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models are composed of many non-linear
computational elements operating in parallel
and arranged in patterns reminiscent of
biological neural nets. Computational elements
or nodes are connected via weights that
typically adapt during use to improve perfor
mance.
This new techniques can be applied to
speech recognition, optimization, classification
of data, especially computer vision and
pattern recognition. It has several advantages:
high computations rates provided by massive
parallelism; a great degree of robustness or
fault tolerance than Van Neumann sequential
computers; the significant learning
mechanism, etc.
Neural net models are specified by the net
topology, node characteristics, and training or
learning rules. These rules specify an initial
set of weights and indicate how weights
should be adapted during use to improve
performance.
In the society of sun/eying, mapping and
GIS/LIS, we can identify the following possible
applications of neural networks:
- the real-time implementation of computer
aided surveying;
- automatic target recognition of aerial
photographs and remote sensing images;
- automatic symbol recognition of scanned
maps;
- fast implementation on some of GIS
operations, for example, overlay operation.
3.4.4 Object oriented grid technology
From the beginning of automating in
cartography the discussion between the
possibilities of grids and vectors played an
important role. A lot of research time is spent
on the conversion of one system to the other.
Although most of the maps that are produced
automatically are raster files, the large scale
topographic maps are converted to vector-
files. Every geographic unit can be
represented with the help of vectors. The
vector data can easily be depicted with
automatic plotters. The technical development
is oriented on the possibilities of grids and
vectors. In the past decennia we saw
sometimes better facilities for vector pictures
(plotters and screens) and sometimes better
possibilities for the processing and depicting
of raster files. Many studies are made for the
conversion of raster to vectors and from
vectors to rasters. The vector-raster conver
sion is relativity simple and can be carried out
very accurately. The required accuracy is still
a problem with the raster-vector conversion. It
is now possible to work completely with raster
techniques because of the availability of raster
plotters (raster scanners and raster screens
were already available). Our research is
oriented on the only problem that remains,
the building of object oriented files in raster
forms.
3.5 Tite presentation of information
The research regarding the presentation of
information plays an important role in our
Centre for Computer Graphics and Mapping.
Several topics are:
- simplification of two-dimensional maps. One
of the characteristics of a map is the data
base. E.g. a topographic map on scale
1:25,000 has a content of about 1Mb
(vectors). Because the use of a map is
unpredictable, a user gets superfluous
information. If somebody is looking to a
road in the north of the country, he gets
extra information of the south of the coun
try. With the computer only the information
can be presented that is necessary whereas
the other information is kept in the data
base. These simple maps are necessary for
new applications like car navigation;
- three-dimensional presentation. Although on
the one hand we see a simplification of the
two-dimensional maps, on the other hand
there is a tendency to represent reality more
realistic with the help of three dimensional
pictures. Especially with planning, manage
ment of space and development of simula
tors, the three dimensional information
attracts a lot of interest. The most important
development are the digital terrain models,
the three dimensional thematic cartography
and the three dimensional topography;
- dynamic information. Many processes are
dynamic, such as changes in weather, traffic
and transport, pollutions of the environment,
etc. For these phenomena dynamic maps
are needed. Much time is spent for this new
field of cartography.
