International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, Vol XXXV, Part B2. Istanbul 2004
analysing multitemporal SAR images. The applicability and
efficiency for updating of various spatial data was evaluated.
2. MATERIALS AND METHOD
2.1 Study Site and Image Data
JERS-1 SAR images were used in this study. The JERS-I
satellite was operational between 1992 and 1998 and it had a
repeat cycle of 44days. JERS-1 has already finished its mission,
and the launch of a successor satellite (ALOS) is planned in
2004. This study is setting its sights on the practical use of
ALOS/PALSAR data, and the method will be applied to
ALOS/PALSAR after development based on JERS-1/SAR. The
JERS-1/SAR sensor is quite suitable for the purpose of this
study, because of the sensor's stable periodicity of data
acquisition. The periodicity of data from these sensors is about
1.5 months, which is satisfactory when compared to the
frequency of updating spatial data (1-5 years) in general.
Kanagawa prefecture, Japan, was selected for the study site.
The reason for this was that Kanagawa prefecture has
appropriate characteristics as follows: a) There are various
geographical characteristics (e.g. urban areas, agricultural areas,
mountainous areas and water areas), and b) The area is located
on the urban fringe of Tokyo. Figure 1 shows a comparison of
data acquisition ratio between JERS-1/SAR and JERS-1/VNIR.
It is clear that optical sensor image has a limitation for
periodical monitoring.
2.2 Method
There are two types of features on the land surface. One is a
changing features and the other is an unchanging features. The
changing features can be further divided into stationary changes
and nonstationary changes. The change in the agricultural area
is an example for stationary change. The agricultural area
changes its land surface in a certain cycle according to the stage
of farming, such as seeding, growing, and harvesting. These
changes are stationary as the land use does not change, and they
should not be a trigger of updating for land use data. On the
other hand, nonstationary change occurs randomly and
suddenly most of the time. Nonstationary change can be
explained by taking urban development and natural disasters as
an example. Most of nonstationary changes require data
updating, while stationary changes often do not. The rule for
updating spatial data depends on the characteristic of each
thematic data. The rule is decided mainly by the stationarity of
the land surface change. Therefore, these two types of changes
have to be considered as completely different changes. The
method focused on the role of a support tool for making
decisions as to whether or not the spatial data should be updated.
Generally, changes of the feature are extracted by subtraction of
two data sets having different time stamps. However, these
methods based on pairs of data cannot tell whether the changes
are stationary or nonstationary. Stationarity of change can be
observed correctly only when data is archived in for a long
enough time, periodically, and frequently enough. This
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Figure 1. Comparison of data acquisition ratio between JERS-1/VNIR and JERS-1/SAR
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