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International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, Vol XXXV, Part B7. Istanbul 2004
Figure 3. The number of stories of the buildings in the studied
area
4. GIS STUDIES
4.1 Processing of Seismic Data
Data of the seismic trace obtained at intervals of 1 m were
filtered using the 30-100 Hz band pass filter. Digital filtration is
the most optimum approach to analysing seismic data
(Campanella, R. G. and Stewart, W. P., 1991; Campanella R. G.
et all, 1989). The average shear wave velocity (Vsav) was
determined using the first and the last reference signals.
4.2 Determination of Fundamental Vibration Period Using
GIS
Various techniques have been used in applications of
determination of earthquake risks and micro-zoning based on
GIS in accordance with the variation of the shear wave velocity
(Huntera, J. A. et all., 2002). Map of fundamental vibration
period of the ground (Tj) is one of the maps used for
determining regional earthquake risk that makes use of the
shear wave velocity.
Fundamental vibration period of the ground (T;) is determined
using the following equation.
4xH;
T, a | (1)
where H = the thickness of the alluvial ground focal length
V = the average shear wave velocity
Determination of the fundamental vibration period of the
ground depends on two variables.
l. (Va): A map of the average shear wave velocity was
obtained by using the SCPT technique. The average shear
wave velocity was determined to vary between 100-340
m/s for all the seismic record depth in each of the 32
different points (Figure 4).
1139
Figure 4. Shear wave velocity map of the studied area
2. Thickness of the alluvium (H): A large part of the
studied area is located over a ground composed of the new
alluvium, containing loose gravel, sand, silt and clay,
carried away by the Porsuk River. Electric resistivity
method has been applied in 112 locations by DSI with a
depth of nearly 60 m. (Azdiken S. and Catalyürekli E.,
2001; Azdiken S. and Catalyürekli E., 2001) (Figure 5).
^
1 i ;
Figure 5. Locations of geophysical resistivity measurements
The geophysical measurements obtained revealed that, the
thickness of the alluvium in the studied area varied between 10-
25 m, and that the northern east part reached a thickness
varying between 10-15 and 15-25 due to the over-storage of
materials carried away by the Porsuk River (Azdiken S. and
Çatalyürekli E., 2001; Azdiken S. and Çatalyürekli E., 2001).
A three-dimensional model of thickness of alluvium was
obtained by using geophysical resistivity data. Values of the
thickness of the alluvium scattered across the study area have
been presented in this model (Figure 6).
