AVO - Shuey's Approximation

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AVO - Shuey's Approximation

From Mavko (2000) we have, P-wave reflectivity versus angle:

$\begin{displaymath} R(\theta)\approx R_{0}+[ER_{0}+\frac{\Delta v}{(1-v)^{2}}]\s... ...1}{2} \frac{\Delta V_{p}}{V_{p}}[\tan^{2}\theta-\sin^{2}\theta]\end{displaymath}$ (10)

$\begin{displaymath} R_{0}\approx \frac{1}{2} (\frac{\Delta V_{p}}{V_{p}} + \frac{\Delta \rho}{\rho})\end{displaymath}$ (11)

$\begin{displaymath} E=F-2(1+F)\frac{1-2v}{1-v}\end{displaymath}$ (12)

$\begin{displaymath} F=\frac{\frac{\Delta V_{p}}{V_{p}}}{\frac{\Delta V_{p}}{V_{p}}+\frac{\Delta \rho}{\rho}}\end{displaymath}$ (13)

Empirical relations for estimating V_s from V_p Mavko (2000)

1\|c\|Lithology	1\|c\|a_i2	1\|c\|a_i1	1\|c\|a_i0
Sandstone		0.80416	-0.85588
Limestone	-0.05508	1.01677	-1.03049
Dolomite		0.58321	-0.07775
Shale		0.76969	-0.86735

Castagna et al. (1992) relation used in this work is

V_s=a_i2V_p²+a_i1V_p+a_i0
(14)

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Stanford Exploration Project
9/5/2000