change that is to be expected. This can be used to roughly 
estimate the completeness of a database at some point in 
time which may be valuable information for the verification 
step. 
4 UNCERTAINTY IN DATA FOR ROAD 
EXTRACTION 
On a first sight one might think that we will have to deal 
with the precision of the GIS data and the precision of the 
extracted image features. Yet, from the above aspects of 
data quality it should have become clear that there are many 
more causes for uncertainty. 
4.1 GIS data 
In fact, positional accuracy of GIS data is only a minor source 
of uncertainty. The available data usually permits to outline 
the sides of the road surface or the middle of the road within 
a few pixels in the image. The (very few) results on updating 
road networks by image interpretation are, however, much 
worse. Thus, there must be other sources of uncertainty. 
Like positional accuracy, attribute accuracy is usually very 
high in comparison to the quality of the interpretation results. 
Consistency of the GIS data may be considered a more impor- 
tant factor. Inconsistent data will yield conflicting evidence 
to some hypotheses and thereby can mislead the reasoning 
process. Of special interest in GIS data are the topological re- 
lations between the features. Egenhofer and Franzosa [1991] 
classified eight different topological relationships between two 
two-dimensional regions (like meet, overlap, disjoint, etc.). 
Winter [1994] argues that such relationships between regions 
can not be considered as certain, due to positional inaccura- 
cies, however small they are. E.g., even due to the smallest 
possible error, two regions that actually meet may be classi- 
fied as disjoint or overlapping. Other changes in topology are 
less likely. E.g., if one region is actually contained in another, 
it is unlikely that they will be classified as disjoint. Winter 
[1994] therefore derives conditional probabilities of topologi- 
cal relations between regions in a GIS, given their true topol- 
ogy. These probabilities very well model the uncertainty in 
topological relations. A reasoning process can now take into 
account the confidence that has to be given to some relation- 
ship and does not have to accept all relations as correct. 
Semantic errors in the GIS can also have a large impact on 
the image interpretation. Suppose that, according to the 
data model, a road database contains the roadsides. This 
definition of the data still allows several interpretations. E.g., 
does the road include the sidewalk, or the shoulder? An 
incorrect interpretation of the data model can clearly lead to 
a large number of errors in the verification step. If the data 
model is ambiguous, the verification step should comprise 
hypotheses for each of the different interpretations in order 
to find the correct one. 
Since the purpose of the image interpretation is in updating 
the road database, it is obvious that the data completeness of 
the GIS is significantly lower than what can be expected for 
an up to date GIS. If available, a rate of change may be used 
to calculate the expected data completeness at the time of 
updating. This number can then be compared to the results 
of the verification step. 
The information in a GIS is clearly insufficient to automat- 
ically solve the interpretation of the aerial images. In this 
  
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sense, the model completeness of the GIS for the task of au- 
tomatic updating is very low. Image interpretation requires 
much richer descriptions of the objects than a few vectors in 
a GIS. This leads to the problem of object modeling. 
4.2 Object models 
Describing roads in generic models such that these models 
contain sufficient information to recognize all kinds of roads 
is an extremely difficult task. Yet, humans have no problems 
in recognizing the roads in figure 1 despite the large variety 
in shape, size, scale, and pavement. 
  
  
Figure 1: Variety of road appearances in aerial imagery. 
Gunst [1996], after [Garnesson et al., 1990] describes a road 
model in terms of geometry, radiometry, topology, function- 
ality and context. Many attempts to describe a road only 
use geometrical and radiometrical properties. E.g., a road is 
defined as two parallel edges that include an elongated ho- 
mogeneous area. According to this definition, a side walk, 
a single traffic lane, a river, a dike, a beach, and probably 
many other objects also can be classified as a road. Some 
improvements can be made by including colour or texture 
information, but a good result can only be expected if the 
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