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When a ray travels in a depth-stratified medium,
Snell's parameter is constant along the ray.
If the ray emerges at the surface,
we can measure the distance x that it has traveled,
the time t it took, and its apparent speed dx/dt=1/p.
A well-known estimate for the earth velocity contains this apparent speed.
| |
(18) |
To see where this velocity estimate comes from,
first notice that the stratified velocity v(z) can be parameterized
as a function of time and take-off angle of a ray from the surface.
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(19) |
The x coordinate of the tip of a ray with Snell parameter p is
the horizontal component of velocity integrated over time.
| |
(20) |
Inserting this into equation (18)
and canceling p=dt/dx we have
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(21) |
which shows that the observed velocity is the ``root-mean-square'' velocity.
When velocity varies with depth,
the traveltime curve is only roughly a hyperbola.
If we break the event into many short line segments where the
i-th segment has a slope pi and a midpoint (ti,xi)
each segment gives a different and we have the unwelcome chore of assembling the best model.
Instead, we can fit the observational data to the best fitting hyperbola
using a different velocity hyperbola for each apex,
in other words,
find so this equation
will best flatten the data in -space.
| |
(22) |
Differentiate with respect to x at constant getting
| |
(23) |
which confirms that the observed velocity
in equation (18),
is the same as no matter where you measure
on a hyperbola.
Next: Layered media
Up: CURVED WAVEFRONTS
Previous: CURVED WAVEFRONTS
Stanford Exploration Project
12/26/2000