Among different discretization approaches, Finite Difference Method (FDM) is widely used for acoustic and elastic full-wave form modeling. An inevitable deficit of the technique, however, is its sever requirement to computational resources. A promising solution is parallelization, where the problem is broken into several segments, and the calculations are distributed over different processors. For the present FD routines, however, such parallelization technique inevitably needs domain-decomposition and inter-core data exchange, due to the coupling of the governing equations. In this study, a new FD-based procedure for seismic wave modeling, named as ‘Modal Finite Difference Method (MFDM)” is introduced, which deals with the simulation in th...
Seismograms (i.e., recordings of seismic waves that propagate through the earth) can be used to unco...
Frequency-domain finite-difference (FDFD) modeling offers several advantages over traditional timedo...
The finite-difference method is among the most popular methods for modelling seismic wave propagatio...
textOur knowledge of elastic wave propagation in general heterogeneous media with complex geological...
Realistic applications of numerical modeling of acoustic wave dynamics usually demand high-performan...
International audienceWe accelerate a three-dimensional finite-difference in the time domain (FDTD) ...
The staggered-grid finite-difference (FD) method is widely used in numerical simulation of the wave ...
Finite difference methods for solving the wave equation more accurately capture the physics of waves...
We present a 3D frequency-domain finite-difference method for acoustic wave propagation modeling. Th...
International audienceWe present a frequency-domain finite-difference method for modeling 3D acousti...
Finite difference methods for solving the wave equation more accurately capture the physics of waves...
With the rapid developments in parallel compute architectures, algorithms for seismic modeling and i...
Simulation of elastic wave propagation is an important method for oil and gas exploration. Accuracy...
The propagation of seismic waves is affected by the type of transmission media. Therefore, it is nec...
Seismograms (i.e., recordings of seismic waves that propagate through the earth) can be used to unco...
Frequency-domain finite-difference (FDFD) modeling offers several advantages over traditional timedo...
The finite-difference method is among the most popular methods for modelling seismic wave propagatio...
textOur knowledge of elastic wave propagation in general heterogeneous media with complex geological...
Realistic applications of numerical modeling of acoustic wave dynamics usually demand high-performan...
International audienceWe accelerate a three-dimensional finite-difference in the time domain (FDTD) ...
The staggered-grid finite-difference (FD) method is widely used in numerical simulation of the wave ...
Finite difference methods for solving the wave equation more accurately capture the physics of waves...
We present a 3D frequency-domain finite-difference method for acoustic wave propagation modeling. Th...
International audienceWe present a frequency-domain finite-difference method for modeling 3D acousti...
Finite difference methods for solving the wave equation more accurately capture the physics of waves...
With the rapid developments in parallel compute architectures, algorithms for seismic modeling and i...
Simulation of elastic wave propagation is an important method for oil and gas exploration. Accuracy...
The propagation of seismic waves is affected by the type of transmission media. Therefore, it is nec...
Seismograms (i.e., recordings of seismic waves that propagate through the earth) can be used to unco...
Frequency-domain finite-difference (FDFD) modeling offers several advantages over traditional timedo...
The finite-difference method is among the most popular methods for modelling seismic wave propagatio...