Geometric Abstraction from Noisy Image-Based 3D Reconstructions
This work addresses the challenge of geometric abstraction for noisy reconstructions, which is incremental as it builds on existing methods for planar structures.
The paper tackles the problem of creating geometric abstracted models from noisy image-based 3D reconstructions by partitioning scenes into slices and solving energy minimization problems, resulting in models with adjustable levels of detail as demonstrated on synthetic and real-world data.
Creating geometric abstracted models from image-based scene reconstructions is difficult due to noise and irregularities in the reconstructed model. In this paper, we present a geometric modeling method for noisy reconstructions dominated by planar horizontal and orthogonal vertical structures. We partition the scene into horizontal slices and create an inside/outside labeling represented by a floor plan for each slice by solving an energy minimization problem. Consecutively, we create an irregular discretization of the volume according to the individual floor plans and again label each cell as inside/outside by minimizing an energy function. By adjusting the smoothness parameter, we introduce different levels of detail. In our experiments, we show results with varying regularization levels using synthetically generated and real-world data.