Bandung is one of the most densely populated cities in Indonesia with vital infrastructures. On the other hand, this area is surrounded by potential sources of earthquakes that make Bandung vulnerable to earthquakes. Structure of seismic velocity and sediment thickness are crucially needed in the earthquake hazard reduction program for Bandung. Based on this consideration, we deployed 64 seismic stations over the Bandung basin to record seismic ambient noise. In this study, we employed a cross-correlation method to the simultaneously recorded data to retrieve interstation Green’s functions. We measured group velocity of the retrieved Green’s functions by using frequency-time analysis technique. By the end of this project, the set of interstation group velocity will be inverted to image the shallow seismic velocity structure of the Bandung basin and its surrounding areas including Mt. Tangkuban Parahu and Lembang fault. As the first stage of this work, currently we focus on Green ’ s function calculation as well as the interstation group velocity measurements. The general characteristics of group velocity can be evaluated from the plot of cross-correlation function as a function of its interstation distance.

1.
Dam
,
M. A. C.
,
Suparan
,
P.
,
Nossin
,
J. J.
,
Voskuil
,
R. P. G. A.
&
G. T. L.
Group
,
1996
,
A chronology for geomorphological developments in the greater Bandung area, West-Java, Indonesia
.
J. Southeast Asian Earth Sci.
14
(
1–2
),
101
115
2.
Suhari
,
S.
, and
Siebenhüner
,
M.
,
1993
,
Environmental geology for land use and regional planning in the Bandung Basin, West Java, Indonesia
.
Journal of Southeast Asian Earth Sciences
.;
8
:
557
566
.
3.
Claerbout
,
J. F.
,
1968
,
Synthesis of a layered medium from its acoustic transmission response
.
Geophysics
,
33
,
264
269
.
4.
Campillo
,
M.
, and
Paul
,
A
,
2003
,
Long range correlations in the diffuse seismic coda
.
Science
299
,
547
549
.
5.
Snieder
,
R.
,
2004
,
Extracting the green’s function from the correlation of coda waves: a derivation based on stationary phase
,
Phys. Rev., E
,
69
,
046610
, doi:
6.
Shapiro
,
N.M.
,
M.
Campillo
,
L.
Stehly
, and
M.
Ritzwoller
,
2005
,
High Resolution Surface Wave Tomography from Ambient Seismic Noise
,
Science
307
,
1615
1618
.
7.
Saygin
,
E.
, and
Kennett
,
B. L. N.
,
2010
,
Ambient noise tomography for the Australian Continent
,
Tectonophysics
,
481
,
116
125
. doi:.
8.
Zulfakriza
,
Z.
,
Saygin
,
E.
,
Cummins
,
P. R.
,
Widiyantoro
,
S.
,
Nugraha
,
A. D.
,
Lühr
,
B.-G.
, and
Bodin
,
T.
,
2014
,
Upper crustal structure of central Java, Indonesia, from transdimensional seismic ambient noise tomography
.
Geophys. J. Int.
197
,
630
63
9.
Herrmann
,
R. B.
,
1987
,
Computer programs in seismology
, vol.
IV
:
Surface waves inversion
:
St.Louis Univ. Press
.
This content is only available via PDF.
You do not currently have access to this content.