Reviews and syntheses: Remotely sensed optical time series for monitoring 
vegetation productivity

Kooistra, Lammert; Berger, Katja; Brede, Benjamin; Graf, Lukas Valentin; Aasen, Helge; Roujean, Jean-Louis; Machwitz, Miriam; Schlerf, Martin; Atzberger, Clement; Prikaziuk, Egor; Ganeva, Dessislava; Tomelleri, Enrico; Croft, Holly; Reyes Muñoz, Pablo; Garcia Millan, Virginia; Darvishzadeh, Roshanak; Koren, Gerbrand; Herrmann, Ittai; Rozenstein, Offer; Belda, Santiago; Rautiainen, Miina; Rune Karlsen, Stein; Figueira Silva, Cláudio; Cerasoli, Sofia; Pierre, Jon; Tanır Kayıkçı, Emine; Halabuk, Andrej; Tunc Gormus, Esra; Fluit, Frank; Cai, Zhanzhang; Kycko, Marlena; Udelhoven, Thomas; Verrelst, Jochem

doi:10.5194/bg-21-473-2024

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Reviews and syntheses: Remotely sensed optical time series for monitoring vegetation productivity

Authors

Kooistra, Lammert
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Berger, Katja
1.2 Global Geomonitoring and Gravity Field, 1.0 Geodesy, Departments, GFZ Publication Database, Deutsches GeoForschungsZentrum;

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Brede, Benjamin
1.4 Remote Sensing, 1.0 Geodesy, Departments, GFZ Publication Database, Deutsches GeoForschungsZentrum;

Graf, Lukas Valentin
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Aasen, Helge
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Roujean, Jean-Louis
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Machwitz, Miriam
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Schlerf, Martin
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Atzberger, Clement
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Prikaziuk, Egor
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Ganeva, Dessislava
External Organizations;

Tomelleri, Enrico
External Organizations;

Croft, Holly
External Organizations;

Reyes Muñoz, Pablo
External Organizations;

Garcia Millan, Virginia
External Organizations;

Darvishzadeh, Roshanak
External Organizations;

Koren, Gerbrand
External Organizations;

Herrmann, Ittai
External Organizations;

Rozenstein, Offer
External Organizations;

Belda, Santiago
External Organizations;

Rautiainen, Miina
External Organizations;

Rune Karlsen, Stein
External Organizations;

Figueira Silva, Cláudio
External Organizations;

Cerasoli, Sofia
External Organizations;

Pierre, Jon
External Organizations;

Tanır Kayıkçı, Emine
External Organizations;

Halabuk, Andrej
External Organizations;

Tunc Gormus, Esra
External Organizations;

Fluit, Frank
External Organizations;

Cai, Zhanzhang
External Organizations;

Kycko, Marlena
External Organizations;

Udelhoven, Thomas
External Organizations;

Verrelst, Jochem
External Organizations;

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5025734.pdf
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Citation

Kooistra, L., Berger, K., Brede, B., Graf, L. V., Aasen, H., Roujean, J.-L., Machwitz, M., Schlerf, M., Atzberger, C., Prikaziuk, E., Ganeva, D., Tomelleri, E., Croft, H., Reyes Muñoz, P., Garcia Millan, V., Darvishzadeh, R., Koren, G., Herrmann, I., Rozenstein, O., Belda, S., Rautiainen, M., Rune Karlsen, S., Figueira Silva, C., Cerasoli, S., Pierre, J., Tanır Kayıkçı, E., Halabuk, A., Tunc Gormus, E., Fluit, F., Cai, Z., Kycko, M., Udelhoven, T., Verrelst, J. (2024): Reviews and syntheses: Remotely sensed optical time series for monitoring vegetation productivity. - Biogeosciences, 21, 2, 473-511.
https://doi.org/10.5194/bg-21-473-2024

Cite as: https://gfzpublic.gfz-potsdam.de/pubman/item/item_5025734

Abstract

Vegetation productivity is a critical indicator of global ecosystem health and is impacted by human activities and climate change. A wide range of optical sensing platforms, from ground-based to airborne and satellite, provide spatially continuous information on terrestrial vegetation status and functioning. As optical Earth observation (EO) data are usually routinely acquired, vegetation can be monitored repeatedly over time, reflecting seasonal vegetation patterns and trends in vegetation productivity metrics. Such metrics include gross primary productivity, net primary productivity, biomass, or yield. To summarize current knowledge, in this paper we systematically reviewed time series (TS) literature for assessing state-of-the-art vegetation productivity monitoring approaches for different ecosystems based on optical remote sensing (RS) data. As the integration of solar-induced fluorescence (SIF) data in vegetation productivity processing chains has emerged as a promising source, we also include this relatively recent sensor modality. We define three methodological categories to derive productivity metrics from remotely sensed TS of vegetation indices or quantitative traits: (i) trend analysis and anomaly detection, (ii) land surface phenology, and (iii) integration and assimilation of TS-derived metrics into statistical and process-based dynamic vegetation models (DVMs). Although the majority of used TS data streams originate from data acquired from satellite platforms, TS data from aircraft and unoccupied aerial vehicles have found their way into productivity monitoring studies. To facilitate processing, we provide a list of common toolboxes for inferring productivity metrics and information from TS data. We further discuss validation strategies of the RS data derived productivity metrics: (1) using in situ measured data, such as yield; (2) sensor networks of distinct sensors, including spectroradiometers, flux towers, or phenological cameras; and (3) inter-comparison of different productivity metrics. Finally, we address current challenges and propose a conceptual framework for productivity metrics derivation, including fully integrated DVMs and radiative transfer models here labelled as “Digital Twin”. This novel framework meets the requirements of multiple ecosystems and enables both an improved understanding of vegetation temporal dynamics in response to climate and environmental drivers and enhances the accuracy of vegetation productivity monitoring.