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that updating of existing cartographic data bases is much more 
time consuming than an initial production of a GIS base related 
to geometrically correct sources. By the use of satellite images 
as background information it is possible to reduce the number 
of interpreted features, which allows a reduced time schedule 
compared to traditional mapping while maintaining quality, 
without any significant reduction of the interpretability of the 
final map product. 
Database. Experiences from these three Baltic data base and 
mapping projects amplify the impressions from earlier data base 
establishment projects. Data bases generally include 
information stored from digitized maps, based on 
cartographically handled information. Today this information is 
not accurate enough when combining the cartographic data with 
geographically correctly positioned information in a GIS 
environment. 
Homogeneous data base quality is of greatest importance for 
future data usage in combination with external sources. The 
quality of the data from the Base Map projects allows a 
combined use with external data sets for production of among 
other things thematic maps. In other words, the information 
stored in the data base, with its well-defined geometry and 
coding, constitutes a platform for further data and map projects. 
Map design. When evaluating the map design of the three 
Baltic projects, the main technical purpose which is the 
establishment of a flexible data base, has to be taken into 
account. The reduced time schedule, which results in a map 
product containing an image background as complementary 
information to interpreted and coded features, has an effect on 
the cartographic balance and layout. Topographic maps in 
general do not include image backgrounds, which resulted in 
the need for investigation and development of production 
procedures optimizing the use of satellite data in combination 
with traditional feature information. 
Education. The development of personal skills using remote 
sensing products in a digital environment, is an aspect that 
should not be overlooked, during such big projects. In 
combination with the development of interpretation and GIS 
procedures such projects include the whole spectrum of the 
latest techniques in map production. 
Time schedule. Due to the minimized production time of these 
projects it was necessary to optimize the production procedures 
with remained expenses. This resulted in the following 
possibilities and decisions: 
* Initial training including remote sensing, interpretation 
technique and GIS. 
* Satellite Ortho Photo Maps as main sources during the 
interpretation. 
* The number of GPS measurements as ground truths was 
minimized by the usage of SSC Satellitbild's orbital 
adjustment model. 
* Efficient usage of existing information, i.e. contour lines. 
* Data Base structure in accordance with the Swedish KF85 
nomenclature. 
* Lowered ambition of interpreted features, compensated by 
an image background. 
* Analog interpretation, instead of time consuming screen 
interpretation and digitalization. 
* Digital cartography, using coded vector data as input to the 
map design environment. 
* Digital data delivery via the Internet. 
4. CONCLUSIONS 
Position accuracy in orthophotos, geometrically corrected by 
GPS measured GCP:s and a generalized DTM, based on 
panchromatic SPOT data on a scale of 1:50,000 in combination 
With multispectral data on a scale of 1:100,000 are feasible 
information for revision of topographic maps on a scale of 
1:50,000. 
459 
The homogeneous data base quality, high geometrical accuracy 
and "intelligent" coding, allows effective data extraction and 
further combination with external data sources. 
A balanced cartographic product, combining satellite images 
and interpreted features from different sources, without any 
decreased quality, verifies the value of topographic base 
mapping projects. 
A combination of initial education (remote sensing, 
interpretation and GIS) followed by production is an efficient 
method for technical transfer during mapping projects similar to 
the Base Mapping Projects in the Baltic States. 
By using a digital technique, methods performing semi- 
automatic revision of existing data bases, it will be possible to 
increase the position accuracy and also reduce the time 
consuming part, manual interpretation, of data base revision 
projects in the future. 
5. REFERENCES 
CNES and SPOT Image, 1988. SPOT user's handbook. 
Dahlgren A., Svedjesten L., 1993. Control Point Determination 
with GPS for Precision Correction of SPOT Satellite Images. 
Master of Science Thesis. The Royal Institute of Technology, 
Department of Photogrammetry, Stockholm, Sweden. 
Harris R., 1987. Satellite Remote Sensing - An Introduction, 
Routledge & Kegan Paul. 
Krusberg P., 1994, Estonian Base Map Project, Estonian Map 
Center. 
Malmstrôm B., Engberg A., 1991. Satellitedata for Topographic 
Mapping, Swedish National Land Board, Swedish Space 
Corporation. (Swedish) 
Rosenholm D., 1987. Some Aspects of Least Squares Matching 
for Automatic Parallax Measurements. The Royal Institute of 
Technology, Department of Photogrammetry, Stockholm, 
Sweden. 
Westin T., 1991. On the Estimation of Interior and Exterior of 
SPOT Imagery. The Royal Institute of Technology, Department 
of Photogrammetry, Stockholm, Sweden. 
International Archives of Photogrammetry and Remote Sensing. Vol. XXXI, Part B4. Vienna 1996