[1] 1耿国华， 张鹏飞， 刘雨萌， 等. 基于断裂面邻域特征的文物碎片拼接［J］. 光学 精密工程， 2021， 29（5）： 1169-1179. doi: 10.37188/OPE.20212905.1169GENGG H， ZHANGP F， LIUY M， et al. Reassembly method of cultural relic fragments based on the neighborhood characteristics of fracture surface［J］. Opt. Precision Eng.， 2021， 29（5）： 1169-1179.（in Chinese）. doi: 10.37188/OPE.20212905.1169

[2] 2林森， 张强. 应用邻域点信息描述与匹配的点云配准［J］. 光学 精密工程， 2022， 30（8）： 984-997. doi: 10.37188/OPE.20223008.0984LINS， ZHANGQ. Point cloud registration using neighborhood point information description and matching［J］. Opt. Precision Eng.， 2022， 30（8）： 984-997.（in Chinese）. doi: 10.37188/OPE.20223008.0984

[3] A TAGLIASACCHI, H ZHANG, D COHEN-OR. Curve skeleton extraction from incomplete point cloud. ACM Transactions on Graphics, 28, 71(2009).

[4] J J CAO, A TAGLIASACCHI, M OLSON et al. Point cloud skeletons via Laplacian based contraction, 187-197(2010).

[5] L LI, W C WANG, Y Y CHU. A simple and stable centeredness measure for 3D curve skeleton extraction. IEEE Transactions on Visualization and Computer Graphics, 28, 1486-1499(2022).

[6] H HUANG, S H WU, D COHEN-OR et al. L₁-medial skeleton of point cloud. ACM Transactions on Graphics, 32, 1-8(2013).

[7] H X QIN, J HAN, N LI et al. Mass-driven topology-aware curve skeleton extraction from incomplete point clouds. IEEE Transactions on Visualization and Computer Graphics, 26, 2805-2817(2020).

[8] P K SAHA, G BORGEFORS, G SANNITI DI BAJA. A survey on skeletonization algorithms and their applications. Pattern Recognition Letters, 76, 3-12(2016).

[9] N D CORNEA, D SILVER, P MIN. Curve-skeleton properties， applications， and algorithms. IEEE Transactions on Visualization and Computer Graphics, 13, 530-548(2007).

[10] M LIVESU, F GUGGERI, R SCATENI. Reconstructing the curve-skeletons of 3D shapes using the visual hull. IEEE Transactions on Visualization and Computer Graphics, 18, 1891-1901(2012).

[11] S S XIE, J D LIU, C D SMITH. Curve skeleton-based shape representation and classification, 529-532(2012).

[12] A TAGLIASACCHI, T DELAME, M SPAGNUOLO et al. 3D skeletons： a state-of-the-art report. Computer Graphics Forum, 35, 573-597(2016).

[13] S BOUIX, K SIDDIQI, A TANNENBAUM. Flux driven fly throughs, I(2003).

[14] M S HASSOUNA, A A FARAG, R FALK. Differential fly-throughs （DFT）： a general framework for computing flight paths, 654-661(2005).

[15] V CHUNDURU, M ROY et al. Hand tracking in 3D space using MediaPipe and PnP method for intuitive control of virtual globe, 1-6(2021).

[16] Y S TANG, Y TIAN, J W LU et al. Deep progressive reinforcement learning for skeleton-based action recognition, 5323-5332(2018).

[17] S Y BOULAHIA, E ANQUETIL, R KULPA et al. 3D multistroke mapping （3DMM）： transfer of hand-drawn pattern representation for skeleton-based gesture recognition, 462-467(2017).

[18] C Y LI, A HAMZA. Skeleton path based approach for nonrigid 3D shape analysis and retrieval, 84-95(2011).

[19] Y SIRIN, M F DEMIRCI. 2D and 3D shape retrieval using skeleton filling rate. Multimedia Tools and Applications, 76, 7823-7848(2017).

[20] T WANG, I CHENG, V LOPEZ et al. Valence normalized spatial Median for skeletonization and matching, 55-62(2009).

[21] S WU, W L WEN, B X XIAO et al. An accurate skeleton extraction approach from 3D point clouds of maize plants. Frontiers in Plant Science, 10, 248(2019).

[22] Z X SU, Y D ZHAO, C J ZHAO et al. Skeleton extraction for tree models. Mathematical and Computer Modelling, 54, 1115-1120(2011).

[23] H L HU, Z LI, X G JIN et al. Curve skeleton extraction from 3D point clouds through hybrid feature point shifting and clustering. Computer Graphics Forum, 39, 111-132(2020).

[24] C LIN, C J LI, Y LIU et al. Point2Skeleton： learning skeletal representations from point clouds, 4275-4284(2021).

[25] R OGNIEWICZ. Voronoi skeletons： theory and applications, 92, 63-69(1992).

[26] L LU, B LÉVY, W WANG. Centroidal Voronoi tessellation of line segments and graphs, 31, 775-784(2012).

[27] A TAGLIASACCHI, I ALHASHIM, M OLSON et al. Mean curvature skeletons. Computer Graphics Forum, 31, 1735-1744(2012).

[28] N VAHRENKAMP, E KOCH, M WÄCHTER et al. Planning high-quality grasps using mean curvature object skeletons. IEEE Robotics and Automation Letters, 3, 911-918(2018).

[29] M CHUANG, M KAZHDAN. Fast mean-curvature flow via finite-elements tracking. Computer Graphics Forum, 30, 1750-1760(2011).

[30] R ATIENZA. Pyramid U-network for skeleton extraction from shape points, 1177-1180(2019).

[31] Z Y DOU, C LIN, R XU et al. Coverage axis： inner point selection for 3D shape skeletonization. Computer Graphics Forum, 41, 419-432(2022).

[32] 32吴庆华， 蔡琼捷思， 黎志昂， 等. 扩展高斯图像聚类的缺失点云配准［J］. 光学 精密工程， 2021， 29（5）： 1199-1206. doi: 10.37188/OPE.20212905.1199WUQ H， CAIQ， LIZ A， et al. Registration of losing point cloud based on clustering extended Gaussian image［J］. Opt. Precision Eng.， 2021， 29（5）： 1199-1206.（in Chinese）. doi: 10.37188/OPE.20212905.1199

[33] 33赵夫群， 周明全. 层次化点云去噪算法［J］. 光学 精密工程， 2020， 28（7）： 1618-1625. doi: 10.37188/OPE.20202807.1618ZHAOF Q， ZHOUM Q. Hierarchical point cloud denoising algorithm［J］. Opt. Precision Eng.， 2020， 28（7）： 1618-1625.（in Chinese）. doi: 10.37188/OPE.20202807.1618

[34] 34汤慧， 周明全， 耿国华. 基于扩展的点特征直方图特征的点云匹配算法［J］. 激光与光电子学进展， 2019， 56（24）： 203-210. doi: 10.3788/lop56.241503TANGH， ZHOUM Q， GENGG H. Point cloud registration algorithm based on extended point feature histogram feature［J］. Laser ＆ Optoelectronics Progress， 2019， 56（24）： 203-210.（in Chinese）. doi: 10.3788/lop56.241503

[35] D S OUYANG, H Y FENG. On the normal vector estimation for point cloud data from smooth surfaces. Computer-Aided Design, 37, 1071-1079(2005).

[36] Y T WANG, H Y FENG, F É DELORME et al. An adaptive normal estimation method for scanned point clouds with sharp features. Computer-Aided Design, 45, 1333-1348(2013).

[37] K KLASING, D ALTHOFF, D WOLLHERR et al. Comparison of surface normal estimation methods for range sensing applications, 3206-3211(2009).

[38] L LI, W C WANG. Contracting medial surfaces isotropically for fast extraction of centred curve skeletons. Computer Graphics Forum, 36, 529-539(2017).