TY  - JOUR
A1  - Lontsi, Agostiny Marrios
A1  - Jose Sanchez-Sesma, Francisco
A1  - Camillo Molina-Villegas, Juan
A1  - Ohrnberger, Matthias
A1  - Krüger, Frank
T1  - Full microtremor H/V(z,f) inversion for shallow subsurface characterization
JF  - Geophysical journal international
N2  - The H/V spectral ratio has emerged as a single station method within the seismic ambient noise analysis field by its capability to quickly estimate the frequency of resonance at a site and through inversion the average profile information. Although it is easy to compute from experimental data, its counter theoretical part is not obvious when building a forward model which can help in reconstructing the derived H/V spectrum. This has led to the simplified assumption that the noise wavefield is mainly composed of Rayleigh waves and the derived H/V often used without further correction. Furthermore, only the right (and left) flank around the H/V peak frequency is considered in the inversion for the subsurface 1-D shear wave velocity profile. A new theoretical approach for the interpretation of the H/V spectral ratio has been presented by Sanchez-Sesmaet al. In this paper, the fundamental idea behind their theory is presented as it applies to receivers at depth. A smooth H/V(z, f) spectral curve on a broad frequency range is obtained by considering a fine integration step which is in turn time consuming. We show that for practical purposes and in the context of inversion, this can be considerably optimized by using a coarse integration step combined with the smoothing of the corresponding directional energy density (DED) spectrum. Further analysis shows that the obtained H/V(z, f) spectrum computed by the mean of the imaginary part of Green's function method could also be recovered using the reflectivity method for a medium well illuminated by seismic sources. Inversion of synthetic H/V(z, f) spectral curve is performed for a single layer over a half space. The striking results allow to potentially use the new theory as a forward computation of the H/V(z, f) to fully invert the experimental H/V spectral ratio at the corresponding depth for the shear velocity profile (Vs) and additionally the compressional velocity profile (Vp) using receivers both at the surface and in depth. We use seismic ambient noise data in the frequency range of 0.2-50 Hz recorded at two selected sites in Germany where borehole information is also available. The obtained 1-D Vs and Vp profiles are correlated with geological log information. Results from shallow geophysical experiment are also used for comparison.
KW  - Inverse theory
KW  - Interferometry
KW  - Site effects
Y1  - 2015
U6  - https://doi.org/10.1093/gji/ggv132
SN  - 0956-540X
SN  - 1365-246X
VL  - 202
IS  - 1
SP  - 298
EP  - 312
PB  - Oxford Univ. Press
CY  - Oxford
ER  - 
TY  - JOUR
A1  - Lontsi, Agostiny Marrios
A1  - Garcia-Jerez, Antonio
A1  - Camilo Molina-Villegas, Juan
A1  - Jose Sanchez-Sesma, Francisco
A1  - Molkenthin, Christian
A1  - Ohrnberger, Matthias
A1  - Krüger, Frank
A1  - Wang, Rongjiang
A1  - Fah, Donat
T1  - A generalized theory for full microtremor horizontal-to-vertical [H/V(z,f)] spectral ratio interpretation in offshore and onshore environments
JF  - Geophysical journal international
N2  - Advances in the field of seismic interferometry have provided a basic theoretical interpretation to the full spectrum of the microtremor horizontal-to-vertical spectral ratio [H/V(f)]. The interpretation has been applied to ambient seismic noise data recorded both at the surface and at depth. The new algorithm, based on the diffuse wavefield assumption, has been used in inversion schemes to estimate seismic wave velocity profiles that are useful input information for engineering and exploration seismology both for earthquake hazard estimation and to characterize surficial sediments. However, until now, the developed algorithms are only suitable for on land environments with no offshore consideration. Here, the microtremor H/V(z, f) modelling is extended for applications to marine sedimentary environments for a 1-D layered medium. The layer propagator matrix formulation is used for the computation of the required Green’s functions. Therefore, in the presence of a water layer on top, the propagator matrix for the uppermost layer is defined to account for the properties of the water column. As an application example we analyse eight simple canonical layered earth models. Frequencies ranging from 0.2 to 50 Hz are considered as they cover a broad wavelength interval and aid in practice to investigate subsurface structures in the depth range from a few meters to a few hundreds of meters. Results show a marginal variation of 8 per cent at most for the fundamental frequency when a water layer is present. The water layer leads to variations in H/V peak amplitude of up to 50 per cent atop the solid layers.
KW  - Numerical modelling
KW  - Earthquake hazards
KW  - Seismic interferometry
KW  - Site effects
KW  - Theoretical seismology
KW  - Wave propagation
Y1  - 2019
U6  - https://doi.org/10.1093/gji/ggz223
SN  - 0956-540X
SN  - 1365-246X
VL  - 218
IS  - 2
SP  - 1276
EP  - 1297
PB  - Oxford Univ. Press
CY  - Oxford
ER  -