EVALUATION OF SATELLITE IMAGE FUSION USING WAVELET TRANSFORM
Oguz Gungor Jie Shan
Geomatics Engineering, School of Civil Engineering, Purdue University
550 Stadium Mall Drive, West Lafayette, IN 47907-2051, USA — (ogungor, jshan) @purdue.edu
Commission III, WG IIV6
Key Words: Fusion, Remote Sensing, Transformation, Multispectral, Spatial, Spectral, Algorithms, Resolution.
ABSTRACT:
This paper addresses the principles, implementation and evaluation of wavelet transformation based image fusion. 2-D discrete
wavelet transformation is presented concisely to facility the understanding of the wavelet based image fusion method. To best retain
the quality of the input images, we propose a strategy that minimizes the necessary resampling operations to limit potential image
quality deterioration. In the proposed fusion approach, the wavelet coefficients for the fused images are selected based on the
suggested maximum magnitude criterion. To evaluate the outcome images, other popular fusion methods including principal
component transformation, Brovey and multiplicative transformation approaches are applied to the same images and the results are
compared to the ones from the wavelet based approach. Fusion results are evaluated both visually and numerically. A quality matrix
is calculated based on the correlation coefficients between the fused image and the original image. It is shown that this quality
measure can indicate the information content of the fused image comparing to the input panchromatic and multispectral images. Our
results clearly suggest that the wavelet based fusion can yield superior properties to other existing methods in terms of both spatial
and spectral resolutions, and their visual appearance. This study is carried out using multiple images over the Davis-Purdue
Agricultural Center (DPAC) and its vicinity with both urban and rural features. Images used include QuickBird panchromatic band
(0.7 m) and multispectral bands (2.7m), and Ikonos panchromatic (1 m) and multispectral bands (4 m).
Principle Component Analysis (PCA), Brovey and
Multiplicative Transformation methods to evaluate the
proposed wavelet transformation approach. Finally, a
1. INTRODUCTION
Image fusion, in. general, can be described as a process of quantitative evaluation criterion is proposed to evaluate the
producing a single image from two or more images that are quality of the fusion outcome.
collected from the same or different sensors. The objective of
the fusion process is to keep maximum spectral information
from the original multispectral image while increasing the
spatial resolution (Chavez et al, 1991; Ranchin et al, 2003).
2. WAVELETS AND WAVELET TRANSFORM
Military, medical imaging, computer vision, robotic industry In this paper, 2-D Discrete Wavelet Transform (DWT) is used
and remote sensing are some of the fields benefiting from the for image fusion process. Wavelet transform is defined as the
image fusion. sum over all time of the signal multiplied by scaled, shifted
version of the mother wavelet y(t). Similar to the Fourier
In the field of remote sensing, lower spatial resolution
is ral images need to be fused with higher resolution A ; :
multispectral images need to b 8 different frequencies, wavelet transform decomposes a signal
panchromatie masses: The fusion techniques should ensure that into the scaled and/or shifted versions of the mother wavelet
all important spatial and spectral information in the input (Misiti, 2002)
images is transferred into the fused image, without introducing
artifacts or inconsistencies, which may damage the quality of
the fused image and distract or mislead the human observer.
Furthermore, in the fused image irrelevant features and noise
should be suppressed to a maximum extent. Image fusion can
be performed at pixel, feature and decision levels according to 272 i
the stage at which the fusion takes place (Pohl and van V un (1) =2 vl t= n) (1)
Genderen, 1998).
analysis that breaks a signal into different sine waves of
In DWT, instead of calculating wavelet coefficients at every
possible scale, the scales and shifts are usually based on power
of two. If we have a mother wavelet,
In this study, a pixel level multispectral image fusion process A signal (1) can be expressed by wavelets as
using wavelet transform approach is performed. The fusion
process is implemented to two categories: images collected by f (= > Con mon (1) (2)
the same sensors at the same time, and images collected by m,n
different sensors. For the same sensors, a QuickBird where m and n are integers (Nikolov et al, 2001). Here,
panchromatic image is fused with QuickBird multispectral PAGS is the dilated and/or translated version of the mother
images. For the different sensors, a QuickBird panchromatic
image is fused with Ikonos multispectral images. Haar and
Daubechies (DB) wavelets are used in this study. For coefficients are needed., These coefficients denote the
comparison purpose, the same images are also fused using approximation of f at each scale. For example a,,, and a,,,,,
wavelet y/ . To implement an iterative wavelet transform dA,
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