04
sic
ial
ral
ey
pre
he
International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, Vol XXXV, Part B7. Istanbul 2004
registered. As for resampling, the Ikonos multispectral images
are resampled from 4m to 2.8m pixel size, which is 2? times
0.7m of the QuickBird panchromatic image resolution and is
the closest number to 4m. In this way, the necessary resampling
is limited to the minimum and the quality of the original image
is best retained in this process. After this preprocessing,
procedures outlined in Figure 2 are followed to conduct the
fusion process. The outcome of this process is four
multispectral images with a spatial resolution of 0.7m.
Original Multispectral Fused Image
Image (Ikonos)
Figure 4. Fusion of QuickBird pan and Ikonos multispectral
images
5.3. Visual and Quantitative Evaluation
5.3.1 Visual Evaluation
For visual evaluation, two approaches are used. First, the
proposed fusion algorithm is evaluated in terms of spatial and
spectral improvements. It is clearly seen from the pictures in
Figure 3 and 4 that the spatial resolutions of the images after
the fusion are improved. In the original QuickBird and Ikonos
images, it is very difficult to discern some physical features like
small buildings. For example, in both multispectral images
there are some circular objects that are very difficult to perceive
whether they are buildings or not. In Ikonos, it becomes even
more difficult, nearly impossible, to see these plants (the blue
circled area).
However, in both fused images, it becomes clear that there are
some circular man-made features, which are most likely silos
that farmers use to store their crops. Also, there is a small road
or water way that can be apparently seen in the fused images
(blue oval), which are not perceivable in the original Ikonos
image. The fused images also keep the original colors that
means that the spectral content of the images are carried to the
fused ones. Therefore, the fused images will significantly
improve the image classification results.
Secondly, as a comparison, the same images are fused also
using PCA, Brovey and Multiplicative image fusion techniques
using Erdas Imagine 8.6. Figure 5 below presents the fusion
results of QuickBird Pan and Multispectral images. It is seen
that these fusion methods also improve the spatial resolution.
1247
But, the colors of the features in the fused images are changed.
This color distortion effect is the largest in Brovey method.
Among these three methods, multiplicative transformation
gives the best result in terms of color conservation. However,
wavelet transform approach is superior to these three results, as
the colors of the features in original multispectral images are
nearly the same in the fused image.
Finally, the images are fused using DB wavelet. As seen from
the Figure 6, the DB wavelet gives a better spatial resolution
when compared to the results from Haar wavelet. This implies
that the selection of different wavelets may affect the fusion
results. In this paper, for its simplicity, fusion results of Haar
wavelet are used for algorithmic description and the
comparisons with the results of other fusion methods in the
visual evaluation part. All correlation coefficients used in
quantitative evaluation part are also calculated using the fused
images with Haar wavelet.
.
s 7
— i Mid
PCA Method
rw
Brovey Mehod Mehod
eu
Lac ; TE ;
Multiplicative Method Multiplicative Method
Figure 5. Fusion of QuickBird pan and multispectral images
using PCA, Brovey and Multiplicative fusion methods.
t
Figure 6. Fusion using Haar (left) and DB 2.2 (right) wavelets.
