In: Wagner W., Szekely, B. (eds.): ISPRS TC VII Symposium - 100 Years ISPRS, Vienna, Austria, July 5-7, 2010, IAPRS, Vol. XXXVIII, Part 7B
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algorithms combing wavelet transform and IHS transform or
PC A transform. Recently, some authors introduce sensors’
spectral response and ground spectral features into fusion
technology on the basis of previous three categories, and
other authors utilize the regularization method to optimize
the last fusion results so as to satisfy the higher resolution
multispectral image model.
2. COMPONENT SUBSTITUTION
FUSION TECHNIQUE
In general, the Component Substitution fusion Technique
consists of three steps: Step 1, Forward transform is applied
to the multispectral bands after they have been registered to
the panchromatic band; Step 2, A component of the new data
space similar to the panchromatic band is replaced with the
higher resolution band; Step 3, The fused results are finally
obtained via inverse transform to the original space.
The typical algorithms of component substitution fusion
technique are IHS transform fusion algorithm (Carper, 1990,
Shettigara, 1992, Chavez, 1991). This algorithm is suitable
when exactly three multispectral (MS) bands are concerned
since the IHS transform is defined for three components only.
Usually, Panchromatic band (PAN) is histogram-matched,
i.e., radiometrically transformed by a constant gain and bias
in such a way that it exhibits mean and variance that are the
same as Intensity, before substitution is carried out. When
more than three bands are available, Tu et al (Tu, et al, 2004)
present a generalized IHS (GIHS) transform by including the
response of the near-infrared (NIR) band into the intensity
component. The GIHS-GA (Garzelli and Nencini, 2006) is
based on CS strategy and genetic algorithm. The weights of
the MS bands in synthesizing the intensity component and
the injection gains are achieved by minimizing a global
distortion metrics (Q4, in this case) by means of a GA. The
GIHS-TP (Choi, 2006) is a CS-based method that trades off
the performances of GIHS in terms of spectral distortion and
spatial enhancement. Aiazzi et al (Aiazzi, et al, 2007)
introduce multivariate regression to improve spectral quality.
In the method based on IHS, a generalized intensity
component is defined as the weighted average of the MS
bands. The weights are obtained as regression coefficients
between the MS bands and the spatially degraded PAN
image with the aim of capturing the spectral responses of the
sensors. Gonzales Audicana and Otazu (Gonzales Audicana
and Otazu, et al, 2006) present a low computational-cost
method to fuse IKONOS images using the spectral response
function of its sensors. Andreja and Kris v tof (Andreja and O.
Kris“tof, 2006) found that for preserving spectral
characteristics, high level of similarity between the
panchromatic image and the respective multispectral
intensity is needed. In order to preserve spectral and spatial
resolution, spectral sensitivity of multispectral and
panchromatic data was performed, and digital values in
individual bands have been modified before fusion. Malpica
(Malpica, 2007) present a technique which consists of a hue
spectral adjustment scheme integrated with an
intensity-hue saturation transformation for vegetation
enhancement. Ling and Ehlers, et al (Ling, Ehlers, et al,
2007) present a method which combines a standard IHS
transform with FFT filtering of both the panchromatic image
and the intensity component of the original multispectral
image.
Other common used CS-based method, PCA transform,
(Shettigara, 1992, Chavez, 1991) make an assumption that
the first principal component (PC) of high variance is an
ideal choice for replacing or injecting it with high spatial
details from the highresolution histogram-matched PAN
image. Shah, et al (Shah, Younan, and King, 2008) use the
adaptive PCA to reduce the spectral distortion in the fusion
scheme combining adaptive PCA approach and contourlets.
Another CS technique reported in the literature is
Gram-Schmidt (GS) spectral sharpening (Laben and Brower,
2000), which is widely used since it has been implemented
in the Environment for Visualizing Images (ENVI) program
package. Aiazzi et al (Aiazzi, et al, 2007) adopts multivariate
regression to create the synthetic low-resolution-intensity
images which is used in the Gram-Schmidt transform. The
proposed enhanced strategy is effective in improving the
quality of the images than ordinary GS technique.
UNB-pansharp (Zhang, 2002) algorithm developed at the
UNB, Canada, is based on CS. The least squares technique is
utilized to reduce color distortion, by identifying the best fit
between gray values of individual image bands and adjusting
the contribution of the individual bands to the fusion result.
3. MODULATION-BASED FUSION
