Konsep Inti
An efficient plane arrangement mechanism that enables the construction of concise polyhedral decompositions for low-polygon surface and volume modeling from complex 3D data.
Abstrak
The paper presents a scalable plane arrangement method for generating low-polygon surface and volume meshes from 3D point clouds. The key contributions are:
- An ordering scheme for the plane insertion operations that prioritizes splits creating cells that cannot be split further and balances the number of polygons in the cells.
- The direct use of input points during arrangement construction to replace costly intersection tests with simple point-plane orientation checks.
- A remeshing and simplification technique to extract low-polygon surface meshes and lightweight convex decompositions of volumes from the arrangement.
The proposed method significantly outperforms existing plane arrangement algorithms in terms of complexity and runtime, while producing state-of-the-art results for low-poly surface and volume modeling tasks. Experiments on the Thingi10k dataset and comparisons to baselines demonstrate the effectiveness of the approach.
Statistik
The average number of polyhedral cells in the decompositions produced by our method is 73 for simple models, 256 for moderate models, and 705 for complex models.
The average number of polygonal facets in the reconstructed surface meshes is 53 for simple models, 167 for moderate models, and 478 for complex models.
The average symmetric Chamfer distance between the ground truth and reconstructed meshes is 0.193 for simple models, 0.254 for moderate models, and 0.224 for complex models.
The average symmetric Hausdorff distance between the ground truth and reconstructed meshes is 1.15 for simple models, 2.32 for moderate models, and 2.78 for complex models.
The average construction time of our method is 3.06 seconds for simple models, 16.3 seconds for moderate models, and 68.1 seconds for complex models.
Kutipan
"The key contribution of our work is an efficient mechanism for constructing more concise arrangements in less time than existing methods."
"We directly exploit input points to avoid unnecessary splitting operations and replace intersection tests between polyhedral cells and polygons with simply point-plane orientation tests."
"We carefully order the plane insertion operations to further lower the computational complexity of the algorithm."