Improved fast marching methods with application in traveltime tomography
Seismic wave speed and anisotropy provide essential constraints on the Earth’s internal velocity structure and deformation history. The propagation of the seismic wave can be modeled by a Hamilton system in the forward modeling. Then the best fit depth-dependent anisotropy is obtained by the opti...
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| Format: | Thesis-Doctor of Philosophy |
| Language: | English |
| Published: |
Nanyang Technological University
2022
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| Online Access: | https://hdl.handle.net/10356/163163 |
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| Institution: | Nanyang Technological University |
| Language: | English |
| Summary: | Seismic wave speed and anisotropy provide essential constraints on the Earth’s
internal velocity structure and deformation history. The propagation of the seismic
wave can be modeled by a Hamilton system in the forward modeling. Then the best
fit depth-dependent anisotropy is obtained by the optimal solution of an inverse
problem. The numerical accuracy of solving the inverse problem has a significant
impact on the resolution and quality of the final tomographic images.
The classical monotone upwind schemes are efficient and accurate in solving the
forward problem modeled by a static convex Hamilton system, for example the fast
marching method, since they compute the timetable following the causal property
of wave propagation. However, in anisotropic media, when velocity is directional dependent,
the fast marching method computes the timetable with the simplex
containing the negative gradient vector whereas the traveltime should be computed
with the simplex containing the characteristics. One way to improve the
accuracy while maintaining the efficiency is to apply the multi-stencils scheme
since it computes the arrivaltime along several staggered stencils with a better directional
coverage. Another problem is the existence of source singularity for seismic
wave simulation where the viscosity solution of the Hamilton–Jacobi–Bellman
(HJB) equation can only achieve first order convergency at source even higher order
scheme has been applied. This problem is solved by applying factorization
to the original eikonal equation which separates the solution into a known initial
timetable with source singularity and a smooth updated factor. If the initial table
has enough accuracy around the source, theoretically we can obtain any order of
accuracy and convergency by factorization. Thirdly, this dijkstra-like algorithm
remains a sorting strategy which is time consuming and limits its potential to apply
in Single Instruction Multiple Data (SIMD) streaming architecture. Inspired
by previous research, in this PhD project, we propose an iterative method which
updates several points in parallel. The proposed method can achieve any order of
accuracy and convergency for anisotropic media and we apply it for both local and
regional seismic tomography.
For anisotropic tomography, we develop a new ray tracing technique with the novel
eikonal solver. The numerical tests show that for some situations, our ray tracing
technique can obtain more accurate results than isotropic ray tracing technique.
Besides the ray based tomographic method, we also come up with an adjoint-state
traveltime tomography method which avoids ray tracing and solves the inverse
problem in a global optimization sense. Rather than accumulating the misfits of
individual records, the novel method solves an adjoint-state field which involves the
density information of ray trajectories and integrates the whole domain to obtain
a global misfit. We apply both methods in some seismologically active regions to
study the subducting process, magmatism and volcanism by inverting the highquality
manually-picked datasets. Those applications demonstrate that the new
methods are reliable tools in producing seismic anisotropy images to study the
ongoing tectonic dynamics in the seismogenic zones. |
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