Accuracy assessment of GEDI terrain elevation, canopy height, and aboveground biomass density estimates in Japanese artificial forests

IF 5.7 Q1 ENVIRONMENTAL SCIENCES
Hantao Li , Xiaoxuan Li , Tomomichi Kato , Masato Hayashi , Junjie Fu , Takuya Hiroshima
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引用次数: 0

Abstract

Global forests face severe challenges owing to climate change, making dynamic and accurate monitoring of forest conditions critically important. Forests in Japan, covering approximately 70% of the country's land area, play a vital role yet often overlooked in global forestry. Japanese forests are unique, with approximately 50% comprising artificial forests, predominantly coniferous forests. Despite the Japanese government's extensive use of airborne Light Detecting and Ranging (LiDAR) to assess forest conditions, these data need more availability and frequency. The Global Ecosystem Dynamics Investigation (GEDI), the first Spaceborne LiDAR data explicitly designed for vegetation monitoring, is expected to provide significant value for high-frequency and high-accuracy forest monitoring. To assess the accuracy of GEDI data in Japanese artificial coniferous forests, the reference data were gathered from 53,967,770 artificial coniferous trees via airborne LiDAR data in Aichi Prefecture, Japan. This data was then compared to the corresponding GEDI-derived terrain elevations, canopy heights (GEDI RH98), and aboveground biomass density (AGBD) estimates to assess the accuracy of GEDI data. This research also explored how different factors influence the accuracy of GEDI terrain elevation estimates, including the type of beam, time of acquisition (day or night), beam sensitivity, and terrain slope. Additionally, the effects of various forest structural parameters, such as the height-to-diameter ratio, crown length ratio, and the number of trees on the accuracy of the GEDI canopy height and AGBD, were investigated. The results showed that GEDI terrain elevation demonstrated high accuracy across various slope conditions, with rRMSE ranging from 2.28% to 3.25% and RMSE ranging from 11.68 m to 16.54 m. After geolocation adjustment, the comparison of canopy height estimates derived from GEDI to airborne LiDAR-derived canopy height also showed high accuracy, exhibiting a rRMSE of 22.04%. In contrast, the GEDI AGBD product showed moderate accuracy, with a rRMSE of 52.79%. The findings also indicated that the accuracy of GEDI RH98 was influenced by terrain slope and crown length ratio, whereas the accuracy of GEDI AGBD was mainly impacted by the number of trees and crown length ratio. This study provided the first baseline accuracy assessment of GEDI terrain elevation, RH98, and AGBD estimates in Japanese artificial forests. Furthermore, this study provided valuable insights into the accuracy of GEDI metrics by examining potential factors.

日本人工林中 GEDI 地形高程、树冠高度和地上生物量密度估算的精度评估
气候变化使全球森林面临严峻挑战,因此对森林状况进行动态和准确的监测至关重要。日本森林面积约占国土面积的 70%,在全球林业中发挥着至关重要的作用,但却经常被忽视。日本的森林非常独特,其中约 50% 为人工林,主要是针叶林。尽管日本政府广泛使用机载光探测和测距仪(LiDAR)来评估森林状况,但这些数据需要更多的可用性和频率。全球生态系统动态调查(GEDI)是首个明确设计用于植被监测的机载激光雷达数据,有望为高频率、高精度的森林监测提供重要价值。为了评估 GEDI 数据在日本人工针叶林中的准确性,我们通过日本爱知县的机载激光雷达数据收集了 53,967,770 株人工针叶树的参考数据。然后将这些数据与 GEDI 得出的相应地形高程、树冠高度(GEDI RH98)和地上生物量密度(AGBD)估计值进行比较,以评估 GEDI 数据的准确性。这项研究还探讨了不同因素如何影响 GEDI 地形高程估算的准确性,包括光束类型、采集时间(白天或夜晚)、光束灵敏度和地形坡度。此外,还研究了各种森林结构参数(如高径比、冠长比和树木数量)对 GEDI 树冠高度和 AGBD 精度的影响。结果表明,GEDI地形高程在各种坡度条件下均表现出较高的精度,rRMSE在2.28%到3.25%之间,RMSE在11.68米到16.54米之间;经过地理定位调整后,GEDI得出的冠层高度估计值与机载LiDAR得出的冠层高度比较也表现出较高的精度,rRMSE为22.04%。相比之下,GEDI AGBD 产品显示出中等精度,rRMSE 为 52.79%。研究结果还表明,GEDI RH98 的准确度受地形坡度和冠长比的影响,而 GEDI AGBD 的准确度主要受树木数量和冠长比的影响。本研究首次对日本人工林中的 GEDI 地形高程、RH98 和 AGBD 估计值进行了基准精度评估。此外,本研究还通过考察潜在因素,为 GEDI 指标的准确性提供了宝贵的见解。
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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