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基于改进V-Net与自适应难样本挖掘的三维地震断层智能识别OA

Intelligent identification of 3D seismic faults based on improved V-Net and adaptive hard example mining

中文摘要英文摘要

三维地震断层的准确识别是地震解释中的关键技术难题之一.传统的地震断层人工解释方法效率低且主观性强,而现有的深度学习方法在断层不连续性识别和样本不平衡处理方面仍存在不足.为此,提出了一种基于改进 V-Net与自适应难样本挖掘的三维地震断层智能识别方法.首先,针对传统 V-Net中反卷积上采样会产生棋盘伪影的问题,采用卷积通道变换与最近邻插值相结合的上采样策略,消除伪影对断层边界特征的干扰,提升了小尺度断层及其边界的识别精度,减少参数冗余,降低计算成本.其次,针对地震数据中断层样本稀疏、边界模糊等问题,设计了融合地质先验知识的自适应难样本挖掘损失函数,该函数通过动态阈值机制识别困难样本,并对断层区域实施差异化权重策略,使模型能够充分学习断层的细节特征,有效缓解因断层样本稀少导致的训练不平衡问题.同时,引入连续性约束项,通过梯度惩罚机制确保断层预测结果符合地质规律.合成数据和实际数据的测试结果表明,基于改进 V-Net与自适应难样本挖掘的三维地震断层智能识别方法在断层检测精度、连续性和泛化能力方面均优于传统的 V-Net方法,其 F1分数(F1-score)达到 0.796 2,平均交并比(mIoU)达到 0.789 1.该方法不仅为三维地震断层的自动识别提供了新的技术途径,也为深度学习在地球物理勘探中的应用拓展了思路.

Accurate 3D fault identification remains a key technical challenge in seismic interpretation.Traditional manual interpretation methods are inefficient and highly subjective,while existing deep learning-based approaches suffer from incomplete fault continuity characterization and sample imbalance.To address these issues,we propose a 3D seismic fault intelligent recognition method based on an improved V-Net architecture and adaptive hard example mining.The architecture adopts an improved upsampling strategy that combines convolutional channel transformation with nearest-neighbor interpolation to address the checkerboard artifacts introduced by deconvolution-based upsampling in conventional V-Net.This strategy effectively mitigates the interference of artifacts on fault boundary features,improves the recognition accuracy of small-scale faults and fault boundaries,and simultaneously reduces parameter redundancy and computational cost.To tackle the challenges of sparse fault samples and ambiguous boundaries in seismic data,we design an adaptive hard example mining loss function that incorporates geological prior knowledge.This loss function employs a dynamic threshold mechanism to identify hard examples and applies a differentiated weighting strategy to fault regions,enabling the model to more effectively learn fine-scale fault features and alleviate the imbalance caused by the scarcity of fault samples.Additionally,a continuity constraint term implemented via gradient penalty is introduced to ensure the geological plausibility of the predicted fault structures.Experimental results on both synthetic and field seismic data demonstrate that the proposed method achieves superior accuracy,continuity,and generalization compared with the conventional V-Net,with an F1 score of 0.796 2 and a mIoU of 0.7891.This work provides a new technical pathway for automatic 3D seismic fault identification and broadens the application potential of deep learning in geophysical exploration.

王健伟;严曙梅;盛志超;刘舒;徐升博;徐天吉

中国石油化工股份有限公司上海海洋油气分公司,上海 200120中国石油化工股份有限公司上海海洋油气分公司,上海 200120中国石油化工股份有限公司上海海洋油气分公司,上海 200120中国石油化工股份有限公司上海海洋油气分公司,上海 200120电子科技大学资源与环境学院,四川 成都 611731电子科技大学资源与环境学院,四川 成都 611731||智能协同计算技术国家级重点实验室,四川 成都 611731

能源科技

三维地震断层识别改进V-Net深度学习自适应难样本挖掘

3D seismic datafault identificationimproved V-Netdeep learningadaptive hard example mining

《石油物探》 2026 (3)

506-520,15

中国石油化工股份有限公司上海海洋油气分公司科研项目(34000000-24-ZC0613-0067)和中国石油天然气集团有限公司重大科技专项(2023ZZ05)共同资助. This research is financially supported by the Research Project of Sinopec Shanghai Offshore Petroleum Company(Grant No.34000000-24-ZC0613-0067)and CNPC Science and Technology Major Project(Grant No.2023ZZ05).

10.12431/issn.1000-1441.2025.0261

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