Ecophysiological variables retrieval and early stress detection: insights from a synthetic spatial scaling exercise

Javier Pacheco-Labrador; M. Pilar Cendrero-Mateo; Shari Van Wittenberghe; Itza Hernandez-Sequeira; Gerbrand Koren; E. Prikaziuk; Szilvia Fóti; Enrico Tomelleri; Kadmiel Maseyk; Nataša Čereković; Rosario Gonzalez-Cascon; Zbyněk Malenovský; Mar Albert-Saiz; Michal Antala; János Balogh; Henning Buddenbaum; Mohammad Hossain Dehghan-Shoar; Joseph T. Fennell; Jean Baptiste Féret; Hamadou Balde; Miriam Machwitz; Ádám Mészáros; Guofang Miao; Miguel Morata; Paul Naethe; Zoltán Nagy; Krisztina Pintér; R. Reddy Pullanagari; Anshu Rastogi; Bastian Siegmann; Sheng Wang; Chenhui Zhang; Daniel Kopkáně

doi:10.1080/01431161.2024.2414435

Ecophysiological variables retrieval and early stress detection: insights from a synthetic spatial scaling exercise

Javier Pacheco-Labrador^*, M. Pilar Cendrero-Mateo, Shari Van Wittenberghe, Itza Hernandez-Sequeira, Gerbrand Koren, E. Prikaziuk, Szilvia Fóti, Enrico Tomelleri, Kadmiel Maseyk, Nataša Čereković, Rosario Gonzalez-Cascon, Zbyněk Malenovský, Mar Albert-Saiz, Michal Antala, János Balogh, Henning Buddenbaum, Mohammad Hossain Dehghan-Shoar, Joseph T. Fennell, Jean Baptiste Féret, Hamadou BaldeMiriam Machwitz, Ádám Mészáros, Guofang Miao, Miguel Morata, Paul Naethe, Zoltán Nagy, Krisztina Pintér, R. Reddy Pullanagari, Anshu Rastogi, Bastian Siegmann, Sheng Wang, Chenhui Zhang, Daniel Kopkáně

^*Corresponding author for this work

Research output: Contribution to journal › Article › Academic › peer-review

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Abstract

The ability to access physiologically driven signals, such as surface temperature, photochemical reflectance index (PRI), and sun-induced chlorophyll fluorescence (SIF), through remote sensing (RS) are exciting developments for vegetation studies. Accessing this ecophysiological information requires considering processes operating at scales from the top-of-the-canopy to the photosystems, adding complexity compared to reflectance index-based approaches. To investigate the maturity and knowledge of the growing RS community in this area, COST Action CA17134 SENSECO organized a Spatial Scaling Challenge (SSC). Challenge participants were asked to retrieve four key ecophysiological variables for a field each of maize and wheat from a simulated field campaign: leaf area index (LAI), leaf chlorophyll content (C_ab), maximum carboxylation rate (V_cmax,25), and non-photochemical quenching (NPQ). The simulated campaign data included hyperspectral optical, thermal and SIF imagery, together with ground sampling of the four variables. Non-parametric methods that combined multiple spectral domains and field measurements were used most often, thereby indirectly performing the top-of-the-canopy to photosystem scaling. LAI and C_ab were reliably retrieved in most cases, whereas V_cmax,25 and NPQ were less accurately estimated and demanded information ancillary to RS imagery. The factors considered least by participants were the biophysical and physiological canopy vertical profiles, the spatial mismatch between RS sensors, the temporal mismatch between field sampling and RS acquisition, and measurement uncertainty. Furthermore, few participants developed NPQ maps into stress maps or provided a deeper analysis of their parameter retrievals. The SSC shows that, despite advances in statistical and physically based models, the vegetation RS community should improve how field and RS data are integrated and scaled in space and time. We expect this work will guide newcomers and support robust advances in this research field.

Original language	English
Pages (from-to)	443-468
Number of pages	26
Journal	International journal of remote sensing
Volume	46
Issue number	1
Early online date	28 Oct 2024
DOIs	https://doi.org/10.1080/01431161.2024.2414435
Publication status	Published - 2025

Keywords

down-scaling
fluorescence
hyperspectral
photosystem
plant physiology
Remote sensing
spatial scaling
temporal mismatch
thermal
top of the canopy
ITC-ISI-JOURNAL-ARTICLE
ITC-HYBRID

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Ecophysiological variables retrieval and early stress detection insights from a synthetic spatial scaling exerciseFinal published version, 7.82 MBLicence: CC BY

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Pacheco-Labrador, J., Cendrero-Mateo, M. P., Van Wittenberghe, S., Hernandez-Sequeira, I., Koren, G., Prikaziuk, E., Fóti, S., Tomelleri, E., Maseyk, K., Čereković, N., Gonzalez-Cascon, R., Malenovský, Z., Albert-Saiz, M., Antala, M., Balogh, J., Buddenbaum, H., Dehghan-Shoar, M. H., Fennell, J. T., Féret, J. B., ... Kopkáně, D. (2025). Ecophysiological variables retrieval and early stress detection: insights from a synthetic spatial scaling exercise. International journal of remote sensing, 46(1), 443-468. https://doi.org/10.1080/01431161.2024.2414435

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title = "Ecophysiological variables retrieval and early stress detection: insights from a synthetic spatial scaling exercise",

abstract = "The ability to access physiologically driven signals, such as surface temperature, photochemical reflectance index (PRI), and sun-induced chlorophyll fluorescence (SIF), through remote sensing (RS) are exciting developments for vegetation studies. Accessing this ecophysiological information requires considering processes operating at scales from the top-of-the-canopy to the photosystems, adding complexity compared to reflectance index-based approaches. To investigate the maturity and knowledge of the growing RS community in this area, COST Action CA17134 SENSECO organized a Spatial Scaling Challenge (SSC). Challenge participants were asked to retrieve four key ecophysiological variables for a field each of maize and wheat from a simulated field campaign: leaf area index (LAI), leaf chlorophyll content (Cab), maximum carboxylation rate (Vcmax,25), and non-photochemical quenching (NPQ). The simulated campaign data included hyperspectral optical, thermal and SIF imagery, together with ground sampling of the four variables. Non-parametric methods that combined multiple spectral domains and field measurements were used most often, thereby indirectly performing the top-of-the-canopy to photosystem scaling. LAI and Cab were reliably retrieved in most cases, whereas Vcmax,25 and NPQ were less accurately estimated and demanded information ancillary to RS imagery. The factors considered least by participants were the biophysical and physiological canopy vertical profiles, the spatial mismatch between RS sensors, the temporal mismatch between field sampling and RS acquisition, and measurement uncertainty. Furthermore, few participants developed NPQ maps into stress maps or provided a deeper analysis of their parameter retrievals. The SSC shows that, despite advances in statistical and physically based models, the vegetation RS community should improve how field and RS data are integrated and scaled in space and time. We expect this work will guide newcomers and support robust advances in this research field.",

keywords = "down-scaling, fluorescence, hyperspectral, photosystem, plant physiology, Remote sensing, spatial scaling, temporal mismatch, thermal, top of the canopy, ITC-ISI-JOURNAL-ARTICLE, ITC-HYBRID",

author = "Javier Pacheco-Labrador and Cendrero-Mateo, \{M. Pilar\} and \{Van Wittenberghe\}, Shari and Itza Hernandez-Sequeira and Gerbrand Koren and E. Prikaziuk and Szilvia F{\'o}ti and Enrico Tomelleri and Kadmiel Maseyk and Nata{\v s}a {\v C}erekovi{\'c} and Rosario Gonzalez-Cascon and Zbyn{\v e}k Malenovsk{\'y} and Mar Albert-Saiz and Michal Antala and J{\'a}nos Balogh and Henning Buddenbaum and Dehghan-Shoar, \{Mohammad Hossain\} and Fennell, \{Joseph T.\} and F{\'e}ret, \{Jean Baptiste\} and Hamadou Balde and Miriam Machwitz and {\'A}d{\'a}m M{\'e}sz{\'a}ros and Guofang Miao and Miguel Morata and Paul Naethe and Zolt{\'a}n Nagy and Krisztina Pint{\'e}r and Pullanagari, \{R. Reddy\} and Anshu Rastogi and Bastian Siegmann and Sheng Wang and Chenhui Zhang and Daniel Kopk{\'a}n{\v e}",

note = "Publisher Copyright: {\textcopyright} 2024 The Author(s). Published by Informa UK Limited, trading as Taylor \& Francis Group.",

year = "2025",

doi = "10.1080/01431161.2024.2414435",

language = "English",

volume = "46",

pages = "443--468",

journal = "International journal of remote sensing",

issn = "0143-1161",

publisher = "Taylor \& Francis",

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Pacheco-Labrador, J, Cendrero-Mateo, MP, Van Wittenberghe, S, Hernandez-Sequeira, I, Koren, G, Prikaziuk, E, Fóti, S, Tomelleri, E, Maseyk, K, Čereković, N, Gonzalez-Cascon, R, Malenovský, Z, Albert-Saiz, M, Antala, M, Balogh, J, Buddenbaum, H, Dehghan-Shoar, MH, Fennell, JT, Féret, JB, Balde, H, Machwitz, M, Mészáros, Á, Miao, G, Morata, M, Naethe, P, Nagy, Z, Pintér, K, Pullanagari, RR, Rastogi, A, Siegmann, B, Wang, S, Zhang, C & Kopkáně, D 2025, 'Ecophysiological variables retrieval and early stress detection: insights from a synthetic spatial scaling exercise', International journal of remote sensing, vol. 46, no. 1, pp. 443-468. https://doi.org/10.1080/01431161.2024.2414435

TY - JOUR

T1 - Ecophysiological variables retrieval and early stress detection

T2 - insights from a synthetic spatial scaling exercise

AU - Pacheco-Labrador, Javier

AU - Cendrero-Mateo, M. Pilar

AU - Van Wittenberghe, Shari

AU - Hernandez-Sequeira, Itza

AU - Koren, Gerbrand

AU - Prikaziuk, E.

AU - Fóti, Szilvia

AU - Tomelleri, Enrico

AU - Maseyk, Kadmiel

AU - Čereković, Nataša

AU - Gonzalez-Cascon, Rosario

AU - Malenovský, Zbyněk

AU - Albert-Saiz, Mar

AU - Antala, Michal

AU - Balogh, János

AU - Buddenbaum, Henning

AU - Dehghan-Shoar, Mohammad Hossain

AU - Fennell, Joseph T.

AU - Féret, Jean Baptiste

AU - Balde, Hamadou

AU - Machwitz, Miriam

AU - Mészáros, Ádám

AU - Miao, Guofang

AU - Morata, Miguel

AU - Naethe, Paul

AU - Nagy, Zoltán

AU - Pintér, Krisztina

AU - Pullanagari, R. Reddy

AU - Rastogi, Anshu

AU - Siegmann, Bastian

AU - Wang, Sheng

AU - Zhang, Chenhui

AU - Kopkáně, Daniel

PY - 2025

Y1 - 2025

N2 - The ability to access physiologically driven signals, such as surface temperature, photochemical reflectance index (PRI), and sun-induced chlorophyll fluorescence (SIF), through remote sensing (RS) are exciting developments for vegetation studies. Accessing this ecophysiological information requires considering processes operating at scales from the top-of-the-canopy to the photosystems, adding complexity compared to reflectance index-based approaches. To investigate the maturity and knowledge of the growing RS community in this area, COST Action CA17134 SENSECO organized a Spatial Scaling Challenge (SSC). Challenge participants were asked to retrieve four key ecophysiological variables for a field each of maize and wheat from a simulated field campaign: leaf area index (LAI), leaf chlorophyll content (Cab), maximum carboxylation rate (Vcmax,25), and non-photochemical quenching (NPQ). The simulated campaign data included hyperspectral optical, thermal and SIF imagery, together with ground sampling of the four variables. Non-parametric methods that combined multiple spectral domains and field measurements were used most often, thereby indirectly performing the top-of-the-canopy to photosystem scaling. LAI and Cab were reliably retrieved in most cases, whereas Vcmax,25 and NPQ were less accurately estimated and demanded information ancillary to RS imagery. The factors considered least by participants were the biophysical and physiological canopy vertical profiles, the spatial mismatch between RS sensors, the temporal mismatch between field sampling and RS acquisition, and measurement uncertainty. Furthermore, few participants developed NPQ maps into stress maps or provided a deeper analysis of their parameter retrievals. The SSC shows that, despite advances in statistical and physically based models, the vegetation RS community should improve how field and RS data are integrated and scaled in space and time. We expect this work will guide newcomers and support robust advances in this research field.

AB - The ability to access physiologically driven signals, such as surface temperature, photochemical reflectance index (PRI), and sun-induced chlorophyll fluorescence (SIF), through remote sensing (RS) are exciting developments for vegetation studies. Accessing this ecophysiological information requires considering processes operating at scales from the top-of-the-canopy to the photosystems, adding complexity compared to reflectance index-based approaches. To investigate the maturity and knowledge of the growing RS community in this area, COST Action CA17134 SENSECO organized a Spatial Scaling Challenge (SSC). Challenge participants were asked to retrieve four key ecophysiological variables for a field each of maize and wheat from a simulated field campaign: leaf area index (LAI), leaf chlorophyll content (Cab), maximum carboxylation rate (Vcmax,25), and non-photochemical quenching (NPQ). The simulated campaign data included hyperspectral optical, thermal and SIF imagery, together with ground sampling of the four variables. Non-parametric methods that combined multiple spectral domains and field measurements were used most often, thereby indirectly performing the top-of-the-canopy to photosystem scaling. LAI and Cab were reliably retrieved in most cases, whereas Vcmax,25 and NPQ were less accurately estimated and demanded information ancillary to RS imagery. The factors considered least by participants were the biophysical and physiological canopy vertical profiles, the spatial mismatch between RS sensors, the temporal mismatch between field sampling and RS acquisition, and measurement uncertainty. Furthermore, few participants developed NPQ maps into stress maps or provided a deeper analysis of their parameter retrievals. The SSC shows that, despite advances in statistical and physically based models, the vegetation RS community should improve how field and RS data are integrated and scaled in space and time. We expect this work will guide newcomers and support robust advances in this research field.

KW - down-scaling

KW - fluorescence

KW - hyperspectral

KW - photosystem

KW - plant physiology

KW - Remote sensing

KW - spatial scaling

KW - temporal mismatch

KW - thermal

KW - top of the canopy

KW - ITC-ISI-JOURNAL-ARTICLE

KW - ITC-HYBRID

U2 - 10.1080/01431161.2024.2414435

DO - 10.1080/01431161.2024.2414435

M3 - Article

AN - SCOPUS:85207947571

SN - 0143-1161

VL - 46

SP - 443

EP - 468

JO - International journal of remote sensing

JF - International journal of remote sensing

IS - 1

ER -

Ecophysiological variables retrieval and early stress detection: insights from a synthetic spatial scaling exercise

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Keywords

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