Acoustic Impedance Prediction Using an Attention-Based Dual-Branch Double-Inversion Network

arXiv - PHYS - Geophysics Pub Date : 2024-08-05 DOI:arxiv-2408.02524

Wen Feng, Yong Li, Yingtian Liu, Huating Li

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Abstract

Seismic impedance inversion is a widely used technique for reservoir characterization. Accurate, high-resolution seismic impedance data form the foundation for subsequent reservoir interpretation. Deep learning methods have demonstrated significant potential in seismic impedance inversion. Traditional single semi-supervised networks, which directly input original seismic logging data, struggle to capture high-frequency weak signals. This limitation leads to low-resolution inversion results with inadequate accuracy and stability. Moreover, seismic wavelet uncertainty further constrains the application of these methods to real seismic data. To address these challenges, we propose ADDIN-I: an Attention-based Dual-branch Double-Inversion Network for Impedance prediction. ADDIN-I's dual-branch architecture overcomes the limitations of single-branch semi-supervised networks and improves the extraction of high-frequency weak signal features in sequence modeling. The network incorporates an attention mechanism to further enhance its feature extraction capabilities. To adapt the method for real seismic data applications, a deep learning forward operator is employed to fit the wavelet adaptively. ADDIN-I demonstrates excellent performance in both synthetic and real data applications.

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利用基于注意力的双支双反网络进行声阻抗预测

地震阻抗反演是一种广泛用于储层特征描述的技术。准确、高分辨率的地震阻抗数据是后续储层解释的基础。深度学习方法已在地震阻抗反演中展现出巨大潜力。传统的单一半监督网络直接输入原始地震测井数据，很难捕捉到高频微弱信号。此外，地震小波的不确定性进一步限制了这些方法在实际地震数据中的应用。为了应对这些挑战，我们提出了 ADDIN-I：基于注意力的双分支双反演阻抗预测网络。ADDIN-I 的双分支架构克服了单分支半监督网络的局限性，改进了序列建模中高频弱信号特征的提取。该网络加入了注意力机制，进一步提高了特征提取能力。为使该方法适用于实际地震数据应用，采用了深度学习前向算子来自适应拟合小波。ADDIN 在合成数据和真实数据应用中都表现出卓越的性能。

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arXiv - PHYS - Geophysics

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