Abstract
Physics-based algorithms estimating large-scale forest above-ground biomass (AGB) from synthetic aperture radar (SAR) data generally use airborne laser scanning (ALS) or grid of national forest inventory (NFI) to reduce uncertainties in the model calibration. This study assesses the potential of multitemporal L-band ALOS-2/PALSAR-2 data to improve forest AGB estimation using the three-parameter water cloud model (WCM) trained with field data from relatively small (0.1 ha) plots. The major objective is to assess the impact of the high uncertainties in field inventory data due to relatively smaller plot size and temporal gap between acquisitions and ground truth on the AGB estimation. This study analyzes a time series of twenty-three ALOS-2 dual-polarized images spanning 5 years acquired under different weather and soil moisture conditions over a subtropical forest test site in India. The WCM model is trained and validated on individual acquisitions to retrieve forest AGB. The accuracy of the generated AGB products is quantified using the root mean square error (RMSE). Further, we use a multitemporal AGB retrieval approach to improve the accuracy of the estimated AGB. Changes in precipitation and soil moisture affect the AGB retrieval accuracy from individual acquisitions; however, using multitemporal data, these effects are mitigated. Using a multitemporal AGB retrieval strategy, the accuracy improves by 15% (55 Mg/ha RMSE) for all field plots and by 21% (39 Mg/ha RMSE) for forests with AGB less than 100 Mg/ha. The analysis shows that any ten multitemporal acquisitions spanning 5 years are sufficient for improving AGB retrieval accuracy over the considered test site. Furthermore, we use allometry from colocated field plots and Global Ecosystem Dynamics Investigation (GEDI) L2A height metrics to produce GEDI-derived AGB estimates. Despite the limited co-location of GEDI and field data over our study area, within the period of interest, the preliminary analysis shows the potential of jointly using the GEDI-derived AGB and multi-temporal ALOS-2 data for large-scale AGB retrieval.
Highlights
Synthetic aperture radar (SAR) remote sensing has been extensively used for forest above-ground biomass (AGB) estimation due to its sensitivity to forest structure and ability to penetrate through clouds
The mean Advanced Land Observation Satellite (ALOS)-2 backscatter for each year is shown by the dots, and the standard deviation is shown by the error bars
We analyze the potential of multitemporal ALOS-2 acquisitions to improve AGB estimates over a subtropical forest using the 3-parameter water cloud model (WCM) model and 0.1 ha field inventory plots
Summary
Synthetic aperture radar (SAR) remote sensing has been extensively used for forest above-ground biomass (AGB) estimation due to its sensitivity to forest structure and ability to penetrate through clouds. The SAR backscatter signal strength increases with AGB up to a saturation level (Yu and Saatchi, 2016; Joshi et al, 2017; Schlund et al, 2019), which depends on the sensor properties such as wavelength and polarization, as well as site conditions including stand structure, ground conditions, and moisture (Dobson et al, 1992; Le Toan et al, 1992; Ghasemi et al, 2011; Huang et al, 2015; Ningthoujam et al, 2018; Khati et al, 2020). Space-borne L-band SAR data are available from the JAXA’s Advanced Land Observation Satellite (ALOS) Phased Array type L-band Synthetic Aperture Radar (PALSAR) and its successor ALOS-2/PALSAR-2 satellite missions
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