融合动态法向量与自适应RANSAC的低空经济LOD1.3模型构建

doi:10.13474/j.cnki.11-2246.2026.0406

摘要/Abstract

摘要： 低空经济快速发展对高精度、可计算的城市三维空间数据提出了迫切需求,LOD1.3建筑物模型作为低空飞行器航线规划与空域管理的核心数字底座,其快速、精准构建至关重要。然而,现有方法在屋顶面片分割中存在精度低、计算冗余度高等问题。本文提出了一种融合动态法向量优化与自适应RANSAC迭代策略的机载激光点云高效建模方法,通过曲率反馈动态调整邻域半径,结合点云密度自适应的RANSAC迭代,提升平面分割稳健性,并集成PCA拟合优化屋顶面片几何精度。试验结果显示,平面拟合均方根误差为0.11 m,较传统方法降低了47.6%;建模效率达1 km²/d,提升了300%;分割精度达86%,复杂屋顶错误率降至12.3%。该方法为实景三维建设提供了高精度、低成本的LOD1.3建模解决方案,能有效支撑低空经济应用的数字化与智能化发展。

关键词: 低空经济, LOD1.3城市三维模型, 机载激光点云, 动态法向量优化, 自适应RANSAC算法, 主成分分析

Abstract: The rapid development of the low-altitude economy creates an urgent demand for high-precision and computable urban 3D spatial data.As the core digital foundation for route planning and airspace management of low-altitude aircraft,the rapid and precise construction of LOD1.3 building models is crucial.However,existing methods suffer from issues such as low accuracy and high computational redundancy in roof facet segmentation.This paper proposes an efficient airborne LiDAR point cloud modeling method that integrates dynamic normal vector optimization with an adaptive RANSAC iteration strategy.By dynamically adjusting the neighborhood radius through curvature feedback and combining it with a point cloud density-adaptive RANSAC iteration,the method enhances the robustness of plane segmentation.It further integrates PCA fitting to optimize the geometric accuracy of roof facets.Experimental results show that the root mean square error of plane fitting reaches 0.11 m,representing a 47.6%reduction compared to traditional methods.The modeling efficiency achieves 1 km²/d,marking a 300% improvement.The segmentation accuracy reaches 86%,while the error rate for complex roofs decreases to 12.3%.This method provides a high-precision and low-cost LOD1.3 modeling solution for 3D real-scene construction,effectively supporting the digital and intelligent development of low-altitude economy applications.

Key words: low-altitude economy, city-level 3D model of LOD1.3, airborne LiDAR data, dynamic normal vector optimization, adaptive ransac, principal component analysis

中图分类号:

P23
P208

李振, 苏通, 王刚, 王国飞. 融合动态法向量与自适应RANSAC的低空经济LOD1.3模型构建[J]. 测绘通报, 2026, 0(4): 41-46,72.

LI Zhen, SU Tong, WANG Gang, WANG Guofei. Construction of low-altitude economy LOD1.3 models integrating dynamic normal vectors and adaptive RANSAC[J]. Bulletin of Surveying and Mapping, 2026, 0(4): 41-46,72.

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