Elena Zhebel scite author profile

The finite‐difference method on rectangular meshes is widely used for time‐domain modelling of the wave equation. It is relatively easy to implement high‐order spatial discretization schemes and parallelization. Also, the method is computationally efficient. However, the use of finite elements on tetrahedral unstructured meshes is more accurate in complex geometries near sharp interfaces. We compared the standard eighth‐order finite‐difference method to fourth‐order continuous mass‐lumped finite elements in terms of accuracy and computational cost. The results show that, for simple models like a cube with constant density and velocity, the finite‐difference method outperforms the finite‐element method by at least an order of magnitude. Outside the application area of rectangular meshes, i.e., for a model with interior complexity and topography well described by tetrahedra, however, finite‐element methods are about two orders of magnitude faster than finite‐difference methods, for a given accuracy.

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Time-stepping stability of continuous and discontinuous finite-element methods for 3-D wave propagation

Mulder

Zhebel²,

Minisini³

2013

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Local time stepping with the discontinuous Galerkin method for wave propagation in 3D heterogeneous media

et al. 2013

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Modeling and imaging techniques for geophysics are extremely demanding in terms of computational resources. Seismic data attempt to resolve smaller scales and deeper targets in increasingly more complex geologic settings. Finite elements enable accurate simulation of time-dependent wave propagation in heterogeneous media. They are more costly than finite-difference methods, but this is compensated by their superior accuracy if the finite-element mesh follows the sharp impedance contrasts and by their improved efficiency if the element size scales with wavelength, hence with the local wave velocity. However, 3D complex geologic settings often contain details on a very small scale compared to the dominant wavelength, requiring the mesh to contain elements that are smaller than dictated by the wavelength. Also, limitations of the mesh generation software may produce regions where the elements are much smaller than desired. In both cases, this leads to a reduction of the time step required to solve the wave propagation and significantly increases the computational cost. Local time stepping (LTS) can improve the computational efficiency and speed up the simulation. We evaluated a local formulation of an LTS scheme with second-order accuracy for the discontinuous Galerkin finite-element discretization of the wave equation. We tested the benefits of the scheme by considering a geologic model for a North-Sea-type example.

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A 3D Tetrahedral Mesh Generator for Seismic Problems

Kononov

Minisini

Zhebel

et al. 2012

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SUMMARYFinite-element modelling of seismic wave propagation on tetrahedra requires meshes that accurately follow interfaces between impedance contrasts or surface topography and have element sizes proportional to the local velocity. We explain a mesh generation approach by example. Starting from a finite-difference representation of the velocity model, triangulated surfaces are generated along impedance discontinuities. These define subdomains that are meshed independently and in parallel, honouring the local velocity values. The resulting volumetric meshes are merged into a single mesh. The approach is flexible, efficient, scalable and capable of producing quality meshes.

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Solving the 3D Acoustic Wave Equation with Higher-order Mass-lumped Tetrahedral Finite Elements

Zhebel¹,

Minisini²,

Kononov³

et al. 2011

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Elena Zhebel

A comparison of continuous mass‐lumped finite elements with finite differences for 3‐D wave propagation

Time-stepping stability of continuous and discontinuous finite-element methods for 3-D wave propagation

Local time stepping with the discontinuous Galerkin method for wave propagation in 3D heterogeneous media

A 3D Tetrahedral Mesh Generator for Seismic Problems

Solving the 3D Acoustic Wave Equation with Higher-order Mass-lumped Tetrahedral Finite Elements

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