Abstract
3D mesh denoising plays an important role in 3D model pre-processing and repair. A fundamental challenge in the mesh denoising process is to accurately extract features from the noise and to preserve and restore the scene structure features of the model. In this paper, we propose a novel feature-preserving mesh denoising method, which was based on robust guidance normal estimation, accurate feature point extraction and an anisotropic vertex denoising strategy. The methodology of the proposed approach is as follows: (1) The dual weight function that takes into account the angle characteristics is used to estimate the guidance normals of the surface, which improved the reliability of the joint bilateral filtering algorithm and avoids losing the corner structures; (2) The filtered facet normal is used to classify the feature points based on the normal voting tensor (NVT) method, which raised the accuracy and integrity of feature classification for the noisy model; (3) The anisotropic vertex update strategy is used in triangular mesh denoising: updating the non-feature points with isotropic neighborhood normals, which effectively suppressed the sharp edges from being smoothed; updating the feature points based on local geometric constraints, which preserved and restored the features while avoided sharp pseudo features. The detailed quantitative and qualitative analyses conducted on synthetic and real data show that our method can remove the noise of various mesh models and retain or restore the edge and corner features of the model without generating pseudo features.
Highlights
The 3D mesh model is widely used in 3D space measurement and positioning technology, augmented reality (AR) and virtual reality (VR), auxiliary medical analysis, industrial measurement, cultural heritage protection or restoration, etc. [1]
We summarize the contributions of the proposed method as follows: (1) A facet normal filtering method considering corner features is proposed, which improves the robustness of the filtering algorithm by improving the guided mesh normal filtering (GMNF) method
Most of the current algorithms can remove the noise on the surface of the model, but the structure retention and restoration effect are still not satisfactory
Summary
The 3D mesh model is widely used in 3D space measurement and positioning technology, augmented reality (AR) and virtual reality (VR), auxiliary medical analysis, industrial measurement, cultural heritage protection or restoration, etc. [1]. Due to the influence of the measurement environment, the limitation of data acquisition accuracy, the 3D mesh data inevitably has different degrees of noise, which seriously affects the surface accuracy of reconstruction. This poses a huge obstacle to the practical application of the 3D mesh model, and it must be preprocessed by appropriate mesh denoising methods. With the development of learning-based methodology, data-driven methods have been used in 3D mesh model denoising [6], which do not need manual input to extract features. These methods require paired data (noisy meshes with ground truths) for training, and the reliability heavily depends on the initial training data set
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