Vectorial nature of georadar data
Details
Serval ID
serval:BIB_CF94F7FE2269
Type
Inproceedings: an article in a conference proceedings.
Collection
Publications
Institution
Title
Vectorial nature of georadar data
Title of the conference
Proceeding of the 8th International Conference on Ground Penetrating Radar, Gold Coast, Australia
ISBN
0819437263
ISSN-L
0277-786x
Publication state
Published
Issued date
2000
Editor
Noon D.A., Stickley G.F., Longstaff D.
Volume
4084
Pages
824-829
Language
english
Abstract
Seismic reflection processing techniques are applied routinely to
georadar data. Although similarities exist between radar and seismic
wave propagation, there are some significant differences (e.g., the
dipole nature of georadar sources, receivers and elemental sources
used to represent scattering bodies). To understand better the consequences
of recording dipolar wavefields, we simulate a number of multi-component
georadar data sets. These simulations are based on a weak scattering
approximation, such that point heterogeneities in the subsurface
can be represented by infinitesimal dipoles with moments parallel
and proportional to the incident georadar wavefields. Since many
subsurface structures can be modeled by appropriate suites of infinitesimal
dipoles, the simulation results are quite general. On the basis of
our simulations, we determine that 'pseudo-scalar' wavefields can
be simulated from coincident georadar data sets acquired with two
pairs of parallel source-receiver antenna, one oriented perpendicular
to the other. Pseudo-scalar georadar data, which are characterized
by low degrees of directionality, can be processed confidently using
standard seismic processing software. To illustrate the advantages
of multi-component georadar data, we combine 3D georadar data sets
acquired with dual component source-receiver antenna pairs to form
pseudo- scalar wavefield images.
georadar data. Although similarities exist between radar and seismic
wave propagation, there are some significant differences (e.g., the
dipole nature of georadar sources, receivers and elemental sources
used to represent scattering bodies). To understand better the consequences
of recording dipolar wavefields, we simulate a number of multi-component
georadar data sets. These simulations are based on a weak scattering
approximation, such that point heterogeneities in the subsurface
can be represented by infinitesimal dipoles with moments parallel
and proportional to the incident georadar wavefields. Since many
subsurface structures can be modeled by appropriate suites of infinitesimal
dipoles, the simulation results are quite general. On the basis of
our simulations, we determine that 'pseudo-scalar' wavefields can
be simulated from coincident georadar data sets acquired with two
pairs of parallel source-receiver antenna, one oriented perpendicular
to the other. Pseudo-scalar georadar data, which are characterized
by low degrees of directionality, can be processed confidently using
standard seismic processing software. To illustrate the advantages
of multi-component georadar data, we combine 3D georadar data sets
acquired with dual component source-receiver antenna pairs to form
pseudo- scalar wavefield images.
Keywords
Ground penetrating radar, Receivers, Simulations, Antennas, Scattering, Software, Wave propagation, Reflection, Radar
Create date
25/11/2013 19:28
Last modification date
20/08/2019 16:50
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