使用带有BSMOTE和热核插值的混合CNN-GRU模型增强致密砂岩储层的岩性分类

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摘要在低渗透性砂岩储层中准确进行岩性分类面临两个关键挑战：解决测井数据不平衡问题以及有效捕捉岩性垂向变化。传统的岩心校准方法常常引入主观偏差，而深度学习虽具备自动特征提取能力，现有模型在建模测井数据的时序依赖性方面仍存在不足。为此，本研究提出一种融合卷积神经网络 (CNN) 与门控循环单元 (GRU) 的混合模型框架，并结合热核插值与边界SMOTE技术以增强数据质量与类别平衡。该方法通过CNN提取局部岩石物理特征，利用GRU捕捉岩性序列信息，并通过合成采样提高模型在不平衡数据下的鲁棒性。在多个井的实际数据集上验证结果表明，该模型的平均分类准确率达到93.3%，在岩性识别中表现出优越性能。研究结果显示，所提方法在缓解数据不均衡与增强预测可靠性方面具有显著优势，为岩性分析提供了一种结构化、可扩展的方法，尤其适用于数据有限或井控条件复杂的储层环境。

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关键词：岩性分类深度学习 CNN - GRU模型不平衡数据处理热核插值

Abstract： Accurate lithofacies classification in low-permeability sandstone reservoirs remains challenging due to class imbalance in well-log data and the difficulty of the modeling vertical lithological dependencies. Traditional core-based interpretation introduces subjectivity, while conventional deep learning models often fail to capture stratigraphic sequences effectively. To address these limitations, we propose a hybrid CNN–GRU framework that integrates spatial feature extraction and sequential modeling. Heat Kernel Imputation is applied to reconstruct missing log data, and Borderline SMOTE (BSMOTE) improves class balance by augmenting boundary-case minority samples. The CNN component extracts localized petrophysical features, and the GRU component captures depth-wise lithological transitions, to enable spatial-sequential feature fusion. Experiments on real-well datasets from tight sandstone reservoirs show that the proposed model achieves an average accuracy of 93.3% and a Macro F1-score of 0.934. It outperforms baseline models, including RF (87.8%), GBDT (81.8%), CNN-only (87.5%), and GRU-only (86.1%). Leave-one-well-out validation further confirms strong generalization ability. These results demonstrate that the proposed approach effectively addresses data imbalance and enhances classification robustness, offering a scalable and automated solution for lithofacies interpretation under complex geological conditions.

Key words： Lithofacies Classification Deep Learning CNN-GRU Model Imbalanced data processing Heat kernel Imputation

收稿日期: 2025-03-13;

基金资助:This research was supported by the Langfang Science and Technology Program with self-raised funds under the project “Application of Deep Learning-Based Joint Well-Seismic Analysis in Lithology Prediction” (Project No. 2024011013), and by the Science and Technology Innovation Program for Postgraduate students in IDP subsidized by Fundamental Research Funds for the Central Universities, under the project “Research on CNN Algorithm Enhanced by Physical Information for Lithofacies Prediction in Tight Sandstone Reservoirs” (Project No. ZY20250328).

通讯作者: Li Jun(Email: woo1cc@163.com). E-mail: woo1cc@163.com

作者简介: 李攀，博士，防灾科技学院副教授。2009年于吉林大学获得博士学位。致力于油气勘探、储层预测及相关领域的研究。

引用本文:

. 使用带有BSMOTE和热核插值的混合CNN-GRU模型增强致密砂岩储层的岩性分类[J]. 应用地球物理, 2025, 22(4): 1141-1157.

. Enhanced Lithofacies Classi?cation of Tight Sandstone Reservoirs Using a Hybrid CNN-GRU Model with BSMOTE and Heat Kernel Imputation[J]. APPLIED GEOPHYSICS, 2025, 22(4): 1141-1157.

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