基于无人机遥感的大坡度地质露头岩性分类

doi:10.13474/j.cnki.11-2246.2023.0325

测绘通报 ›› 2023, Vol. 0 ›› Issue (11): 42-47.doi: 10.13474/j.cnki.11-2246.2023.0325

基于无人机遥感的大坡度地质露头岩性分类

常乐^1,2,3, 韩磊^1,3, 陈宗强^1,3, 盛辉², 刘善伟²

1. 青岛市勘察测绘研究院, 山东青岛 266033;
2. 中国石油大学(华东)海洋与空间信息学院, 山东青岛 266580;
3. 海陆地理信息集成与应用国家地方联合工程研究中心(青岛), 山东青岛 266033

收稿日期:2023-01-30 发布日期:2023-12-07
通讯作者: 盛辉。E-mail:sheng@upc.edu.cn
作者简介:常乐(1996—),男,硕士,研究方向为摄影测量与遥感地学应用。E-mail:a511974858@qq.com

Lithology classification of large slope geological outcrop based on UAV multi spectral remote sensing

CHANG Le^1,2,3, HAN Lei^1,3, CHEN Zongqiang^1,3, SHENG Hui², LUI Shanwei²

1. Qingdao Surveying & Mapping Institute, Qingdao 266033, China;
2. College of Oceanography and Space Informatics in China University of Petroleum(East China), Qingdao 266580, China;
3. National-local Joint Engineering Research Center of Integration and Application of Marineterrestrial Geographical Information(Qingdao), Qingdao 266033, China

Received:2023-01-30 Published:2023-12-07

摘要/Abstract

摘要： 针对卫星影像难以获取大坡度地质露头数据、传统分类方法无法有效利用影像信息导致地质露头剖面岩性分类精度较低等问题,本文通过无人机遥感技术获取高精度野外大坡度地质露头数据,并提出了一种多尺度混合特征网络模型。研究结果表明:无人机与贴近摄影测量技术相结合的方法在采集地质露头数据的应用中具有较强的可行性;多尺度混合特征网络模型能够有效地提取无人机多光谱影像中的光谱特征和空间特征,实现了大坡度地质露头岩性的高精度分类。以云台山地质公园某露头为例,本文模型的总体分类精度可达89.91%,Kappa系数可达0.85,相比于传统的机器学习算法SVM和MLC精度提高接近15%,相比于Inception V3和ResNet18总体分类精度提高约10%,相比于Hybrid CNN总体分类精度提高1.5%。

关键词: 无人机, 地质露头, 深度学习, 岩性分类

Abstract: Aiming at the problems that satellite images are difficult to obtain geological outcrop data with large slopes, and traditional classification methods cannot effectively use image information leading to geological outcrop section lithology classification accuracy being relatively low, this research obtains high-precision field geological outcrop data with large slope based on UAV remote sensing technology and proposes a multi-scale hybrid feature network model. The results show that the combination of UAV and close photogrammetry is feasible in collecting geological outcrop data. The multi-scale hybrid feature network model can effectively extract the spectral features and spatial features from the multi-spectral images of UAV and realize the high-precision lithology classification of geological outcrops with large slopes. Taking an outcrop in Yuntaishan geopark as an example, the overall classification accuracy of the proposed model can reach 89.91%, and the Kappa coefficient can reach 0.85. The general classification accuracy is nearly 15% higher than traditional machine learning algorithms SVM and MLC, about 10% higher than Inception V3 and ResNet18, and 1.5% higher than Hybrid CNN.

Key words: UAV, geological outcrop, deep learning, lithology classification

中图分类号:

P237

常乐, 韩磊, 陈宗强, 盛辉, 刘善伟. 基于无人机遥感的大坡度地质露头岩性分类[J]. 测绘通报, 2023, 0(11): 42-47.

CHANG Le, HAN Lei, CHEN Zongqiang, SHENG Hui, LUI Shanwei. Lithology classification of large slope geological outcrop based on UAV multi spectral remote sensing[J]. Bulletin of Surveying and Mapping, 2023, 0(11): 42-47.

参考文献

[1] 盛辉,段政明,刘善伟,等.大坡度地质露头高分辨率无人机影像采集方法与建模实践[J].古地理学报,2020,22(4): 799-806.
[2] 王延章,林红梅,冯建伟,等.砂砾岩物源供给能力定量评价: 以济阳坳陷车镇凹陷郭局子洼陷为例[J].石油与天然气地质,2018,39(6): 1154-1163.
[3] 郭清宏,周永章,曹姝旻,等.广绿玉玉石的矿物学研究[J].中山大学学报(自然科学版),2010,49(3): 146-151.
[4] ZAINI N,VAN DER MEER F,VAN DER WERFF H.Determination of carbonate rock chemistry using laboratory-based hyperspectral imagery[J].Remote Sensing,2014,6(5): 4149-4172.
[5] 冉明佳,钟康惠,罗明非,等.西藏冈底斯带东段石炭纪构造环境讨论[J].地质论评,2012,58(2): 250-258.
[6] 孙书勤,汪云亮,张成江.玄武岩类岩石大地构造环境的Th、Nb、Zr判别[J].地质论评,2003,49(1): 40-47.
[7] 周新平,张文选,刘广林,等.应用岩性统计法定量分析沉积相: 以陕北地区延长组长8段为例[J].西安石油大学学报(自然科学版),2016,31(6): 9-14,22.
[8] BARABOSHKIN E E,ISMAILOVA L S,ORLOV D M,et al.Deep convolutions for in-depth automated rock typing[J].Computers & Geosciences,2020,135:104330.
[9] LIU Xiaobo,WANG Huaiyuan,JING Hongdi,et al.Research on intelligent identification of rock types based on faster R-CNN method[J].IEEE Access,2020,8: 21804-21812.
[10] 马德锋,李培军.加入多尺度图像纹理的岩性分类[J].岩石学报,2008,24(6): 1425-1430.
[11] LI Na,HAO Huizhen,GU Qing,et al.A transfer learning method for automatic identification of sandstone microscopic images[J].Computers & Geosciences,2017,103: 111-121.
[12] 张野,李明超,韩帅.基于岩石图像深度学习的岩性自动识别与分类方法[J].岩石学报,2018,34(2): 333-342.
[13] YANG Jiahui,LIAO Cankai,GUO Chenhui,et al.Lithology identification based on ResNeSt in high-resolution rock images[C]//Proceedings of the 4th International Conference on Information Communication and Signal Processing (ICICSP).Shanghai: IEEE,2021: 415-419.
[14] XU Zhenhao,SHI Heng,LIN Peng,et al.Integrated lithology identification based on images and elemental data from rocks[J].Journal of Petroleum Science and Engineering,2021,205: 108853.
[15] 万剑华,王朝,刘善伟,等.倾斜摄影测量构建地质数字露头[J].地质科技情报,2019,38(1): 258-264.
[16] 言司.独辟蹊径,不断创新贴近摄影测量: 第三种摄影测量方式的诞生: 专访武汉大学遥感信息工程学院张祖勋院士[J].中国测绘,2019(10): 31-37.
[17] 杨润书,马燕燕,殷海舟.低空无人机航摄系统地面分辨率与航高的关系研究[J].地矿测绘,2013,29(3): 1-2.
[18] ROY S K,KRISHNA G,DUBEY S R,et al.HybridSN: exploring 3-D-2-D CNN feature hierarchy for hyperspectral image classification[J].IEEE Geoscience and Remote Sensing Letters,2020,17(2): 277-281.

基于无人机遥感的大坡度地质露头岩性分类

Lithology classification of large slope geological outcrop based on UAV multi spectral remote sensing

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