partially due to the monetary
constraint
posed by commercial software and the availability of computers,
base maps, satellite
imagery, work load, etc.
3.
This paper outlines some developments in satellite imagery, GPS and GIS
with
reference to census mapping activities, and provides some insight on the
similarities
between a geographic information process and a census mapping
process, therefore, it urges
for the integration of these geospatial
technologies within the census mapping process. It
suggests some future
actions to undertake in order to help kick-start the development of
this
field in developing countries.
I.
GIS, GPS AND AERIAL AND SATELLITE IMAGERY RECENT
TECHNICAL CAPABILITIES
4. The
census symposium, held in New York in 2001, provided a comprehensive
review
of the significant capabilities of GPS, Satellite imagery, GIS and
handheld computers, and
their relevance to census mapping operations (Dekker,
2001 and Tripathi, 2001s). Hence,
our presentation will focus on the recent
developments regarding these geospatial
technologies, and specifically with
regard to their better integration.
5.
GPS, remote sensing (including aerial photography) and GIS are technologies that
are
being increasingly used in the field of data collection, including census
mapping operations.
Until recently, aerial photography did play a major role
in geographic data acquisition in
urban areas, and the use of satellite
imagery, due to its low resolution, was limited to the
study of some
phenomena like floods and urban pollution. However, recent satellite
imagery
is extending its use to urban areas with the increase of its resolution to
one-meter
(i.e. IKONOS satellite), its high positional accuracy, the revisit
frequency of only three
days, and its GIS-readiness, despite their relative
expensive cost (Montoya, 2002).
6. GPS
receivers have become popular and widespread, offering a greater accuracy at
a
reduced cost (a variety of units less than $500). Indeed, some
cost-effective GPS can handle
real-time differential correction capable of
sharpening accuracy to five meters or better.
Furthermore, GPS coordinates
(waypoints) can be displayed real-time in a GIS software3
(i.e. ArcPad). GIS
are becoming more powerful and friendly to use, and GPS more accurate
and
cost-effective. Both are more integrated, streamlining the acquisition and
processing of
coordinate data. The future of satellite positioning system
looks promising, particularly
with the new system under construction,
Galileo, the European system dedicated to civil
activities.
7.
Beside GIS desktop and Internet GIS, Mobile GIS is becoming a reality. GIS
software
has been tailored to the needs of the field operations, allowing GIS
to move from the office
to the field. Indeed, improvements in handheld
computers and other portable devices, as
well as greater accuracy and the
reduced cost of GPS units, have made significant
contributions to the
development of mobile GIS (ArcUser, January-March 2004). With
mobile GIS, it
is now possible to capture, manipulate, analyze and visualize data in the
field
in real time, and ground truthing has become possible1 (see a summary
on an interesting
example, illustrating how advanced mobile mapping
techniques were used to delineate
census enumeration areas in Dili
metropolis, Timor-Leste).
s
8. Furthermore, the combination of digital video (DV), satellite
imagery and GPS for the
data capture and the input of this data into a GIS
for manipulation, analysis and display, is
empowering data collection and
integration (for ground observations of buildings, GPS can
be used in
combination with digital video). Indeed, the most significant development
in
these recent years lies in the better integration of GPS, image processing
and GIS systems.
Hence, collecting data in the field, and storing it in a
geographic database, can obviously
improve the efficiency of the census
mapping process.
II. GEOGRAPHIC INFORMATION PROCESS
9. The
geographic information process consists of three stages: data acquisition,
data
processing and data dissemination. As illustrated in fig. 1, geospatial
technologies are
spanning through these three stages: GPS and satellite
imagery, among others, are useful
tools for geographic data collection; GIS
have demonstrated their powerful capacities to
enable data integration,
analysis, display and dissemination. Hence, remote sensing
techniques, GPS
and GIS have become ubiquitous in developing policies for
integrated
management (Laaribi, 2000).