Estimation of fine-scale vegetation distribution information from RPAS-generated imagery and structure to aid restoration monitoring

IF 5.7 Q1 ENVIRONMENTAL SCIENCES
Rik J.G. Nuijten , Nicholas C. Coops , Dustin Theberge , Cindy E. Prescott
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引用次数: 0

Abstract

Detailed maps of vegetation composition are vital for restoration planning, implementation, and monitoring, particularly at early stages of succession. This is usually accomplished through ground surveys, which can be costly and impractical depending on extent and accessibility, or conducted at too broad a spatial scale. In this study, we propose a methodology for mapping regenerating vegetation composition at 2 × 2 m2 spatial resolution, using very high spatial resolution (<1 m) remote sensing imagery obtained from remotely piloted aerial systems (RPAS) in conjunction with digital aerial photogrammetry (DAP) techniques for reconstructing vegetation structure. We applied logistic regression on multispectral orthomosaics, clusters of vegetation structure, and local illumination estimates to develop presence-absence models for eight key plant groups at various taxonomic levels as well as six plant functional types (conifer tree seedlings, grasses, tall- and low-growing forbs, shrubs, and mosses). Our results show higher accuracies for plant functional types (mean F-score = 0.67) compared to lower taxonomic levels (0.57). Notably, shrubs (F-score = 0.79), low-growing forbs (0.70), and mosses (0.69) exhibited the highest accuracies, while grasses (0.46), the aster family (Asteraceae spp; 0.48), and spruce seedlings (Picea spp; 0.54) demonstrated lower accuracies. Vegetation structure variables were identified as the most influential in the models, with mean NIRv ranking highest among spectral variables. High average ranks of spectral variation metrics (e.g., standard deviation of NIRv) implied the influence of environmental determinants such as plant co-occurrences and micro-habitat conditions, which drive spectral variation. Discrete composition maps were produced for three restoration sites and analogous wildfire-disturbed sites. Plant compositions found at one site pair exhibited similarity (Bray-Curtis = 0.28), however, certain key plant groups covered larger extents of the restoration site than anticipated. Willows (Salix spp; 25.4% vs. 9.3%), which are typically planted for soil stabilization and obstruction, and clovers (Trifolium spp; 11.1% vs. 3.6%), which represent non-native agronomic vegetation, were prominent. The developed methodology facilitates the generation of detailed plant composition maps, aiding evaluations of vegetation patterns that are difficult to discern visually or through conventional field sampling. This approach can effectively help assess restoration goals and guide adaptive management strategies, especially when incorporating the expertise of restoration ecologists in understanding how different vegetation types affect habitat quality.

从 RPAS 生成的图像和结构中估算精细尺度的植被分布信息,以帮助监测恢复情况
详细的植被组成图对于恢复规划、实施和监测至关重要,尤其是在演替的早期阶段。这通常需要通过地面勘测来完成,而地面勘测的成本可能很高,而且由于范围和交通不便而不切实际,或者在太宽的空间范围内进行。在这项研究中,我们提出了一种方法,利用遥控航空系统(RPAS)获得的超高空间分辨率(1 米)遥感图像,结合数字航空摄影测量(DAP)技术,以 2 × 2 平方米的空间分辨率绘制再生植被组成图,重建植被结构。我们对多光谱正射影像图、植被结构群和局部光照度估计值进行了逻辑回归,为不同分类级别的八个主要植物群以及六种植物功能类型(针叶树苗、禾本科植物、高矮草本植物、灌木和苔藓)建立了存在-不存在模型。结果表明,与较低的分类水平(0.57)相比,植物功能类型的准确度更高(平均 F 分数 = 0.67)。值得注意的是,灌木(F-score = 0.79)、低矮草本植物(0.70)和苔藓(0.69)的准确度最高,而禾本科(0.46)、菊科(Asteraceae spp; 0.48)和云杉苗(Picea spp; 0.54)的准确度较低。植被结构变量被认为是对模型影响最大的变量,其中近红外平均值在光谱变量中排名最高。光谱变化指标(如近红外光谱的标准偏差)的平均排名较高,这意味着环境决定因素(如植物共生和微生境条件)的影响,而环境决定因素是光谱变化的驱动力。为三个恢复地点和类似的野火扰动地点绘制了离散成分图。在一个地点对发现的植物组成具有相似性(Bray-Curtis = 0.28),但是,某些关键植物群在恢复地点的覆盖范围比预期的要大。柳树(Salix spp;25.4% 对 9.3%)和三叶草(Trifolium spp;11.1% 对 3.6%)比较突出,柳树和三叶草是典型的土壤稳定和阻挡植物,三叶草代表非本地农艺植被。所开发的方法有助于生成详细的植物组成图,从而帮助评估难以通过视觉或常规实地取样辨别的植被模式。这种方法可有效帮助评估恢复目标并指导适应性管理策略,尤其是在结合恢复生态学家的专业知识,了解不同植被类型如何影响栖息地质量时。
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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CiteScore
12.20
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