1. IntroductionThe Taisetsu mountai

1. Introduction
The Taisetsu mountains consists of many quaternary volcanic
mountains over 2000 meters. The eruption of about
30,000 years ago formed Ohachi caldera and the last eruption
is estimated about 500 to 600 years ago forming the
explosion crater at the western flank of the mountains. The
steaming activity of Mt. Asahidake is still active at present.
The 1988 eruption of Mt. Tokachidakewas phreatomagmatic
with a pyroclastic flow of about 1 km. In case of the 1926
eruption the massive debris/mud flow caused a large disaster.
The volcanic activity of Mt. Tokachidake is in the alert
watch level (Monthly Report on Earthquakes and Volcanoes
in Japan, 2000).
The mountain chain is a part of the complicated structure in
and near Japan with the interaction among Okhotsk, Pacific,
and Eurasia plates (Fig. 1). In contrast to the volcanic activity,
the seismic activity in this region is unexpectedly low
(Fig. 2). This coincides with the small crustal deformation in
the central part of Hokkaido (Tada and Kimura, 1987). The
seismic activity and tectonics have to be investigated more in
detail to understand the complex plate configuration in this
region.
The triangulation survey has been conducted by Geographical
Survey Institute of Japan (GSI). Crustal deformation by
the survey is characterized by the northwestern movement in
the eastern side and by the southeastern in the western side
of the Taisetsu mountains (Tada and Kimura, 1987). This
is generally consistent with the crustal deformation by the
GPS measurement in the surrounding region of the mountain,
which has been conducted by GSI in the last few year
(GSI, 1999).
There are not enough GPS survey-data at the mountainous
Copy rightc The Society of Geomagnetism and Earth, Planetary and Space Sciences
(SGEPSS); The Seismological Society of Japan; The Volcanological Society of Japan;
The Geodetic Society of Japan; The Japanese Society for Planetary Sciences.
area to retrieve the present deformation. Our primary purpose
is to know the precise/temporal crustal deformation in
the mountain chain, which would not be made by analyzing
the ten-year interval traditional survey and not by the GPS
measurement in the surrounding region carried out by GSI.
2. Observation and Data Analysis
Table 1 summarizes the GPS survey in the Taisetsu mountains
we have made in 1998 and 1999. We made the GPS
survey three times. Each survey with three to five members
took three days except for the last one in Table 1. Usually
there is a bench mark used in the triangulation survey by GSI
at the mountain peak. The one at Mt. Kurodake has been
destroyed because of the collapse of the peak-cliff and some
are heavily displaced because of the frost heaving. Otherwise
the bench marks at the peaks are measured by GPS using
tripods.
GPS data acquisition at each observation has been made
for more than three hours at every thirty-second interval. We
have analyzed the obtained data using Bernese GPS Software
Version 4.0 (Rothacher and Mervert, 1996) with IGS precise
ephemeris and International Earth Rotation Service (IERS)
Bulletin-B earth rotation parameters.
Kamikawa GPS station of GSI is one of the closest to
our surveyed area and its continuous data is available. The
coordinate of Kamikawa in the IERS Terrestrial reference
frame (ITRF) 96 is evaluated relative to Tsukuba (TSKB) IGS
global tracking station. The coordinates at each summit peak
are evaluated referring to the Kamikawa’s. The advantage to
analyze L1 and L2 band data is to evaluate the correction of
the delay due to the ionosphere. Since the baseline lengths
between Kamikawa and our GPS sites are about 10 km, the
delay on the measurementswould be the same. Therefore, we
have used only L1 data for the analysis. Since this excludes
noisy L2 band data, the estimation error is usually reduced.
Tropospheric delays are estimated at each station in every
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