An ecologically-constrained deep learning model for tropical leaf phenology monitoring using PlanetScope satellites

Jing Wang; Guangqin Song; Michael Liddell; Patricia Morellato; Calvin K.F. Lee; Dedi Yang; Bruna Alberton; Matteo Detto; Xuanlong Ma; Yingyi Zhao; Henry C.H. Yeung; Hongsheng Zhang; Michael Ng; Bruce W. Nelson; Alfredo Huete; Jin Wu

doi:10.1016/j.rse.2022.113429

An ecologically-constrained deep learning model for tropical leaf phenology monitoring using PlanetScope satellites

Jing Wang, Guangqin Song, Michael Liddell, Patricia Morellato, Calvin K.F. Lee, Dedi Yang, Bruna Alberton, Matteo Detto, Xuanlong Ma, Yingyi Zhao, Henry C.H. Yeung, Hongsheng Zhang, Michael Ng, Bruce W. Nelson, Alfredo Huete, Jin Wu

Plant-Soil Interactions

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23 Scopus citations

Abstract

In tropical forests, leaf phenology signals leaf-on/off status and exhibits considerable variability across scales from a single tree-crown to the entire forest ecosystem. Such phenology signals importantly regulate large-scale biogeochemical cycles and regional climate. PlanetScope CubeSats data with a 3-m resolution and near-daily global coverage provide an unprecedented opportunity to monitor both fine- and ecosystem-scale phenology variability along large environmental gradients. However, a scalable method that accurately characterizes leaf phenology from PlanetScope with biophysically meaningful metrics remains lacking. We developed an index-guided, ecologically constrained autoencoder (IG-ECAE) method to automatically derive a deciduousness metric (percentage of upper tree canopies with leaf-off status within an image pixel) from PlanetScope. The IG-ECAE first estimated the reflectance spectra of leafy/leafless canopies based on their spectral indices characteristics, then used the derived reflectance spectra to guide an autoencoder deep learning method with additional ecological constraints to refine the reflectance spectra, and finally used linear spectral unmixing to estimate the relative abundance of leafless canopies (or deciduousness) per PlanetScope image pixel. We tested the IG-ECAE method at 16 tropical forest sites spanning multiple continents and a large precipitation gradient (1470–2819 mm year⁻¹). Among these sites, we evaluated the PlanetScope-derived deciduousness against corresponding measures derived from WorldView-2 (n = 9 sites) and local phenocams (n = 9 sites). Our results show that PlanetScope-derived deciduousness agrees: 1) with that derived from WorldView-2 at the patch level (90 m × 90 m) with r² = 0.89 across all sites; and 2) with that derived from phenocams to quantify ecosystem-scale seasonality with r² ranging from 0.62 to 0.96. These results demonstrate the effectiveness and scalability of IG-ECAE in characterizing the wide variability in deciduousness across scales from pixels to forest ecosystems, and from a single date to the full annual cycle, indicating the potential for using high-resolution satellites to track the large-scale phenological patterns and response of tropical forests to climate change.

Original language	English
Article number	113429
Journal	Remote Sensing of Environment
Volume	286
DOIs	https://doi.org/10.1016/j.rse.2022.113429
State	Published - Mar 1 2023

Funding

This work was supported by National Natural Science Foundation of China (#31922090), Hong Kong Research Grant Council General Research Fund (#17316622) and the São Paulo Research Foundation – FAPESP (grants FAPESP – Microsoft Research Institute #2013/50155-0, #2019/11835-2, 2019/16191-6). J. Wang was in part supported by Shenzhen Science and Technology Program (Grant No. 20220816162849005) and the Division of Ecology and Biodiversity PDF research award. CKFL was in part supported by HKU seed fund for basic research (#202011159154) and the HKU 45th round PDF scheme. DY was supported by the United States Department of Energy contract No. DE-SC0012704 to Brookhaven National Laboratory. BA received PhD fellowships from FAPESP (#2014/00215-0 and #2016/01413-5) and a Post-doctoral fellowship from CAPES Print Program (#88887.512218/2020-00) at UNESP. LPCM receives research productivity fellowships from National Council for Scientific and Technological Development (CNPq grant #428055/2018-4). XM was supported by the National Natural Science Foundation of China (42171305), the Natural Science Foundation of Gansu Province, China (21JR7RA499), the Director Fund of the International Research Center of Big Data for Sustainable Development Goals (CBAS2022DF006), and the Open Fund of Key laboratory of Geographic Information Science (Ministry of Education), East China Normal University. M. Ng was supported in part by Hong Kong Research Grant Council GRF 12300519, 17201020, 17300021, C1013-21GF, C7004-21GF and Jointly by NSFC-RGC N-HKU76921. Phenocam data collection at the Australian sites was supported by the Australian Government's Terrestrial Ecosystem Research Network (TERN, www.tern.org.au ). Phenocam data collection at the Amazon Tall Tower tower was supported by the Brazilian Ministry of Science, Technology and Innovation (MCTI) and the German Federal Ministry of Education and Research (BMBF) .

Keywords

Carbon cycles
Deciduousness
Environmental gradient
Machine learning
Multi-scale remote sensing
Tropical forests

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10.1016/j.rse.2022.113429

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Wang, J., Song, G., Liddell, M., Morellato, P., Lee, C. K. F., Yang, D., Alberton, B., Detto, M., Ma, X., Zhao, Y., Yeung, H. C. H., Zhang, H., Ng, M., Nelson, B. W., Huete, A., & Wu, J. (2023). An ecologically-constrained deep learning model for tropical leaf phenology monitoring using PlanetScope satellites. Remote Sensing of Environment, 286, Article 113429. https://doi.org/10.1016/j.rse.2022.113429

@article{2911074f8e1644ea9026a6ba4412ec09,

title = "An ecologically-constrained deep learning model for tropical leaf phenology monitoring using PlanetScope satellites",

abstract = "In tropical forests, leaf phenology signals leaf-on/off status and exhibits considerable variability across scales from a single tree-crown to the entire forest ecosystem. Such phenology signals importantly regulate large-scale biogeochemical cycles and regional climate. PlanetScope CubeSats data with a 3-m resolution and near-daily global coverage provide an unprecedented opportunity to monitor both fine- and ecosystem-scale phenology variability along large environmental gradients. However, a scalable method that accurately characterizes leaf phenology from PlanetScope with biophysically meaningful metrics remains lacking. We developed an index-guided, ecologically constrained autoencoder (IG-ECAE) method to automatically derive a deciduousness metric (percentage of upper tree canopies with leaf-off status within an image pixel) from PlanetScope. The IG-ECAE first estimated the reflectance spectra of leafy/leafless canopies based on their spectral indices characteristics, then used the derived reflectance spectra to guide an autoencoder deep learning method with additional ecological constraints to refine the reflectance spectra, and finally used linear spectral unmixing to estimate the relative abundance of leafless canopies (or deciduousness) per PlanetScope image pixel. We tested the IG-ECAE method at 16 tropical forest sites spanning multiple continents and a large precipitation gradient (1470–2819 mm year−1). Among these sites, we evaluated the PlanetScope-derived deciduousness against corresponding measures derived from WorldView-2 (n = 9 sites) and local phenocams (n = 9 sites). Our results show that PlanetScope-derived deciduousness agrees: 1) with that derived from WorldView-2 at the patch level (90 m × 90 m) with r2 = 0.89 across all sites; and 2) with that derived from phenocams to quantify ecosystem-scale seasonality with r2 ranging from 0.62 to 0.96. These results demonstrate the effectiveness and scalability of IG-ECAE in characterizing the wide variability in deciduousness across scales from pixels to forest ecosystems, and from a single date to the full annual cycle, indicating the potential for using high-resolution satellites to track the large-scale phenological patterns and response of tropical forests to climate change.",

keywords = "Carbon cycles, Deciduousness, Environmental gradient, Machine learning, Multi-scale remote sensing, Tropical forests",

author = "Jing Wang and Guangqin Song and Michael Liddell and Patricia Morellato and Lee, {Calvin K.F.} and Dedi Yang and Bruna Alberton and Matteo Detto and Xuanlong Ma and Yingyi Zhao and Yeung, {Henry C.H.} and Hongsheng Zhang and Michael Ng and Nelson, {Bruce W.} and Alfredo Huete and Jin Wu",

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year = "2023",

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doi = "10.1016/j.rse.2022.113429",

language = "English",

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Wang, J, Song, G, Liddell, M, Morellato, P, Lee, CKF, Yang, D, Alberton, B, Detto, M, Ma, X, Zhao, Y, Yeung, HCH, Zhang, H, Ng, M, Nelson, BW, Huete, A & Wu, J 2023, 'An ecologically-constrained deep learning model for tropical leaf phenology monitoring using PlanetScope satellites', Remote Sensing of Environment, vol. 286, 113429. https://doi.org/10.1016/j.rse.2022.113429

TY - JOUR

T1 - An ecologically-constrained deep learning model for tropical leaf phenology monitoring using PlanetScope satellites

AU - Wang, Jing

AU - Song, Guangqin

AU - Liddell, Michael

AU - Morellato, Patricia

AU - Lee, Calvin K.F.

AU - Yang, Dedi

AU - Alberton, Bruna

AU - Detto, Matteo

AU - Ma, Xuanlong

AU - Zhao, Yingyi

AU - Yeung, Henry C.H.

AU - Zhang, Hongsheng

AU - Ng, Michael

AU - Nelson, Bruce W.

AU - Huete, Alfredo

AU - Wu, Jin

PY - 2023/3/1

Y1 - 2023/3/1

N2 - In tropical forests, leaf phenology signals leaf-on/off status and exhibits considerable variability across scales from a single tree-crown to the entire forest ecosystem. Such phenology signals importantly regulate large-scale biogeochemical cycles and regional climate. PlanetScope CubeSats data with a 3-m resolution and near-daily global coverage provide an unprecedented opportunity to monitor both fine- and ecosystem-scale phenology variability along large environmental gradients. However, a scalable method that accurately characterizes leaf phenology from PlanetScope with biophysically meaningful metrics remains lacking. We developed an index-guided, ecologically constrained autoencoder (IG-ECAE) method to automatically derive a deciduousness metric (percentage of upper tree canopies with leaf-off status within an image pixel) from PlanetScope. The IG-ECAE first estimated the reflectance spectra of leafy/leafless canopies based on their spectral indices characteristics, then used the derived reflectance spectra to guide an autoencoder deep learning method with additional ecological constraints to refine the reflectance spectra, and finally used linear spectral unmixing to estimate the relative abundance of leafless canopies (or deciduousness) per PlanetScope image pixel. We tested the IG-ECAE method at 16 tropical forest sites spanning multiple continents and a large precipitation gradient (1470–2819 mm year−1). Among these sites, we evaluated the PlanetScope-derived deciduousness against corresponding measures derived from WorldView-2 (n = 9 sites) and local phenocams (n = 9 sites). Our results show that PlanetScope-derived deciduousness agrees: 1) with that derived from WorldView-2 at the patch level (90 m × 90 m) with r2 = 0.89 across all sites; and 2) with that derived from phenocams to quantify ecosystem-scale seasonality with r2 ranging from 0.62 to 0.96. These results demonstrate the effectiveness and scalability of IG-ECAE in characterizing the wide variability in deciduousness across scales from pixels to forest ecosystems, and from a single date to the full annual cycle, indicating the potential for using high-resolution satellites to track the large-scale phenological patterns and response of tropical forests to climate change.

AB - In tropical forests, leaf phenology signals leaf-on/off status and exhibits considerable variability across scales from a single tree-crown to the entire forest ecosystem. Such phenology signals importantly regulate large-scale biogeochemical cycles and regional climate. PlanetScope CubeSats data with a 3-m resolution and near-daily global coverage provide an unprecedented opportunity to monitor both fine- and ecosystem-scale phenology variability along large environmental gradients. However, a scalable method that accurately characterizes leaf phenology from PlanetScope with biophysically meaningful metrics remains lacking. We developed an index-guided, ecologically constrained autoencoder (IG-ECAE) method to automatically derive a deciduousness metric (percentage of upper tree canopies with leaf-off status within an image pixel) from PlanetScope. The IG-ECAE first estimated the reflectance spectra of leafy/leafless canopies based on their spectral indices characteristics, then used the derived reflectance spectra to guide an autoencoder deep learning method with additional ecological constraints to refine the reflectance spectra, and finally used linear spectral unmixing to estimate the relative abundance of leafless canopies (or deciduousness) per PlanetScope image pixel. We tested the IG-ECAE method at 16 tropical forest sites spanning multiple continents and a large precipitation gradient (1470–2819 mm year−1). Among these sites, we evaluated the PlanetScope-derived deciduousness against corresponding measures derived from WorldView-2 (n = 9 sites) and local phenocams (n = 9 sites). Our results show that PlanetScope-derived deciduousness agrees: 1) with that derived from WorldView-2 at the patch level (90 m × 90 m) with r2 = 0.89 across all sites; and 2) with that derived from phenocams to quantify ecosystem-scale seasonality with r2 ranging from 0.62 to 0.96. These results demonstrate the effectiveness and scalability of IG-ECAE in characterizing the wide variability in deciduousness across scales from pixels to forest ecosystems, and from a single date to the full annual cycle, indicating the potential for using high-resolution satellites to track the large-scale phenological patterns and response of tropical forests to climate change.

KW - Carbon cycles

KW - Deciduousness

KW - Environmental gradient

KW - Machine learning

KW - Multi-scale remote sensing

KW - Tropical forests

UR - http://www.scopus.com/inward/record.url?scp=85145773613&partnerID=8YFLogxK

U2 - 10.1016/j.rse.2022.113429

DO - 10.1016/j.rse.2022.113429

M3 - Article

AN - SCOPUS:85145773613

SN - 0034-4257

VL - 286

JO - Remote Sensing of Environment

JF - Remote Sensing of Environment

M1 - 113429

ER -

An ecologically-constrained deep learning model for tropical leaf phenology monitoring using PlanetScope satellites

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