TY - JOUR
T1 - Q Inversion and Comparison of Influential Factors among Three Methods: CFS, SR, and AA
AU - Wu , Yinting
AU - Wu , J. T.
JO - Communications in Computational Physics
VL - 1
SP - 356
EP - 371
PY - 2020
DA - 2020/05
SN - 28
DO - http://doi.org/10.4208/cicp.OA-2018-0290
UR - https://global-sci.org/intro/article_detail/cicp/16843.html
KW - Q inversion, centroid frequency shift, amplitude attenuation, spectral ratio, zero-offset VSP data.
AB - <p style="text-align: justify;">The goals of this study were to examine factors influencing Q inversion and
to provide references for practical application. Three different methods for inverting
Q values with VSP data were explored, including centroid frequency shift (CFS), spectral ratio (SR), and amplitude attenuation (AA). Comparison between the CFS and the
other two methods was conducted on frequency band widths and low attenuation,
wavefield components, interface interference, and thin layers. Results from several
sets of VSP modeling data indicated that the CFS method is more stable and accurate
for dealing with thin and high Q layers. Frequency band width, especially the presence
of high frequencies, influences the inversion effect of all three methods. The wider the
band, the better the results. Q inversion from downgoing wavefield was very similar
to that of the upgoing wavefield. The CFS method had fewer outliers or skip values
from the full wavefield than the other two methods. Moreover, the applications to Q
inversion for the set of field VSP data demonstrated that the Q curves from the CFS
method coincided with the geological interpretations better than the Q curves of the
other methods. Meanwhile, inverse Q filtering shifted the frequency component from
25 Hz to 35 Hz. The results demonstrated that the Q curve is more sensitive to geological horizons than velocity.</p>