![[*]](http://sepwww.stanford.edu/latex2html/prev_gr.gif)
This chapter is a condensation of wave extrapolation and finite-difference basics from IEI which is now out of print. On the good side, this new organization is more compact and several errors have been corrected. On the bad side, to follow up on many many interesting details you will need to find a copy of IEI (http://sepwww.stanford.edu/sep/prof/).
In chapter ![[*]](http://sepwww.stanford.edu/latex2html/cross_ref_motif.gif)
we learned how
to extrapolate wavefields down into the earth.
The process proceeded simply, since it is just a multiplication in the
frequency domain by ![$\exp [ ik_z ( \omega , k_x ) z ]$](img1.gif){kind=small}
.In this chapter
instead of multiplying a wavefield by a function of kx
to downward continue waves,
we will convolve them along the x-axis
with a small filter that represents a differential equation.
On space axes, a concern is the seismic velocity v.
With
lateral velocity variation, say v(x), then the operation of extrapolating wavefields upward and downward can no longer be expressed as a product in the kx-domain. (Wave-extrapolation procedures in the spatial frequency domain are no longer multiplication, but convolution.) The alternative we choose here is to go to finite differences which are convolution in the physical x domain. This is what the wave equation itself does.