Abstract:In order to improve the efficiency and accuracy of geological hazard investigation in dense vegetation mountainous areas, the author used oblique aerial photography technology to obtain its image data. The mountainous area image data were preprocessed through uniform light and color processing positioning system (POS). On the basis of photometric multi-view stereo (PMVS) algorithm, dense matching of dense vegetation mountainous area images was achieved. The three-dimensional reconstruction of the mountainous area was completed, and the interpretation criteria for geological hazards were established. Geological hazard investigation in dense vegetation mountainous areas was completed through computer-aided interpretation method. The experimental data show that under different experimental conditions, the integrity of mountainous image data and the accuracy of geological hazard investigation are higher after the application of oblique aerial photography technology, indicating its good application effect. The research results have some guiding significance for geological hazard investigation in mountainous areas, and could provide scientific references for the identification and investigation, risk assessment, and formulation of prevention and control plans of geological hazards in mountainous areas.
[1] 孙涛,徐明宇,董秀军,等.机载LiDAR技术应用于茂密植被山区地质灾害调查[J].测绘通报,2021(4):90-97. Sun T,Xu M Y,Dong X J,et al.Application of airborne LiDAR technology in geological hazard investigation in mountainous area with dense vegetation[J].Bulletin of Surveying and Mapping,2021(4):90-97. [2] 郭猛猛,刘海,段涛,等.无人机勘测技术在皖南山区地质灾害识别中的应用[J].安徽地质,2021,31(4):331-335. Guo M M,Liu H,Duan T,et al.Application of UAV survey technology in geological hazard identification in the southern Anhui mountainous area[J].Geology of Anhui,2021,31(4):331-335. [3] 李亚东,曹明兰,李长青,等.PPK技术在无人机森林航空摄影测量中的应用[J].中南林业科技大学学报,2021,41(7):20-25. Li Y D,Cao M L,Li C Q,et al.Applications of PPK technology in aerial photogrammetry of forest by an unmanned aerial vehicle[J].Journal of Central South University of Forestry & Technology,2021,41(7):20-25. [4] 王凤艳,赵明宇,王明常,等.无人机摄影测量在矿山地质环境调查中的应用[J].吉林大学学报:地球科学版,2020,50(3):866-874. Wang F Y,Zhao M Y,Wang M C,et al.Application of UAV photogrammetry in mine geological environment survey[J].Journal of Jilin University:Earth Science Edition,2020,50(3):866-874. [5] 王绚,范宣梅,杨帆,等.植被茂密山区地质灾害遥感解译方法研究[J].武汉大学学报:信息科学版,2020,45(11):1771-1781. Wang X,Fan X M,Yang F,et al.Remote sensing interpretation method of geological hazards in Lush Mountainous Area[J].Geomatics and Information Science of Wuhan University,2020,45(11):1771-1781. [6] 蒲川豪,许强,赵宽耀,等.基于遥感分析的延安新区平山造城工程地面沉降及植被恢复特征研究[J].工程地质学报,2020,28(3):597-609. Pu C H,Xu Q,Zhao K Y,et al.Remote sensing analysis of land subsidence and vegetation restoration characteristics in excavation and filling areas of mountain region for urban extension in Yan'an[J].Journal of Engineering Geology,2020,28(3):597-609. [7] 文桃,周自强,应赛,等.基于GIS与AHP属性辨识模型的地质灾害危险性评价——以涪陵页岩气开采区为例[J].重庆师范大学学报(自然科学版),2020,37(4):68-74. Wen T,Zhou Z Q,Ying S,et al.Geologic hazard risk assessment based on GIS and AHP attribute identification model:Taking exploration area of Fuling Shale Gasfield as an example[J].Journal of Chongqing Normal University (Natural Science Edition),2020,37(4):68-74. [8] 刘祥龙,张文君,陈朝亮,等.内江市景观格局对地质灾害易发性的影响分析[J].测绘科学,2021,46(5):118-125. Liu X L,Zhang W J,Chen C L,et al.Analysis of the influence of landscape pattern on geological disaster susceptibility[J].Science of Surveying and Mapping,2021,46(5):118-125. [9] 李怡飞,刘延国,梁丽萍,等.青藏高原高山峡谷地貌区地质灾害危险性评价——以雅江县为例[J].水土保持研究,2021,28(3):364-370. Li Y F,Liu Y G,Liang L P,et al.Assessment on hazard of geological disasters in alpine and canyon landforms of Qinghai-Tibet Plateau:A case study of Yajiang County[J].Research of Soil and Water Conservation,2021,28(3):364-370. [10] 叶振南,田运涛,陈宗良,等.西藏芒康县斜坡地质灾害空间分布特征与易发性区划[J].自然灾害学报,2021,30(3):199-208. Ye Z N,Tian Y T,Chen Z L,et al.Spatial distribution and susceptibility of geological disasters in Mangkang County[J].Journal of Natural Disasters,2021,30(3):199-208. [11] 万佳威,丰成君,戚帮申,等.河北省顺平县地质灾害发育特征及易发性评价[J].地质力学学报,2020,26(4):604-614. Wan J W,Feng C J,Qi B S,et al.Characteristics and susceptibility evaluation of geohazard development in Shunping county,Hebei province[J].Journal of Geomechanics,2020,26(4):604-614. [12] 覃乙根,杨根兰,江兴元,等.基于确定性系数模型与逻辑回归模型耦合的地质灾害易发性评价——以贵州省开阳县为例[J].科学技术与工程,2020,20(1):96-103. Qin Y G,Yang G L,Jiang X Y,et al.Geohazard susceptibility assessment based on integrated certainty factor model and logistic regression model for Kaiyang,China[J].Science Technology and Engineering,2020,20(1):96-103. [13] 梁京涛,铁永波,赵聪,等.基于贴近摄影测量技术的高位崩塌早期识别技术方法研究[J].中国地质调查,2020,7(5):107-113. Liang J T,Tie Y B,Zhao C,et al.Technology and method research on the early detection of high-level collapse based on the nap-of-the-object photography[J].Geological Survey of China,2020,7(5):107-113. [14] 梁京涛,赵聪,马志刚.多源遥感技术在地质灾害早期识别应用中的问题探讨——以西南山区为例[J].中国地质调查,2022,9(4):92-101. Liang J T,Zhao C,Ma Z G.Application discussion on early identification of geohazards based on multi-source remote sensing technology:A case study on mountainous areas of southwestern China[J].Geological Survey of China,2022,9(4):92-101. [15] 周定义,左小清,喜文飞,等.联合SBAS-InSAR和PSO-BP算法的高山峡谷区地质灾害危险性评价[J].农业工程学报,2021,37(23):108-116. Zhou D Y,Zuo X Q,Xi W F,et al.Combined SBAS-InSAR and PSO-BP algorithm for evaluating the risk of geological disasters in alpine valley regions[J].Transactions of the Chinese Society of Agricultural Engineering,2021,37(23):108-116.
2024, Vol. 11 
