Vicarious calibration of the Tropospheric Monitoring Instrument (TROPOMI) short-wave infrared (SWIR) module over the Railroad Valley Playa

Tim A. Van Kempen; Tim J. Rotmans; Richard M. Van Hees; Carol Bruegge; Dejian Fu; Ruud Hoogeveen; Thomas J. Pongetti; Robert Rosenberg; Ilse Aben

doi:10.5194/amt-16-4507-2023

Vicarious calibration of the Tropospheric Monitoring Instrument (TROPOMI) short-wave infrared (SWIR) module over the Railroad Valley Playa

Tim A. Van Kempen^*
, Tim J. Rotmans
, Richard M. Van Hees
, Carol Bruegge
, Dejian Fu
, Ruud Hoogeveen
, Thomas J. Pongetti
, Robert Rosenberg
, Ilse Aben

^*Corresponding author for this work

Earth Sciences

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

Abstract

The short-wave infrared (SWIR) module of the Tropospheric Monitoring Instrument (TROPOMI) on board the ESA's Sentinel-5 precursor (S5p) satellite has been very stable during its 5 years in orbit. Calibration was performed on the ground, complemented by measurements during in-flight instrument commissioning. The radiometric response and general performance of the SWIR module are monitored by on-board calibration sources. We show that after 5 years in orbit, TROPOMI-SWIR has continued to show excellent performance with degradation of at most 0.1 % in transmission and having lost less than 0.3 % of the detector pixels. Independent validation of the instrument calibration, via vicarious calibration, can be done through comparisons with ground-based reflectance data. In this work, ground measurements at the Railroad Valley Playa, a valley in central Nevada that is often used as a reference for satellite measurements, are used to perform vicarious calibration of the TROPOMI-SWIR measurements. This is done using dedicated measurement campaigns as well as automated reflectance measurements within the RADCALNET programme. As such, TROPOMI-SWIR is an excellent test case to explore the methodology of vicarious calibration applied to infrared spectroscopy. Using methodology developed for the vicarious calibration of the OCO-2 and GOSAT missions, the absolute radiometry of TROPOMI-SWIR performance is independently verified to be stable down to ∼ 6 %-10 % using the Railroad Valley when both the absolute and relative radiometric calibrations are applied. Differences with the on-board calibration originate from the bidirectional reflection distribution function (BRDF) effects of the desert surface, the large variety in viewing angles, and the different sizes of footprints of the TROPOMI pixels. Vicarious calibration is shown to be an additional valuable tool in validating radiance-level performances of infrared instruments such as TROPOMI-SWIR in the field of atmospheric composition. It remains clear that for instruments of similar design and resolution to TROPOMI-SWIR, on-board calibration sources will continue to provide superior results due to the limitations of the vicarious calibration method.

Original language	English
Pages (from-to)	4507-4527
Number of pages	21
Journal	Atmospheric Measurement Techniques
Volume	16
Issue number	19
Early online date	11 Oct 2023
DOIs	https://doi.org/10.5194/amt-16-4507-2023
Publication status	Published - 2023

Bibliographical note

Funding Information:
TROPOMI is a collaboration between Airbus Defence and Space Netherlands, KNMI (Koninklijke Nederlands Meteorologisch Instituut), SRON Netherlands Institute for Space Research, and TNO (Toegepast Natuurwetenschappelijk Onderzoek), on behalf of the NSO (Netherlands Space Office) and ESA (European Space Agency). Airbus Defence and Space Netherlands is the main contractor for the design, building, and testing of the instrument. KNMI and SRON are the principal investigator institutes for the instrument. TROPOMI is funded by the following ministries of the Dutch government: the Ministry of Economic Affairs; the Ministry of Education, Culture and Science; and the Ministry of Infrastructure and the Environment.

Funding Information:
The research of Tim A. van Kempen is funded by the TROPOMI national programme from the Netherlands Space Office (NSO). This work was supported by the Earthnet Data Assessment Pilot (EDAP) subcontract TPZVUK/AG/19/02305.

Publisher Copyright:
© 2023 Tim A. van Kempen et al.

Funding

TROPOMI is a collaboration between Airbus Defence and Space Netherlands, KNMI (Koninklijke Nederlands Meteorologisch Instituut), SRON Netherlands Institute for Space Research, and TNO (Toegepast Natuurwetenschappelijk Onderzoek), on behalf of the NSO (Netherlands Space Office) and ESA (European Space Agency). Airbus Defence and Space Netherlands is the main contractor for the design, building, and testing of the instrument. KNMI and SRON are the principal investigator institutes for the instrument. TROPOMI is funded by the following ministries of the Dutch government: the Ministry of Economic Affairs; the Ministry of Education, Culture and Science; and the Ministry of Infrastructure and the Environment. The research of Tim A. van Kempen is funded by the TROPOMI national programme from the Netherlands Space Office (NSO). This work was supported by the Earthnet Data Assessment Pilot (EDAP) subcontract TPZVUK/AG/19/02305.

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Van Kempen, T. A., Rotmans, T. J., Van Hees, R. M., Bruegge, C., Fu, D., Hoogeveen, R., Pongetti, T. J., Rosenberg, R., & Aben, I. (2023). Vicarious calibration of the Tropospheric Monitoring Instrument (TROPOMI) short-wave infrared (SWIR) module over the Railroad Valley Playa. Atmospheric Measurement Techniques, 16(19), 4507-4527. https://doi.org/10.5194/amt-16-4507-2023

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title = "Vicarious calibration of the Tropospheric Monitoring Instrument (TROPOMI) short-wave infrared (SWIR) module over the Railroad Valley Playa",

abstract = "The short-wave infrared (SWIR) module of the Tropospheric Monitoring Instrument (TROPOMI) on board the ESA's Sentinel-5 precursor (S5p) satellite has been very stable during its 5 years in orbit. Calibration was performed on the ground, complemented by measurements during in-flight instrument commissioning. The radiometric response and general performance of the SWIR module are monitored by on-board calibration sources. We show that after 5 years in orbit, TROPOMI-SWIR has continued to show excellent performance with degradation of at most 0.1 \% in transmission and having lost less than 0.3 \% of the detector pixels. Independent validation of the instrument calibration, via vicarious calibration, can be done through comparisons with ground-based reflectance data. In this work, ground measurements at the Railroad Valley Playa, a valley in central Nevada that is often used as a reference for satellite measurements, are used to perform vicarious calibration of the TROPOMI-SWIR measurements. This is done using dedicated measurement campaigns as well as automated reflectance measurements within the RADCALNET programme. As such, TROPOMI-SWIR is an excellent test case to explore the methodology of vicarious calibration applied to infrared spectroscopy. Using methodology developed for the vicarious calibration of the OCO-2 and GOSAT missions, the absolute radiometry of TROPOMI-SWIR performance is independently verified to be stable down to ∼ 6 \%-10 \% using the Railroad Valley when both the absolute and relative radiometric calibrations are applied. Differences with the on-board calibration originate from the bidirectional reflection distribution function (BRDF) effects of the desert surface, the large variety in viewing angles, and the different sizes of footprints of the TROPOMI pixels. Vicarious calibration is shown to be an additional valuable tool in validating radiance-level performances of infrared instruments such as TROPOMI-SWIR in the field of atmospheric composition. It remains clear that for instruments of similar design and resolution to TROPOMI-SWIR, on-board calibration sources will continue to provide superior results due to the limitations of the vicarious calibration method.",

author = "\{Van Kempen\}, \{Tim A.\} and Rotmans, \{Tim J.\} and \{Van Hees\}, \{Richard M.\} and Carol Bruegge and Dejian Fu and Ruud Hoogeveen and Pongetti, \{Thomas J.\} and Robert Rosenberg and Ilse Aben",

note = "Funding Information: TROPOMI is a collaboration between Airbus Defence and Space Netherlands, KNMI (Koninklijke Nederlands Meteorologisch Instituut), SRON Netherlands Institute for Space Research, and TNO (Toegepast Natuurwetenschappelijk Onderzoek), on behalf of the NSO (Netherlands Space Office) and ESA (European Space Agency). Airbus Defence and Space Netherlands is the main contractor for the design, building, and testing of the instrument. KNMI and SRON are the principal investigator institutes for the instrument. TROPOMI is funded by the following ministries of the Dutch government: the Ministry of Economic Affairs; the Ministry of Education, Culture and Science; and the Ministry of Infrastructure and the Environment. Funding Information: The research of Tim A. van Kempen is funded by the TROPOMI national programme from the Netherlands Space Office (NSO). This work was supported by the Earthnet Data Assessment Pilot (EDAP) subcontract TPZVUK/AG/19/02305. Publisher Copyright: {\textcopyright} 2023 Tim A. van Kempen et al.",

year = "2023",

doi = "10.5194/amt-16-4507-2023",

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AU - Van Kempen, Tim A.

AU - Rotmans, Tim J.

AU - Van Hees, Richard M.

AU - Bruegge, Carol

AU - Fu, Dejian

AU - Hoogeveen, Ruud

AU - Pongetti, Thomas J.

AU - Rosenberg, Robert

AU - Aben, Ilse

N1 - Funding Information: TROPOMI is a collaboration between Airbus Defence and Space Netherlands, KNMI (Koninklijke Nederlands Meteorologisch Instituut), SRON Netherlands Institute for Space Research, and TNO (Toegepast Natuurwetenschappelijk Onderzoek), on behalf of the NSO (Netherlands Space Office) and ESA (European Space Agency). Airbus Defence and Space Netherlands is the main contractor for the design, building, and testing of the instrument. KNMI and SRON are the principal investigator institutes for the instrument. TROPOMI is funded by the following ministries of the Dutch government: the Ministry of Economic Affairs; the Ministry of Education, Culture and Science; and the Ministry of Infrastructure and the Environment. Funding Information: The research of Tim A. van Kempen is funded by the TROPOMI national programme from the Netherlands Space Office (NSO). This work was supported by the Earthnet Data Assessment Pilot (EDAP) subcontract TPZVUK/AG/19/02305. Publisher Copyright: © 2023 Tim A. van Kempen et al.

PY - 2023

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N2 - The short-wave infrared (SWIR) module of the Tropospheric Monitoring Instrument (TROPOMI) on board the ESA's Sentinel-5 precursor (S5p) satellite has been very stable during its 5 years in orbit. Calibration was performed on the ground, complemented by measurements during in-flight instrument commissioning. The radiometric response and general performance of the SWIR module are monitored by on-board calibration sources. We show that after 5 years in orbit, TROPOMI-SWIR has continued to show excellent performance with degradation of at most 0.1 % in transmission and having lost less than 0.3 % of the detector pixels. Independent validation of the instrument calibration, via vicarious calibration, can be done through comparisons with ground-based reflectance data. In this work, ground measurements at the Railroad Valley Playa, a valley in central Nevada that is often used as a reference for satellite measurements, are used to perform vicarious calibration of the TROPOMI-SWIR measurements. This is done using dedicated measurement campaigns as well as automated reflectance measurements within the RADCALNET programme. As such, TROPOMI-SWIR is an excellent test case to explore the methodology of vicarious calibration applied to infrared spectroscopy. Using methodology developed for the vicarious calibration of the OCO-2 and GOSAT missions, the absolute radiometry of TROPOMI-SWIR performance is independently verified to be stable down to ∼ 6 %-10 % using the Railroad Valley when both the absolute and relative radiometric calibrations are applied. Differences with the on-board calibration originate from the bidirectional reflection distribution function (BRDF) effects of the desert surface, the large variety in viewing angles, and the different sizes of footprints of the TROPOMI pixels. Vicarious calibration is shown to be an additional valuable tool in validating radiance-level performances of infrared instruments such as TROPOMI-SWIR in the field of atmospheric composition. It remains clear that for instruments of similar design and resolution to TROPOMI-SWIR, on-board calibration sources will continue to provide superior results due to the limitations of the vicarious calibration method.

AB - The short-wave infrared (SWIR) module of the Tropospheric Monitoring Instrument (TROPOMI) on board the ESA's Sentinel-5 precursor (S5p) satellite has been very stable during its 5 years in orbit. Calibration was performed on the ground, complemented by measurements during in-flight instrument commissioning. The radiometric response and general performance of the SWIR module are monitored by on-board calibration sources. We show that after 5 years in orbit, TROPOMI-SWIR has continued to show excellent performance with degradation of at most 0.1 % in transmission and having lost less than 0.3 % of the detector pixels. Independent validation of the instrument calibration, via vicarious calibration, can be done through comparisons with ground-based reflectance data. In this work, ground measurements at the Railroad Valley Playa, a valley in central Nevada that is often used as a reference for satellite measurements, are used to perform vicarious calibration of the TROPOMI-SWIR measurements. This is done using dedicated measurement campaigns as well as automated reflectance measurements within the RADCALNET programme. As such, TROPOMI-SWIR is an excellent test case to explore the methodology of vicarious calibration applied to infrared spectroscopy. Using methodology developed for the vicarious calibration of the OCO-2 and GOSAT missions, the absolute radiometry of TROPOMI-SWIR performance is independently verified to be stable down to ∼ 6 %-10 % using the Railroad Valley when both the absolute and relative radiometric calibrations are applied. Differences with the on-board calibration originate from the bidirectional reflection distribution function (BRDF) effects of the desert surface, the large variety in viewing angles, and the different sizes of footprints of the TROPOMI pixels. Vicarious calibration is shown to be an additional valuable tool in validating radiance-level performances of infrared instruments such as TROPOMI-SWIR in the field of atmospheric composition. It remains clear that for instruments of similar design and resolution to TROPOMI-SWIR, on-board calibration sources will continue to provide superior results due to the limitations of the vicarious calibration method.

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Vicarious calibration of the Tropospheric Monitoring Instrument (TROPOMI) short-wave infrared (SWIR) module over the Railroad Valley Playa

Abstract

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