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Bottom Topography Observation in the Intertidal Zone Using the Camera Monitoring System
TAERIM KIM
School of Ocean Applied Science & Technology , Kunsan University, SAN 68, Miryong-Dong Kunsan 573-701 KOREA E-mail:
trkim @kunsan.ac.kr
Commission PS, WG VII/6
KEY WORDS: Orthoimage, Monitoring, Bathymetry, Measurement, Change Detection, Oceanography
ABSTRACT:
The intertidal zone is characterized by periodic exposures to water level changes between high and low tides. Time series of
waterline changes during a flood/ebb cycle can be utilized for supplementary data for measuring bottom topography. The waterlines
extracted from consecutive images are substituted for depth contours using water level data. The distances between contours are
quantified through a rectification image process.
This technique is applied to the western coastal regions of Korea. This coastal area is famous for high tidal ranges over 7 meters
and very mild slope expanding the intertidal mud flat for several kilometers. The traditional bottom topography measurement
method is very difficult to apply in these regions because of the very mild slope and muddy environment.
A camera monitoring technique supported by natural water level changes produces bottom topography with high precision. It is
also less time consuming and more economical. The technique can be utilized effectively to the physical modeling for measuring
bottom changes in three dimensional basin.
1. INTRODUCTION
The man-initiated coastal development is increasing
recently and provokes rapid changes of environments in coastal
area by losing its equilibrium maintained for a long period in
nature. These undesirable impacts to the coastal environments
also occur in a wide area of mud flat in the intertidal zone
caused by large scaled reclamation projects or construction of
embankment around ports. The mud flat region has been
regarded as very stable condition and not experiencing high
external forces compared to the sand beach. However, the
issues generated by the change of mud flat environments
demand regular and longterm monitoring of the coastal
environment with the immediate remedies against the loss of
the flat. Especially, the mud flat area is now revaluated as
an important place ecologically and economically, and
received nation wide interest for the preservation of that area,
which has been deserted for a long time. In addition to the mud
flat, sand beaches are also experiencing serious erosion
problems being covered by shovels or mud and losing their
merit as a resort.
Intertidal zone is the region that is above the low-water
mark and below the high-water mark, and only exposed during
lowest tides. The mild slope of these regions makes it difficult
to measure the bottom topography and sometimes the soft mud
flat is dangerous place to survey. Because of these reasons, the
traditional in-sifu measurements on the intertidal topography
was done only at the small number of fixed points and had
difficulties to figure out quantitatively the characteristics of
wide region in the intertidal zone. Especially, considering a
very little morphological changes of mud flat, new observation
technique for the wide area of mud flat in the intertidal zone is
needed. Also, in terms of numerical model, there is not enough
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data for the comparison between the model results and the field
data on the bottom changes in the intertidal zone.
The advancement of digital imaging technique with remote
controlling system makes it possible to use a camera for
monitoring many kinds of natural phenomena. It has an ability
to look spatial features and is more intuitive. In recent years,
the camera observation including satellite remote sensing is
begun to be used for monitoring longterm shoreline changes in
several countries. However, in a case of west coast of Korea,
the wide range of intertidal zone and the continuously changing
flood lines are regarded as shortcomings for image observation
of shoreline changes. Theses shortcomings can be converted to
very valuable conditions for measuring the topography in the
intertidal zone. The rising of boundary lines between water
and land during the flood indicates depth contours from the
lowest waters to the highest waters. By extracting the contours,
we can construct three dimensional bottom topography in the
intertidal zone and monitor morphological changes.
In this research, new technique for the observation of
bottom topography in the intertidal zone is introduced with
some examples.
2. METHOD
This technique includes three important steps to configure
three dimensional topography from time series image data.
The first one is to extract boundary lines between water and
land from time series image data during a flood. The second
one is to estimate the depth of each flood lines extracted from
images.
