基于地面激光扫描数据的单木分枝结构参数自动提取

doi:10.11707/j.1001-7488.20160315

Abstract

Abstract: [Objective] Using terrestrial laser scanning(TLS) data to extract skeleton of individual tree and developing an automatic measurement algorithm of branch structure based on skeleton model for parameterized modeling and visualization simulation of forest.[Method] We applied FARO terrestrial laser scanner, with a quarter of the resolution, speed 244 000 s^-1 to obtain three trees' TLS data. Firstly, skeleton model was generated by SkelTre algorithm using TLS data with noise. Then, we developed a new method to extract branch structure with depth first search algorithm. According to the skeleton model, we searched the branch nodes connecting parent branch with child branch. Each node contained some information about this dominated direction, number of different branches and those coordinates. Due to the position error caused by skeletonization, we adopted the cylinder fitting to correct the extension direction of the branches and reduce the error of the branches' angle estimated by the skeleton model. Finally, we extracted the morphological structure based on the revised branches' angle through verification of total length of the estimated and measured branches.[Result] The experimental trees' branch structure was clear. Branch length and angle were all automatically determinated. Primary branches extracted were totally 22 and the secondary branches were 43. Regression equation of the estimated and measured length was Y=1.003X+0.03 which performed with R-squared of 0.998. The root mean square error (RMSE) between estimated length and measured length was 0.029 m. Moreover, regression equation of the branch angle estimated and measured by skeleton model was Y=0.672X+16.779, which performed with R-squared of 0.356 and RMSE of 20.45°. Nevertheless, regression equation of the branch angle estimated and measured by cylinder fitting was Y=1.008X+0.18, it performed with R-squared of 0.975 and RMSE of 3.44°.[Conclusion] The algorithm of estimation and extraction based on cylinder fitting could accurately determine branch structure on individual tree. Furtherly, the extracted branches' length performed high precision and cylinder fitting method could effectively improve accuracy of the branch angles estimated by skeleton model.

Key words: terrestrial laser scanning, skeleton model, branch length, morphological structure, branch angle

CLC Number:

S757

Liu Jinpeng, Zhang Huaiqing, Liu Min, Li Yongliang. Automatic Extraction of Individual Tree Branch Structure Parameters from Terrestrial Laser Scanning Data[J]. Scientia Silvae Sinicae, 2016, 52(3): 121-128.

References

倪文俭,过志峰,孙国清,等. 2010.基于地基激光雷达数据的单木结构参数提取研究.高技术通讯, (2):191-198.
(Ni W J, Guo Z F, Sun G Q, et al. 2010. Structure parameters extraction of individual tree based on terrestrial laser ladar data. Chinese High Technology Letters,(2):191-198.[in Chinese])
王宁宁,尹文广,黄秦军,等. 2015.三维扫描技术在获取杨树树冠结构特征参数上的应用.林业科学,51(5):108-116.
(Wang N N, Yin W G, Huang Q J, et al. 2015. Application of 3-D scanning technology on acquiring poplar crown structure characteristic parameters. Scientia Silvae Sinicae,51(5):108-116.[in Chinese])
张国财,原瑶,阳艳岚. 2008.树木分枝结构研究概述.林业科技情报, 40(1):8-9.
(Zhang G C, Yuan Y, Yang Y L. 2008.The trees branch structure research overview. Forestry Science and Technology Information, 40(1):8-9.[in Chinese])
Bienert A, Scheller S, Keane E, et al. 2006. Application of terrestrial laser scanners for the determination of forest inventory parameters. International Archives of Photogrammetry, Remote Sensing and Spatial Information Sciences, 36:Part 5.
Bienert A, Scheller S, Keane E, et al. 2007. Tree detection and diameter estimations by analysis of forest terrestrial laser scanner point clouds.ISPRS Workshop on Laser Scanning 2007 and SilviLaser 2007 Espoo, Espoo, Finland, 12-14 September, 50-55.
Bucksch A, Lindenbergh R, Menenti M. 2010. SkelTre. The Visual Computer, 26(10):1283-1300.
Bucksch A, Lindenbergh R. 2008. CAMPINO-a skeletonization method for point cloud processing. ISPRS Journal of Photogrammetry and Remote Sensing, 63(1):115-127.
Cao J, Tagliasacchi A, Olson M, et al. 2010. Point cloud skeletons via laplacian based contraction. Published in Shape Modeling International Conference(SMI), 187-197.
Gorte B, Pfeifer N. 2004. Structuring laser-scanned trees using 3D mathematical morphology. International Archives of Photogrammetry and Remote Sensing, 35(B5):929-933.
Király G, Brolly G. 2010. Volume calculations of single trees based on terrestrial laser scanning. Silvilaser, Freiburg, Germany.
Livny Y, Yan F, Olson M, et al. 2010. Automatic reconstruction of tree skeletal structures from point clouds. ACM Transactions on Graphics (TOG), 29(6):151.
Reeb G. 1946. Sur les points singuliers d'une forme de pfaff completement intégrable ou d'une fonction numérique. CR Acad Sci Paris, 222:847-849.
Srinivasan S, Popescu S C, Eriksson M, et al. 2015. Terrestrial laser scanning as an effective tool to retrieve tree level height, crown width, and stem diameter. Remote Sensing, 7(2):1877-1896.
Su Z, Zhao Y, Zhao C, et al. 2011. Skeleton extraction for tree models. Mathematical and Computer Modelling, 54(3):1115-1120.
Tagliasacchi A, Zhang H, Cohen-Or D. 2009. Curve skeleton extraction from incomplete point cloud. ACM Transactions on Graphics (TOG)-Proceedings of ACM,28(3):71.
Verroust A, Lazarus F. 2000. Extracting skeletal curves from 3D scattered data. The Visual Computer, 16(1):15-25.

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Automatic Extraction of Individual Tree Branch Structure Parameters from Terrestrial Laser Scanning Data

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