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Lithological Classification by Hyperspectral Images Based on a Two-Layer XGBoost Model, Combined with a Greedy Algorithm
Lithology classification is important in mineral resource exploration, engineering geological exploration, and disaster monitoring. Traditional laboratory methods for the qualitative analysis of rocks are limited by sampling conditions and analytical techniques, resulting in high costs, low efficien...
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| Published in: | Remote sensing (Basel, Switzerland) Switzerland), 2023-08, Vol.15 (15), p.3764 |
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| creator | Lin, Nan Fu, Jiawei Jiang, Ranzhe Li, Genjun Yang, Qian |
| description | Lithology classification is important in mineral resource exploration, engineering geological exploration, and disaster monitoring. Traditional laboratory methods for the qualitative analysis of rocks are limited by sampling conditions and analytical techniques, resulting in high costs, low efficiency, and the inability to quickly obtain large-scale geological information. Hyperspectral remote sensing technology can classify and identify lithology using the spectral characteristics of rock, and is characterized by fast detection, large coverage area, and environmental friendliness, which provide the application potential for lithological mapping at a large regional scale. In this study, ZY1-02D hyperspectral images were used as data sources to construct a new two-layer extreme gradient boosting (XGBoost) lithology classification model based on the XGBoost decision tree and an improved greedy search algorithm. A total of 153 spectral bands of the preprocessed hyperspectral images were input into the first layer of the XGBoost model. Based on the tree traversal structural characteristics of the leaf nodes in the XGBoost model, three built-in XGBoost importance indexes were split and combined. The improved greedy search algorithm was used to extract the spectral band variables, which were imported into the second layer of the XGBoost model, and the bat algorithm was used to optimize the modeling parameters of XGBoost. The extraction model of rock classification information was constructed, and the classification map of regional surface rock types was drawn. Field verification was performed for the two-layer XGBoost rock classification model, and its accuracy and reliability were evaluated based on four indexes, namely, accuracy, precision, recall, and F1 score. The results showed that the two-layer XGBoost model had a good lithological classification effect, robustness, and adaptability to small sample datasets. Compared with the traditional machine learning model, the two-layer XGBoost model shows superior performance. The accuracy, precision, recall, and F1 score of the verification set were 0.8343, 0.8406, 0.8350, and 0.8157, respectively. The variable extraction ability of the constructed two-layer XGBoost model was significantly improved. Compared with traditional feature selection methods, the GREED-GFC method, when applied to the two-layer XGBoost model, contributes to more stable rock classification performance and higher lithology prediction accuracy |
| doi_str_mv | 10.3390/rs15153764 |
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Traditional laboratory methods for the qualitative analysis of rocks are limited by sampling conditions and analytical techniques, resulting in high costs, low efficiency, and the inability to quickly obtain large-scale geological information. Hyperspectral remote sensing technology can classify and identify lithology using the spectral characteristics of rock, and is characterized by fast detection, large coverage area, and environmental friendliness, which provide the application potential for lithological mapping at a large regional scale. In this study, ZY1-02D hyperspectral images were used as data sources to construct a new two-layer extreme gradient boosting (XGBoost) lithology classification model based on the XGBoost decision tree and an improved greedy search algorithm. A total of 153 spectral bands of the preprocessed hyperspectral images were input into the first layer of the XGBoost model. Based on the tree traversal structural characteristics of the leaf nodes in the XGBoost model, three built-in XGBoost importance indexes were split and combined. The improved greedy search algorithm was used to extract the spectral band variables, which were imported into the second layer of the XGBoost model, and the bat algorithm was used to optimize the modeling parameters of XGBoost. The extraction model of rock classification information was constructed, and the classification map of regional surface rock types was drawn. Field verification was performed for the two-layer XGBoost rock classification model, and its accuracy and reliability were evaluated based on four indexes, namely, accuracy, precision, recall, and F1 score. The results showed that the two-layer XGBoost model had a good lithological classification effect, robustness, and adaptability to small sample datasets. Compared with the traditional machine learning model, the two-layer XGBoost model shows superior performance. The accuracy, precision, recall, and F1 score of the verification set were 0.8343, 0.8406, 0.8350, and 0.8157, respectively. The variable extraction ability of the constructed two-layer XGBoost model was significantly improved. Compared with traditional feature selection methods, the GREED-GFC method, when applied to the two-layer XGBoost model, contributes to more stable rock classification performance and higher lithology prediction accuracy, and the smallest number of extracted features. The lithological distribution information identified by the model was in good agreement with the lithology information verified in the field.</description><identifier>ISSN: 2072-4292</identifier><identifier>EISSN: 2072-4292</identifier><identifier>DOI: 10.3390/rs15153764</identifier><language>eng</language><publisher>Basel: MDPI AG</publisher><subject>Accuracy ; Adaptability ; Algorithms ; Artificial intelligence ; Classification ; Cost analysis ; Decision making ; Decision trees ; Engineering geology ; Exploration ; Feature selection ; Geology ; Greedy algorithms ; hyperspectral ; Hyperspectral imaging ; Image classification ; International economic relations ; Laboratory methods ; Lithofacies ; Lithology ; lithology classification ; Machine learning ; Methods ; Mineral exploration ; Mineral industry ; Mineral resources ; Mining industry ; Model accuracy ; Neural networks ; Optimization algorithms ; Performance indices ; Qualitative analysis ; Recall ; Regression analysis ; Reliability analysis ; Remote sensing ; Resource exploration ; Rocks ; Search algorithms ; Spectral bands ; Verification ; Wavelet transforms ; XGBoost</subject><ispartof>Remote sensing (Basel, Switzerland), 2023-08, Vol.15 (15), p.3764</ispartof><rights>COPYRIGHT 2023 MDPI AG</rights><rights>2023 by the authors. Licensee MDPI, Basel, Switzerland. This article is an open access article distributed under the terms and conditions of the Creative Commons Attribution (CC BY) license (https://creativecommons.org/licenses/by/4.0/). Notwithstanding the ProQuest Terms and Conditions, you may use this content in accordance with the terms of the License.</rights><lds50>peer_reviewed</lds50><oa>free_for_read</oa><woscitedreferencessubscribed>false</woscitedreferencessubscribed><citedby>FETCH-LOGICAL-c400t-296de970354bbd1240fc691154e68777035ee63e92f29ec5e27ffb58b753029b3</citedby><cites>FETCH-LOGICAL-c400t-296de970354bbd1240fc691154e68777035ee63e92f29ec5e27ffb58b753029b3</cites></display><links><openurl>$$Topenurl_article</openurl><openurlfulltext>$$Topenurlfull_article</openurlfulltext><thumbnail>$$Tsyndetics_thumb_exl</thumbnail><linktopdf>$$Uhttps://www.proquest.com/docview/2849111045/fulltextPDF?pq-origsite=primo$$EPDF$$P50$$Gproquest$$Hfree_for_read</linktopdf><linktohtml>$$Uhttps://www.proquest.com/docview/2849111045?pq-origsite=primo$$EHTML$$P50$$Gproquest$$Hfree_for_read</linktohtml><link.rule.ids>314,780,784,25753,27924,27925,37012,44590,74998</link.rule.ids></links><search><creatorcontrib>Lin, Nan</creatorcontrib><creatorcontrib>Fu, Jiawei</creatorcontrib><creatorcontrib>Jiang, Ranzhe</creatorcontrib><creatorcontrib>Li, Genjun</creatorcontrib><creatorcontrib>Yang, Qian</creatorcontrib><title>Lithological Classification by Hyperspectral Images Based on a Two-Layer XGBoost Model, Combined with a Greedy Algorithm</title><title>Remote sensing (Basel, Switzerland)</title><description>Lithology classification is important in mineral resource exploration, engineering geological exploration, and disaster monitoring. Traditional laboratory methods for the qualitative analysis of rocks are limited by sampling conditions and analytical techniques, resulting in high costs, low efficiency, and the inability to quickly obtain large-scale geological information. Hyperspectral remote sensing technology can classify and identify lithology using the spectral characteristics of rock, and is characterized by fast detection, large coverage area, and environmental friendliness, which provide the application potential for lithological mapping at a large regional scale. In this study, ZY1-02D hyperspectral images were used as data sources to construct a new two-layer extreme gradient boosting (XGBoost) lithology classification model based on the XGBoost decision tree and an improved greedy search algorithm. A total of 153 spectral bands of the preprocessed hyperspectral images were input into the first layer of the XGBoost model. Based on the tree traversal structural characteristics of the leaf nodes in the XGBoost model, three built-in XGBoost importance indexes were split and combined. The improved greedy search algorithm was used to extract the spectral band variables, which were imported into the second layer of the XGBoost model, and the bat algorithm was used to optimize the modeling parameters of XGBoost. The extraction model of rock classification information was constructed, and the classification map of regional surface rock types was drawn. Field verification was performed for the two-layer XGBoost rock classification model, and its accuracy and reliability were evaluated based on four indexes, namely, accuracy, precision, recall, and F1 score. The results showed that the two-layer XGBoost model had a good lithological classification effect, robustness, and adaptability to small sample datasets. Compared with the traditional machine learning model, the two-layer XGBoost model shows superior performance. The accuracy, precision, recall, and F1 score of the verification set were 0.8343, 0.8406, 0.8350, and 0.8157, respectively. The variable extraction ability of the constructed two-layer XGBoost model was significantly improved. Compared with traditional feature selection methods, the GREED-GFC method, when applied to the two-layer XGBoost model, contributes to more stable rock classification performance and higher lithology prediction accuracy, and the smallest number of extracted features. The lithological distribution information identified by the model was in good agreement with the lithology information verified in the field.</description><subject>Accuracy</subject><subject>Adaptability</subject><subject>Algorithms</subject><subject>Artificial intelligence</subject><subject>Classification</subject><subject>Cost analysis</subject><subject>Decision making</subject><subject>Decision trees</subject><subject>Engineering geology</subject><subject>Exploration</subject><subject>Feature selection</subject><subject>Geology</subject><subject>Greedy algorithms</subject><subject>hyperspectral</subject><subject>Hyperspectral imaging</subject><subject>Image classification</subject><subject>International economic relations</subject><subject>Laboratory methods</subject><subject>Lithofacies</subject><subject>Lithology</subject><subject>lithology classification</subject><subject>Machine learning</subject><subject>Methods</subject><subject>Mineral exploration</subject><subject>Mineral industry</subject><subject>Mineral resources</subject><subject>Mining industry</subject><subject>Model accuracy</subject><subject>Neural networks</subject><subject>Optimization algorithms</subject><subject>Performance indices</subject><subject>Qualitative analysis</subject><subject>Recall</subject><subject>Regression analysis</subject><subject>Reliability analysis</subject><subject>Remote sensing</subject><subject>Resource exploration</subject><subject>Rocks</subject><subject>Search algorithms</subject><subject>Spectral bands</subject><subject>Verification</subject><subject>Wavelet transforms</subject><subject>XGBoost</subject><issn>2072-4292</issn><issn>2072-4292</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2023</creationdate><recordtype>article</recordtype><sourceid>PIMPY</sourceid><sourceid>DOA</sourceid><recordid>eNpNUU1r3DAQNaWFhiSX_AJBbqVO9Gmvjpul3Sxs6SWF3IQkjxwttrWVHBL_-066pa100PDmzXsPTVVdMXojhKa3uTDFlGgb-a4647TlteSav_-v_lhdlnKgeIRgmsqz6nUf56c0pD56O5DNYEuJAes5pom4hdwvR8jlCH7O2N-NtodC7myBjiDBkoeXVO_tApk8bu9SKjP5ljoYPpNNGl2ckPaCBkjcZoBuIeuhTxmR8aL6EOxQ4PLPe179-PrlYXNf779vd5v1vvaS0rnmuulAt1Qo6VzHuKTBN5oxJaFZte1bA6ARoHngGrwC3obg1Mq1SlCunTivdifdLtmDOeY42ryYZKP5DaTcG5vn6AcwWlhmKaNooSTaOO-6sHJOBtawxnPUuj5pHXP6-QxlNof0nCeMb_hKYipGpULWzYnVWxSNU0j4dx5vB2P0aYIQEV-3DUVVpVoc-HQa8DmVkiH8jcmoedus-bdZ8Qu0aJSF</recordid><startdate>20230801</startdate><enddate>20230801</enddate><creator>Lin, Nan</creator><creator>Fu, Jiawei</creator><creator>Jiang, Ranzhe</creator><creator>Li, Genjun</creator><creator>Yang, Qian</creator><general>MDPI 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Classification by Hyperspectral Images Based on a Two-Layer XGBoost Model, Combined with a Greedy Algorithm</title><author>Lin, Nan ; Fu, Jiawei ; Jiang, Ranzhe ; Li, Genjun ; Yang, Qian</author></sort><facets><frbrtype>5</frbrtype><frbrgroupid>cdi_FETCH-LOGICAL-c400t-296de970354bbd1240fc691154e68777035ee63e92f29ec5e27ffb58b753029b3</frbrgroupid><rsrctype>articles</rsrctype><prefilter>articles</prefilter><language>eng</language><creationdate>2023</creationdate><topic>Accuracy</topic><topic>Adaptability</topic><topic>Algorithms</topic><topic>Artificial intelligence</topic><topic>Classification</topic><topic>Cost analysis</topic><topic>Decision making</topic><topic>Decision trees</topic><topic>Engineering geology</topic><topic>Exploration</topic><topic>Feature selection</topic><topic>Geology</topic><topic>Greedy algorithms</topic><topic>hyperspectral</topic><topic>Hyperspectral imaging</topic><topic>Image classification</topic><topic>International economic 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disaster monitoring. Traditional laboratory methods for the qualitative analysis of rocks are limited by sampling conditions and analytical techniques, resulting in high costs, low efficiency, and the inability to quickly obtain large-scale geological information. Hyperspectral remote sensing technology can classify and identify lithology using the spectral characteristics of rock, and is characterized by fast detection, large coverage area, and environmental friendliness, which provide the application potential for lithological mapping at a large regional scale. In this study, ZY1-02D hyperspectral images were used as data sources to construct a new two-layer extreme gradient boosting (XGBoost) lithology classification model based on the XGBoost decision tree and an improved greedy search algorithm. A total of 153 spectral bands of the preprocessed hyperspectral images were input into the first layer of the XGBoost model. Based on the tree traversal structural characteristics of the leaf nodes in the XGBoost model, three built-in XGBoost importance indexes were split and combined. The improved greedy search algorithm was used to extract the spectral band variables, which were imported into the second layer of the XGBoost model, and the bat algorithm was used to optimize the modeling parameters of XGBoost. The extraction model of rock classification information was constructed, and the classification map of regional surface rock types was drawn. Field verification was performed for the two-layer XGBoost rock classification model, and its accuracy and reliability were evaluated based on four indexes, namely, accuracy, precision, recall, and F1 score. The results showed that the two-layer XGBoost model had a good lithological classification effect, robustness, and adaptability to small sample datasets. Compared with the traditional machine learning model, the two-layer XGBoost model shows superior performance. The accuracy, precision, recall, and F1 score of the verification set were 0.8343, 0.8406, 0.8350, and 0.8157, respectively. The variable extraction ability of the constructed two-layer XGBoost model was significantly improved. Compared with traditional feature selection methods, the GREED-GFC method, when applied to the two-layer XGBoost model, contributes to more stable rock classification performance and higher lithology prediction accuracy, and the smallest number of extracted features. The lithological distribution information identified by the model was in good agreement with the lithology information verified in the field.</abstract><cop>Basel</cop><pub>MDPI AG</pub><doi>10.3390/rs15153764</doi><oa>free_for_read</oa></addata></record> |
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| subjects | Accuracy Adaptability Algorithms Artificial intelligence Classification Cost analysis Decision making Decision trees Engineering geology Exploration Feature selection Geology Greedy algorithms hyperspectral Hyperspectral imaging Image classification International economic relations Laboratory methods Lithofacies Lithology lithology classification Machine learning Methods Mineral exploration Mineral industry Mineral resources Mining industry Model accuracy Neural networks Optimization algorithms Performance indices Qualitative analysis Recall Regression analysis Reliability analysis Remote sensing Resource exploration Rocks Search algorithms Spectral bands Verification Wavelet transforms XGBoost |
| title | Lithological Classification by Hyperspectral Images Based on a Two-Layer XGBoost Model, Combined with a Greedy Algorithm |
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