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A Stable Phantom Material for Optical and Acoustic Imaging
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Published on: June 16, 2023

Virtual reflector representation theorem (acoustic medium).

Flavio Poletto1, Kees Wapenaar

  • 1Instituto Nazionale di Oceanografia e di Geofisica Sperimentale, Sgonico, Trieste. Italy fpoletto@ogs.trieste.it

The Journal of the Acoustical Society of America
|April 10, 2009
PubMed
Summary
This summary is machine-generated.

The virtual reflector method uses recorded seismic data to simulate new signals. This technique generates virtual reflected signals, effectively imaging absent reflectors in seismic exploration.

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Area of Science:

  • Geophysics
  • Seismic Imaging
  • Wave Propagation

Background:

  • Seismic exploration relies on analyzing wave propagation to understand subsurface structures.
  • Simulating seismic responses is crucial for interpreting geological formations and identifying potential resources.
  • Existing methods may face limitations in imaging complex geological scenarios or absent reflectors.

Purpose of the Study:

  • To introduce and detail the virtual reflector method for seismic signal simulation.
  • To provide a theoretical framework for generating virtual reflected signals using recorded seismic traces.
  • To extend the method's applicability to acoustic media with and without boundaries, and to variable reflection coefficients.

Main Methods:

  • The virtual reflector method is based on the cross-convolution of recorded seismic signals from multiple sources and receivers.
  • The theory is grounded in the Kirchhoff integral representation theorem for wave propagation.
  • The method is generalized to account for variable reflection coefficients in scattered wavefields.

Main Results:

  • The virtual reflector method successfully simulates new seismic signals by processing existing data.
  • It enables the retrieval of the Green's function for virtual reflected signals, mimicking the presence of a reflector.
  • The approach is theoretically validated for acoustic media and extended for scattered wavefields with variable reflection coefficients.

Conclusions:

  • The virtual reflector method offers a novel approach to seismic data processing and subsurface imaging.
  • It provides a powerful tool for generating virtual seismic reflections, enhancing the interpretation of geological structures.
  • This technique has the potential to improve seismic exploration by imaging absent or poorly defined reflectors.