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see, that the results are very similar with the most 
obvious difference in the classes „Fields‘‘ and 
Settlement". It looks like the satellite image analysis 
overestimates the ,Settlement" class at the cost of 
Fields". 
Column 3 shows the number of pixels which are identical 
if compared pixel by pixel. While the percentage of 
identical pixels is very high for the classes "Water", 
"Forest" and "Fields", the class ,Settlement shows a 
poor result. The main reason for that inaccuracy is the 
uncertainty of the texture analysis for the ,Settlement" 
segmentation, which tends to extend the class into 
surrounding areas (usually fields) while the visual 
interpreter has decided to set the class boundary much 
tighter to recognizable houses. The poorer result is not 
necessarily a pure drawback of the computer analysis. We 
should be aware that already the class definition is not 
very clear: Are backyards ,Settlements", for instance? 
(see figure 5) 
81% of the controlled pixels are classified with high 
certainty. Column 4 lists the number of those pixels, that 
are identical with the visual interpretation. In this group 
the percentage of successful classification is, not 
unexpectedly, greater and significantly greater for the 
previously mentioned uncertain classes. 
Additionally we wanted to take into consideration a slight 
inaccuracy of the geometric rectification. We know, and 
we must expect in any case, that our layers of the various 
data sources do not geometrically fit to each other within 
the accuracy of one pixel. In order to allow a small 
displacement of some 10 m, we perform the identity 
check again by comparing in 3x3 window instead of pixel 
by pixel (i.e. a Ix] window). Column 5 lists the number 
of pixels whose classes are identical. The total number of 
identical pixels rises from 90% to 93%, while there is 
almost no difference for the pixels classified with high 
certainty (column 6). They are usually not boundary 
pixels and therefore not influenced by the window check. 
     
QU a xai : 
a. : 
Fig 4: Comparison of classification and visual interpretation of 
the class ,,Forest* 
Figure 4 and figure 5 show details of the comparison. The 
left image contains the classification result, the right one 
the panchromatic satellite image. Superimposed on both 
are the class boundaries of the visual interpretation from 
the orthophoto. The forest boundary in figure 4 gives a 
rough idea about the geometric accuracy of the image 
rectification. The vector image of the forest boundary has 
the same shape as in the satellite image but from the 
slight displacement in the order of 2 to 3 image pixels we 
must conclude inaccurate geometric rectification. On the 
left hand image the reference boundary is clearly outside 
the classified forest by some 15 m. Figure 5 reveals one 
typical problem of the settlement classification that has 
been already concluded from table 2. The visual 
interpreter found much smaller areas than the automatic 
algorithms, that overestimates settlement areas by 
including gardens and backyards in the class. 
  
  
  
  
the class ,,Settlement* 
7 CONCLUSION 
The completion and the update of a nation-wide 
information system (such as the DLM of the Austrian 
BEV) with landuse data can be carried out successfully 
up to a certain accuracy by classifying high resolution 
data together with multispectral data and if possible with 
information from an already existing GIS. All the data 
sources are subjected to special classification procedures 
and then linked to each other in a rule based hierarchical 
classifier. The quality of the result depends on the 
resolution of the original images, of course, but also on 
the classes. For not well-defined classes like ,,Settlement* 
one must expect a need for some additional work for 
visual post-interpretation or field verification. Still, the 
automatic procedure can be enormously cost-saving as 
the process works automatically to a high extent and for 
all uncertain program decisions the user receives hints 
through reliability or certainty codes where a closer check 
is recommended. The practical example proved that with 
current satellite sensors, such as IRS-1C, SPOT and 
Landsat TM, a geometric acurracy of about 15 m x 15 m 
can be achieved. The classification compared to a visual 
interpretation yielded an average success rate of up to 
93%. With the new generation of satellites that have been 
announced for the near future and with adapted 
interpretation algorithms (texture analysis will become 
increasingly important) the overall quality may even be 
improved. As a summarising result and a proof of the 
quality figure 6 shows the landuse layer with the situation 
layer of the Austrian map 1:50000 superimposed on it. 
8 REFERENCES 
Ament R. (1997) Orthobilder in der ATKIS-Fortführung. 
In Fritsch, Hobbie (Eds): Photogrammetric Week '97,. 
Wichmann Verlag Heidelberg, pp. 127-134. 
Fórstner W. (1991), Statistische Verfahren für die 
automatische Bildanalyse und ihre Bewertung bei der 
Objekterkennung und -vermessung, Heft Nr. 370. DGK, 
München. 
Intemational Archives of Photogrammetry and Remote Sensing. Vol. XXXII, Part 7, Budapest, 1998 279