TY - JOUR
T1 - 3D Point Cloud Denoising Using Graph Laplacian Regularization of a Low Dimensional Manifold Model
AU - Zeng, Jin
AU - Cheung, Gene
AU - Ng, Michael
AU - Pang, Jiahao
AU - Yang, Cheng
N1 - The work of Gene Cheung was supported by the Natural Sciences and Engineering Research Council of Canada (NSERC) under Grant RGPIN-2019-06271 and Grant RGPAS-2019-00110. The work of Michael Ng was supported in part by the HKRGC GRF under Grant 12306616, Grant 12200317, Grant 12300218, and Grant 12300519 and in part by HKU under Grant 104005583.
Publisher Copyright:
© 1992-2012 IEEE.
PY - 2020/1
Y1 - 2020/1
N2 - 3D point cloud - a new signal representation of volumetric objects - is a discrete collection of triples marking exterior object surface locations in 3D space. Conventional imperfect acquisition processes of 3D point cloud - e.g., stereo-matching from multiple viewpoint images or depth data acquired directly from active light sensors - imply non-negligible noise in the data. In this paper, we extend a previously proposed low-dimensional manifold model for the image patches to surface patches in the point cloud, and seek self-similar patches to denoise them simultaneously using the patch manifold prior. Due to discrete observations of the patches on the manifold, we approximate the manifold dimension computation defined in the continuous domain with a patch-based graph Laplacian regularizer, and propose a new discrete patch distance measure to quantify the similarity between two same-sized surface patches for graph construction that is robust to noise. We show that our graph Laplacian regularizer leads to speedy implementation and has desirable numerical stability properties given its natural graph spectral interpretation. Extensive simulation results show that our proposed denoising scheme outperforms state-of-the-art methods in objective metrics and better preserves visually salient structural features like edges.
AB - 3D point cloud - a new signal representation of volumetric objects - is a discrete collection of triples marking exterior object surface locations in 3D space. Conventional imperfect acquisition processes of 3D point cloud - e.g., stereo-matching from multiple viewpoint images or depth data acquired directly from active light sensors - imply non-negligible noise in the data. In this paper, we extend a previously proposed low-dimensional manifold model for the image patches to surface patches in the point cloud, and seek self-similar patches to denoise them simultaneously using the patch manifold prior. Due to discrete observations of the patches on the manifold, we approximate the manifold dimension computation defined in the continuous domain with a patch-based graph Laplacian regularizer, and propose a new discrete patch distance measure to quantify the similarity between two same-sized surface patches for graph construction that is robust to noise. We show that our graph Laplacian regularizer leads to speedy implementation and has desirable numerical stability properties given its natural graph spectral interpretation. Extensive simulation results show that our proposed denoising scheme outperforms state-of-the-art methods in objective metrics and better preserves visually salient structural features like edges.
KW - Graph signal processing
KW - low-dimensional manifold
KW - point cloud denoising
UR - http://www.scopus.com/inward/record.url?scp=85079647239&partnerID=8YFLogxK
U2 - 10.1109/TIP.2019.2961429
DO - 10.1109/TIP.2019.2961429
M3 - Journal article
AN - SCOPUS:85079647239
SN - 1057-7149
VL - 29
SP - 3474
EP - 3489
JO - IEEE Transactions on Image Processing
JF - IEEE Transactions on Image Processing
ER -