Mapping the Forest Canopy Height in Northern China by Synergizing ICESat-2 with Sentinel-2 Using a Stacking Algorithm

Jiang, Fugen; Zhao, Feng; Ma, Kaisen; Li, Dongsheng; Sun, Hua

doi:10.3390/rs13081535

Cited by 39 publications

(38 citation statements)

References 63 publications

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“…In accordance with previous studies, the MSI was more useful than the SAR and DEM for the LAI estimation, providing a wider range of the predicted LAI values. This is likely because the MSI data consist of optical sensor readings; spectral indices from the narrow-band, red-edge, and SWIR spectral regions are sensitive to green vegetation and are useful for retrieving forest phenology, physiology, and structure [13,23,28]. However, the MSI suffers from data saturation due to the forest canopy's shading of solar radiation in thick forest zones, which causes the MSI to a record horizontal vegetation structure more effectively than vertical biophysical characteristics [49].…”

Section: Roles Of Sentinel-1 and 2 And Alos-dem In Forest Lai Estimationmentioning

confidence: 99%

“…We also found that the NBL significantly affected the SL model performance. However, many previous prediction studies [25,[27][28][29][30] did not attempt to optimize the NBL when generating SL models. In this work, the best NBL for estimating the LAI was determined through a comparative analysis of SL models (Figure 4), which revealed that the use of too many or too few base learners reduced the accuracy of SL models.…”

Section: Usefulness Of Stacking Learning Models For Forest Lai Quanti...mentioning

confidence: 99%

“…Additionally, the LAI is a key input for the ecosystem-level correlation [26]. A group of SL models has been developed and successfully used to monitor static and dynamic forest traits including forest change [27], forest canopy height [28], vegetation cover [29], growing stem volume [30], and aboveground biomass [25]. The use of SL was shown to increase the accuracy when compared to the use of individual ML methods because it uses both simple numerical information from instruments and the outputs of low-level models as input data [26,31].…”

Section: Introductionmentioning

confidence: 99%

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Improving Leaf Area Index Retrieval Using Multi-Sensor Images and Stacking Learning in Subtropical Forests of China

Yang

et al. 2021

Remote Sensing

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The leaf area index (LAI) is a key indicator of the status of forest ecosystems that is important for understanding global carbon and water cycles as well as terrestrial surface energy balances and the impacts of climate change. Machine learning (ML) methods offer promising ways of generating spatially explicit LAI data covering large regions based on optical images. However, there have been few efforts to analyze the LAI in heterogeneous subtropical forests with complex terrain by fusing high-resolution multi-sensor data from the Sentinel-1 Synthetic Aperture Radar (SAR), Sentinel-2 Multi Spectral Instrument (MSI), and Advanced Land Observing Satellite-1 digital elevation model (DEM). Here, forest LAI mapping was performed by integrating the MSI, SAR, and DEM data using a stacking learning (SL) approach that incorporates distinct predictions from a set of optimized individual ML algorithms. The method’s performance was evaluated by comparison to field forest LAI measurements acquired in Xingguo and Gandong of subtropical China. The results showed that the addition of the SAR and DEM images using the SL model compared to the inputs of only optical images reduced the mean absolute error (MAE) and root mean square error (RMSE) by 26% and 18%, respectively, in Xingguo, and by 12% and 8%, respectively, in Gandong. Furthermore, the combination of all images had the best prediction performance. SL was found to be more robust and accurate than conventional individual ML models, while the MAE and RMSE were decreased by 71% and 64%, respectively, in Xingguo, and by 68% and 59%, respectively, in Gandong. Therefore, the SL model using the three-source data combination produced satisfied prediction accuracy with the coefficients of determination (R2), MAE, and RMSE of 0.96, 0.17, and 0.28, respectively, in Xingguo and 0.94, 0.30, and 0.47, respectively, in Gandong. This study revealed the potential of the SL algorithm for retrieving the forest LAI using multi-sensor data in areas with complex terrain.

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Section: Roles Of Sentinel-1 and 2 And Alos-dem In Forest Lai Estimationmentioning

confidence: 99%

Section: Usefulness Of Stacking Learning Models For Forest Lai Quanti...mentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Improving Leaf Area Index Retrieval Using Multi-Sensor Images and Stacking Learning in Subtropical Forests of China

Yang

et al. 2021

Remote Sensing

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“…For instance, the NASA's Geoscience Laser Altimeter System (GLAS) was used to estimate fire fuel models (e.g., Ashworth et al, 2010), canopy fuel properties for crown fire behavior (e.g., García et al, 2012), and canopy structure and fuel data (e.g., Peterson et al, 2013). The NASA's Advanced Topographic Laser Altimeter System (ATLAS) instrument, launched in 2018, can also be used for vegetation characterization (Narine et al, 2020), although few studies have been conducted to date (e.g., Jiang et al, 2021;Lin et al, 2020;Narine et al, 2019) and none of them on the estimation of forest fuels. However, it should be noted that both GLAS and ATLAS systems were not initially optimized for vegetation and forest structure characterization (Leite et al, 2022, Potapov et al, 2021.…”

Section: Introductionmentioning

confidence: 99%

Assessing GEDI-NASA system for forest fuels classification using machine learning techniques

Hoffrén

Lamelas

Fernández

et al. 2023

International Journal of Applied Earth Observation and Geoinfor

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“…The airborne laser radar can obtain very high inversion accuracy, but only on a small scale. Spaceborne lidar can cover the entire world, but can only provide sampling spot data [14]. At present, ICESat-1 (ice, cloud, and land Elevation Satellite 1), ICESat-2 (ice, cloud, and land Elevation Satellite 2) and GEDI (Global Ecosystem Dynamics Investigation) are the main spaceborne lidars for forest parameter structure measurement.…”

Section: Introductionmentioning

confidence: 99%

Estimation of Quercus Biomass in Shangri-La Based on GEDI Spaceborne Lidar Data

Shu

et al. 2023

Forests

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Accurately estimating forest biomass based on spaceborne lidar on a county scale is challenging due to the incomplete coverage of spaceborne lidar data. Therefore, this research aims to interpolate GEDI spots and explore the feasibility of approaches to improving Quercus forest biomass estimation accuracy in the alpine mountains of Yunnan Province, China. This paper uses GEDI data as the main information source and a typical mountainous area in Shangri-La, northwestern Yunnan Province, China, as the study area. Based on the pre-processing of light spots. A total of 38 parameters were extracted from the canopy and vertical profiles of 1307 light spots in the study area, and the polygon data of the whole study area were obtained from the light spot data through Kriging interpolation. Multiple linear regression, support vector regression, and random forest were used to establish biomass models. The results showed that the optimal model is selected using the semi-variance function for the Kriging interpolation of each parameter of GEDI spot, the optimal model of modis_nonvegetated is a linear model, and the optimal model for rv, sensitivity, and modis_treecover is the exponential model. Analysis of the correlation between 39 parameters extracted from GEDI L2B and three topographic factors with oak biomass showed that sensitivity had a highly significant positive correlation (p < 0.01) with Quercus biomass, followed by a significant negative correlation (p < 0.05) with aspect and modis_nonvegation. After variable selection, the estimation model of Quercus biomass established using random forest had R2 = 0.91, RMSE = 19.76 t/hm2, and the estimation accuracy was better than that of multiple linear regression and support vector regression. The estimated total biomass of Quercus in the study area was mainly distributed between 26.48 and 257.63 t/hm2, with an average value of 114.33 t/hm2 and a total biomass of about 1.26 × 107 t/hm2. This study obtained spatial consecutive information using Kriging interpolation. It provided a new research direction for estimating other forest structural parameters using GEDI data.

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Mapping the Forest Canopy Height in Northern China by Synergizing ICESat-2 with Sentinel-2 Using a Stacking Algorithm

Cited by 39 publications

References 63 publications

Improving Leaf Area Index Retrieval Using Multi-Sensor Images and Stacking Learning in Subtropical Forests of China

Improving Leaf Area Index Retrieval Using Multi-Sensor Images and Stacking Learning in Subtropical Forests of China

Assessing GEDI-NASA system for forest fuels classification using machine learning techniques

Estimation of Quercus Biomass in Shangri-La Based on GEDI Spaceborne Lidar Data

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