Practical deep learning inversion using neural architecture search and a flexible training dataset generator

82nd EAGE Annual Conference & Exhibition Pub Date : 2021-10-18 DOI:10.3997/2214-4609.202112777

T. Shibayama, N. Mizuno, H. Kusano, A. Kinoshita, M. Minegishi, R. Sakamoto, K. Hasegawa, F. Kachi

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Abstract

Summary Deep learning has the potential to estimate velocity models directly from shot gathers, which would reduce the turn-around time of seismic inversion. Our study addresses two challenges in implementing deep learning techniques for seismic inversion: the practical generation of a large amount of training data and the search for the best neural network architecture. First, we propose a flexible system which parametrically generates velocity models to create a large-scale, complex and fully synthetic training dataset, without using a target subsurface model. Using this system, we created 300,000 synthetic velocity models for our experiments. Second, we employ neural architecture search techniques to design a suitable neural network using Optuna, an automatic hyperparameter optimisation framework. We incorporated the residual network into an encoder–decoder model and optimised its architecture. Thus, we obtained an optimal neural network model consisting of more than 100 hidden layers. We evaluated our model using the Marmousi2 model and the 1994 Amoco statics test dataset. The model demonstrated comprehensible estimations of the benchmark velocity models.

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使用神经结构搜索和灵活的训练数据集生成器的实用深度学习反演

深度学习有可能直接从射击集估计速度模型，这将减少地震反演的周转时间。我们的研究解决了在地震反演中实施深度学习技术的两个挑战:大量训练数据的实际生成和寻找最佳神经网络架构。首先，我们提出了一个灵活的系统，该系统可以参数化地生成速度模型，以创建大规模、复杂和完全合成的训练数据集，而无需使用目标地下模型。使用这个系统，我们为我们的实验创建了30万个合成速度模型。其次，我们采用神经结构搜索技术，使用Optuna(一个自动超参数优化框架)设计一个合适的神经网络。我们将残差网络整合到编码器-解码器模型中，并对其结构进行了优化。因此，我们得到了一个由100多个隐藏层组成的最优神经网络模型。我们使用Marmousi2模型和1994年Amoco静态测试数据集来评估我们的模型。该模型证明了基准速度模型的可理解估计。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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82nd EAGE Annual Conference & Exhibition

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