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Anisotropic Gauss Reconstruction for Unoriented Point Clouds (2405.17193v1)

Published 27 May 2024 in cs.GR

Abstract: Unoriented surface reconstructions based on the Gauss formula have attracted much attention due to their elegant mathematical formulation and excellent performance. However, the isotropic characteristics of the formulation limit their capacity to leverage the anisotropic information within the point cloud. In this work, we propose a novel anisotropic formulation by introducing a convection term in the original Laplace operator. By choosing different velocity vectors, the anisotropic feature can be exploited to construct more effective linear equations. Moreover, an adaptive selection strategy is introduced for the velocity vector to further enhance the orientation and reconstruction performance of thin structures. Extensive experiments demonstrate that our method achieves state-of-the-art performance and manages various challenging situations, especially for models with thin structures or small holes. The source code will be released on GitHub.

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References (35)
  1. Digs: Divergence guided shape implicit neural representation for unoriented point clouds. In Proceedings of the IEEE/CVF Conference on Computer Vision and Pattern Recognition. 19323–19332.
  2. Fatih Calakli and Gabriel Taubin. 2011. SSD: Smooth signed distance surface reconstruction. In Computer Graphics Forum, Vol. 30. Wiley Online Library, 1993–2002.
  3. Eric Darve. 2000. The Fast Multipole Method: Numerical Implementation. J. Comput. Phys. 160, 1 (2000), 195–240. https://doi.org/10.1006/jcph.2000.6451
  4. Tamal K Dey and Jian Sun. 2005. . An Adaptive MLS Surface for Reconstruction with Guarantees.. In Symposium on Geometry processing. 43–52.
  5. Points2surf learning implicit surfaces from point clouds. In European Conference on Computer Vision. Springer, 108–124.
  6. Implicit geometric regularization for learning shapes. arXiv preprint arXiv:2002.10099 (2020).
  7. Pcpnet learning local shape properties from raw point clouds. In Computer graphics forum, Vol. 37. Wiley Online Library, 75–85.
  8. Surface reconstruction from unorganized points. In Proceedings of the 19th annual conference on computer graphics and interactive techniques. 71–78.
  9. Iterative poisson surface reconstruction (ipsr) for unoriented points. arXiv preprint arXiv:2209.09510 (2022).
  10. Variational implicit point set surfaces. ACM Transactions on Graphics (TOG) 38, 4 (2019), 1–13.
  11. Bilateral Hermite Radial Basis Functions for Contour-based Volume Segmentation. In Computer Graphics Forum, Vol. 32. Wiley Online Library, 123–132.
  12. Michael Kazhdan. 2005. Reconstruction of solid models from oriented point sets. In Proceedings of the third Eurographics symposium on Geometry processing. 73–es.
  13. Poisson surface reconstruction. In Proceedings of the fourth Eurographics symposium on Geometry processing, Vol. 7. 0.
  14. Poisson surface reconstruction with envelope constraints. In Computer graphics forum, Vol. 39. Wiley Online Library, 173–182.
  15. Michael Kazhdan and Hugues Hoppe. 2013. Screened poisson surface reconstruction. ACM Transactions on Graphics (ToG) 32, 3 (2013), 1–13.
  16. Diederik P Kingma and Jimmy Ba. 2014. Adam: A method for stochastic optimization. arXiv preprint arXiv:1412.6980 (2014).
  17. Ravikrishna Kolluri. 2008. Provably good moving least squares. ACM Transactions on Algorithms (TALG) 4, 2 (2008), 1–25.
  18. Shs-net: Learning signed hyper surfaces for oriented normal estimation of point clouds. In Proceedings of the IEEE/CVF Conference on Computer Vision and Pattern Recognition. 13591–13600.
  19. Surface Reconstruction from Point Clouds without Normals by Parametrizing the Gauss Formula. ACM Trans. Graph. 42, 2 (2023), 14:1–14:19.
  20. A closed-form formulation of HRBF-based surface reconstruction by approximate solution. Computer-Aided Design 78 (2016), 147–157.
  21. Surface Reconstruction Based on the Modified Gauss Formula. ACM Trans. Graph. 38, 1 (2019), 2:1–2:18.
  22. Hermite radial basis functions implicits. In Computer Graphics Forum, Vol. 30. Wiley Online Library, 27–42.
  23. Streaming surface reconstruction using wavelets. In Computer Graphics Forum, Vol. 27. Wiley Online Library, 1411–1420.
  24. Margaret McIntyre and Grant Cairns. 1993. A new formula for winding number. Geometriae Dedicata 46, 2 (1993), 149–159.
  25. Orienting point clouds with dipole propagation. ACM Transactions on Graphics (TOG) 40, 4 (2021), 1–14.
  26. Interpolating implicit surfaces from scattered surface data using compactly supported radial basis functions. In Proceedings International Conference on Shape Modeling and Applications. 89–98. https://doi.org/10.1109/SMA.2001.923379
  27. ROYUD Nishino and Shohei Hido Crissman Loomis. 2017. Cupy: A numpy-compatible library for nvidia gpu calculations. 31st confernce on neural information processing systems 151, 7 (2017).
  28. Shape as points: A differentiable poisson solver. Advances in Neural Information Processing Systems 34 (2021), 13032–13044.
  29. Biorthogonal wavelet surface reconstruction using partial integrations. In Computer Graphics Forum, Vol. 37. Wiley Online Library, 13–24.
  30. Implicit surfaces with globally regularised and compactly supported basis functions. Advances in Neural Information Processing Systems 19 (2006).
  31. Neural-Singular-Hessian: Implicit Neural Representation of Unoriented Point Clouds by Enforcing Singular Hessian. ACM Transactions on Graphics (TOG) 42, 6 (2023), 1–14.
  32. Point normal orientation and surface reconstruction by incorporating isovalue constraints to Poisson equation. Computer Aided Geometric Design 103 (2023), 102195.
  33. Globally Consistent Normal Orientation for Point Clouds by Regularizing the Winding-Number Field. ACM Trans. Graph. 42, 4 (2023), 111:1–111:15.
  34. Globally consistent normal orientation for point clouds by regularizing the winding-number field. ACM Transactions on Graphics (TOG) 42, 4 (2023), 1–15.
  35. Learning consistency-aware unsigned distance functions progressively from raw point clouds. Advances in Neural Information Processing Systems 35 (2022), 16481–16494.
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