canals disappear in the region-based segmentation process,
although the segmentation results are otherwise quite good. To
improve the interpretation results, images with higher spatial
resolution are needed.
The advantage of the segmentation in this study was the
increase in the Maximum Likelihood classification accuracy
compared to a pixel-based classification (Table 8). A segment-
based classification gives a result with homogeneous regions
like in a map. If segmentation is not used, good generalisation
procedures are needed.
In this study, only three information sources were available in
the rule-based postclassification, and the belief values, which
were based on relationships between reference points and
classification attributes, were the same for all the test area. The
changes in the postclassification compared to the Maximum
Likelihood results were quite straightforward. For instance,
every segment or pixel which was cultivated land on the old
map, forest in the Maximum Likelihood classification and the
height of which was between 0 and 10 metres was
postclassified as rice. A more ideal solution would be belief
values which change continuously depending on characteristics
of each segment or pixel. For instance, the probability that a
field changes to urban area is much bigger near the town centre
than far from it and the probability that forests exist increases as
the height increases. However, to reliably exploit this kind of
information, more reference points than what was available for
this study would be needed.
The future research will focus on use of SAR images and SPOT
panchromatic images together with Landsat TM images and use
of spatial information, such as neighbourhood relationships of
segments, in the interpretation process. The interpretation
method has been designed and implemented so that it allows
addition of these new data sources. The most difficult problem
is to find good rules which give realistic and objective belief
values based on the different data sources.
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International Archives of Photogrammetry and Remote Sensing. Vol. XXXI, Part B4. Vienna 1996
