Travel time tomography by ray tracing using the fast sweeping method

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Abstract This paper presents a gradient-descent travel time tomography method for solving the acoustictype velocity model inversion problem. Similarly to the adjoint-state method, the proposed method is based on the Eikonal equation, enabling simultaneous calculation of contributions from all common-source receivers to the gradient. This overcomes the ineffi ciency inherent in conventional travel time tomography methods, which rely on a two-point ray tracing process. By directly calculating Fréchet derivatives, our method avoids the complex derivation processes associated with the adjoint-state method. The key to calculating the Fréchet derivatives is to calculate a so-called ray-path term. Consequently, compared to the adjoint-state method, the proposed method can explicitly obtain the ray paths, resulting in a more concise and intuitive derivation process. Furthermore, our method retains the benefits of the adjoint-state method, such as speed, low memory usage, and robustness. This paper focuses on elucidating the principles and algorithms for calculating the raypath term based on the fast sweeping method. The algorithms could be further speeded up by using parallel computational techniques. Synthetic tests demonstrate that our proposed travel time tomographic method accurately calculates ray paths, regardless of the complexity of the model and recording geometry.

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Key words： tomography velocity model building ray tracing fast-sweeping method

Received: 2024-01-05;

Fund: This work was supported by 14th Five-Year Plan major science and technology projects (no.KJGG2022-0201)

Corresponding Authors: Renjun Xie,(Email: xierj@cnooc.com.cn).
E-mail: xierj@cnooc.com.cn

About author: Huai-gu Tang is working at CNOOC Research Institute as a drilling engineer, engaged in the processing and interpretation of collarborative seismic, well logging and drilling data. He got bachelor’s and master’s degree from Ocean University of China, and got PhD degree from National University of Singapore. His research interests are elastic wave forward modeling, velocity model building, and imaging.

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. Travel time tomography by ray tracing using the fast sweeping method[J]. APPLIED GEOPHYSICS, 2024, 21(4): 697-714.

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