A machine learning approach to model leaf area index in Eucalyptus plantations using high-resolution satellite imagery and airborne laser scanner data

IF 1.7 3区 农林科学 Q2 FORESTRY
A. Hirigoyen, Cristina Acosta, Antonio Ariza, Maria Angeles Vero-Martinez, C. Rachid, J. Franco, Rafael Navara-Cerrillo
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引用次数: 4

Abstract

As a forest structural parameter, leaf area index (LAI) is crucial for efficient intensive plantation management. Leaf area is responsible for the energy absorption needed for photosynthetic production and transpiration, both affecting growth. Currently, LAI can be estimated either by remote-sensing methods or ground-based methods. However, unlike ground-based methods, remote estimation provides a cost-effective and ecologically significant advance The aim of our study was to evaluate whether machine learning algorithms can be used to quantify LAI, using either optical remote sensing or LiDAR metrics.in Eucalyptus dunnii and Eucalyptus grandis stands First, empirical relationships between LAI and remote-sensing data using LiDAR metrics and multispectral high-resolution satellite metrics, were assessed. Selected variables for LAI estimation were: LiDAR forest canopy cover, laser penetration index, and canopy relief ratio - from among the LiDAR data and the green normalized difference vegetation index and normalized difference vegetation index - from among the ground-based data we compared the accuracy of three machine learning algorithms: artificial neural networks (ANN), random forest (RF) and support vector regression (SVR). The coefficient of determination ranged from 0.60, for ANN, to 0.84, for SVR. The SVR regression methods showed the best performance in terms of overall model accuracy and RMSE (0.60). The results show that the remote sensing data applied through machine learning algorithms provide an effective method to estimate LAI in eucalyptus plantations. The methodology proposed is directly applicable for operational forest planning at the landscape level.
利用高分辨率卫星图像和机载激光扫描仪数据建立桉树人工林叶面积指数模型的机器学习方法
叶面积指数(LAI)作为一个森林结构参数,对高效集约经营具有重要意义。叶面积负责光合生产和蒸腾所需的能量吸收,两者都影响生长。目前,LAI可以通过遥感方法或地基方法进行估计。然而,与地面方法不同,远程估计提供了一种具有成本效益和生态意义的进步。我们研究的目的是评估机器学习算法是否可以用于量化LAI,使用光学遥感或激光雷达测量,使用激光雷达度量和多光谱高分辨率卫星度量评估了LAI和遥感数据之间的经验关系。LAI估计的选定变量是:激光雷达森林覆盖率、激光穿透指数和冠层松解率——从激光雷达数据和绿色归一化差异植被指数和归一化差异植被指标中——从地面数据中——我们比较了三种机器学习算法的准确性:人工神经网络(ANN),随机森林(RF)和支持向量回归(SVR)。ANN的决定系数在0.60到SVR的0.84之间。SVR回归方法在总体模型精度和RMSE(0.60)方面表现最佳。结果表明,通过机器学习算法应用的遥感数据为估计桉树人工林LAI提供了一种有效的方法。所提出的方法直接适用于景观一级的森林业务规划。
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来源期刊
CiteScore
2.20
自引率
11.10%
发文量
11
审稿时长
12 weeks
期刊介绍: Annals of Forest Research is a semestrial open access journal, which publishes research articles, research notes and critical review papers, exclusively in English, on topics dealing with forestry and environmental sciences. The journal promotes high scientific level articles, by following international editorial conventions and by applying a peer-review selection process.
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