In borehole seismic experiments the presence of the borehole has a significant effect on observations. Unfortunately, including boreholes explicitly in modeling schemes excludes the use of some methods (e.g., frequency‐wavenumber) and adds prohibitively to the cost of others (e.g., finite difference). To overcome this problem, we use the concept of an effective source/receiver array to replace the explicit representation of the borehole by a distributed seismic source/receiver. This method mimics the presence of the borehole at seismic frequencies under a wide variety of conditions without adding a significant computational cost. It includes the effects of dispersive and attenuative tube wave propagation, the generation of secondary sources at interfaces and caliper changes, and the generation of conical waves in low‐velocity layers. Comparison with a finite‐difference scheme with an explicit borehole representation validates the approach. The modeling method applied to a continuity logging geometry demon...
[1]
Tube waves, seismic waves and effective sources
,
1993
.
[2]
Andrew L. Kurkjian,et al.
Numerical computation of individual far-field arrivals excited by an acoustic source in a borehole
,
1985
.
[3]
B. Kennett,et al.
Reflections, rays, and reverberations
,
1974,
Bulletin of the Seismological Society of America.
[4]
T. Marzetta.
Inverse borehole coupling theory and its application to hydrophone vertical seismic profiling
,
1992
.