Geographic Information Systems
Geographic information systems (GIS) technology can be used for
scientific
investigations, resource management, and development planning. For
example, a
GIS might allow emergency planners to easily calculate
emergency response times
and effected areas of the ocean during an oil spill
based on the spills
location. You may ask, what is GIS? In the strictest
sense, a GIS is a computer
system capable of assembling, storing,
manipulating, and displaying
geographically referenced information, i.e. data
identified according to their
locations. Practitioners also regard the total
GIS as including operating
personnel and the data that go into the system. A
geographic information system
(GIS) works in a series of steps, First there
is the relating information from
different sources. If you could relate
information about oil spill location to
the oceans surface currents, you
might be able to tell where to start clean up
based on how long the oil has
been in the ocean. A GIS, which can use
information from many different
sources, in many different forms can help with
such analyses. The primary
requirement for the source data is that the locations
for the variables are
known. Location may be annotated by x, y, and z
coordinates of longitude,
latitude, and elevation and any variable that can be
located spatially can be
fed into a GIS. Several computer databases that can be
directly entered into
a GIS are being produced by Federal agencies and private
firms. Different
kinds of data in map form can be entered into a GIS. A GIS can
also convert
existing digital information, which may not yet be in map form into
forms it
can recognize and use. For example, digital satellite images can be
analyzed
to produce a map like layer of digital information about marine
life
productivity. Likewise, sea-grass data can be converted to map-like
form,
serving as layers of thematic information in a GIS. Next Step for
Geographic
information systems (GIS) would be to Capture the data If the data
to be used is
not already in digital form, that is, in a form the computer
can recognize,
various techniques can capture the information. Maps can be
digitized, or
hand-traced with at computer mouse, to collect the coordinates
of features.
Electronic scanning devices will also convert map lines and
points to digits. A
GIS can be used to emphasize the spatial
relationships among the objects being
mapped. While a computer-aided mapping
system may represent a shoreline simply
as a line, a GIS may also recognize
that shoreline as the border between ocean
and land, and correctly display
the tidal differences of the shoreline based on
its location on the earth.
Data capture, putting the information into the
system, is the time-consuming
component of GIS work. Identities of the objects
on the map must be
specified, as well as their spatial relationships. Editing of
information
that is automatically captured can also be difficult. Electronic
scanners
record blemishes on a map just as faithfully as they record the map
features.
For example, a fleck of dirt might connect two lines that should not
be
connected. Extraneous data must be edited, or removed from the digital
data
file. After the data is collected we must integrate the data. A GIS
makes it
possible to link, or integrate, information that is difficult to
associate
through any other means. Thus, a GIS can use combinations of mapped
variables to
build and analyze new variables. Before the digital data can be
analyzed, they
may have to undergo other manipulations - projection
conversions, for example -
that integrate them into a GIS. Projection is a
fundamental component of
mapmaking. A projection is a mathematical means of
transferring information from
the Earth's three-dimensional curved surface to
a two-dimensional medium - paper
or a computer screen. Different projections
are used for different types of maps
because each projection is particularly
appropriate to certain uses. For
example, a projection that accurately
represents the shapes of the continents
will distort their relative sizes.
Since much of the information in a GIS comes
from existing maps, GIS uses the
processing power of the computer to transform
digital information, gathered
from sources with different projections to a
common projection. Can a seabed
map be related to a satellite image of marine
life, as indicator of the
importance of seabed to marine life productivity? Yes,
but since digital data
are collected and stored in various ways, the two data
sources may not be
entirely compatible. So a GIS must be able to convert data
from one structure
to another. Image data from a satellite that has been
interpreted by a
computer to produce a marine life productivity map can be
"read into" the GIS
in raster format. Raster data files consist of
rows of uniform cells coded
according to data values. Raster data files can be
manipulated quickly by the
computer, but they are often less detailed an may be
less visually appealing
than vector data files, which can approximate the
appearance of more
traditional hand-drafted maps. Vector digital data have been
captured as
points, lines (a series of point coordinates), or areas (shapes
bounded by
lines). GIS to convert data into different formats can perform
data
restructuring. For example, a GIS may be used to convert a satellite
image map
to a vector structure by generating lines around all cells with the
same
classification, while determining the cell spatial relationships, such
as
adjacency or inclusion. Thus a GIS can be used to analyze seabed
information in
conjunction with marine life information. It is difficult to
relate multiple
sets of data using conventional means, however a GIS can be
used to depict two-
and three-dimensional characteristics of the Earth's
surface, subsurface, and
atmosphere from information points. How is the GIS
data used? GIS is powerful
and Information retrieved from GIS can be very
useful. What do you know about
the current status of the different parts of
the ocean? With a GIS you can
"point" at a location, object, or area on the
screen and retrieve
recorded information about it from off-screen files.
Using scanned aerial
photographs as a visual guide, you can ask a GIS about
the geology or hydrology
of the different areas of the ocean. This kind of
analytic function allows you
to draw conclusions about the oceans
environmental sensitivity. GIS can also
help in site selection. For example
the U.S. Geological survey (USGS), in a
cooperative project with the
Connecticut Department of Natural Resources,
digitized more than 40 map
layers for the areas covered by the USGS Broad Brook
and Ellington 7.5-minute
topographic quadrangle maps. This information can be
combined and manipulated
in a GIS to address planning and natural resource
issues. GIS information was
used to locate a potential site for new water well
within half a mile of the
Somers Water Company service area. To prepare the
analysis, digital maps of
the water service areas were stored in the GIS. Using
the buffer function in
the GIS, a half-mile zone was drawn around the water
company service area.
This buffer zone was the "window" used to view and
combines the various map
coverage relevant to the well site selection. A GIS was
used to select
undeveloped areas from the land use and land cover map as the
first step in
finding well sites. The developed areas were eliminated from
further
consideration. The quality of water in Connecticut streams is
closely
monitored. Some of the streams in the study area known to be unusable
as
drinking water sources. To avoid pulling water from these streams into
the
wells, 100-meter buffer zones were created around the unsuitable streams
using
the GIS, and the zones were plotted on the map. A map showing the
buffered zone
was combined with the land use and land cover map to eliminate
areas around
unsuitable streams from the analysis. The Connecticut Department
of Natural
Resources records point sources of pollution. These records
consist of a
geographic location and a text description of the pollutant. To
avoid these
toxic areas, a buffer zone of 500 meters was established around
each point. This
information was combined with other relative GIS layers to
produce a new map of
areas suitable for well sites. The condition of the
Earth's surface, atmosphere,
and subsurface can be examined by feeding
satellite data into a GIS. GIS
technology gives researchers the ability to
examine the variations in Earth
processes over days, months, and years. As an
example, the changes in vegetation
vigor through a growing season can be
animated to determine when drought was
most extensive in a particular region.
The resulting graphic, known as a
normalized vegetation index, represents a
rough measure of plant health. Working
with two variables over time will
allow researchers to detect regional
differences in the lag between a decline
in rainfall and its effect on
vegetation. These analyses are made possible
both by GIS technology and by the
availability of digital data on regional
and global scales. The Advanced Very
High Resolution Radiometer or AVHRR
produces the satellite sensor output used to
generate the vegetation graphic.
This sensor system detects the amounts of
energy reflected from the Earth's
surface across various bands of the spectrum
for surface areas of about 1
square kilometer. The satellite sensor produces
images of a particular
location on the Earth twice a day. AVHRR is only one of
many sensor systems
used for Earth surface analysis. More sensors will follow,
generating greater
amounts of data. With this type of technology, scientist not
only have the
resources to help preserve our earth, they also have the proof of
destruction
at a global scale derived from GIS.
Bibliography
Magazine: GIS
World October 98, February 99 Internet: www.gw.geoplace.com
Magazine: GIS
Info Systems (Application of GIS and related spatial
information
technologies) November 98, March 99 Internet: www.erdas.com
Magazine: GPS World
January
98