International Archive 
derived digital orthoimages the creation of 'GIS'-proof DCMs 
will be discussed. 
2. BUILDING EXTRACTION - STATE OF THE ART 
Airborne laser scanning has become one of the most important 
acquisition techniques for surface reconstruction. By collecting 
a huge amount of points (3D locations) with a very high 
resolution and accuracy they provide an optimal input for 
building extraction algorithms. Several approaches have been 
presented, among them one by Rottensteiner's (2004), which 
can be divided into three major steps. The first one is to 
hierarchically apply a robust interpolation using a skew error 
distribution function in order to separate terrain points from 
points that lie not on the ground. The outcome is a DTM 
(Digital Terrain Model). The second step is to distinguish 
between building points and off-terrain points (e.g. vegetation). 
This is achieved by applying an analysis of height differences 
between the DSM and the previously computed DTM. Finally, 
the third step comprises the creation of polyhedral building 
models. 
A different method for automated building reconstruction is 
described in Peternell and Steiner (2003). Assuming that a 
dense point cloud is given, they try to determine all planar 
regions of a building. Firstly, local regression planes for all 
points are computed. The planar faces of the building possess 
local planes of regression (local planar fits) that are close to 
each other. The finding of the faces is achieved by 
transforming the local planes of regression into a parameter 
system where a segmentation is carried out. A drawback is the 
fact, that additional input information (digital map) is needed 
for defining the area of an object. 
Both approaches need a dense and highly accurate point cloud 
in order to be able to derive and analyse the roof faces of 
buildings. They aim at a rather large scale reconstruction. 
Unfortunately these algorithms cannot be adapted to point 
clouds created by spaceborne or line-scanning systems since the 
geometric resolution as well as the accuracy and completeness 
is usually insufficient. 
3. CHANGE DETECTION / UPDATING - STATE OF 
THE ART 
Most of the algorithms for updating check the existing 
buildings in the data base for changes. They are not able to find 
new objects at locations with no entry in the old data base. 
The ATOMI project (Eidenbenz et al., 2000) was used to 
update vector data of building roof outlines and increase their 
accuracy by applying image analysis techniques on aerial 
images. For finding new buildings Niederoest (2000) tried to 
localize extracted DSM blobs or apply a multispectral 
classification. In order to extract DSM blobs that really 
correspond to buildings we have to assume that there exists no 
big and high vegetation and that the DSM resolution and 
quality is good enough to be able to separate buildings from 
each other or from trees. The idea of applying a multispectral 
cassification in order to determine new buildings is of course 
only relevant if multispectral data is available, which is 
unfortunately not the case for high-resolution satellite imagery 
most of the time. 
Knudsen's (2003) strategy for updating digital map databases 
makes also use of pixel-based classification. The algorithm 
uses vector and spectral data as input to an unsupervised 
spectral classification method that controls a subsequent 
Mahalanobis classification step. Due to good geometric 
s of the Photogrammetry, Remote Sensing and Spatial Information Sciences, Vol XXXV, Part B7. Istanbul 2004 
resolution and the potential of using RGB images, changes may 
be traced and even new buildings detected, although again due 
to the pixel-based approach obtaining topologic information of 
the new situation becomes cumbersome. 
4. WORKFLOW 
The proposed workflow is divided into two major parts. The 
first one is data preparation and comprises all steps from data 
acquisition to the derived DSM. There are many off-the-shelf 
software packages available for solving this task. The second 
part deals with the actual creation of the DCM including 
building recognition and extraction. Figure 1 gives an overview 
of the proposed workflow. 
Data Acquisition 
L Satellite / 3-line sensor 
T E 
  
  
  
  
  
  
Y 
Stereo Matching Multi-Image (Ray) Matching] 
Digital Surface Model rer rie Orthophoto 
| 
Shih ERE HU, t A | 
Digital Terrain Model Normalized Surface Model | 
ces | 
| 
Thresholding / Masking | 
| | 
niue | 
Building Recognition | 
ER, M e s pu E 
Old (City) Database | Building Extraction pere 
dq 
Updating apres Digital City Model 
Visualization 
Figure 1. Proposed workflow 
  
| 
| 
* : | 
Orientation (RPCs) r Orientation (IMU/GPS) | 
"esp — —— 575 —— | 
| 
| 
| 
  
  
l 
   
4.1 Data Preparation 
High resolution satellites deliver overlapping image scenes in 
form of stereo pairs, whereas multi-line scanners generate one 
image strip for each sensor line, where each strip is associated 
with a different viewing angle. The orientation of multi-line 
sensor data can be automated to a very high degree. 
Vozikis et al. (2003) have shown that images from the new 
high-resolution satellite sensors (IKONOS and Quickbird) 
cannot be oriented by applying the common procedures used in 
acrial photogrammetry, because, firstly, most distributors do 
not provide any calibration information (interior orientation 
parameters) and secondly, due to the extremely narrow field of 
view (bad intersection quality of the rays), the well-known 
collinearity equation would fail. Diverse orientation models 
have been proposed, but the fastest way is employing the so- 
called RPCs (Rational Polynomial Coefficients), which are 
usually provided together with the images. These coefficients 
describe a relation between object and image space and should 
give the end-user the possibility to start immediately with 
image exploitation. Unfortunately the RPCs are affected by a 
constant shift and hence are not very accurate, SO they have to 
be refined by using two or three GCPs (Ground Control Points) 
(Hanley et al., 2001). 
For the airborne line scanner image strips, the orientation 
procedure is a little bit different. Together with the image data 
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