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EXTRACTING SEMANTIC BUILDING MODELS FROM AERIAL STEREO 
IMAGES AND CONVERSION TO CITYGML 
A.Sengul * 
? ITU, Civil Engineering Faculty, Dept. of Geomatic Engineering, 80626 Maslak Istanbul, Turkey ahmetsengul@gmail.com 
Commission III, WG IV 
KEY WORDS: 3D City model, CityGML, Data model 
ABSTRACT: 
The collection of geographic data 1s of primary importance for the creation and maintenance of a GIS. Traditionally the acquisition 
of 3D information has been the task of photogrammetry using aerial stereo images. Digital photogrammetric systems employ 
sophisticated software to extract digital terrain models or to plot 3D objects. The demand for 3D city models leads to new 
applications and new standards. City Geography Mark-up Language (CityGML), a concept for modelling and exchange of 3D city 
and landscape models, defines the classes and relations for the most relevant topographic objects in cities and regional models with 
respect to their geometrical, topological, semantically and topological properties. It now is increasingly accepted, since it fulfils the 
prerequisites required e.g. for risk analysis, urban planning, and simulations. There is a need to include existing 3D information 
derived from photogrammetric processes in CityGML databases. In order to filling the gap, this paper reports on a framework 
transferring data plotted by Erdas LPS and Stereo Analyst for ArcGIS software to CityGML using Safe Software's Feature 
Manupulate Engine (FME) 
1. INTRODUCTION 
1.1 General Information 
Virtual 3D city models gain more and more importance in 
Science, government, and private industry. Several 
municipalities decide nowadays to build up 3D city models in 
order to clearly understand the cities' real situations. With the 
increasing number of more complex applications and objectives 
more sophisticated models are required not only based on 
geometric information, but on semantic information as well as 
on 3D topology, representing the meaning and functionality of 
urban objects. CityGML, an OGC standard for city and 
landscape modelling, is able to identify structures for the 
organization of urban information which can be used in a broad 
range of applications, e.g., for analysis in urban planning, 
disaster management, and environmental simulations. 
Traditionally, acquisition of 3D objects is done by 
photogrammetric methods, using aerial stereo images. Leica 
Photogrammetrry Suite (LPS) by Erdas for example, offers 
sophisticated tools for stereo feature collection. But there is a 
gap between the photogrammetric measurement and the storage 
of processed objects in CityGML which is filled by a student’s 
master thesis completed at the Technische Universitit Berlin. 
2. 3D CITY MODELLING 
2.1 3D City Models 
3D City Models are digital representations of the Earth’s 
surface and related objects belonging to urban areas. In order to 
get information about a city it is necessary to collect data from 
different sources. There are several methods of collecting the 
data such as LIDAR, laser scanning, surveying measurements, 
aerial and satellite images. ..etc. 
2.2 Semantic 3D City Models 
Semantic 3D city models comprise besides the spatial and 
graphical aspects particularly the ontological structure including 
thematic classes, attributes, and their interrelationships. It 
follows structures that are given or can be observed in the real 
world. For example, a building can be decomposed into 
different building parts, if they have different roof types and 
their own entrances like a house and the garage (Kolbe,2009). 
3.DATA MODELLING 
Data modelling defines the relationships between data elements 
and structures. Data modelling techniques are used to model 
data in a standard, consistent, predictable manner in order to 
manage it as a resource (Carlis, 2001). 
3.1 Building model in photogrammetric tools 
The photogrammetric tools are combined with ERDAS Imagine 
— LPS and ArcGIS Stereo Analyst in the thesis work. The 
building data model of ERDAS which could not reach 
anywhere and it decided to build using UML diagram. 
Modelling the UML diagram of the ERDAS Imagine LPS 
module and ArcGIS Stereo Analyst is another task to follow on 
the project, while working on the photogrammetric methods. 
The UML diagram will help the user to follow the thesis work. 
It is representing the details of the workflow (Fig3.1).