Access to highly detailed models of heterogeneous forests from the near surface to above the tree canopy at varying scales is of increasing demand as it enables more advanced computational tools for analysis, planning, and ecosystem management. LiDAR sensors available through different scanning platforms including terrestrial, mobile and aerial have become established as one of the primary technologies for forest mapping due to their inherited capability to collect direct, precise and rapid 3D information of a scene. However, their scalability to large forest areas is highly dependent upon use of effective and efficient methods of co-registration of multiple scan sources. Surprisingly, work in forestry in GPS denied areas has mostly resorted to methods of co-registration that use reference based targets (e.g., reflective, marked trees), a process far from scalable in practice. In this work, we propose an effective, targetless and fully automatic method based on an incremental co-registration strategy matching and grouping points according to levels of structural complexity. Empirical evidence shows the method's effectiveness in aligning both TLS-to-TLS and TLS-to-ALS scans under a variety of ecosystem conditions including pre/post fire treatment effects, of interest to forest inventory surveyors.
翻译:访问具有不同规模的近地面到树冠以上的异质森林高度详细模型,可实现更高级计算工具进行分析,规划和生态系统管理。由于LiDAR传感器具有收集场景的直接,精确和快速的3D信息的能力,因此它们可在不同扫描平台(包括陆地,移动和空中)上通过各种方法成为森林映射的首选技术之一。然而,它们在大型森林区域的可扩展性高度依赖于使用有效且高效的多扫描源配准方法。令人惊讶的是,GPS禁飞区域中的林业工作大多采用基于参考目标(例如,反射,标记的树木)的配准方法,这在实践中远非可扩展。在本文中,我们提出了一种有效,无目标并且完全自动的方法,该方法基于按结构复杂度级别匹配和分组的增量配准策略。经验证据表明,在包括林业清查测量工程师感兴趣的各种生态系统条件下,该方法在对齐TLS对TLS和TLS对ALS扫描方面都具有良好的效果,包括火前后处理效果。