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International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, Volume XXXIX-B4, 2012
XXII ISPRS Congress, 25 August — 01 September 2012, Melbourne, Australia
Materials used:
1) Scenes from WorldView-II sensor obtained in June 10^
2010, with off-nadir angle 16° and 11 bits radiometric
resolution, delivered by DIGITALGLOBE.
2) Vector files of blocks in the databank of Säo Luis, from the
city planning agency.
3) GCPs collected during Field survey in August 2011 with
TOPCON Hiper L GPS geodetic equipment.
4) Contour lines in vector format, 1 m equidistance of contours,
for the Sáo Luis region.
The following software was used for image processing: ENVI
4.7 (ITT, 2009), for fusion and preparation of both test sites:
PCI Geomatics V10.3.1 (PCI Geomatics, 2010) to work with
the Digital Elevation Model and control points, followed by
WorldView-2 image orthorectification, InterIMAGE v1.27
(InterIMAGE 2010) and GeoDMA for the exploratory analysis
of image attributes and land cover classification.
Ortho-rectification was performed in order to correct for image
distortions. In order to accomplish this task, Ground Control
Points were collected using a DGPS (Differential Global
Positioning System). The GCPs were collected on the entire
scene (Figure 5).
The NDVI was used routinely to calculate the relation NIR -
RED/NIR + RED for the determination of vegetation covered
areas according to ROUSE et al (1974).
In order to evaluate the performance of the additional bands
from WorldView-II, image classications were made with the
following procedure:
Y Considering only the four bands corresponding to
those found at most high resolution satellites, namely
blue, green, red and near infrared;
Y Including all 8 bands of WorldView-II;
Y Using only bands Red and Near infrared 1 to
demonstrate the capacity — for vegetation
discrimination of those bands available traditionally;
Y Inserting bands Red edge and Near infrared 2, to
demonstrate the capacity for target discrimination at
these new spectral bands;
Y Testing bands Coastal, Yellow and Red Edge on
decision rules to improve class separability.
By visual classification, confusion matrices were tabulated for
each of the above mentioned classifications, and the respective
Kappa indices calculated.
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Figure 5: Distribution of GCPs in the area under study.
4. RESULTS
One of the most important results indicates that Red Edge
(705-745nm) band is sensitive to different spectral behaviour
of vegetation types, which can be due to its localization on the
electromagnetic spectrum corresponding to the end of
absorption of wavelengths red and beginning of infrared by
vegetation. So it is interesting to calculate the NDVI using this
band instead of the red one, which is normally used.
Figure 6 shows the NDVI images from the area under study
using both Red and Near infrared 1 bands as well as Red Edge
and Near Infrared 2. Analyzing visually these images,
enhanced by a color scale where the lowest NDVI values are in
blue and the highest in red tones, one verifies the capacity of
the new WorldView-II bands to differentiate vegetation types
Semi-evergreen Tropical Forest (A) and mangrove (B). For
further details see SOUZA et al. (2011).
Red & Near Inf. 1 Red Edge & Near Inf. 2
Figure 6: NDVI images from area under study: (A) Semi-
evergreen Tropical forest, (B) Mangrove.
An analysis was made to quantify the improvement by the new
WorldView-II bands mentioned, based on four classifications
in the area under study and considering the respective
confusion matrices compared to a visual reference
classification and the Kappa indices for each classification
(Figure 7).
