International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, Vol XXXV, Part B4. Istanbul 2004 
following: black color layer (map grid, objects, text, map sheet 
description, spot heights, etc), blue layer (hydrography), brown 
layer (contours and terrain forms), green layer (vegetation) and 
some other special layers (masks for hydrography, vegetation 
and road classifications). For building DTM only first three 
layers are used. 
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One of the basic characteristics of 1:25000 topographic maps is 
that there is a very long cycle of updating these maps for the 
whole territory. Therefore, for some of these maps the last 
update was done twenty years ago. Fortunately, this is 
something that is not so dangerous when DTM that 
corresponds to 1:25000 maps is considered. Of course, there 
are certain areas such as open mine areas that would require 
special updating of existing map data. 
The major data acquisition method for height data mapping for 
1:25000 maps was aerial photogrammetry and most of the data 
was captured from 1955 to 1965. The aerial photography was 
done in 1:33000, 1:30000, and 1:26000 photo scales. Absolute 
orientation of photo models for some maps was done without 
prior aerial triangulation, so this could be one of the important 
sources of errors. Direct contouring in dynamic mode was 
mostly done by using analog photogrammetric plotters. Major 
contour interval is 10m, but in flat areas there are also contours 
on 5m and 2.5m interval. 
3. DTM DATA ACQUISITION 
Map layers containing height data were scanned together with 
all the other map layers within a single campaign. Drum 
scanner was used. Scanning resolution for most map layers was 
508 DPI. This unusual scanning resolution is chosen to get map 
pixel with some logical metrics (0.05mm on map, 1.25m on the 
field). 
There were two options for digitizing height data. One of them 
was to use separate map layers with height data, and the other 
was to use color paper map with all the layers merged. First 
option was preferable, and it was selected, because it was 
much more convenient to use automatic and semi-automatic 
procedures for contour vectorization without prior color 
separation, which was required for the merged color map. 
Disadvantage was that there were only four map corner marks 
available for georeferencing height map layers. This was the 
case for all the map layers, except for the black layer (contains 
map grid in Gauss-Kriiger projection, and meridians and 
parallels). This was a problem, because it was not possible to 
use advanced methods for determination and removal of map 
distortions caused by distortions of the map material and 
scanning errors. Some tests were carried out and it has been 
estimated that these errors were about 4-5m (0.16-0.20mm on 
a map). Since it was not possible to detect and remove these 
errors using only four corner marks, these errors would 
contribute to the overall error budget of the DTM. For map 
layers with available map grid these errors were analyzed and 
systematic part of the total error, regardless of the source (map 
distortion or scanning errors) was successfully removed from 
the map image. 
Contour vectorization was done by using semi-automatic, line- 
following technique. This was relatively fast, and most suitable 
considering the type of available contour maps. Contour 
heights were assigned manually to the digitized contours 
during vectorization. Problems that were experienced during 
this stage were related to the vectorization of maps for certain 
terrain types featuring lot of stones, extremely high slopes and 
lot of small pits. However, this process was rather 
straightforward in general, and it can be said that there were 
very few critical issues. Several workstations were dedicated 
for this task, working 16 hours per day. Also, all available spot 
heights are manually digitized. Spot heights data will be useful 
for improving DTM quality, but also for the detection of gross 
errors made during initial data capture and during contour 
vectorization and height assignment and spot height 
digitization. The whole process for contour vectorization and 
spot height digitization took about 18 months, including data 
verification. 
    
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vectorization from contour map layer 
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After all map layers with contours were vectorized contours 
were checked and their connections on map borders are 
corrected. This was done by using standard CAD tools. 
4. SOFTWARE FOR DTM ANALYSIS 
Since it was the necessary to provide as many workstations for 
DTM capture, verification and editing as possible, it was 
decided to use some relatively low-cost DTM software. The 
other requirements were related to the possibility of unlimited 
software customization and development of new algorithms for 
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