使用端对端变压器识别地球化学异常现象

IF 4.8 2区 地球科学 Q1 GEOSCIENCES, MULTIDISCIPLINARY Natural Resources Research Pub Date : 2024-05-10 DOI:10.1007/s11053-024-10334-4
Shuyan Yu, Hao Deng, Zhankun Liu, Jin Chen, Keyan Xiao, Xiancheng Mao
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引用次数: 0

摘要

深度学习方法在识别矿产勘探中的地球化学异常方面取得了显著成功。通常情况下,这些方法通过重构地球化学背景来识别异常,而地球化学背景具有长距离空间变异性,从而在地球化学信号中产生长距离空间依赖性。然而,目前用于识别地球化学异常的深度学习模型在捕捉错综复杂的长程空间依赖性方面存在局限性。此外,现有深度学习模型的预处理涉及生成插值图像和拓扑图来表示地球化学样本的空间结构,其不确定性也令人担忧。在本文中,我们提出了一种基于 Transformer 模型的新型端到端地球化学异常提取方法。我们的模型利用自我注意机制,从整体角度充分捕捉地球化学样本之间的全局和局部相互联系,从而实现地球化学背景的重建。此外,自我关注机制允许 Transformer 模型直接输入自由形式的地球化学样本,消除了通常需要对地球化学样本进行事先插值或图形生成所带来的不确定性。为了使地球化学数据与 Transformer 的架构相匹配,我们定制了一种专门的数据组织,将可学习的位置编码和数据屏蔽整合在一起。这样就能将整个地球化学数据输入 Transformer 进行异常识别。利用注意力机制提供的灵活性,我们设计了一种用于训练的对比损失,建立了一种自我监督学习方案,增强了异常识别的模型泛化能力。我们利用所提出的方法识别了中国东部胶东半岛西北部与金矿化有关的地球化学异常。通过与图注意网络模型和地理加权回归模型识别的异常进行比较,证明了所提出的方法在识别与成矿相关的异常方面更为有效,且更符合地质学原理。该方法在地球化学异常识别方面的优异表现归功于其捕捉地球化学数据长程依赖关系的能力。
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Identification of Geochemical Anomalies Using an End-to-End Transformer

Deep learning methods have demonstrated remarkable success in recognizing geochemical anomalies for mineral exploration. Typically, these methods identify anomalies by reconstructing the geochemical background, which is marked by long-distance spatial variability, giving rise to long-range spatial dependencies within geochemical signals. However, current deep learning models for geochemical anomaly recognition face limitations in capturing intricate long-range spatial dependencies. Additionally, concerns emerge from the uncertainty associated with preprocessing in existing deep learning models, which involve generating interpolated images and topological graphs to represent the spatial structure of geochemical samples. In this paper, we present a novel end-to-end method for geochemical anomaly extraction based on the Transformer model. Our model utilizes self-attention mechanism to adequately capture both global and local interconnections among geochemical samples from a holistic perspective, enabling the reconstruction of geochemical background. Moreover, the self-attention mechanism allows the Transformer model to directly input free-form geochemical samples, eliminating the uncertainty associated with the employment of prior interpolation or graph generation typically required for geochemical samples. To align geochemical data with Transformer's architecture, we tailor a specialized data organization integrating learnable positional encoding and data masking. This enables the ingestion of entire geochemical data into the Transformer for anomaly recognition. Capitalizing on the flexibility afforded by the attention mechanism, we devise a contrastive loss for training, establishing a self-supervised learning scheme that enhances model generalizability for anomaly recognition. The proposed method is utilized to recognize geochemical anomalies related to Au mineralization in the northwest Jiaodong Peninsula, Eastern China. By comparison with anomalies identified by models of graph attention network and geographically weighted regression, it is demonstrated that the proposed method is more effective and geologically sound in identifying mineralization-associated anomalies. This superior performance in geochemical anomaly recognition is attributed to its ability to capture long-range dependencies within geochemical data.

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来源期刊
Natural Resources Research
Natural Resources Research Environmental Science-General Environmental Science
CiteScore
11.90
自引率
11.10%
发文量
151
期刊介绍: This journal publishes quantitative studies of natural (mainly but not limited to mineral) resources exploration, evaluation and exploitation, including environmental and risk-related aspects. Typical articles use geoscientific data or analyses to assess, test, or compare resource-related aspects. NRR covers a wide variety of resources including minerals, coal, hydrocarbon, geothermal, water, and vegetation. Case studies are welcome.
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