ND45 = (TM4 - TM5)/(TM4 + TM5)*128 + 128, 
The image values were generalized for the forest stands 
by computing the mean image value for each stand. 
These computations were performed in a raster-based 
GIS environment. Boundary pixels and known roads 
were omitted from the computations. The computed 
values were stored for each forest stand, as an 
additional attribute in the forest data base. 
The correlation between crown closure and ND45 was 
tested for a set of undisturbed, SE-facing (illuminated) 
forest stands (N=71), and a linear regression function 
was computed and tested for preliminary evaluation. 
Forest stands with a potential for logging were extracted 
from the database and considered as candidates for 
change (N=228). Change detection was carried out by 
robust regression between map attribute crown closure 
and image attribute ND45. The algorithm has been 
described in Baarda (1968). Outliers were automatically 
detected in the regression. Outliers with unexpectedly 
low ND45 values were labeled as logged forest stands. 
4.3 Results and discussion 
It was demonstrated that crown closure and ND45 were 
correlated on a polygon level for undisturbed forest 
stands (figure 7). The regression coefficient for the linear 
regression function was 0.97. The two data sets had low 
correlation on a per-pixel basis. This can be explained by 
the natural heterogeneity of the landscape, and by the 
influence of factors which could not be kept under 
control, such as understory vegetation or secondary 
species in the canopy. 
* 1 std dev 
mean unchanged 
forest stands 
- 1 std dev 
ND(4,5) 
+ 1 std dev 
  
mean logged 
forest stands 
  
90 - 1 std dev 
  
  
Crown Closure Class 
Figure 7. The relationship between crown closure, as 
derived from the map, and ND45, a standwise image 
measure of forest density. The means and the standard 
deviations for undisturbed and logged forest stands 
indicate the separability between the two groups of data, 
for the various crown closure classes. 
10 out of 10 completely (> 60%) logged forest stands in 
the test area were detected, with one error of 
commission. Confusion with rock outcrops and forest of 
low density was avoided. The influence from natural 
spectral variation was minimized. 
388 
Partially logged (< 60 %) were not detected. As 
discussed previously (section 3), standwise image 
means should not be computed for these stands since 
they contain at least two statistically separate 
populations of pixel values. Some clustering algorithms, 
combined with fragmentation index computations were 
tested to initially detect and identify partially logged 
forest stands, with promising preliminary results. 
4.4 Conclusions from the case study 
The polygon-based approach radically reduced the 
problems related to landscape heterogeneity, in 
comparison to multi-spectral classification. In 
combination with the GIS-based sub-selection of forest 
stands, it also reduced the confusion with features of 
similar spectral characteristics. 
The case study underlines the need for improved image 
generalization functions, especially to deal with 
spectrally heterogeneous map polygons. 
A revision system is envisioned where polygon-based 
change detection is the first step. The result, map 
polygons which exhibit strong spectral anomalies, is 
signalled to the operator, who will make the final decision. 
The second step will be semi-automatic geometric 
adjustment of polygon boundaries. Another advantage of 
the polygon-based method is that existing polygon 
boundaries can be used as first approximations in this 
process. Preliminary investigations are being undertaken 
in this area. 
5. OPERATIONAL MAP REVISION 
Currently, semi-automated revision of geographical 
databases from satellite image data requires that raster 
and vector GIS are operated in parallell. The map with its 
attribute database is stored in a vector GIS. It is 
converted from vector to raster format and imported to a 
raster GIS, where it is combined with the image to 
computer generalized image values. These region-based 
values must be exported back to the attribute database 
of the vector-GIS, for integrated analysis with the other 
polygon attributes. 
This situation would hardly be acceptable in an 
operational situation. Too much time is spent converting 
data back and forth, and it is required that parallel 
databases (raster and vector) are maintained. There is 
an apparent risk of introducing errors in the data. 
Several authors (e.g. Star et al., 1991; Ehlers et al., 
1991; Goodenough, 1988) have suggested development 
of high level data management systems or expert 
systems to perform low level tasks such as format 
conversion in a manner transparent to the user. This 
level of integrated analysis, where two systems are 
working in parallell under a common user interface Is 
referred to as "seamless integration" by Ehlers et al. 
(1989). 
Integrated systems should certainly be a development 
goal, but perhaps they lie far in the future. Most 
geographic databases have been created and are being 
maintained in vector systems. In addition, a large number 
of data bases with environmentally related point 
measurements exist (e.g. runoff, precipitation, ground 
water quality), which can be linked to vector GIS based 
International Archives of Photogrammetry and Remote Sensing. Vol. XXXI, Part B4. Vienna 1996 
  
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