The issues of prestack reverse time migration and solutions with Graphic Processing Unit implementation

Liu, Hongwei; Li, Bo; Liu, Hong; Tong, Xunqian; Liu, Qin; Wang, Xiwen; Liu, Wenqing

doi:10.1111/j.1365-2478.2011.01032.x

Cited by 41 publications

(13 citation statements)

References 47 publications

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“…; Liu et al . ). A review of applications of the FD methods to geophysical imaging is given in Virieux, Calandra and Plessix ().…”

Section: Introductionmentioning

confidence: 97%

“…The FD methods are efficient in calculation since the methods need less memory and are easy to be implemented and hence are widely used in seismic forward problems and reverse-time migration (McMechan 1989;Etgen and O'Brien 2007;Bansal and Sen 2008;Buur and T. Kuhnel 2008;Zhang, Zhang and Zhang 2011;Guan et al 2011;Yang, Tong and Deng 2012). Recent works show that this method can be greatly accelerated using graphics processing unit clusters (Abdelkhalek et al 2012;Liu et al 2012). A review of applications of the * E-mail address: yfwang@mail.iggcas.ac.cn FD methods to geophysical imaging is given in Virieux, Calandra and Plessix (2011).…”

Section: Introductionmentioning

confidence: 99%

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Determining finite difference weights for the acoustic wave equation by a new dispersion‐relationship‐preserving method

Liang

Wang

Yang

2014

Geophysical Prospecting

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Numerical simulation of the acoustic wave equation is widely used to theoretically synthesize seismograms and constitutes the basis of reverse‐time migration. With finite‐difference methods, the discretization of temporal and spatial derivatives in wave equations introduces numerical grid dispersion. To reduce the grid dispersion effect, we propose to satisfy the dispersion relation for a number of uniformly distributed wavenumber points within a wavenumber range with the upper limit determined by the maximum source frequency, the grid spacing and the wave velocity. This new dispersion‐relationship‐preserving method relatively uniformly reduces the numerical dispersion over a large‐frequency range. Dispersion analysis and seismic numerical simulations demonstrate the effectiveness of the proposed method.

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“…; Liu et al . ). A review of applications of the FD methods to geophysical imaging is given in Virieux, Calandra and Plessix ().…”

Section: Introductionmentioning

confidence: 97%

Section: Introductionmentioning

confidence: 99%

Determining finite difference weights for the acoustic wave equation by a new dispersion‐relationship‐preserving method

Liang

Wang

Yang

2014

Geophysical Prospecting

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“…The classic RTM algorithms in the time domain are known to be computationally and I/O intensive (Ji et al, 2012;Liu et al, 2012) because the forward-and time-reversed wavefields have to be computed and stored. If the correlation between these fields is carried out during the time-reversed computation of the receiver data, only snapshots of the forward wavefield have to be stored.…”

Section: Introductionmentioning

confidence: 99%

“…In this case, the propagation effort is doubled because the forward wavefield is first computed, after which the backward propagation and the time-reversed forward wavefield are calculated simultaneously. This method has been implemented on a GPU by Liu et al (2012).…”

Section: Migration In the Time Domainmentioning

confidence: 99%

Closing the performance gap between an iterative frequency-domain solver and an explicit time-domain scheme for 3D migration on parallel architectures

et al. 2014

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Three-dimensional reverse-time migration with the constantdensity acoustic wave equation requires an efficient numerical scheme for the computation of wavefields. An explicit finitedifference scheme in the time domain is a common choice. However, it requires a significant amount of disk space for the imaging condition. The frequency-domain approach simplifies the correlation of the source and receiver wavefields, but requires the solution of a large sparse linear system of equations. For the latter, we use an iterative Krylov solver based on a shifted Laplace multigrid preconditioner with matrixdependent prolongation. The question is whether migration in the frequency domain can compete with a time-domain implementation when both are performed on a parallel architecture. Both methods are naturally parallel over shots, but the frequency-domain method is also parallel over frequencies. If we have a sufficiently large number of compute nodes, we can compute the result for each frequency in parallel and the required time is dominated by the number of iterations for the highest frequency. As a parallel architecture, we consider a commodity hardware cluster that consists of multicore central processing units (CPUs), each of them connected to two graphics processing units (GPUs). Here, GPUs are used as accelerators and not as an independent compute node. The parallel implementation of the 3D migration in frequency domain is compared to a time-domain implementation. We optimize the throughput of the latter with dynamic load balancing, asynchronous I/O, and compression of snapshots. Because the frequency-domain solver uses matrix-dependent prolongation, the coarse-grid operators require more storage than available on GPUs for problems of realistic size. Due to data transfer, there is no significant speedup using GPU-accelerators. Therefore, we consider an implementation on CPUs only. Nevertheless, with the parallelization over shots and frequencies, this approach could compete with the time-domain implementation on multiple GPUs.

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“…Naturally, RTM is the first choice to improve the imaging quality of the salt dome structures in Pre-Caspian Basin. However, the verification of RTM is using the salt dome model of the Gulf of Mexico deep-water oil field (Liu et al 2009;Zhang et al 2007a, b;Liu et al 2012). It is necessary to analyze and compare the imaging capabilities of RTM and WPDM based on the actual regional geologic characteristics, and then give some suggestions to apply the migration method to the real seismic data processing.…”

Section: Introductionmentioning

confidence: 99%

Salt-related structure geologic model of Pre-Caspian Basin and analysis on imaging capability

Wang

Ma²,

et al. 2016

Acta Geod Geophys

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The Pre-Caspian Basin is one of the most prolific petroliferous basins in Kazakhstan. However, the hydrocarbon reservoir is always located in salt dome and presalt structures. The salt-related structure is so complex that it is difficult to obtain the satisfied imaging results. In order to improve the imaging precision and provide authentic amplitude information to reservoir prediction, we should analyze the imaging and amplitude preserving capability between different migration methods. According to actual geologic and reservoir characteristics, we design a typical complex salt-related structure model of the basin. Based on the forward modelling seismic record, we compare the one-

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The issues of prestack reverse time migration and solutions with Graphic Processing Unit implementation

Cited by 41 publications

References 47 publications

Determining finite difference weights for the acoustic wave equation by a new dispersion‐relationship‐preserving method

Determining finite difference weights for the acoustic wave equation by a new dispersion‐relationship‐preserving method

Closing the performance gap between an iterative frequency-domain solver and an explicit time-domain scheme for 3D migration on parallel architectures

Salt-related structure geologic model of Pre-Caspian Basin and analysis on imaging capability

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