IS, Vol. XXXVIII, Part 7B
In: Wagner W., Szekely, B. (eds.): ISPRS TC VII Symposium - 100 Years ISPRS, Vienna, Austria, July 5-7, 2010, IAPRS, Vol. XXXVIII, Part 7B
49
VHRR data
VHRR data
t orient classification is
.lgorithm does not only
but also on pixel spatial
channel means, standard
The Sixteen components
in this study. The five
itellite images (primary
imponents such as albedo
bands , solar zenith and
iperature (LST) & Sea
Normalized Difference
ation of nadir and cloud
components use directly
> on classification. The
ected in this study. This
on and a knowledge-free
this method the used
eratures of band 4 and 5
1, whereas the Digital
ST and NDVI that show
i by 0.2 (Gottsche and
h medium area and more
y medium scale of 50 is
in (level 1 that called
using infrared or albedo
l classification technique,
relationship between cold
rnds were also used to
lows the multiresolution
Figure3. Multiresolution segmentation in analysis level
In remote sensing studies we cannot detect a specific cloud in
a range of Digital number in visible or infrared images
exactly. For example, the cumulonimbus clouds (Cb) in each
region and time can are detected with various range of digital
number. But studies show that this type of cloud is brighter
than others in VIS and IR images or stratus clouds (St) are
darker than others in IR images. The other types of clouds
can were detected similarly that is showed in figure 4 but
texture, shape and thickness of clouds are useful option for
decision. Figure 4 is the principle of bi-spectral technique in
this study.
Figure4. Brightness of each type of clouds in VIS and IR
images.(Ito ,2000)
3. RESULTS AND DISCUSSIONS
In this study 8 classes were identified that were included a
non-cloud class (sea and terrain) and 7 cloud classes (Ns, Ci,
Cb, Cu, Cg, Sc, St). After detecting of classes and scrutiny of
features (mean, standard deviation, to super object, shape
(area and density) and texture (homogeneity, contrast and
entropy), classification was carried out. The nearest neighbor
classification of level 1 object was performed for mean and
standard deviation of AVHRR channels of 1, 2 and 4. The
relationships between objects were included in the
hierarchical classification for getting the better results. The
classifications of clouds were performed in level 2 called
cloud level. The result of classification illustrated in figure 5.
El ■
classes
^ cirrus
(3 cumulonimbus
^ cumulus
(3 cumulus congestus
(3 nimbo stratus
Q no douds(sea&terrain)
HI strato cumulus
4) stratus
Figure 5. Classified clouds with eCognition
Since the detected cloud in sky of each area is the dominant
cloud on that hour and the other type of clouds may be
existed during the day, so collecting of control points for
accurate assessment is not possible. So, the regions that have
the most adaptation with bi-spectral cloud classification
theories were used as training samples optically.
The NIR and IR channels 3, 4, and 5 of the data were
processed for temperature and brightness. In IR image cold
clouds are high clouds, so the colors typically highlight the
colder regions Mid height clouds with TB below 230k were
identified as cumulonimbus cloud. Darker clouds in IR
images were associated to warm stratus, Strato cumulus,
cumulus clouds and thin cirrus cloud that were colder than
others. Using this knowledge and bi-spectral technique, the
sampling areas were selected and error matrix and kappa
coefficient performed using TTA MASK in eCognition
software. The obtained kappa coefficient was equal of 0.887
and the overall accuracy is 0.905 that illustrate the accurate of
classification is high. The window of error matrix based on
TTA Mask is showed in figure 6.
Figure 6. Error matrix based on TTA Mask
4. References
Billa, L, Mansor,Sh, Mahmud ,A.R, Ghazali ,A,H, 2004.
Integration of RS, GIS and MIKE 11 Hydrodynamic
Modeling for Flood Early Warning: A case study of the
