Your search keyword '"Wu, Ru-Shan"' showing total 4 results

1. Frequency Controllable Envelope Operator and Its Application in Multiscale Full-Waveform Inversion.

Author

Gao, Zhaoqi, Pan, Zhibin, Gao, Jinghuai, and Wu, Ru-Shan

Subjects

INVERSION (Geophysics), SEISMIC waves, THEORY of wave motion, WAVELENGTHS, PARAMETERIZATION

Abstract

Full-waveform inversion (FWI) attempts to find optimal models of subsurface by using full information of the observed data. One difficulty in conventional FWI is that the misfit function has many local minima because of cycle skipping. Envelope inversion (EI), which uses the envelope operator (EO)-based misfit function, has been proven to be effective in mitigating cycle skipping and recovering long-wavelength velocity model. However, EI ignores the fact that the information within different frequency bands plays different roles in inversion. In this paper, a frequency controllable EO, which can control the frequency components being used to construct envelope, is proposed. We propose a new misfit function and a multiscale FWI method. Using synthetic experiments based on the Marmousi model, we demonstrate that the proposed method is better than EI in mitigating cycle skipping and in building an accurate initial model for conventional FWI to significantly improve its final result. In addition, this method can tolerate a wide range of noise levels. Its effectiveness has also been successfully demonstrated using a field data set. [ABSTRACT FROM AUTHOR]

Published

2019

2. Reflection multi‐scale envelope inversion.

Author

Chen, Guo‐Xin, Wu, Ru‐Shan, and Chen, Sheng‐Chang

Subjects

*INVERSION (Geophysics), *SEISMIC reflection method, *ALGORITHMS, *SOUND waves, *WAVELENGTHS

Abstract

ABSTRACT: Sufficient low‐frequency information is essential for full‐waveform inversion to get the global optimal solution. Multi‐scale envelope inversion was proposed using a new Fréchet derivative to invert the long‐wavelength component of the model by directly using the low‐frequency components contained in an envelope of seismic data. Although the new method can recover the main structure of the model, the inversion quality of the model bottom still needs to be improved. Reflection waveform inversion reduces the dependence of inversion on low‐frequency and long‐offset data by using travel‐time information in reflected waves. However, when the underground medium contains strong contrast or the initial model is far away from the true model, it is hard to get reliable reference reflectors for the generation of reflected waves. Here, we propose a combination inversion algorithm, i.e., reflection multi‐scale envelope inversion, to overcome the limitations of multi‐scale envelope inversion and reflection waveform inversion. First, wavefield decomposition was introduced into the multi‐scale envelope inversion to improve the inversion quality of the long‐wavelength components of the model. Then, after the initial model had been established to be accurate enough, migration and de‐migration were introduced to achieve multi‐scale reflection waveform inversion. The numerical results of the salt‐layer model and the SEG/EAGE salt model verified the validity of the proposed approach and its potential. [ABSTRACT FROM AUTHOR]

Published

2018

3. Seismic envelope inversion: reduction of local minima and noise resistance.

Author

Luo, Jingrui and Wu, Ru‐Shan

Subjects

*INVERSION (Geophysics), *SEISMOLOGY, *WAVE analysis, *WAVELENGTHS, *INTERFERENCE (Sound), *RANDOM noise theory

Abstract

ABSTRACT Waveform inversion met severe challenge in retrieving long-wavelength background structure. We have proposed to use envelope inversion to recover the large-scale component of the model. Using the large-scale background recovered by envelope inversion as new starting model, we can get much better result than the conventional full waveform inversion. By comparing the configurations of the misfit functional between the envelope inversion and the conventional waveform inversion, we show that envelope inversion can greatly reduce the local minimum problem. The combination of envelope inversion and waveform inversion can deliver more faithful and accurate final result with almost no extra computation cost compared to the conventional full waveform inversion. We also tested the noise resistance ability of envelope inversion to Gaussian noise and seismic interference noise. The results showed that envelope inversion is insensitive to Gaussian noise and, to a certain extent, insensitive to seismic interference noise. This indicates the robustness of this method and its potential use for noisy data. [ABSTRACT FROM AUTHOR]

Published

2015

4. Numerical tests on generalized diffraction tomography.

Author

Zhu, Xiaosan, Wu, Ru-Shan, Chen, Xiaofei, and Gao, Rui

Subjects

*TOMOGRAPHY, *OPTICAL diffraction, *GENERALIZATION, *WAVELENGTHS, *NUMERICAL analysis, *WAVENUMBER

Abstract

Abstract: In this paper we formulate the generalized diffraction tomography based on the volume scattering model in heterogeneous media. The frequency-dependent effect due to the finite spatial aperture of the acquisition system is corrected in the local angle domain, resulting in less artifacts and more balanced amplitude for recovering velocity perturbations. Using multiple frequencies, the blind area in the spectral domain in the traditional diffraction tomography can be partially filled and the qualities of the local spectra can be improved in both coverage and uniformity in the local wavenumber domain. Through the preliminary tests using a simple box model in a smoothly varying v(z) medium, the generalized diffraction tomography can recover the long-wavelength component of velocity perturbations up to 23% with respect to the background velocity. It can also reconstruct the low-wavenumber-component Marmousi velocity model very well when low-frequency waves are used in the process. [Copyright &y& Elsevier]

Published

2014