SimpliCity：用简单的正则化 3D 模型重建建筑物

arXiv - CS - Computational Geometry Pub Date : 2024-04-11 DOI:arxiv-2404.08104

Jean-Philippe Bauchet, Raphael Sulzer, Florent Lafarge, Yuliya Tarabalka

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引用次数: 0

摘要

从机载激光雷达点云重建建筑物的自动方法侧重于以快速和可扩展的方式生成精确的三维模型，但它们忽略了向用户提供简单和正则化模型的问题。因此，输出的网格往往在拐角处存在连接性近似问题，要么存在多个顶点和微小切面，要么必须打破屋顶截面和立面组件的平面性约束。我们提出了一个基于二维平面布置的框架来解决这个问题。我们首先规范化的不是文献中常见的三维平面，而是由平面构建的二维多面体分区。其次，我们通过一个优化过程将该分区挤出到三维空间，该过程保证了屋顶部分的平面性，并保留了垂直不连续性和水平屋顶边缘。我们展示了我们的方法与现有方法相比的优势，即可以生成更简单的三维模型，同时提供相似的保真度和效率。

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SimpliCity: Reconstructing Buildings with Simple Regularized 3D Models

Automatic methods for reconstructing buildings from airborne LiDAR point clouds focus on producing accurate 3D models in a fast and scalable manner, but they overlook the problem of delivering simple and regularized models to practitioners. As a result, output meshes often suffer from connectivity approximations around corners with either the presence of multiple vertices and tiny facets, or the necessity to break the planarity constraint on roof sections and facade components. We propose a 2D planimetric arrangement-based framework to address this problem. We first regularize, not the 3D planes as commonly done in the literature, but a 2D polyhedral partition constructed from the planes. Second, we extrude this partition to 3D by an optimization process that guarantees the planarity of the roof sections as well as the preservation of the vertical discontinuities and horizontal rooftop edges. We show the benefits of our approach against existing methods by producing simpler 3D models while offering a similar fidelity and efficiency.

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arXiv - CS - Computational Geometry

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