TY - JOUR
T1 - Ecoregion-wise fractional mapping of tree functional composition in temperate mixed forests with sentinel data
T2 - Integrating time-series spectral and radar data
AU - Lin, Ziyu
AU - Cheng, K. H.
AU - Yang, Dedi
AU - Xu, Fei
AU - Song, Guangqin
AU - Meng, Ran
AU - Wang, Jing
AU - Zhu, Xiaolin
AU - Ng, Michael
AU - Wu, Jin
N1 - We would like to thank the editors and two reviewers for providing valuable suggestions and comments, which are greatly helpful in improving the quality of this work. The work was primarily supported by the National Natural Science Foundation of China (#31922090), Hong Kong Research Grant Council General Research Fund (#17316622 and #17305321) and Collaborative Research Fund (#C5062-21GF), the HKU Seed Funding for Basic Research (2021115931), the HKU Seed Funding for Strategic Interdisciplinary Research Scheme, the Hung Ying Physical Science Research Fund 2021-22, and the Innovation and Technology Fund (funding support to State Key Laboratories in Hong Kong of Agrobiotechnology) of the HKSAR, China. RM was supported by the Fundamental Research Funds for the Central Universities, Beijing, China (Grant Nos. 2662022ZHYJ002; 2662022JC006). DY was supported by the United States Department of Energy contract No. DESC0012704 to Brookhaven National Laboratory and NASA’s Future Investigators in NASA Earth and Space Science and Technology (FINESST) Grant 80NSSC22K1296. MNg is funded by HKRGC GRF 12300519, 17201020 and 17300021, HKRGC CRF C1013-21GF and C7004-21GF, and Joint NSFC and RGC N-HKU769/21.
Publisher Copyright:
© 2024 Elsevier Inc.
PY - 2024/4/1
Y1 - 2024/4/1
N2 - Temperate mixed forest ecosystems are composed of various tree functional types (TFTs) that differ in canopy structure, phenology, and physiological response to climate change. An accurate characterization of the composition of these TFTs is important for quantifying land surface carbon, energy, and water cycling, as well as process-based simulation of forest dynamics. However, because the pixel size of satellite imagery is usually larger than temperate tree crowns, it is challenging to untangle the significant pixel-wise signal mixture of TFT across mixed forest regions. Spectral Mixture Analysis (SMA) has been widely used to derive the sub-pixel fractional composition of TFT from satellite imagery, but accounting for the broad spectral variability within TFTs across space and time remains a challenge. Synthetic aperture radar (SAR) can indicate biomass mixture information, but it has not been fully exploited for deriving subpixel TFT composition. To improve TFT composition mapping in mixed forest regions, we developed a Fisher-transformation-based Spectral and Radar Time-series Mixture Analysis (F-SRTMA) framework on Google Earth Engine. The F-SRTMA framework aims to address the space-time TFT variability of satellite signatures based on two modified modules: (1) the use of spectral and radar data with spatial and temporal information, and (2) feature optimization based on Fisher Discriminant Analysis (FDA). We tested the F-SRTMA at three representative temperate mixed landscapes located in the northeastern United States, where time-series Sentinel-1 and -2 data were used to calibrate our F-SRTMA approach. Airborne hyperspectral and LiDAR-derived canopy height data were used to generate ground reference TFT fraction maps for validation. The results demonstrate that (1) compared to the spectral time-series model, the synergy of spectral and radar time-series features yielded higher accuracy at the local sites (r2 = 0.649 vs. 0.680); (2) optimized feature based on FDA significantly minimized the within-TFT variability while maximizing the between-TFT variability, which further improved model generalizability across different landscapes, yielding the highest accuracy with cross-site r2 increasing from 0.634 to 0.715 and RMSE decreasing from 0.207 to 0.164. Collectively, these results suggest that F-SRTMA can be an accurate and generalizable approach for sub-pixel fraction mapping across temperate mixed landscapes, with the potential to be applied to other mixed forest ecosystems.
AB - Temperate mixed forest ecosystems are composed of various tree functional types (TFTs) that differ in canopy structure, phenology, and physiological response to climate change. An accurate characterization of the composition of these TFTs is important for quantifying land surface carbon, energy, and water cycling, as well as process-based simulation of forest dynamics. However, because the pixel size of satellite imagery is usually larger than temperate tree crowns, it is challenging to untangle the significant pixel-wise signal mixture of TFT across mixed forest regions. Spectral Mixture Analysis (SMA) has been widely used to derive the sub-pixel fractional composition of TFT from satellite imagery, but accounting for the broad spectral variability within TFTs across space and time remains a challenge. Synthetic aperture radar (SAR) can indicate biomass mixture information, but it has not been fully exploited for deriving subpixel TFT composition. To improve TFT composition mapping in mixed forest regions, we developed a Fisher-transformation-based Spectral and Radar Time-series Mixture Analysis (F-SRTMA) framework on Google Earth Engine. The F-SRTMA framework aims to address the space-time TFT variability of satellite signatures based on two modified modules: (1) the use of spectral and radar data with spatial and temporal information, and (2) feature optimization based on Fisher Discriminant Analysis (FDA). We tested the F-SRTMA at three representative temperate mixed landscapes located in the northeastern United States, where time-series Sentinel-1 and -2 data were used to calibrate our F-SRTMA approach. Airborne hyperspectral and LiDAR-derived canopy height data were used to generate ground reference TFT fraction maps for validation. The results demonstrate that (1) compared to the spectral time-series model, the synergy of spectral and radar time-series features yielded higher accuracy at the local sites (r2 = 0.649 vs. 0.680); (2) optimized feature based on FDA significantly minimized the within-TFT variability while maximizing the between-TFT variability, which further improved model generalizability across different landscapes, yielding the highest accuracy with cross-site r2 increasing from 0.634 to 0.715 and RMSE decreasing from 0.207 to 0.164. Collectively, these results suggest that F-SRTMA can be an accurate and generalizable approach for sub-pixel fraction mapping across temperate mixed landscapes, with the potential to be applied to other mixed forest ecosystems.
KW - Google Earth engine
KW - SAR
KW - Sentinel
KW - Spatiotemporal variability
KW - Spectral mixture analysis
KW - Tree functional type
UR - http://www.scopus.com/inward/record.url?scp=85184013761&partnerID=8YFLogxK
U2 - 10.1016/j.rse.2024.114026
DO - 10.1016/j.rse.2024.114026
M3 - Journal article
AN - SCOPUS:85184013761
SN - 0034-4257
VL - 304
JO - Remote Sensing of Environment
JF - Remote Sensing of Environment
M1 - 114026
ER -