International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, Vol XXXV, Part B4. Istanbul 2004 
  
  
  
  
  
4.2 GeoPro™ 
In our next example application, GeoPro*, the visualisation 
of the terrain is not the primary goal of the application, but it 
is still a very important part which adds understanding to the 
created scene. 
The goal of GeoPro”” is the visualisation of the ground water 
table and hydro geological layers in combination with 
planned construction sites. The visualised region is usually 
fairly small. 
When starting a GeoPro"? project the user loads the region he 
is interested in into the 2D map of GlSterm. There he must 
select ground water measuring points, which are available 
through the ground water data base. Additionally he needs to 
digitise the planned buildings in the 2D map. With this 
information GeoPro?P creates a virtual scene with the 
following content: 
e The ground water table is visualised in three ground 
water layers with information from the ground 
water database. 
e Hydro geological layers are additionally created 
from the information of the ground water database. 
e The data for the terrain layer is selected with the 
Height-Service out of the database. Usually the 5 m 
high resolution DEM of Baden-Württemberg has 
the appropriate resolution. 
* A building layer is created with the user digitised 
information from the 25D view. The building is 
placed on top of the terrain. 
Fig. 7 shows a virtual scene created with GeoPro?P, 
        
  
   
   
isi disy GISterm SUM ER" os 
.GiSterm Karte. Ihema Diagramm Grafik Extras RIPS 30 Men 
sa@eacaa ot rEg 
  
  
  
  
  
  
  
  
SenPro302 | 
  
  
bruchhausen: 19946 bytes... Position 345370944,541071128 Maßstab 4: 10923 | 
Fig. 7 Scene created with GeoPro^? 
  
GeoPro?? provides several analysis possibilities of the scene, 
like clipping the construction site for detecting conflicts with 
the water table or creating 2D view profiles for visualising 
the run of the hydro geological layers. The visualisation of 
the textured terrain adds a realistic impression into the scene, 
which helps the user to understand the visualised analysis 
tasks. 
5. CONCLUSIONS 
This paper discussed data handling and visualisation 
techniques for the integration of high resolution digital 
elevation models into 3D GIS systems. These techniques 
were adopted successfully for two different visualisation 
applications of the Environmental Information System of 
Baden-Württemberg. The used techniques are generally 
transferable to other examples. 
6. REFERENCES 
AJA, 2004, Projekt AJA (Anwendung JAVA-basierte 
Lösungen in den Bereichen ‚Umwelt Verkehr und 
Verwaltung), http://www.lfu.baden- 
wuerttemberg.de/Ifu/uis/forschuhg/, (accessed April 2004) 
# 
disy, 2004, disy, http://www.disy.net/de/start_de/index html,’ 
(accessed April 2004) 
Hibbard, 2004, : 
http://www.ssec.wisc.edu/~billh/visad.html, (accessed April 
2004) 
Hilbring 2002, Projekt AJA, Anwendung Java-basierter 
Lösungen in den Bereichen Umwelt, Verkehr und 
Verwaltung, Phase IN 2002, GISterm3D — 
Weiterentwicklung vonGeoPro?? und Neuentwicklung des 
Height-Service für die Integration digitaler Gelándemodelle, 
S. 37-56 in  Mayer-Fóll  Keitel, Geiger  (Hrsg.), 
Wissenschaftliche Bereichte, FZKA 6777, 
Forschungszentrum Karlsruhe, Technik und Umwelt 
Hofmann, Veszelka, Wiesel, 1999, Projekt GLOBUS, Von 
Komponenten zu vernetzten Systemen für die Nutzung 
globaler Umweltsachdaten im Umweltinformationssystem, 
Baden-Württemberg und anderen  fachiibergreifenden 
Anwendungen, Phase VI 1999, GIStermFramework — das 
flexible komponentenbasierte Geodatenzugriffsystem, S. 57- 
79 in Mayer-Fóll, Jaeschke (Hrsg.), Wissenschaftliche 
Berichte, FZKA 6410, Forschungszentrum Karlsruhe, 
Technik und Umwelt 
Hofmann, Hilbring, Veszelka, Wiesel, 2000, Projekt AJA, 
Anwendung Java-basierter Lösungen in den Bereichen 
Umwelt, Verkehr und Verwaltung, Phase 1 2000, GISterm — 
Weiterentwicklung des flexiblen Frameworks zur Analyse 
und Visualisierung von raumbezogenen Daten, S. 147-169 in 
Mayer-Foll, Keitel, Geiger (Hrsg.), Wissenschaftliche 
Bereichte, FZKA 6565, Forschungszentrum Karlsruhe, 
Technik und Umwelt 
IPF, 2004, Institut für Photogrammetrie und Fernerkundung, 
http://www.ipf.uni-karlsruhe.de/, (accessed April 2004) 
Java 3D, 2004, Java 3D API, 
http://java.sun.com/products/java-media/3D/, (accessed April 
2004) 
Java 3D Tutorial, 2004, Dokumentation Collateral, 
Chapter 7, http://java.sun.com/products/java- 
media/3D/collateral/ (accessed April 2004) 
LfU, 2004, Landesanstalt für Umweltschutz, 
http://www.lfu.baden-wuerttemberg.de/, (accessed April 
2004) 
Virtual Terrain Project, 2004, Virtual Terrain Project, 
Hardware Support for Large | Texture Maps, 
http://www.vterrain.org/LargeTextures/index.html, (accessed 
April 2004) 
VisAD, 
1.1 
Th 
of 
dir 
wh 
ad 
fur 
mc 
eal 
au; 
Hc 
sel 
Inc 
an: 
ve 
ro: 
CO] 
dri 
do 
ree 
pre 
lid 
be 
dif 
da 
tor 
sin 
int 
ort