Assessment of Slope-Adaptive Metrics of GEDI Waveforms for Estimations of Forest Aboveground Biomass over Mountainous Areas

遥感学报 Pub Date : 2021-08-27 DOI:10.34133/2021/9805364
W. Ni, Zhiyu Zhang, G. Sun
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引用次数: 11

Abstract

Waveform broadening effects of large-footprint lidar caused by terrain slopes are still a great challenge limiting the estimation accuracy of forest aboveground biomass (AGB) over mountainous areas. Slope-adaptive metrics of waveforms were proposed in our previous studies. However, its validation was limited by the unavailability of enough reference data. This study made full validation of slope-adaptive metrics using data acquired by the Global Ecosystem Dynamics Investigation (GEDI) mission, meanwhile exploring GEDI waveforms on estimations of forest AGB. Three types of waveform metrics were employed, including slope-adaptive metrics (RHT), typical height metrics relative to ground peaks (RH), and waveform parameters (WP). In addition to terrain slopes, two other factors were also explored including the geolocation issue and signal start and ending points of waveforms. Results showed that footprint geolocations in the first version GEDI data products were shifted to the left forward of nominal geolocations with a distance of about 24 m~30 m and were substantially corrected in the second version; the fourth and fifth groups of signal start and ending points of waveforms had worse performance than the rest of the four groups because they used the maximum and minimum signal thresholds, respectively. Taking airborne laser scanner (ALS) data as reference, the root mean square error (RMSE) of terrain slopes extracted from the digital elevation model of the shuttle radar topography mission (SRTM DEM) was about 3°. The coefficients of determination (R2) of estimation models of forest AGB based on RH metrics were improved from 0.48 to 0.68 with RMSE decreased from 19.7 Mg/ha to 15.4 Mg/ha by the second version geolocations. The RHT and WP metrics gave the best and the worst estimation accuracy, respectively. RHT further improved R2 to 0.77 and decreased RMSE to 13.0 Mg/ha using terrain slopes extracted from SRTM DEM with a resolution of 1 arc second. R2 of estimation models based on RHT was finally improved to 0.8 with RMSE decreased to 11.7 Mg/ha using exact terrain slopes from ALS data. This study demonstrated the great potential of slope-adaptive metrics of GEDI waveforms on estimations of forest aboveground biomass over mountainous areas.
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山地森林地上生物量GEDI波形的斜率自适应度量评估
地形斜坡引起的大足迹激光雷达的波形加宽效应仍然是限制山区森林地上生物量估计精度的一大挑战。在我们之前的研究中提出了波形的斜率自适应度量。然而,由于没有足够的参考数据,其验证受到限制。本研究利用全球生态系统动力学调查(GEDI)任务获得的数据对坡度自适应指标进行了充分验证,同时探索了GEDI波形对森林AGB的估计。采用了三种类型的波形度量,包括斜率自适应度量(RHT)、相对于地峰的典型高度度量(RH)和波形参数(WP)。除了地形坡度外,还探讨了其他两个因素,包括地理位置问题和波形的信号起点和终点。结果显示,第一个版本GEDI数据产品中的足迹地理位置被转移到标称地理位置的左前方,距离约为24 m~30 m,并且在第二版本中被基本校正;第四组和第五组波形的信号起点和终点的性能比四组中的其余组差,因为它们分别使用了最大和最小信号阈值。以机载激光扫描仪(ALS)数据为参考,从航天飞机雷达地形任务(SRTM DEM)的数字高程模型中提取的地形坡度均方根误差(RMSE)约为3°。基于RH指标的森林AGB估计模型的确定系数(R2)从0.48提高到0.68,RMSE从19.7降低 Mg/ha至15.4 Mg/ha由第二版本地理位置决定。RHT和WP度量分别给出了最佳和最差的估计精度。RHT将R2进一步提高到0.77,RMSE降低到13.0 Mg/ha,使用从SRTM DEM中提取的地形坡度,分辨率为1弧秒。基于RHT的估计模型的R2最终提高到0.8,RMSE降低到11.7 Mg/ha,使用ALS数据中的精确地形坡度。本研究证明了GEDI波形的斜率自适应指标在估计山区森林地上生物量方面的巨大潜力。
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遥感学报
遥感学报 Social Sciences-Geography, Planning and Development
CiteScore
3.60
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0.00%
发文量
3200
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