Construction of prediction model for water retention of forest ecosystem in alpine region based on vegetation spectral features

IF 7 2区环境科学与生态学 Q1 ENVIRONMENTAL SCIENCES

Ecological Indicators Pub Date : 2024-11-27 DOI:10.1016/j.ecolind.2024.112889

Teng Niu , Zhongze Hou , Jiaxin Yu , Jie Lu , Qiang Yu , Linzhe Yang , Jun Ma , Yafei Liu , Hui Shi , Xuyang Jin

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引用次数: 0

Abstract

The water retention service of the forest ecosystem has ecological functions such as adjusting the climate and maintaining the ecological water balance. The Qinghai-Tibet Plateau is an alpine region. Due to its high altitude and harsh environment, it is difficult to manually observe the water retention in the field, and it is impossible to better evaluate the water retention function. In order to better obtain the water retention in the alpine region, hyperspectral technology is introduced and applied to the acquisition of surface vegetation information, and the water retention in a specific area is obtained by constructing a model. In this study, the Bayi District of Nyingchi Prefecture was used as the research area. The main tree species in the study area are Picea likiangensis var. linzhiensis(PLVL), Quercus aquifolioides(QA), Pinus densata(PD) and Rhododendron nivale(RN). In actual situations, it is not easy to directly obtain water retention information, so a model can be found to quantitatively express the relationship between leaf spectrum and water retention. Then based on the leaf spectrum to invert the water retention. In order to study the quantitative relationship between different vegetation and water retention, each type of vegetation collects leaf samples and water retention data at 30 sampling points. Use ASD Fildsoec Handheld spectrometer to obtain hyperspectral data. Seven band indexes of red edge, green peak, NDVI, NDWI, EVI, WBI and NDPI were selected, and the relationship between vegetation band index and water conservation was fitted through many kinds of regression models. Comparing the fitting results, construct water retention prediction model. The interception of vegetation canopy, litter water holding capacity and soil water content are obtained through experiments. The sum of the three represents the water retention capacity of vegetation. The reflectance spectra of the four types of vegetation leaves all show similar regularities, and the difference in the visible light band is not obvious. The near-infrared to mid-infrared bands show four distinct water absorption bands, with the highest reflectivity in the red to near-infrared bands (700 nm-1400 nm). The reflectance of the four types of vegetation varies across different spectral bands, with the reflectance levels exhibiting the characteristic order of QA > PD > PLVL ≈ RN. Comparing the fitting results of different regression models with seven waveband parameters, the R² of the four types of vegetation are higher in the regression models of EVI and NDPI, and reach a significant level. According to the regression model corresponding to each kind of vegetation, the water retention prediction model is composed, and the simulation accuracy is tested by R² and RMSE. The overall simulation accuracy R² is greater than 0.7 and the RMSE is basically less than 10 t·hm⁻², indicating that the forecasting model has a good forecasting effect and the model can effectively estimate the water retention of the forest ecosystem.

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基于植被光谱特征的高寒地区森林生态系统保水性预测模型的构建

森林生态系统的水源涵养功能具有调节气候、维持生态水量平衡等生态功能。青藏高原属于高寒地区。由于海拔高、环境恶劣，人工野外观测保水性困难，无法更好地评价保水功能。为了更好地获取高寒地区的水源涵养情况，引入了高光谱技术，并将其应用于地表植被信息的获取，通过构建模型获取特定区域的水源涵养情况。本研究以宁蒗县巴宜区为研究区域。研究区域内的主要树种为林芝红豆杉（PLVL）、水曲柳（QA）、五针松（PD）和杜鹃花（RN）。在实际情况中，直接获取保水性信息并不容易，因此可以找到一个模型来定量表达叶谱与保水性之间的关系。然后根据叶光谱反演保水性。为了研究不同植被与保水性之间的定量关系，每种植被在 30 个采样点采集叶片样本和保水性数据。使用 ASD Fildsoec 手持式光谱仪获取高光谱数据。选取红边、绿峰、NDVI、NDWI、EVI、WBI 和 NDPI 七种波段指数，通过多种回归模型拟合植被波段指数与保水性之间的关系。比较拟合结果，构建保水性预测模型。通过实验得到植被冠层截水量、枯落物持水量和土壤含水量。三者之和代表植被的保水能力。四种植被叶片的反射光谱均表现出相似的规律性，可见光波段差异不明显。近红外至中红外波段显示出四个不同的吸水波段，其中红外至近红外波段（700 nm-1400 nm）的反射率最高。四种植被在不同光谱波段的反射率各不相同，其反射率水平呈现出 QA > PD > PLVL ≈ RN 的特征顺序。比较 7 个波段参数的不同回归模型的拟合结果，四类植被在 EVI 和 NDPI 回归模型中的 R2 均较高，且达到显著水平。根据每种植被对应的回归模型，组成水分保持预测模型，并用 R2 和 RMSE 检验模拟精度。总体模拟精度 R2 大于 0.7，RMSE 基本小于 10 t-hm-2，表明该预测模型具有较好的预测效果，能有效估算森林生态系统的保水量。

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来源期刊

Ecological Indicators 环境科学-环境科学

CiteScore

11.80

自引率

8.70%

发文量

1163

审稿时长

78 days

期刊介绍： The ultimate aim of Ecological Indicators is to integrate the monitoring and assessment of ecological and environmental indicators with management practices. The journal provides a forum for the discussion of the applied scientific development and review of traditional indicator approaches as well as for theoretical, modelling and quantitative applications such as index development. Research into the following areas will be published. • All aspects of ecological and environmental indicators and indices. • New indicators, and new approaches and methods for indicator development, testing and use. • Development and modelling of indices, e.g. application of indicator suites across multiple scales and resources. • Analysis and research of resource, system- and scale-specific indicators. • Methods for integration of social and other valuation metrics for the production of scientifically rigorous and politically-relevant assessments using indicator-based monitoring and assessment programs. • How research indicators can be transformed into direct application for management purposes. • Broader assessment objectives and methods, e.g. biodiversity, biological integrity, and sustainability, through the use of indicators. • Resource-specific indicators such as landscape, agroecosystems, forests, wetlands, etc.