ood
Reference classes Reference classes
Class Water | Field | Forest | Urban | Open | Total Class Water | Field | Forest | Urban | Open | Total
Water 7 0 0 0 0 7 Water 7 0 0 0 0 7
Field 2 52 6 2 3 65 Field 2 53 1 0 3 39
Forest 0 1 9 0 0 10 Forest 0 0 14 1 0 15
Urban 2 7 1 13 5 28 Urban 2 7 1 14 5 29
Open 0 1 0 2 17 20 Open 0 1 0 2 17 20
Total 11 61 16 17 25 130 Total 11 61 16 17 25 130
Table 5. Confusion matrix of the segment-based Maximum
Likelihood classification.
4.2 Rule-based postclassification
Table 6 presents the confusion matrix of the rule-based
classification when also this classification was based on
segments. When the rule-based classification was pixel-based,
the confusion matrix presented in Table 7 was obtained. The
result of the pixel-based classification is presented in Figure 5.
It should be noted that segments had been interpreted in the
Maximum Likelihood classification stage also in this case.
Reference classes
Class Water | Field | Forest | Urban | Open | Total
Water 7 0 0 0 0 7
Field 2 52 2 1 3 60
Forest 0 1 13 1 0 15
Urban 2 7 1 13 5 28
Open 0 1 0 2 17 20
Total 11 61 16 17 25 130
Table 6. Confusion matrix of the segment-based
postclassification.
Forest
Figure 5. Result of the pixel-based postclassification.
Table 7. Confusion matrix of the pixel-based postclassification.
The mean accuracy and the total accuracy of the classifications
are presented in Table 8. In addition to the classifications
discussed above, a pixel-based Maximum Likelihood
classification was made to allow evaluation of usefulness of the
segmentation as a preprocessing operation.
Classifications
Class 1 2 3 4
Water 47% 78 9o 78 % 78 %
Field 78 % 83 % 86 % 88 %
Forest 69 % 69 % 84 % 90 %
Urban 32% 58 % 58 % 61 %
Open 72 % 76 % 76 % 76 %
Total 67 % 75 % 78 % 81 %
Table 8. The mean accuracy and total accuracy of different
classifications. Column 1 is the pixel-based ML-classification,
column 2 is the segment-based ML-classification, column 3 is
the segment-based ML-classification followed by the segment-
based postclassification and column 4 is the segment-based
ML-classification followed by the pixel-based
postclassification.
5. DISCUSSION AND CONCLUSIONS
The rule-based postclassification improved the interpretation
results, especially when it was pixel-based. The biggest changes
in the postclassification occurred in the hilly areas where some
forests had been misclassified as field in the preclassification,
and on the other hand in the flat area where some fields had
been misclassified as forest. Some of the forest and field areas
are very similar in the spectral space which causes the errors in
the Maximum Likelihood classification. For interpretation of
these classes, the old land use data and height data are very
useful. It improved the result both in the pixel-based and in the
segment-based postclassification.
A very remarkable change in the pixel-based postclassification
was that the numerous narrow canals of the old land use map,
which were missing in the segment-based Maximum
Likelihood classification, appeared in the results. This change
cannot be seen in the error matrices because of the small
number of reference points available for the accuracy
evaluation. When the postclassification was segment-based, the
canals were also missing in the final result because of errors in
the segmentation stage.
Mixels and errors in the segmentation cause a basic error which
is impossible to remove in the interpretation stage. A big
problem in the study area is that many features are too small to
be reliably detected in Landsat TM images. For instance, the
width of many canals is about one pixel or less and thus the
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International Archives of Photogrammetry and Remote Sensing. Vol. XXXI, Part B4. Vienna 1996
