International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, Vol XXXV, Part B4. Istanbul 2004 
  
  
accurate in xy. It would be best to load these data in the future 
database, after recovering the z-values from the CAD-files. 
The first 720 km?, dating from 1988, had far less detailed contents 
than the data in the rest of the country. Furthermore, at the rate 
that the landscape has changed, there will be not much left 
unchanged. We therefore decided that the datacollection in these 
areas should be redone completely. 
During the following 15 years, from 1989 till now, the 
specifications for the data classification, the stereoplotting and the 
data structuring have evolved continuously. We retrieved nearly 
all instruction-notes with new specifications valid from a certain 
date, but not telling whether the map sheets that were being 
produced at that time already took in account the new 
specifications or not. Did the operators follow a new specification 
for the active or the next working area or only for the next map 
sheet ? Even though we kept a record of all begin- and end dates 
of each major production step in each working area, we cannot 
‘answer this question for sure without verifying the data 
themselves. 
The updating operators at every stage of the work will need to 
learn about the initial situation of the data in a certain area so that 
whilst performing the update they may pay attention to certain 
changes in the specifications. This illustrates the importance of 
metadata. The operators will need clear instructions on what they 
should adapt to the new specifications and what they should leave 
as it 1s. 
3.2 The data for the 1:50.000 map 
The 50K data cover the whole country and are already being 
updated on basis of field survey and orthophotographs before we 
start the ‘Seamless GIS of Reference’. By comparing the 
production years of the base map data with the first and second 
edition of the 1:50.000 map data, and sorting the results, we 
learned that because of the 15 years’ difference in age of the data, 
it would be most interesting to study the updates in the map 31/3- 
4. This study confirmed that it is very useful to glance over the 
50K update data whilst updating the 10K database. Those data are 
also an important source of information on the number and kind 
of modifications that we may expect in the landscape. 
3.3 The external data 
At the moment, there are but very few external data sets that could 
directly be useful for our project. One of these is the high tension 
lines file from ELIA, the public utility which manages the 
transport of the high tension power in Belgium. The file was 
originally made by us, but it was accurately kept up to date by 
ELIA. Hence, it would be best if we could load their data into the 
future database. A similar co-operation is being organized with 
the national railroad company. In the future, we expect to obtain 
more and more external update data e.g. building-update-data 
from the cadastre and from the regional authorities, which are 
collecting large scale data. 
4. COMBINING THE BEST PART OF THE 
MOST IMPORTANT DATA SETS 
Since stereoplotting will remain a very important updating tool, 
the data have to be 3D. For most object types it would be best to 
load Top10V-GIS in the future database, after giving z-values 
to the data. For many object types, the best way to do so would be 
744 
to project the ToplOV-GIS data on a very good DTM, c.g. 
produced by laser scanning. For some other objects, as well as for 
nearly all objects in the many areas where we do not have a laser 
scanned DTM, the most accurate method is by recovering the z- 
values from the parent CAD-files. This way, we combine the 
advantages of the two most important data sets: being 
topologically structured, identified and 3D. 
For recovering the z-values from the parent CAD-files our 
colleague Hugues Bruynseels wrote a VBA-script that uses some 
predefined functionalities of ArcMap. In a first step, it converts 
the elements of the CAD-files into a cloud of 3D points in an 
ArcGIS 8.3 Geodatabase. Then the Top10V-GIS-coverages are 
imported into the same Geodatabase and a z co-ordinate (with 
default = 0) is given to each pair of xy co-ordinates. Since the 
original data were subject to manipulations during the structuring; 
small displacements, splittings, creation of additional nodes due 
to topological cleaning, the script needs to perform a proximity 
search: in a third stage, the application goes over every element of 
Top10V-GIS and for each encountered vertex it runs a proximity 
search and selects the corresponding triplet (x,y,z) from the point 
cloud. The distance in this search is a parameter; we have limited 
it to 10 meter. At 10 m the search is interrupted. If no 
corresponding triplet was found in the point cloud, the z-value is 
set to z — -99, in order to make it easy to detect the problem and 
correct it manually. The efficiency of this method varies with the 
object categories. It works extremely well for buildings, which 
solves our main problem. It does not work as well for the linear 
elements, though we hope to improve the results by generating 
additional points at intersections in the parent data. There will 
always remain a number of objects that have to be projected on a 
DEM. The best available DEM has to be chosen in function of the 
object type and the area. | 
5. THE FUTURE DIGITAL 
PHOTOGRAMMETRICAL 
WORKSTATION CONFIGURATION 
For updating the future ‘Seamless GIS of Reference’- database by 
stereoplotting, we need our digital stereoplotters to be linked with 
a GIS. This is one of the most important requirements for the 
updating implementation; it may be a limiting factor in the choice 
of the underlaying DBMS. C. Heipke (2004) described how the 
ideal GIS should look like in general, from a photogrammetrical 
point of view. We would like to point out some more detailed 
requirements for the future stereoplotter configuration. It should 
answer positively to the following requirements. Many of them 
seem obvious, but we point them out explicitly because they are 
not as often available as one would expect. 
It should be possible to (N=Necessary, D=Desirable): 
N1) visualize the DBMS-contents in 3D 
N2) edit the DBMS-contents in 3D 
N3) automatically check input attribute values against their list 
domain or range domain and give warnings when not OK 
N4) automatically timestamp each operation 
N5) automatically source stamp each operation with a user group 
N6) clean overshoots, undershoots and intersections, making a 
vertically projected 2D topology without messing up the z-values 
nor the db-linkages: in batch 
D7) automatically adapt the corresponding stereo-images when 
performing a queued locate on the DBMS-contents 
D8) shift the stereomodel in x,y,z in order to make it locally 
coincide with the vector data 
D9) visualize all elements of a 2D-file in 3D at the height of the 
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