International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences. Vol XXXV, Part B2. Istanbul 2004 
  
where s represent sub-band images, acquired from 
stationary wavelet transform. 
4. Updating the membership matrix U. 
, 7-1 
d 2h ey) m-i 
«(bs ul) 
(21 
ven = Fh 
j=i qe di 
  
  
À 
5. Stopif UT! — UU < e , otherwise increase t and go 
to step 3. 
The FCM algorithm is proved to be very well suitable for 
remote sensing image segmentation. But at the same time it 
exhibits sensitivity to the initial guess with regard to both speed 
and stability and also shows sensitivity to noise. 
Figure 4 and 7 are the two- and three-region classification 
results for the images in Figure 4 using this FCM method. 
2.3 Decision Trees 
Another common approach to classification is to use decision 
trees. The decision tree itself is a set of decision rules that 
describe each group's patterns learned from these given 
examples. 
The decision tree algorithm used here is the "Quick, Unbiased, 
Efficient Statistical Trees" (QUEST). The algorithm is 
described in [16] and the performance of this algorithm 
compared with other classification methods can be found in 
[17]. 
Applying the QUEST to the original images in Figure 4 to 
discriminate regions of land and water, Figure 5 gives the 
classification results. The three-region results are plotted in 
Figure 8. 
We must note before applying the above classification 
techniques, denoising method should be applied to the original 
images. In this paper, we use the wavelet denoising method 
combined with simple nonlinear speckle reduction filters (i.e. 
median filters). At first we apply median filtering to the original 
images. Median filtering is a widely used nonlinear process 
useful in reducing impulses, or salt-and-pepper noise. It is also 
useful in preserving edges in an image while reducing random 
noise. The wavelet denoising method is then applied. Wavelet 
transform is a useful tool for the time-frequency analysis of 
signals. From the viewpoint of signal processing, wavelet 
analysis represents a signal by its components in a series of 
independent frequency channels (scales). By analyzing the 
behavior of the signal in each scale, we can find the features of 
the signal or discriminate different parts (such as the noise and 
the useful signal) of the combined signal. Mallat's [11] research 
indicated that the local maximums of the wavelet transform of 
noise and signal have different variation rules with the change 
of the scale. So denoising by wavelet method can be realized by 
observing these local maximums at each scale. A commonly 
used wavelet denoising method proposed by Donoho [12] 
regards the wavelet coefficient below a threshold as noise and 
set them to be zero. 
The results of classifications should be then filtered using 
median and sieve filters to remove noise and all polygons that 
are smaller than a given minimum size, measured in pixels. The 
774 
level of filtering must be chosen adequately to both keep 
small or isolated feature map lines and remove enough grid 
lines and contours that may reduce the feature visibility. 
Comparing the classification results using these three 
different techniques. it is easy to find that the classified 
images in Figure 3 and 6 using thresholding method are the 
clearest. The FCM algorithm is very noise sensitive. The 
images in Figure 4 and 7 present a lot of salt-and-pepper 
noise. Since in this example the images are single band/ the 
decision tree method is very similar to the thresholding 
method. By analyzing the training data, a tree is structured 
with the pixel value being the only split variable for each 
node. It is like using the sample data to find the threshold and 
then do the thresholding classification. The performance of 
the decision tree method depends on the accurateness of the 
sample data and is more sensitive to the additive noise than 
the thresholding technique. Among these three methods, the 
FCM algorithm is the most automatic one, which doesn't 
need the training data, but at the same time, gives the worst 
results. 
For the multi-spectral, hyper-spectral or multi-polarized 
images, classification may be done using matched filter [3]. 
[5-7] or matched subspace filter. 
3. CREATION OF LAYERS 
"Layers" can be defined as images containing part of the 
information of the original image. For example, for a multi- 
band image, each band can be viewed as a layer. The mean of 
all the bands can be also viewed as a layer. Applying the 
Principle Component Analysis (PCA) to the multi-band 
image, the images generated by the principle components are 
also the layers of the original image. Another example of 
layers is applying the orthogonal decomposition to the 
original image, the resulting orthogonal components are the 
layers of the image. Saying a set of layers are "complete" 
means the original image can be fully generated using this set 
of layers. 
The layers are generated based on the user's need. Each layer 
should contain only part of the information of interested. 
Normally, compared with the original image, each layer 
contains less information, so it's easier to perform the 
calculations, transformations based on layers. Furthermore, in 
some cases, only parts of the layers are useful such as in 
image fusion by PCA. 
For the topographic change detection, we are interested in the 
region changes for different time, so the layers we used in 
this paper are based on the region classifications. Each layer 
contains only one region of the original image. In Figure 6, 
cach image contains three regions that are land, shallow 
water and deep water. These regions should be extracted one 
by one to generate the layers. Figure 9 shows the 
corresponding layers of both images. The images in red are 
the layers of the image taken in May, and the layers taken in 
August are plotted in green. (a) and (d) are the layer-of-land 
with land represented in red/green. In (b) and (c), except the 
regions of shallow water, all the others are in black. So they 
are the layer-of-shallow water. Similarly, (c) and (f) are the 
layers-of-deep water. 
Internati 
4. TOP 
4.1 Ch: 
Topograj 
surface | 
topograp 
present a 
automati 
level cla 
where S;. 
contours. 
same reg 
changing 
are name 
region S 
change ( 
additions 
p- 
y = 
D° = 
49 = 
where th 
represent 
advantag 
In a log « 
changes | 
In the fo 
cases an 
processir 
updates 
over time 
For the 
interestec 
deletion. 
presentec 
interest i 
values "| 
idea is ci 
one. Nar 
each pair 
our previ 
the S i 
I, the con 
ST 
R, 
where tl 
multiplic 
which is 
In this wi 
ti) / 
A," z( 
and the d 
Di =