CMRT09: Object Extraction for 3D City Models, Road Databases and Traffic Monitoring - Concepts, Algorithms, and Evaluation 
104 
which is essential in crisis scenarios. Depending on the type and 
complexity of the input data, the system can be run in a fully 
automatic or semi-automatic mode, where a human operator can 
edit intermediate results to ensure the required quality of the final 
results. 
Section 2 describes the generic near-realtime classification sys 
tem with the objective to classify and evaluate objects using re 
mote sensing and other available data. In Section 3 the system is 
applied to road objects in case of natural disasters. Two test sce 
narios of flooded areas are used to verify the system. By means 
of manually generated reference data, the applicability and effi 
ciency of the system is evaluated in Section 4. Finally, further 
investigations in future work are pointed out. 
2 CLASSIFICATION SYSTEM 
The fusion of multi-sensor images is an important issue, because 
the corregistration between optical and radar images is still a cur 
rent research topic (Pohl and Van Genderen, 1998). Methods 
such as mutual information can be applied for the system (Inglada 
and Giros, 2004). The system has to deal with multi-temporal 
images having the possibility to derive important information on 
time. This leads to an even more complex corregistration pro 
cess. Change detection algorithms can provide information about 
the variation of assessed objects. In this article the temporal fac 
tor is neglected, but will be an essential part in future research. 
The main core of the system represents the classification. The 
goal is to classify each object into a different state Si. For each 
object probabilities are derived belonging to a certain state. The 
methods estimating the probabilities depends on the data: typ 
ical examples are multispectral classification or fuzzy member 
ship functions (Figure 2). 
The goal of the developed classification system is the assessment 
of GIS-objects using up-to-date remote sensing data. The system 
is designed in a general and modular way to provide the opportu 
nity to label GIS-objects into different states. Typical states de 
scribe the functionality of infrastructure objects as roads or build 
ings. The generic system embeds different kinds of image data: 
multi-sensor as well as multi-temporal data. Additionally, any 
kinds of available data sources and spatial knowledge, which con 
tributes information for the assessment, can be embedded. Typi 
cal examples are digital elevation models (DEM) and further G1S 
information, e.g. land cover or waterways. The minimum re 
quirement of the system are the objects to be assessed and one 
up-to-date image which provides the information for the assess 
ment. 
Time 
Point t-| 
Optical 
Imagery 1 
SAR 
Imagery 1 
DEM ► 
GIS- 
object 
1 
Classification 
System 
GIS ► 
I 
Optical 
Imagery 2 
Time SAR 
Imagery 2 Classification 
System 
GIS- 
Object 
I 
data 1 
► method 1 - 
—► 
PlIlSi) Pil:S;> 
••• > Pd,S, 
data 2 
► method 2 - 
—► 
Pd.Sp Pd:S;r 
■■■ t Pd;S! 
... 
— - - 
—► 
■■ 
data n 
► method n 
—► 
PaSh PJ„S:> 
••• ) Pd& 
Figure 2: 
Derivation of probabilities 
from data 
using various 
methods 
Beside the derivation of the individual probabilities from each 
data source the combination plays a decisive role: 
Psi =Pd 1 ,s 1 ®Pd 2 ,s 1 <S> • • • <8>Pd n ,s x 
Ps 2 = Pd 1 ,s 2 <S> Pd 2 ,s 2 ® ■ ■ ■ ® Pd n ,s 2 
: (1) 
PSi = Pd 1 .Si ® Pd 2 .Si ® • • • <8> Pd n ,Si■ 
The variable Pd n ,Si denotes the probability that the state Si oc 
curs given data d n ■ The indices i and n describe the number of 
available states and data, respectively. The result pSi shows the 
probability that a GIS-object belongs to the state S',-. For each 
type of data weights w n can be introduced in order to cope with 
the different influence of infonnation content. Hence, Equation 1 
for one state i leads to: 
i 
up-to-date 
map 
Figure 1 : Classification system 
PSi = m • Pdi,Si ® • • • <8> w n • Pd n ,Si■ (2) 
Finally, the object is assigned to the state S, with the largest prob 
ability pSi. A basic characteristic of the whole system is the 
combination at the probability level in order to remain flexible 
concerning the available data. 
The classification system depicted in Figure 1 can be subdivided 
into different components. Starting point are the GIS-objects to 
be assessed. Secondly, the input data as imagery or digital eleva 
tion models which contribute the information for the assessment. 
In the following this information is called data. Thirdly, the clas 
sification system by itself and, finally, a resulting up-to-date map. 
3 MODEL FOR ROAD OBJECTS 
After describing the generic system, a model is shown which as 
sesses linear objects as roads after flooding. However, this model 
is transferable to other linear objects like railways and further