structure of height database - projects to the 50x50 grid 
network and include the covering information. 
The user environment integrate the height, the vector 
covering and the raster covering database constitutes as 
a complex unit. Their formation's aim was to give a 
suitable base to the different government and technical 
tasks. 
2. New technical possibilities 
The new application areas increased the requirements of 
the data quality and information complexity. For global 
geographic modeling and analysis the airborne and 
satellite-born sensors provide much primary data. In the 
last decade drastically increased the hardware 
performance, the memory and secondary storage 
capacity. The remote sensing and the digital 
photogrammetric methods become practical parts of the 
industrial data capturing and analysis production 
technologies. 
The new technical developments give a chance to 
integrate the remote sensing and digital Photogrammetry 
in the GIS applications. 
In our case we analyzed the following issues: 
- merging remotely sensed data, digital photogrammetric 
images and data from other sources 
- data acquisition and processing of huge amount of 
image information 
- image classification based on available land cover 
database 
3. Proposed technologies 
3.1. Hardware background 
In the TU. of Budapest an Intergraph ImageStation 
Digital Photogrammetric Workstation was installed in 
1995. The configuration give a possibilities to solve the 
secondary data entry (manual digitizing, scanning), 
image processing, digital photogrammetric stereo 
compilation and analysis tasks. The Weitek graphic 
board and the real-time JPEG card give a possibility to 
solve the real time image manipulation problems. 
3.2. Software background 
The Intergraph ImageStation is a spatial 3D Digital 
Photogrammetric Workstation with a standard UNIX 
based operating system (CLIX). On the ImageStation the 
MicroStation (Bentley-Intergraph) as the standard graphic 
engine and the Modular GIS Environment with ORACLE 
database management system ( with input, management, 
analysis and presentation modules) as an application 
software can be used. 
The digital photogrammetric and remote sensing modules 
embedded in the standard graphic engine. 
3.3. Revision and updating of the data base 
The following methods was tested as 'real production’ 
technologies. 
Application of Landsat TM images with unsupervised and 
supervised classification the interpretation of the different 
covering types: river, road, meadow, low vegetation, 
water surface, low-medium-high vegetation, low-medium- 
high buildings can be solved. 
The result is excellent for the 50x50 m raster database, 
but the high precision vector database required more 
precise technology. The original vector database was 
derived with the manual digitalization of analog maps. 
The high resolution applications (GSM telecommunication 
planing) required 3D object database. The 2D planimetric 
mapping object can be get the elevation information with 
a simple interpolating technique based on the 50x50m 
DTM database. After these elevation interpolation step the 
derived 3D element can be superimposed in the digital 
photogrammetric images. 
In the same graphic environment the operator can be 
modified, updated the vector database and real stereo 
photogrammetric observations can be used to stand up 
the 3D object database. 
A quite efficient and simple method the mono-plotting 
technique. With application of aerial photographs and the 
DTM data base in a low-end environment can be solved 
the database updating. The first case use contact copies 
of the air photos take to a digitizing tablet, the DTM 
database and the orientation parameters of the images. 
After the orientation of the contact copy a common 
digitizing table the required revision task can be done by 
real-time projection of the image coordinates to the 
ground. With a simple 2D device we can get precise 3D 
coordinates of the objects. The self-developed mono- 
plotting software used the MicroStation as a graphic 
engine. 
The second case of monoplotting use the rectified ortho 
images. With applications of the ortho images and the 
DTM data base 3D data capturing can be done. 
4. Data quality 
Generally in a GIS the final quality depends on source 
quality. Four aspects of data acquisition comprise the 
criteria for selecting data quality (Bernhardsen, 1992): 
(1) need, 
(2) costs, 
(3) accessibility, 
(4) time frame. 
In the project the data quality was determined in an 
iterative process, where the possible technology of data 
acquisition and the data quality were analyzed. 
The needful quality of the Land Cover Telecommunication 
Database can determined by the analysis of wave 
propagation models. It is necessary to distinguish 
between two cases: 
-the radiation of the waves in all directions ( isotrop case), 
the radiation of the waves between two 
telecommunication stations (anisotrop case). 
In the second case it is necessary higher data quality 
than in the first case. From economical point of view it is 
better the realization of the Land Cover 
Telecommunication Database only for the first case. The 
220 
International Archives of Photogrammetry and Remote Sensing. Vol. XXXI, Part B4. Vienna 1996 
nec 
stati 
The 
of 1 
met 
mor 
not 
of d 
date 
The 
prot 
The 
Tele 
prof 
with 
In t 
moa 
qual 
(1)! 
(2) ¢ 
(3) e 
(4)c 
(9) € 
(6) € 
(7) € 
Sorr 
disc 
well 
Tele 
data 
The 
geoi 
use 
accel 
The 
dete 
acci 
moc 
incl 
acci 
met 
The 
vari 
date 
elev 
way 
The 
of 1: 
The 
attri 
diffi 
mis: 
oni 
valu 
radi: 
The 
simi 
The 
mis: 
For 
for 
prac 
the