Submarine cable detection using an end-to-end neural network-based magnetic data inversion

To process magnetic anomaly data, appropriate parameters for field separation, denoising, and Euler deconvolution must be manually selected. The traditional workflow is inefficient and cannot fulfill the rapid detection of submarine cables due to complex processing and manual parameter tuning. This...

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Bibliographic Details
Published in:Journal of geophysics and engineering 2024-04, Vol.21 (3), p.884-896
Main Authors: Liu, Yutao, Wu, Yuquan, Li, Gang, Abbas, Aqeel, Shi, Taikun
Format: Article
Language:English
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Summary:To process magnetic anomaly data, appropriate parameters for field separation, denoising, and Euler deconvolution must be manually selected. The traditional workflow is inefficient and cannot fulfill the rapid detection of submarine cables due to complex processing and manual parameter tuning. This study presents an end-to-end deep learning approach for the identification and positioning of submarine cables based on magnetic anomalies. The proposed approach effectively establishes a direct mapping correlation between the magnetic field data and the position of the submarine cable. Synthetic tests suggest that our method performs better in terms of positioning accuracy than the conventional Euler method. Our results for the field data are comparable to those obtained using conventional techniques. Furthermore, the proposed method achieves an optimal solution by employing a clustering technique and selecting the solution with the maximum confidence, which avoids spurious solutions associated with traditional methods. The proposed method can directly determine the position of the submarine cables using the raw magnetic field data. Contrary to the traditional processing workflow, field separation and denoising are not necessary in this novel approach, resulting in higher processing efficiency and a simpler processing process.
ISSN:1742-2132
1742-2140
DOI:10.1093/jge/gxae045