Developing laser scanning applications for mapping and monitoring single tree characteristics for the needs of urban forestry

Dissertationes Forestales Pub Date : 2016-10-28 DOI:10.14214/DF.230

Topi Tanhuanpää

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引用次数: 1

Abstract

Urban forests provide various ecosystem services. However, they also require fairly intensive management, which can be supported with up-to-date tree-level data. Until recently, the data have been collected using traditional field measurements. Laser scanning (LS) techniques provide efficient means for acquiring detailed three-dimensional (3D) data from the vegetation. The objective of this dissertation was to develop methods for mapping and monitoring urban forests at tree level. In substudy I, a method (MS-STI) utilizing multiple data sources was developed for extracting tree-level attributes. The method combined airborne laser scanning (ALS), field measurements, and tree locations. The field sample was generalized using the non-parametric nearest neighbor (NN) approach. The relative root mean square error (RMSE) of diameter at breast height (DBH) varied between 18.8–33.8%. The performance of MS-STI was assessed in substudy II by applying it to an existing tree register. 88.8% of the trees were successfully detected, and the relative RMSE of DBH for the most common diameter classes varied between 21.7–24.3%. In substudy III, downed trees were mapped from a recreational forest area by detecting changes in the canopy. 97.7% of the downed trees were detected and the commission error was 10%. Species group, DBH, and volume were estimated for all downed trees using ALS metrics and existing allometric models. For the DBH, the relative RMSE was 20.8% and 34.1% for conifers and deciduous trees respectively. Finally, in substudy IV, a method utilizing terrestrial laser scanning (TLS) and tree basic density was developed for estimating tree-level stem biomass for urban trees. The relative RMSE of the stem biomass estimates varied between 8.4–10.5%. The dissertation demonstrates the applicability of LS data in assessing tree-level attributes for urban forests. The methods developed show potential in providing the planning and management of urban forests with cost-efficient and up-to-date tree-level data.

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开发激光扫描应用于测绘和监测单株树木的特征，以满足城市林业的需要

城市森林提供各种生态系统服务。然而，它们也需要相当密集的管理，这可以用最新的树级数据来支持。直到最近，这些数据都是使用传统的现场测量方法收集的。激光扫描(LS)技术为获取植被的详细三维数据提供了有效手段。本文的目的是发展城市森林在树木水平上的制图和监测方法。在子研究1中，开发了一种利用多数据源提取树级属性的方法(MS-STI)。该方法结合了机载激光扫描(ALS)、现场测量和树木定位。采用非参数最近邻(NN)方法对现场样本进行广义化。胸高直径的相对均方根误差(RMSE)在18.8 ~ 33.8%之间。子研究II通过将MS-STI应用于现有的树寄存器来评估其性能。88.8%的树木被成功检测，最常见径级的胸径相对RMSE在21.7% ~ 24.3%之间。在子研究III中，通过检测林冠的变化，从一个休闲林区绘制了被砍伐树木的地图。97.7%的树木被检测到，委托误差为10%。利用ALS指标和现有异速生长模型对所有倒下树木的物种群、胸径和体积进行了估计。对于胸径，针叶树和落叶树的相对RMSE分别为20.8%和34.1%。最后，在子研究IV中，建立了基于地面激光扫描(TLS)和树木基本密度的城市树木树干生物量估算方法。茎生物量估计值的相对RMSE在8.4 ~ 10.5%之间。本文论证了LS数据在城市森林树级属性评估中的适用性。所制订的方法显示出在为城市森林的规划和管理提供具有成本效益的最新树木数据方面的潜力。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Dissertationes Forestales

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