The EnMAP spaceborne imaging spectroscopy mission: Initial scientific results two years after launch

Sabine Chabrillat; Saskia Foerster; Karl Segl; Alison Beamish; Maximilian Brell; Saeid Asadzadeh; Robert Milewski; Kathrin J. Ward; Arlena Brosinsky; Katrin Koch; Daniel Scheffler; Stephane Guillaso; Alexander Kokhanovsky; Sigrid Roessner; Luis Guanter; Hermann Kaufmann; Nicole Pinnel; Emiliano Carmona; Tobias Storch; Tobias Hank; Katja Berger; Mathias Wocher; Patrick Hostert; Sebastian van der Linden; Akpona Okujeni; Andreas Janz; Benjamin Jakimow; Astrid Bracher; Mariana A. Soppa; Leonardo M.A. Alvarado; Henning Buddenbaum; Birgit Heim; Uta Heiden; Jose Moreno; Cindy Ong; Niklas Bohn; Robert O. Green; Martin Bachmann; Raymond Kokaly; Martin Schodlok; Thomas H. Painter; Ferran Gascon; Fabrizia Buongiorno; Matti Mõttus; Vittorio Ernesto Brando; Hannes Feilhauer; Matthias Betz; Simon Baur; Rupert Feckl; Anke Schickling; Vera Krieger; Michael Bock; Laura La Porta; Sebastian Fischer

doi:10.1016/j.rse.2024.114379

The EnMAP spaceborne imaging spectroscopy mission: Initial scientific results two years after launch

Sabine Chabrillat^*
, Saskia Foerster
, Karl Segl
, Alison Beamish
, Maximilian Brell
, Saeid Asadzadeh
, Robert Milewski
, Kathrin J. Ward
, Arlena Brosinsky
, Katrin Koch
, Daniel Scheffler
, Stephane Guillaso
, Alexander Kokhanovsky
, Sigrid Roessner
, Luis Guanter
, Hermann Kaufmann
, Nicole Pinnel
, Emiliano Carmona
, Tobias Storch
, Tobias Hank

Katja Berger, Mathias Wocher, Patrick Hostert, Sebastian van der Linden, Akpona Okujeni, Andreas Janz, Benjamin Jakimow, Astrid Bracher, Mariana A. Soppa, Leonardo M.A. Alvarado, Henning Buddenbaum, Birgit Heim, Uta Heiden, Jose Moreno, Cindy Ong, Niklas Bohn, Robert O. Green, Martin Bachmann, Raymond Kokaly, Martin Schodlok, Thomas H. Painter, Ferran Gascon, Fabrizia Buongiorno, Matti Mõttus, Vittorio Ernesto Brando, Hannes Feilhauer, Matthias Betz, Simon Baur, Rupert Feckl, Anke Schickling, Vera Krieger, Michael Bock, Laura La Porta, Sebastian Fischer

^*Corresponding author for this work

BA6408 Remote sensing

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

53 Citations (Scopus)

Abstract

Imaging spectroscopy has been a recognized and established remote sensing technology since the 1980s, mainly using airborne and field-based platforms to identify and quantify key bio- and geo-chemical surface and atmospheric compounds, based on characteristic spectral reflectance features in the visible-near infrared (VNIR) and short-wave infrared (SWIR). Spaceborne missions, a leap in technology, were sparse, starting with the CHRIS/PROBA and EO1/Hyperion missions in the early 2000s, and providing spectroscopy data with limited spectral coverage and/or low data quality in the SWIR. Since 2019, several countries and agencies have successfully launched a number of spaceborne imaging spectroscopy systems into orbit or deployed them on the International Space Station (ISS) such as DESIS, PRISMA, HISUI, GF-5, EnMAP and EMIT. Among these recent missions, the German Environmental Mapping and Analysis Program (EnMAP) stands for its long-term development, sophisticated design with on-board calibration, high data quality requirements, and extensive accompanying science program. EnMAP was launched in April 2022 and, following a successful commissioning phase, started its operational activities in November 2022. The EnMAP mission encompasses global coverage from 80° N to 80° S through on-demand data acquisitions. Data are free and open access with 30 m spatial resolution, a high spectral resolution with a spectral sampling distance of 6.5 nm and 10 nm in the VNIR and SWIR regions respectively, and a high signal-to-noise ratio. In this paper, we aim to present the mission's current status, coverage, science capabilities and performance two years after launch. We show the potential of EnMAP for space-based imaging spectroscopy to operate in various environments, including high and low light levels, dense forests, Antarctic glaciers, and arid agricultural areas. EnMAP enables various applications in fields such as agriculture and forestry, soil compositional, raw materials, and methane mapping, as well as water quality assessment, and snow and ice properties. The results show that EnMAP's performance exceeds the mission requirements, and highlights the significant potential for contribution to scientific exploitation in various geo- and biochemical sciences. EnMAP is also expected to serve as a key tool for the development and testing of data processing algorithms for upcoming global operational missions.

Original language	English
Article number	114379
Journal	Remote Sensing of Environment
Volume	315
DOIs	https://doi.org/10.1016/j.rse.2024.114379
Publication status	Published - 15 Dec 2024
MoE publication type	A1 Journal article-refereed

Funding

This study was supported by the EnMAP science program (grant numbers 50EE1923 and 50EE2401) under the DLR Space Agency with resources from the German Federal Ministry of Economic Affairs and Climate Action (BMWK). A.B. and L.M.A contributions were further supported by the TypSynSat project (grant number 50EE1915) under the DLR/BMWK funding. A portion of this research was carried out at the Jet Propulsion Laboratory, California Institute of Technology, under a contract with the National Aeronautics and Space Administration (80NM0018D0004).

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

SDG 6 Clean Water and Sanitation

Keywords

Bio-geochemical mapping
EnMAP mission
Science cases
Space-based imaging spectroscopy
Surface and atmosphere
VNIR-SWIR

Access to Document

10.1016/j.rse.2024.114379

Cite this

Chabrillat, S., Foerster, S., Segl, K., Beamish, A., Brell, M., Asadzadeh, S., Milewski, R., Ward, K. J., Brosinsky, A., Koch, K., Scheffler, D., Guillaso, S., Kokhanovsky, A., Roessner, S., Guanter, L., Kaufmann, H., Pinnel, N., Carmona, E., Storch, T., ... Fischer, S. (2024). The EnMAP spaceborne imaging spectroscopy mission: Initial scientific results two years after launch. Remote Sensing of Environment, 315, Article 114379. https://doi.org/10.1016/j.rse.2024.114379

@article{dc202a0c64284437a9cf3619fc5e2e8f,

title = "The EnMAP spaceborne imaging spectroscopy mission: Initial scientific results two years after launch",

abstract = "Imaging spectroscopy has been a recognized and established remote sensing technology since the 1980s, mainly using airborne and field-based platforms to identify and quantify key bio- and geo-chemical surface and atmospheric compounds, based on characteristic spectral reflectance features in the visible-near infrared (VNIR) and short-wave infrared (SWIR). Spaceborne missions, a leap in technology, were sparse, starting with the CHRIS/PROBA and EO1/Hyperion missions in the early 2000s, and providing spectroscopy data with limited spectral coverage and/or low data quality in the SWIR. Since 2019, several countries and agencies have successfully launched a number of spaceborne imaging spectroscopy systems into orbit or deployed them on the International Space Station (ISS) such as DESIS, PRISMA, HISUI, GF-5, EnMAP and EMIT. Among these recent missions, the German Environmental Mapping and Analysis Program (EnMAP) stands for its long-term development, sophisticated design with on-board calibration, high data quality requirements, and extensive accompanying science program. EnMAP was launched in April 2022 and, following a successful commissioning phase, started its operational activities in November 2022. The EnMAP mission encompasses global coverage from 80° N to 80° S through on-demand data acquisitions. Data are free and open access with 30 m spatial resolution, a high spectral resolution with a spectral sampling distance of 6.5 nm and 10 nm in the VNIR and SWIR regions respectively, and a high signal-to-noise ratio. In this paper, we aim to present the mission's current status, coverage, science capabilities and performance two years after launch. We show the potential of EnMAP for space-based imaging spectroscopy to operate in various environments, including high and low light levels, dense forests, Antarctic glaciers, and arid agricultural areas. EnMAP enables various applications in fields such as agriculture and forestry, soil compositional, raw materials, and methane mapping, as well as water quality assessment, and snow and ice properties. The results show that EnMAP's performance exceeds the mission requirements, and highlights the significant potential for contribution to scientific exploitation in various geo- and biochemical sciences. EnMAP is also expected to serve as a key tool for the development and testing of data processing algorithms for upcoming global operational missions.",

keywords = "Bio-geochemical mapping, EnMAP mission, Science cases, Space-based imaging spectroscopy, Surface and atmosphere, VNIR-SWIR",

author = "Sabine Chabrillat and Saskia Foerster and Karl Segl and Alison Beamish and Maximilian Brell and Saeid Asadzadeh and Robert Milewski and Ward, \{Kathrin J.\} and Arlena Brosinsky and Katrin Koch and Daniel Scheffler and Stephane Guillaso and Alexander Kokhanovsky and Sigrid Roessner and Luis Guanter and Hermann Kaufmann and Nicole Pinnel and Emiliano Carmona and Tobias Storch and Tobias Hank and Katja Berger and Mathias Wocher and Patrick Hostert and \{van der Linden\}, Sebastian and Akpona Okujeni and Andreas Janz and Benjamin Jakimow and Astrid Bracher and Soppa, \{Mariana A.\} and Alvarado, \{Leonardo M.A.\} and Henning Buddenbaum and Birgit Heim and Uta Heiden and Jose Moreno and Cindy Ong and Niklas Bohn and Green, \{Robert O.\} and Martin Bachmann and Raymond Kokaly and Martin Schodlok and Painter, \{Thomas H.\} and Ferran Gascon and Fabrizia Buongiorno and Matti M{\~o}ttus and Brando, \{Vittorio Ernesto\} and Hannes Feilhauer and Matthias Betz and Simon Baur and Rupert Feckl and Anke Schickling and Vera Krieger and Michael Bock and \{La Porta\}, Laura and Sebastian Fischer",

year = "2024",

month = dec,

day = "15",

doi = "10.1016/j.rse.2024.114379",

language = "English",

volume = "315",

journal = "Remote Sensing of Environment",

issn = "0034-4257",

publisher = "Elsevier",

}

Chabrillat, S, Foerster, S, Segl, K, Beamish, A, Brell, M, Asadzadeh, S, Milewski, R, Ward, KJ, Brosinsky, A, Koch, K, Scheffler, D, Guillaso, S, Kokhanovsky, A, Roessner, S, Guanter, L, Kaufmann, H, Pinnel, N, Carmona, E, Storch, T, Hank, T, Berger, K, Wocher, M, Hostert, P, van der Linden, S, Okujeni, A, Janz, A, Jakimow, B, Bracher, A, Soppa, MA, Alvarado, LMA, Buddenbaum, H, Heim, B, Heiden, U, Moreno, J, Ong, C, Bohn, N, Green, RO, Bachmann, M, Kokaly, R, Schodlok, M, Painter, TH, Gascon, F, Buongiorno, F, Mõttus, M, Brando, VE, Feilhauer, H, Betz, M, Baur, S, Feckl, R, Schickling, A, Krieger, V, Bock, M, La Porta, L & Fischer, S 2024, 'The EnMAP spaceborne imaging spectroscopy mission: Initial scientific results two years after launch', Remote Sensing of Environment, vol. 315, 114379. https://doi.org/10.1016/j.rse.2024.114379

TY - JOUR

T1 - The EnMAP spaceborne imaging spectroscopy mission

T2 - Initial scientific results two years after launch

AU - Chabrillat, Sabine

AU - Foerster, Saskia

AU - Segl, Karl

AU - Beamish, Alison

AU - Brell, Maximilian

AU - Asadzadeh, Saeid

AU - Milewski, Robert

AU - Ward, Kathrin J.

AU - Brosinsky, Arlena

AU - Koch, Katrin

AU - Scheffler, Daniel

AU - Guillaso, Stephane

AU - Kokhanovsky, Alexander

AU - Roessner, Sigrid

AU - Guanter, Luis

AU - Kaufmann, Hermann

AU - Pinnel, Nicole

AU - Carmona, Emiliano

AU - Storch, Tobias

AU - Hank, Tobias

AU - Berger, Katja

AU - Wocher, Mathias

AU - Hostert, Patrick

AU - van der Linden, Sebastian

AU - Okujeni, Akpona

AU - Janz, Andreas

AU - Jakimow, Benjamin

AU - Bracher, Astrid

AU - Soppa, Mariana A.

AU - Alvarado, Leonardo M.A.

AU - Buddenbaum, Henning

AU - Heim, Birgit

AU - Heiden, Uta

AU - Moreno, Jose

AU - Ong, Cindy

AU - Bohn, Niklas

AU - Green, Robert O.

AU - Bachmann, Martin

AU - Kokaly, Raymond

AU - Schodlok, Martin

AU - Painter, Thomas H.

AU - Gascon, Ferran

AU - Buongiorno, Fabrizia

AU - Mõttus, Matti

AU - Brando, Vittorio Ernesto

AU - Feilhauer, Hannes

AU - Betz, Matthias

AU - Baur, Simon

AU - Feckl, Rupert

AU - Schickling, Anke

AU - Krieger, Vera

AU - Bock, Michael

AU - La Porta, Laura

AU - Fischer, Sebastian

PY - 2024/12/15

Y1 - 2024/12/15

N2 - Imaging spectroscopy has been a recognized and established remote sensing technology since the 1980s, mainly using airborne and field-based platforms to identify and quantify key bio- and geo-chemical surface and atmospheric compounds, based on characteristic spectral reflectance features in the visible-near infrared (VNIR) and short-wave infrared (SWIR). Spaceborne missions, a leap in technology, were sparse, starting with the CHRIS/PROBA and EO1/Hyperion missions in the early 2000s, and providing spectroscopy data with limited spectral coverage and/or low data quality in the SWIR. Since 2019, several countries and agencies have successfully launched a number of spaceborne imaging spectroscopy systems into orbit or deployed them on the International Space Station (ISS) such as DESIS, PRISMA, HISUI, GF-5, EnMAP and EMIT. Among these recent missions, the German Environmental Mapping and Analysis Program (EnMAP) stands for its long-term development, sophisticated design with on-board calibration, high data quality requirements, and extensive accompanying science program. EnMAP was launched in April 2022 and, following a successful commissioning phase, started its operational activities in November 2022. The EnMAP mission encompasses global coverage from 80° N to 80° S through on-demand data acquisitions. Data are free and open access with 30 m spatial resolution, a high spectral resolution with a spectral sampling distance of 6.5 nm and 10 nm in the VNIR and SWIR regions respectively, and a high signal-to-noise ratio. In this paper, we aim to present the mission's current status, coverage, science capabilities and performance two years after launch. We show the potential of EnMAP for space-based imaging spectroscopy to operate in various environments, including high and low light levels, dense forests, Antarctic glaciers, and arid agricultural areas. EnMAP enables various applications in fields such as agriculture and forestry, soil compositional, raw materials, and methane mapping, as well as water quality assessment, and snow and ice properties. The results show that EnMAP's performance exceeds the mission requirements, and highlights the significant potential for contribution to scientific exploitation in various geo- and biochemical sciences. EnMAP is also expected to serve as a key tool for the development and testing of data processing algorithms for upcoming global operational missions.

AB - Imaging spectroscopy has been a recognized and established remote sensing technology since the 1980s, mainly using airborne and field-based platforms to identify and quantify key bio- and geo-chemical surface and atmospheric compounds, based on characteristic spectral reflectance features in the visible-near infrared (VNIR) and short-wave infrared (SWIR). Spaceborne missions, a leap in technology, were sparse, starting with the CHRIS/PROBA and EO1/Hyperion missions in the early 2000s, and providing spectroscopy data with limited spectral coverage and/or low data quality in the SWIR. Since 2019, several countries and agencies have successfully launched a number of spaceborne imaging spectroscopy systems into orbit or deployed them on the International Space Station (ISS) such as DESIS, PRISMA, HISUI, GF-5, EnMAP and EMIT. Among these recent missions, the German Environmental Mapping and Analysis Program (EnMAP) stands for its long-term development, sophisticated design with on-board calibration, high data quality requirements, and extensive accompanying science program. EnMAP was launched in April 2022 and, following a successful commissioning phase, started its operational activities in November 2022. The EnMAP mission encompasses global coverage from 80° N to 80° S through on-demand data acquisitions. Data are free and open access with 30 m spatial resolution, a high spectral resolution with a spectral sampling distance of 6.5 nm and 10 nm in the VNIR and SWIR regions respectively, and a high signal-to-noise ratio. In this paper, we aim to present the mission's current status, coverage, science capabilities and performance two years after launch. We show the potential of EnMAP for space-based imaging spectroscopy to operate in various environments, including high and low light levels, dense forests, Antarctic glaciers, and arid agricultural areas. EnMAP enables various applications in fields such as agriculture and forestry, soil compositional, raw materials, and methane mapping, as well as water quality assessment, and snow and ice properties. The results show that EnMAP's performance exceeds the mission requirements, and highlights the significant potential for contribution to scientific exploitation in various geo- and biochemical sciences. EnMAP is also expected to serve as a key tool for the development and testing of data processing algorithms for upcoming global operational missions.

KW - Bio-geochemical mapping

KW - EnMAP mission

KW - Science cases

KW - Space-based imaging spectroscopy

KW - Surface and atmosphere

KW - VNIR-SWIR

UR - https://www.scopus.com/pages/publications/85206298433

U2 - 10.1016/j.rse.2024.114379

DO - 10.1016/j.rse.2024.114379

M3 - Article

AN - SCOPUS:85206298433

SN - 0034-4257

VL - 315

JO - Remote Sensing of Environment

JF - Remote Sensing of Environment

M1 - 114379

ER -

The EnMAP spaceborne imaging spectroscopy mission: Initial scientific results two years after launch

Abstract

Funding

UN SDGs

Keywords

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