A coarse-to-fine approach for intelligent logging lithology identification with extremely randomized trees
A coarse-to-fine approach for intelligent logging lithology identification with extremely randomized trees
Lithology identification is vital for reservoir exploration and petroleum engineering. Recently, there has been growing interest in using an intelligent logging approach for lithology classification. Machine learning has emerged as a powerful tool in inferring the lithology types with the logging curves. However, the well logs are susceptible to logging parameter manual entry, borehole conditions, tool calibrations. Most studies in the field of lithology classification with machine learning approaches have only focused on improving the prediction accuracy of classifiers. Also, the model trained in one location is not reusable in a new location due to different data distributions. In this paper, a unified framework is provided to train the multi-class lithology classification model for the data set with outlier data. In this paper, a coarse-to-fine framework that combines outlier detection, multi-class classification with an extremely randomized tree-based classifier is proposed to solve these issues. Firstly, an unsupervised learning approach is used to detect the outliers in the data set. Then a coarse-to-fine inference procedure is used to infer the lithology class with the extremely randomized tree classifier. Two real-world data sets of well-logging are used to demonstrate the effectiveness of the proposed framework. The comparisons are conducted with some baseline machine learning classifiers, namely random forest, gradient tree boosting, and xgboosting. Results show that the proposed framework has higher prediction accuracy in sandstones compared with other approaches.
859–876
Xie, Yunxin
5d7e68fa-ced2-4381-9183-92a58e46ebd6
Zhu, Chenyang
67a1c085-5e0b-4dcf-8770-b99c520115fc
Hu, Runshan
18986f90-49c4-430e-8047-3bf6b2be61c3
Zhu, Zhengwei
90a8bf82-034a-4c94-93cf-afadf9ca7a19
Xie, Yunxin
5d7e68fa-ced2-4381-9183-92a58e46ebd6
Zhu, Chenyang
67a1c085-5e0b-4dcf-8770-b99c520115fc
Hu, Runshan
18986f90-49c4-430e-8047-3bf6b2be61c3
Zhu, Zhengwei
90a8bf82-034a-4c94-93cf-afadf9ca7a19
Xie, Yunxin, Zhu, Chenyang, Hu, Runshan and Zhu, Zhengwei
(2020)
A coarse-to-fine approach for intelligent logging lithology identification with extremely randomized trees.
Mathematical Geosciences, .
(doi:10.1007/s11004-020-09885-y).
Abstract
Lithology identification is vital for reservoir exploration and petroleum engineering. Recently, there has been growing interest in using an intelligent logging approach for lithology classification. Machine learning has emerged as a powerful tool in inferring the lithology types with the logging curves. However, the well logs are susceptible to logging parameter manual entry, borehole conditions, tool calibrations. Most studies in the field of lithology classification with machine learning approaches have only focused on improving the prediction accuracy of classifiers. Also, the model trained in one location is not reusable in a new location due to different data distributions. In this paper, a unified framework is provided to train the multi-class lithology classification model for the data set with outlier data. In this paper, a coarse-to-fine framework that combines outlier detection, multi-class classification with an extremely randomized tree-based classifier is proposed to solve these issues. Firstly, an unsupervised learning approach is used to detect the outliers in the data set. Then a coarse-to-fine inference procedure is used to infer the lithology class with the extremely randomized tree classifier. Two real-world data sets of well-logging are used to demonstrate the effectiveness of the proposed framework. The comparisons are conducted with some baseline machine learning classifiers, namely random forest, gradient tree boosting, and xgboosting. Results show that the proposed framework has higher prediction accuracy in sandstones compared with other approaches.
Text
MG2020
- Accepted Manuscript
More information
Accepted/In Press date: 28 July 2020
e-pub ahead of print date: 12 August 2020
Identifiers
Local EPrints ID: 443062
URI: http://eprints.soton.ac.uk/id/eprint/443062
ISSN: 1874-8961
PURE UUID: 5b7e7844-fe03-48d6-b643-390358eed7f5
Catalogue record
Date deposited: 07 Aug 2020 16:36
Last modified: 17 Mar 2024 05:47
Export record
Altmetrics
Contributors
Author:
Yunxin Xie
Author:
Chenyang Zhu
Author:
Runshan Hu
Author:
Zhengwei Zhu
Download statistics
Downloads from ePrints over the past year. Other digital versions may also be available to download e.g. from the publisher's website.
View more statistics