基于深度学习的二维斜率层析反演模型误差校正方法

doi:10.11720/wtyht.2025.1191

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Abstract

Slope tomography is a method to estimate subsurface velocity macromodels from the slopes and traveltimes of local coherent reflection events. In geologically complex areas, the macromodels obtained from slope tomography tend to yield larger errors. To address this issue, this study proposed a method for error correction of the models using deep learning. Specifically, with macromodels determined using slope tomography-based inversion serving as input and corresponding theoretical models as labels, a neural network was trained, yielding a nonlinear mapping from the slope tomography-derived macromodel to the corresponding theoretical model. To ensure that the trained neural network was applicable to measured seismic data, the training samples were generated from the inversion model and migration profiles of measured seismic data. Tests based on the data synthesized using the theoratical model validated the accuracy and effectiveness of the proposed method. The proposed method was then applied to the 2D measured seismic data from beaches and shallow seas, yielding velocity models with elevated precision and depth migration imaging profiles with high quality.

Key words： slope tomography imaging deep learning error correction velocity model neural network

Received: 26 April 2024 Published: 22 April 2025

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	Da-Ming GE

Cite this article:

Da-Ming GE. A deep learning-based method for error correction of 2D slope tomography-based inversion models[J]. Geophysical and Geochemical Exploration, 2025, 49(2): 385-393.

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https://www.wutanyuhuatan.com/EN/10.11720/wtyht.2025.1191 OR https://www.wutanyuhuatan.com/EN/Y2025/V49/I2/385

Architecture of the U-net in this paper

Error-correction process for tomographic models

The geometry of the survey line

Tomographic model (a) and depth-domain migration image (b) of the field seismic data

A training sample constructed

Five representative training samples

The objective function values of the network training

The velocity error distributions of all discrete grids of the testing samples

Five representative testing samples

Nefword predicted model for measured data (a) and its corresponding depth-domain migration image (b)

Common imaging point gathers calculated by different distances and methods

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