Journal of Jilin University(Earth Science Edition) ›› 2021, Vol. 51 ›› Issue (6): 1921-1931.doi: 10.13278/j.cnki.jjuese.20200216

Previous Articles     Next Articles

Real Evidence of Mapping Accuracy of Low-Altitude UAV Tilt Photogrammetry

Lu Yanlin, Zhang Sen, Ji Jiao   

  1. Tianjin Water Planning Survey and Design Limited Company, Tianjin 300000, China
  • Received:2020-10-02 Online:2021-11-26 Published:2021-11-24
  • Supported by:
    Supported by the National Key R&D Program of China (2017YFE0119600)

PDF (PC)

111

Abstract: In order to study the improvement of surveying accuracy by tilt photogrammetry, taking two survey areas A and B as an example, the two-piece and multi-piece intersection, vertical and tilt images are used as contrast conditions to establish a stereoscopic model and a real scene 3D model. Through the error statistics of the checkpoints in the models and digital line graphic, the plane accuracy and elevation accuracy are compared and analyzed. Compared with the stereoscopic model based on the two-piece front intersection, the real scene 3D model based on the multi-piece front intersection has higher accuracy. In the survey area A where the terrain is highly mountainous, the errors in plane and elevation are increased from decimeter level to centimeter level, and combining with Specifications for Aerotriangulation of Digital Aerophotogrammetry, it can reach the mapping standard of 1:500 scale. Compared with vertical photogrammetry, oblique photogrammetry has more intersection rays, so its model accuracy is higher. In the survey area B where the terrain is mountainous, the elevation accuracy can be equivalent to the plane accuracy, and the median error is within 5 cm, which solves the problem of poor elevation accuracy in aerial photogrammetry due to image acquisition methods, and by 3D mapping based on the tilted real 3D model, the error in the contour meets the accuracy requirements of the 1:500 scale in Specifications for Aerophotogrammetric Office Operation of 1:500 1:1 000 1:2 000 Topographic Maps.

Key words: tilt photogrammetry, scene 3D model, precision analysis

CLC Number: 

  • P231.5
[1] 林卉, 王仁礼. 数字摄影测量学[M]. 徐州:中国矿业大学出版社, 2015. Lin Hui, Wang Renli. Digital Photogrammetry[M].Xuzhou:China University of Mining and Technology Press, 2015.
[2] 李明. 基于倾斜影像的城市三维场景重建若干关键技术研究[D].武汉:武汉大学, 2016. Li Ming. Key Technologies Research of City Three-Dimensional Scene Reconstruction Based on Oblique Images[D]. Wuhan:Wuhan University, 2016.
[3] 李英杰. 航空倾斜多视影像匹配方法研究[D].北京:中国测绘科学研究院, 2014. Li Yingjie. Research on Multi-View Matching Method of Multiple Aerial Image[D]. Beijing:Chinese Academy of Surveying and Mapping, 2014.
[4] Zhen W, Zou J, Zhao X, et al. Research on 3D Modeling Technology Based on Digital Photogrammetry[C]//Sixth International Conference on Digital Earth. Beijing:ISDE, 2009:1-7.
[5] 周杰. 倾斜摄影测量在实景三维建模中的关键技术研究[D]. 昆明:昆明理工大学, 2017. Zhou Jie. Research on the Key Technology of Oblique Photogrammetry in 3D Modeling of Real Scene[D]. Kunming:Kunming University of Science and Technology, 2017.
[6] Jeschke W. Digital Close-Range Photogrammetry for Surface Measurement[C]//Close-Range Photogrammetry Meets Machine Vision.[S.l.]:The International Society for Optical Engineering, 2017:1058.
[7] 吴迪军, 张萌萌, 潘飞, 等. 多片前方交会法无人机测图技术[J].测绘科学, 2018,43(10):125-130. Wu Dijun, Zhang Mengmeng, Pan Fei, et al.Unmanned Aerial Vehicles Mapping Technology of Multiple Images Space Forward Intersection[J]. Science of Surveying and Mapping, 2018,43(10):125-130.
[8] 鲁勇奇, 郭佳郁, 冯振贵. 浅谈两点前方交会角对测点的精度影响[J].海峡科技与产业, 2017(7):122-123. Lu Yongqi, Guo Jiayu, Feng Zhengui. Talking About the Influence of the Intersection Angle of Two Points on the Accuracy of the Measuring Point[J]. Technology and Industry Across the Straits, 2017(7):122-123.
[9] 李忠美, 边少锋, 瞿勇. 多像空间前方交会的抗差总体最小二乘估计[J].测绘学报, 2017,46(5):593-604. Li Zhongmei, Bian Shaofeng, Qu Yong. Robust Total Least Squares Estimation of Space Intersection Appropriate for Multi-Images[J]. Acta Geodaetica et Cartographica Sinica, 2017,46(5):593-604.
[10] 张剑清, 胡安文. 多基线摄影测量前方交会方法及精度分析[J].武汉大学学报(信息科学版), 2007,32(10):847-851. Zhang Jianqing, Hu Anwen. Multi-Baseline Photogrammetry Forward Intersection Method and Accuracy Analysis[J]. Geomatics and Information Science of Wuhan University, 2007, 32(10):847-851.
[11] 隋婧, 金伟其. 双目立体视觉技术的实现及其进展[J].电子技术应用, 2004(10):4-6. Sui Jing,Jin Weiqi. Realization and Progress of Binocular Stereo Vision Technology[J]. Application of Electronic Technique, 2004(10):4-6.
[12] 宋文平. 无人机航测系统集成及影像后处理有关问题研究[D]. 西安:长安大学, 2016. Song Wenping. Research on Integration of Low Altitude Remote Sensing System of UAV and Related Questions of Image Data Processing[D]. Xi'an:Chang'an University, 2016.
[13] 李伟哲. 基于ContextCapture实景建模及应用[J].西北水电, 2018(3):27-31. Li Weizhe. Real Scene Modeling and Application Based on ContextCapture[J]. Northwest Hydropower, 2018(3):27-31.
[14] 数字航空摄影测量空中三角测量规范:GB/T 23236-2009[S].北京:中国标准出版社,2009. Specifications for Aerotriangulation of Digital Aerophotogrammetry:GB/T 23236-2009[S]. Beijing:China Quality and Standards Publishing & Media Co Ltd, 2009.
[15] 范攀峰, 李露露. 基于Smart3D的低空无人机倾斜摄影实景三维建模研究[J]. 测绘通报, 2017(增刊2):77-81. Fan Panfeng, Li Lulu. A Three-Dimensional Modeling Study Based on the Technique of Low-Altitude UAV Oblique Photogrammetry and Smart3D Software[J]. Bulletin of Surveying and Mapping, 2017(Sup. 2):77-81.
[16] 1:5001:10001:2000地形图航空摄影测量内业规范:GB/T 7930-2008[S]. 北京:中国标准出版社,2008. Specifications for Aerotriangulation Office Operation of 1:5001:10001:2000 Topographic Maps:GB/T 7930-2008[S]. Beijing:China Quality and Standards Publishing & Media Co Ltd, 2008.
No related articles found!
Viewed
Full text


Abstract

Cited
  Shared   
  Discussed   
[1] CHENG Li-ren, ZHANG Yu-jie, ZHANG Yi-chun. Ordovician Nautiloid Fossils of Xainza Region,Tibet[J]. J4, 2005, 35(03): 273 -0282 .
[2] LI Bing-cheng. Preliminary Studies on Holocene Climatic In Fuping,Shaanxi Province[J]. J4, 2005, 35(03): 291 -0295 .
[3] HE Zhong-hua,YANG De-ming,WANG Tian-wu,ZHENG Chang-qing. SHRIMP U[CD*2]Pb Dating of Zircons from Two-Mica Granite in Baga Area in Gangdise Belt[J]. J4, 2005, 35(03): 302 -0307 .
[4] CHEN Li, NIE Lei, WANG Xiu-fan, LI Jin. Seismic Risk Analysis of Some Electric Power Equipment Station in Suizhong[J]. J4, 2005, 35(05): 641 -645 .
[5] JI Hong-jin,SUN Feng-yue2,CHEN Man,HU Da-qian,SHI Yan-xiang,PAN Xiang-qing. Geochemical Evaluation for Uncovered GoldBearing Structures in Jiaodong Area[J]. J4, 2005, 35(03): 308 -0312 .
[6] CHU Feng-you, SUN Guo-sheng,LI Xiao-min,MA Wei-lin, ZHAO Hong-qiao. The Growth Habit and Controlling Factors of the CobaltRich Crusts in Seamount of the Central Pacific[J]. J4, 2005, 35(03): 320 -0325 .
[7] LI Bin, MENG Zi-fang, LI Xiang-bo, LU Hong-xuan, ZHENG Min. The Structural Features and Depositional Systems of the Early Tertiary in the Biyang Depression[J]. J4, 2005, 35(03): 332 -0339 .
[8] LI Tao, WU Sheng-jun, CAI Shu-ming, XUE Huai-ping, YASUNORI Nakayama. Simulation Analysis of the Storage Capacity Based on DEM Before and After Connecting to Yangtze River in Zhangdu Lake[J]. J4, 2005, 35(03): 351 -0355 .
[9] KUANG Li-xiong,GUO Jian-hua, MEI Lian-fu, TONG Xiao-lan, YANG Li. Study on the Upheaval of the Bogeda Mountain Block from Angle of Oil and Gas Exploration[J]. J4, 2005, 35(03): 346 -0350 .
[10] ZHANG Guang-xin, DENG Wei, HE Yan, RAMSIS Salama. An Application of Hydrological Response Units in Assessment of Soil Salinization Risks[J]. J4, 2005, 35(03): 356 -0360 .
Copyright © Journal of Jilin University(Earth Science Edition), All Rights Reserved.
Tel: +86-431-88502374;13756165364 E-mail: xuebao1956@jlu.edu.cn
Powered by Beijing Magtech Co. Ltd