3D-UNet3+中嵌入聚类任务的故障自动解释方法

IF 7.5 1区计算机科学 Q1 COMPUTER SCIENCE, ARTIFICIAL INTELLIGENCE

Expert Systems with Applications Pub Date : 2025-04-22 DOI:10.1016/j.eswa.2025.127704

Chunxia Zhang , Qing Zou , Jiangshe Zhang , Yongjun Wang , Lu Huang , Chunfeng Tao

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引用次数: 0

摘要

为了提高地下数据分析的效率，对断层进行精确解释是至关重要的。目前的研究主要集中在断层的二值分割上，往往不能准确地捕捉到不同断层之间的复杂关系。因此，本文在故障二值分割的基础上进一步进行实例分割，重点研究如何有效分割故障概率体。为了实现深度学习的数据多样性，我们基于合成数据创建了包含200个训练集和20个验证集的标记故障数据集。随后，我们开发了一个充分集成全尺度信息的3D-UNet3+网络，结合mean shift聚类技术实现故障实例分割。为了保证不同故障实例之间的精确区分，我们选择判别损失作为损失函数进行训练。通过对合成数据和现场数据的广泛测试，我们的算法可以在几十秒内完成对新数据的预测，并表现出良好的分割性能。与现有的方法相比，该方法不仅提高了分割精度，而且显著减少了参数的数量，为故障自动解释提供了一种创新的、更有效的解决方案。

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Automatic fault interpretation method embedded with clustering task in 3D-UNet3+

To enhance the efficiency of subsurface data analysis, it is crucial to conduct precise interpretation of faults. Current research mainly focuses on the binary segmentation of faults, which often fails to accurately capture the intricate relationships between different faults. Therefore, this paper further carries out instance segmentation on the basis of binary segmentation of faults, focusing on how to effectively segment fault probability volume. To fulfill the data diversity of deep learning, we have created a labeled fault dataset containing 200 training sets and 20 validation sets based on synthetic data. Afterwards, we develop a 3D-UNet3+ network that fully integrates full-scale information, combined with mean shift clustering technology, to achieve fault instance segmentation. To guarantee precise differentiation among different fault instances, we select discriminative loss as the loss function for training. Extensively tested on synthetic and field data, our algorithm can complete the prediction of new data within tens of seconds and demonstrates excellent segmentation performance. In comparison to prevalent methodologies, our method not only improves segmentation precision but also significantly reduces the number of parameters, offering an innovative and more efficacious resolution for automatic fault interpretation.

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来源期刊

Expert Systems with Applications 工程技术-工程：电子与电气

CiteScore

13.80

自引率

10.60%

发文量

2045

审稿时长

8.7 months

期刊介绍： Expert Systems With Applications is an international journal dedicated to the exchange of information on expert and intelligent systems used globally in industry, government, and universities. The journal emphasizes original papers covering the design, development, testing, implementation, and management of these systems, offering practical guidelines. It spans various sectors such as finance, engineering, marketing, law, project management, information management, medicine, and more. The journal also welcomes papers on multi-agent systems, knowledge management, neural networks, knowledge discovery, data mining, and other related areas, excluding applications to military/defense systems.