Modeling a new taper curve and form factor of tree branches using terrestrial laser scanning

IF 3 2区 农林科学 Q1 FORESTRY
Forestry Pub Date : 2024-01-11 DOI:10.1093/forestry/cpad064
Muluken N Bazezew, Lutz Fehrmann, Christoph Kleinn, Nils Nölke
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引用次数: 0

Abstract

Modeling branch taper curve and form factor contributes to increasing the efficiency of tree crown reconstructions: the branch taper, defined as the sequential measure of diameters along the course of the branch, is pivotal to accurately estimate key branch variables such as biomass and volume. Branch diameters or volumes have commonly been estimated from terrestrial laser scanning (TLS) based on automatized voxelization or cylinder-fitting approaches, given the whole branch length is sufficiently covered by laser reflections. The results are, however, often affected by ample variations in point cloud characteristics caused by varying point density, occlusions, and noise. As these characteristics of TLS can hardly be sufficiently controlled or eliminated in automatized techniques, we proposed a new branch taper curve model and form factor, which can be employed directly from the laser reflections and under variable point cloud characteristics. In this paper, the approach is demonstrated on primary branches using a set of TLS-derived datasets from a sample of 20 trees (six species). The results showed an R2 of 0.86 and a mean relative absolute error of 1.03 cm (29%) when validated with field-measured diameters. The approach improved the accuracy of diameter estimates for the fine branch scales (<10 cm) as compared to the quantitative structural model (QSM). Our approach also allowed branch diameter estimation for a relatively larger number of manually recognized primary branches (>85%) from point clouds when validated with panoramic images acquired simultaneously with laser scanning. Frequently used automatized crown reconstructions from QSM, on the other hand, were affected by gaps in the point clouds due to obstruction, with the crown-tops and finer branches being the most critical. Our approach reports mean form factors across the examined species of 0.35 and 0.49, with the diameters determined at 5% and 10% of the total branch length, respectively. Our approach may have the potential to produce branch volume information with reasonable accuracy from only knowing the length and respective diameter of each branch. Our model delivers a first approximation for the taper curve and form factor for primary branches but was developed on a relatively small set of samples. We believe that our approach holds the potential to improve the accuracy of the assessment of branch diameter and volume from TLS data. The approach may also be extended to other branch orders. This could expand the horizon for volumetric calculations and biomass estimates from non-destructive TLS proxies in tree crowns.
利用陆地激光扫描建立树枝新锥度曲线和形状系数模型
树枝锥度曲线和形状因子建模有助于提高树冠重建的效率:树枝锥度是指沿着树枝走向对直径进行的连续测量,对于准确估算生物量和体积等关键树枝变量至关重要。树枝直径或体积通常是通过陆地激光扫描(TLS)估算出来的,这种估算基于自动体素化或圆柱拟合方法,前提是整个树枝长度被激光反射充分覆盖。然而,由于点密度、遮挡物和噪声的不同而导致点云特征变化很大,往往会影响结果。由于 TLS 的这些特性很难在自动化技术中得到充分控制或消除,我们提出了一种新的树枝锥度曲线模型和形式因子,它可以在点云特性可变的情况下直接从激光反射中使用。本文使用一组从 20 棵树(6 个树种)样本中提取的 TLS 数据集,在主枝上演示了该方法。结果表明,在与实地测量直径进行验证时,R2 为 0.86,平均相对绝对误差为 1.03 厘米(29%)。与定量结构模型(QSM)相比,该方法提高了细枝尺度(<10 厘米)直径估算的准确性。在与激光扫描同时获取的全景图像进行验证时,我们的方法还可以从点云中估算出相对较多的人工识别主枝直径(>85%)。而常用的 QSM 自动树冠重建则会受到点云中因障碍物造成的间隙的影响,其中树冠顶端和较细的枝条最为关键。我们的方法报告了受检物种的平均形式因子,分别为 0.35 和 0.49,直径分别按树枝总长度的 5%和 10%确定。我们的方法有可能在只知道每个枝条的长度和各自直径的情况下,以合理的准确度得出枝条的体积信息。我们的模型提供了主枝锥度曲线和形状因子的第一近似值,但它是在一组相对较小的样本上开发出来的。我们相信,我们的方法有可能提高通过 TLS 数据评估树枝直径和体积的准确性。这种方法还可以扩展到其他枝序。这将扩大树冠非破坏性 TLS 代用数据的体积计算和生物量估算的范围。
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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来源期刊
Forestry
Forestry 农林科学-林学
CiteScore
6.70
自引率
7.10%
发文量
47
审稿时长
12-24 weeks
期刊介绍: The journal is inclusive of all subjects, geographical zones and study locations, including trees in urban environments, plantations and natural forests. We welcome papers that consider economic, environmental and social factors and, in particular, studies that take an integrated approach to sustainable management. In considering suitability for publication, attention is given to the originality of contributions and their likely impact on policy and practice, as well as their contribution to the development of knowledge. Special Issues - each year one edition of Forestry will be a Special Issue and will focus on one subject in detail; this will usually be by publication of the proceedings of an international meeting.
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