multivariate data set consisting of intercorrelated
spectral bands into an uncorrelated data set, with a
geometrical dimension less than the geometrical
dimension of the original multispectral image,we
applied this technique on LANDSAT MSS images,
and we verified the signal - to - noise ratio theory
(Santiesteban & Munoz - 1978).
t
Fig.7. Landsat TM - 1989 image(left), compared to SAR - ERS - 1
(right) showing the morphological changes of the Sacalin Island.
4.3. The new image band, the first principal
component, is used in image enhancement, for
change and edge detection. For edge detection we
have used a photogrammetric technique described
in the following:
- considering the remote sensing image as a
"positive image " we compute its " negative " by
subtracting from an established maximum grey
level the grey level values of every pixel;
- adding the "positive image" to this "negative",
shifted with one line and one column, we obtain the
edge of the phenomena appearing in the remote
sensing image.
4.4 Classification of different turbidity level waters:
(a) a bitmap has been drawn, by thresholding the
MSS 7 band in - between 0-4 grey level values and
TM 5 band in - between 1-16 grey level values.
Fig.8. Classification of the different turbidity level waters on the
Landsat MSS image of July 1975.
The best spectral bands to detect the suspended
sediment concentration are the MSS 4, 5 and TM 1,
2, 3; the MSS 6 is adequate for chlorophil pigment
detection; (b) an unsupervised classification Was
performed (ISOCLUS program, together With
extracting the spectral signature for each class;
(c)the spectral signatures obtained were used for à
maximum likelihood classification (MLC program);
(d) an average filter (FAV) and a modal filter
(FMO) were used for eliminating the "striping" type
noise.
For each of the 2 images classifications (see fig. 4,
fig.5) the confusion matrices were drawn; the
maximum confusion values obtained were 87-88%
- An interpretation of the two classified images can
be performed having the meteorological conditions
in the moment of the images acquisition: for the
Landsat TM image (fig. 4) the N-NE wind direction
and 10 m/s speed, can explain the narrowing and the
direction of the suspended sediments plume (lower
part of fig.4), as well as merging of the waters with
different turbidity - upper part of fig.4. In the
Landsat TM classified image, both of these
suspended sediment plumes were much enlarged
and the different turbidity level classes very well
separated, in good correlation with the wind
direction and speed (W,2 m/s).
- Atmospheric corrections were performed on the
TM 6 thermal band, in order to extract temperature
information (ATCORT O program); the grey levels
were transformed into grey levels, corresponding to
temperatures, after the atmospheric correction - see
fig.6.
- Isodensity lines were drawn (fig.9) over the
Landsat MSS, following the algorithm:
= 2 T
I TR x
^ 2 3 >
he Zn >
E
a 5
T Jd
Fig.9. Isodensity lines over the Landsat MSS image, separating the
calsses of water with different turbidity levels.
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International Archives of Photogrammetry and Remote Sensing. Vol. XXXI, Part B7. Vienna 1996
