11.2.1.2.2 Mesh Representations from 3D Point Clouds

Kang, X.C.[Xiao-Chen], Liu, J.P.[Ji-Ping], Lin, X.G.[Xiang-Guo],
Streaming Progressive TIN Densification Filter for Airborne LiDAR Point Clouds Using Multi-Core Architectures,
RS(6), No. 8, 2014, pp. 7212-7232.
DOI Link 1410
BibRef

Lhuillier, M.[Maxime],
Surface reconstruction from a sparse point cloud by enforcing visibility consistency and topology constraints,
CVIU(175), 2018, pp. 52-71.
Elsevier DOI 1812
Surface reconstruction, Manifold, Genus, Visibility, Sparse features, Environment modeling BibRef

Lhuillier, M.[Maxime],
Improving Thin Structures in Surface Reconstruction from Sparse Point Cloud,
3D-Wild18(I:443-458).
Springer DOI 1905
BibRef

Lhuillier, M.[Maxime], Yu, S.[Shuda],
Manifold surface reconstruction of an environment from sparse Structure-from-Motion data,
CVIU(117), No. 11, 2013, pp. 1628-1644.
Elsevier DOI 1309
BibRef
Earlier: A2, A1:
Genus refinement of a manifold surface reconstructed by sculpting the 3d-Delaunay triangulation of Structure-from-Motion points,
ICPR12(1021-1025).
WWW Link. 1302
2-Manifold reconstruction BibRef

Dong, Y.Q.[You-Qiang], Cui, X.[Ximin], Zhang, L.[Li], Ai, H.B.[Hai-Bin],
An Improved Progressive TIN Densification Filtering Method Considering the Density and Standard Variance of Point Clouds,
IJGI(7), No. 10, 2018, pp. xx-yy.
DOI Link 1811
BibRef

Mérigot, Q.[Quentin], Meyron, J.[Jocelyn], Thibert, B.[Boris],
An Algorithm for Optimal Transport between a Simplex Soup and a Point Cloud,
SIIMS(11), No. 2, 2018, pp. 1363-1389.
DOI Link 1807
applications such as optimal quantization of a probability density over a surface, remeshing, or rigid point set registration on a mesh. BibRef

Hou, J.,
Permuted Sparse Representation for 3D Point Clouds,
SPLetters(26), No. 12, December 2019, pp. 1847-1851.
IEEE DOI 2001
image reconstruction, image representation, image sampling, iterative methods, optimisation, stereo image processing, irregular structure BibRef

Xu, W.[Wei], Neumann, I.[Ingo],
Finite Element Analysis based on A Parametric Model by Approximating Point Clouds,
RS(12), No. 3, 2020, pp. xx-yy.
DOI Link 2002
BibRef

Schöps, T.[Thomas], Sattler, T.[Torsten], Pollefeys, M.[Marc],
SurfelMeshing: Online Surfel-Based Mesh Reconstruction,
PAMI(42), No. 10, October 2020, pp. 2494-2507.
IEEE DOI 2009
Real-time systems, Simultaneous localization and mapping, Surface reconstruction, Cameras, surfels BibRef

Bláha, M., Rothermel, M., Oswald, M.R., Sattler, T., Richard, A., Wegner, J.D., Pollefeys, M., Schindler, K.,
Semantically Informed Multiview Surface Refinement,
ICCV17(3839-3847)
IEEE DOI 1802
computational geometry, image segmentation, inference mechanisms, mesh generation, solid modelling, 3D surface meshes, MRF inference, BibRef

Ladický, L.[Lubor], Saurer, O., Jeong, S., Maninchedda, F., Pollefeys, M.[Marc],
From Point Clouds to Mesh Using Regression,
ICCV17(3913-3922)
IEEE DOI 1802
feature extraction, image colour analysis, image reconstruction, learning (artificial intelligence), mesh generation, octrees, Training BibRef

Lee, J.[Jinwon], Cheon, S.U.[Sang-Uk], Yang, J.[Jeongsam],
Connectivity-based convolutional neural network for classifying point clouds,
PR(112), 2021, pp. 107708.
Elsevier DOI 2102
Convolutional neural networks, Delaunay triangulation, Dense connectivity, Neighbor connectivity, Point clouds classification BibRef

Lv, C.L.[Chen-Lei], Lin, W.S.[Wei-Si], Zhao, B.Q.[Bao-Quan],
Voxel Structure-Based Mesh Reconstruction From a 3D Point Cloud,
MultMed(24), No. 2022, pp. 1815-1829.
IEEE DOI 2204
Optimization, Surface reconstruction, Image reconstruction, Noise reduction, Measurement, Reconstruction algorithms, isotropic property BibRef

Liu, Q.[Qi], Xu, S.B.[Shi-Biao], Xiao, J.[Jun], Wang, Y.[Ying],
Sharp Feature-Preserving 3D Mesh Reconstruction from Point Clouds Based on Primitive Detection,
RS(15), No. 12, 2023, pp. xx-yy.
DOI Link 2307
BibRef

Song, S.[Shuang], Cui, Z.P.[Zhao-Peng], Qin, R.[Rongjun],
Vis2Mesh: Efficient Mesh Reconstruction from Unstructured Point Clouds of Large Scenes with Learned Virtual View Visibility,
ICCV21(6494-6504)
IEEE DOI 2203
Point cloud compression, Surface reconstruction, Solid modeling, Pipelines, Neural networks, Reconstruction algorithms, Stereo, BibRef

Wei, X.K.[Xing-Kui], Chen, Z.Q.[Zheng-Qing], Fu, Y.W.[Yan-Wei], Cui, Z.P.[Zhao-Peng], Zhang, Y.[Yinda],
Deep Hybrid Self-Prior for Full 3D Mesh Generation,
ICCV21(5785-5794)
IEEE DOI 2203
Deep learning, Point cloud compression, Geometry, Solid modeling, Image color analysis, Neural networks, Stereo, Transfer/Low-shot/Semi/Unsupervised Learning BibRef

Sulzer, R.[Raphael], Landrieu, L.[Loïc], Boulch, A.[Alexandre], Marlet, R.[Renaud], Vallet, B.[Bruno],
Deep Surface Reconstruction from Point Clouds with Visibility Information,
ICPR22(2415-2422)
IEEE DOI 2212
Point cloud compression, Surface reconstruction, Adaptation models, Codes, Neural networks, Data models BibRef

Caraffa, L.[Laurent], Marchand, Y.[Yanis], Brédif, M.[Mathieu], Vallet, B.[Bruno],
Efficiently Distributed Watertight Surface Reconstruction,
3DV21(1432-1441)
IEEE DOI 2201
BibRef
And: A2, A4, A1, Only:
Evaluating Surface Mesh Reconstruction of Open Scenes,
ISPRS21(B2-2021: 369-376).
DOI Link 2201
Point cloud compression, Surface reconstruction, Laser radar, Pipelines, Clustering algorithms, Reconstruction algorithms, big data. BibRef

Milani, S.,
A Syndrome-Based Autoencoder For Point Cloud Geometry Compression,
ICIP20(2686-2690)
IEEE DOI 2011
Decoding, Encoding, Geometry, Correlation, Convolutional codes, Image reconstruction, UNet BibRef

Liu, M.H.[Ming-Hua], Zhang, X.S.[Xiao-Shuai], Su, H.[Hao],
Meshing Point Clouds with Predicted Intrinsic-extrinsic Ratio Guidance,
ECCV20(VIII:68-84).
Springer DOI 2011
BibRef

Lê, E.T.[Eric-Tuan], Mitra, N.J.[Niloy J.], Kokkinos, I.[Iasonas],
Softmesh: Learning Probabilistic Mesh Connectivity via Image Supervision,
3DV21(1065-1074)
IEEE DOI 2201
Point cloud compression, Pipelines, Transfer learning, Pose estimation, Transforms, Rendering (computer graphics), differentiable rendering BibRef

Wang, H.Y.[Hao-Yang], Güler, R.A.[Riza Alp], Kokkinos, I.[Iasonas], Papandreou, G.[George], Zafeiriou, S.P.[Stefanos P.],
BLSM: A Bone-level Skinned Model of the Human Mesh,
ECCV20(V:1-17).
Springer DOI 2011
BibRef

Daroya, R., Atienza, R., Cajote, R.,
REIN: Flexible Mesh Generation from Point Clouds,
WiCV20(1444-1453)
IEEE DOI 2008
Surface reconstruction, Image reconstruction, Surface treatment, Mesh generation, Feature extraction BibRef

Li, C.L.[Chun-Liang], Simon, T.[Tomas], Saragih, J.[Jason], Poczos, B.[Barnabas], Sheikh, Y.[Yaser],
LBS Autoencoder: Self-Supervised Fitting of Articulated Meshes to Point Clouds,
CVPR19(11959-11968).
IEEE DOI 2002
BibRef

Zeng, W.[Wei], Gevers, T.[Theo],
3DContextNet: K-d Tree Guided Hierarchical Learning of Point Clouds Using Local and Global Contextual Cues,
DeepLearn-G18(III:314-330).
Springer DOI 1905
BibRef

Zhang, C.[Cha], Florencio, D.[Dinei], Loop, C.[Charles],
Point cloud attribute compression with graph transform,
ICIP14(2066-2070)
IEEE DOI 1502
Discrete cosine transforms BibRef

Turner, E., Zakhor, A.,
Watertight Planar Surface Meshing of Indoor Point-Clouds with Voxel Carving,
3DV13(41-48)
IEEE DOI 1311
architecture BibRef

Daribo, I.[Ismael], Furukawa, R.[Ryo], Sagawa, R.[Ryusuke], Kawasaki, H.[Hiroshi],
Adaptive arithmetic coding for point cloud compression,
3DTV12(1-4).
IEEE DOI 1212
BibRef

Daribo, I.[Ismael], Furukawa, R.[Ryo], Sagawa, R.[Ryusuke], Kawasaki, H.[Hiroshi], Hiura, S.[Shinsaku], Asada, N.[Naoki],
Point cloud compression for grid-pattern-based 3D scanning system,
VCIP11(1-4).
IEEE DOI 1201
BibRef
And:
Dynamic Compression of Curve-Based Point Cloud,
PSIVT11(II: 323-334).
Springer DOI 1111
BibRef

Hoppe, C., Kramker, S.,
Adaptive meshing and detail-reduction of 3D-point clouds from laser scans,
3DARCH09(xx-yy).
PDF File. 0902
BibRef

Shi, Z.K.[Zhi-Kuan], Tang, G.A.[Guo-An],
An Approach from Point Cloud plus Feature Data to Grid DEM,
ISPRS08(B3b: 247 ff).
PDF File. 0807
BibRef

Yang, Z.W.[Zhou-Wang], Seo, Y.H.[Yeong-Hwa], Kim, T.W.[Tae-Wan],
Reconstructing a Mesh from a Point Cloud by Using a Moving Parabolic Approximation,
GMP08(xx-yy).
Springer DOI 0804
BibRef

Aganj, E.[Ehsan], Keriven, R.[Renaud], Pons, J.P.[Jean-Philippe],
Photo-consistent surface reconstruction from noisy point clouds,
ICIP09(505-508).
IEEE DOI 0911
BibRef

Labatut, P.[Patrick], Pons, J.P.[Jean-Philippe], Keriven, R.[Renaud],
Efficient Multi-View Reconstruction of Large-Scale Scenes using Interest Points, Delaunay Triangulation and Graph Cuts,
ICCV07(1-8).
IEEE DOI 0710
Start from point cloud, generate triangulation. BibRef

Rodríguez Gonzálvez, P., González Aguilera, D., Gómez Lahoz, J.,
From Point Cloud to Surface: Modeling Structures in Laser Scanner Point Clouds,
Laser07(338).
PDF File. 0709
BibRef

Singh, J.M.[Jag Mohan], Narayanan, P.J.,
Progressive Decomposition of Point Clouds Without Local Planes,
ICCVGIP06(364-375).
Springer DOI 0612
BibRef

Volodine, T.[Tim], Vanderstraeten, D.[Denis], Roose, D.[Dirk],
Smoothing of Meshes and Point Clouds Using Weighted Geometry-Aware Bases,
GMP06(687-693).
Springer DOI 0607
BibRef

Chapter on 3-D Object Description and Computation Techniques, Surfaces, Deformable, View Generation, Video Conferencing continues in
Feature Extraction and Processing on Mesh Representation .