AN EDGE DETECTOR BASED ON WIDE-NARROW MORPHOLOGICAL OPERATIONS
OF SATELLITE REMOTE SENSING IMAGES
Makoto KAWAMURA, Toyohashi University of Technology, JAPAN
Yuji TSUJIKO, Fukui National College of Technology, JAPAN
Sanath JAYAMANNA, Toyohashi University of Technology, JAPAN
Commission Il!, Working Group 3
KEY WORDS: Remote Sensing, Classification, Extraction, Algorithm, Edge, Landsat
ABSTRACT
In a classification of satellite remote sensing data, spectral distribution in a feature space is usually used.
However, MIXELs at class boundaries cause miss-classification results. To solve this problem many
researchers have carried out increasing the feature space dimensions by giving additional information. In
this study, we describes the method creating additional information mentioned above. In particular, a
new Wide-Narrow Morphological Edge Detection (WNED) algorithm to make edge information is
introduced. WNED differs from previous morphological edge detectors in that it manipulates two
conventional minimum-based operations in the target domain at the same time. As the results of a case
study for Landsat TM data it is found that WNED algorithm is effective to extract edge information clearly
and it can control the detection of the spurious edge information.
1. INTRODUCTION
Remote sensing technology has contributed in
assisting to make accurate maps timely, widely
and economically. A large number of studies have
introduced the effectiveness of satellite remote
sensing data and ifs applicabilities for the
monitoring. In the land cover classification,
however, mixed pixels (mixel) which are laid
among some categories produce the
miss-classification outpts. To extract or to avoid
these pixels, many researchers have tried to detect
edge pixels using conventional segmentation
methods such as convolutional filterings. Recently,
there are some cases using mathematical
morphology to execute the segmentation
(Kawamura, 1994 and 1995)). This study also
describes the segmentation method in terms of
edge detection to improve the classification
accuracy using mathematical morphology. In
particular, a new algorithm to make accurate and
clear edge information is introduced.
Theoretical background of mathematical
morphology was established at the Centre de
Morphologie Mathematique in France, in the mid
1970's (Matheron, 1975) and extended to
application for image processing (Haralick, 1987).
It is also well-known that image shape features
such as edges, fillets, holes and skeletons can be
obtained by combining morphological
fundamental operations and structuring elements.
In this study, the combination of morphological
International Archives of Photogrammetry and Remote Sensing. Vol. XXXI, Part B3. Vienna 1996
fundamental operations and structuring elements
is focused.
2. MORPHOLOGICAL OPERATION
Morphological operations are classified in a binary
morphology and a gray-scale morphology. Usually
satellite remote sensing data are given as
gray-scale image. Therefore this analysis describes
the gray-scale morphological operations. The
gray-scale morphological operations can be
defined as follows. Let f(x) and k(x) be 1-dimesional
gray-tone functions of coordinate x, where f(x) is
the original remote sensing image, and k(x) is the
operator (filter) called structuring element. Let E
represent Euclidean space. Then f:F?E and k:K—E.
The dilation and the erosion operations are defined
as follows:
dilation : (f®k) (x)=max{f(x-z)+k(z)}=d(x)
VzC€K, xzC€F (1)
erosion : (fO k) (x) »min(f(x*z)-k(z))&a e(x).
VzCK, xvz€F (2)
The opening and closing operations can be
defined in terms of dilation and erosion operations
as follows:
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