Leveraging a Supervised Machine Learning Toolkit For Better Seismic Processing Quality Control

M. Chambefort; N. Salaun; E. Chautru; S. Clémençon

doi:10.3997/2214-4609.201901618

Leveraging a Supervised Machine Learning Toolkit For Better Seismic Processing Quality Control
Authors M. Chambefort^1,2, N. Salaun¹, E. Chautru², S. Clémençon³
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Affiliations: ¹ CGG ² MinesParisTech ³ Université Paris Saclay
Publisher: European Association of Geoscientists & Engineers
Source: Conference Proceedings, 81st EAGE Conference and Exhibition 2019, Jun 2019, Volume 2019, p.1 - 5
DOI: https://doi.org/10.3997/2214-4609.201901618

Abstract

Summary

Geophysicists are facing great challenges to process increasingly large volumes of seismic data in a faster, better and more reliable way. In order to achieve this, one key element is to be able to perform quality control of processing steps in an effective and efficient manners. In this paper we present two cases where machine learning techniques are used to help speed up the quality control process. The first case describes an application of supervised learning with K-nearest neighbor to identify areas that may potentially cause cycle-skipping in full waveform inversion. The second case uses a logistic regression machine learning approach to detect and classify the presence of rig noise on shot points. Furthermore, we also tested an automated data reduction method using a long short-term memory auto-encoder, that could speed up the algorithm significantly without losing key information in the original data.

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2019-06-03

2024-04-26

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Leveraging a Supervised Machine Learning Toolkit For Better Seismic Processing Quality Control

Conference Proceedings 2019, 1 (2019); https://doi.org/10.3997/2214-4609.201901618

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Leveraging a Supervised Machine Learning Toolkit For Better Seismic Processing Quality Control

Abstract

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The natural combination of full and image‐based waveform inversion

Poststack diffraction imaging using reverse‐time migration

Characterizing the effect of elastic interactions on the effective elastic properties of porous, cracked rocks

Fracture detection by Gaussian beam imaging of seismic data and image spectrum analysis

Laboratory measurements of guided‐wave propagation within a fluid‐saturated fracture