An assessment of non-geophysical effects in spaceborne GNSS Reflectometry data from the UK TechDemoSat-1 mission
An assessment of non-geophysical effects in spaceborne GNSS Reflectometry data from the UK TechDemoSat-1 mission
An assessment of non-geophysical effects in spaceborne global navigation satellite system reflectometry (GNSS-R) data from the UK TechDemoSat-1 (TDS-1) mission is presented. TDS-1 was launched in July 2014 and provides the first new spaceborne GNSS-R data since the pioneering UK-disaster monitoring constellation experiment in 2003. Non-geophysical factors evaluated include ambient L-band noise, instrument operating mode, and platform-related parameters. The findings are particularly relevant to users of uncalibrated GNSS-R signals for the retrieval of geophysical properties of the Earth surface. Substantial attitude adjustments of the TDS-1 platform are occasionally found to occur that introduce large uncertainties in parts of the TDS-1 GNSS-R dataset, particularly for specular points located outside the main beam of the nadir antenna where even small attitude errors can lead to large inaccuracies in the geophysical inversion. Out of eclipse however, attitude adjustments typically remain smaller than 1.5°, with larger deviations of up to 10° affecting less than 5% of the overall sun-lit data. Global maps of L1 ambient noise are presented for both automatic and programmed gain modes of the receiver, revealing persistent L-band noise hotspots along the Equator that can reach up to 2.5 dB, most likely associated with surface reflection of signals from other GNSS transmitters and constellations. Sporadic high-power noise events observed in certain regions point to sources of human origin. Relevant conclusions of this study are that platform attitude knowledge is essential and that radiometric calibration of GNSS-R signals should be used whenever possible. Care should be taken when considering using noise measurements over the equatorial oceans for calibration purposes, as ambient noise and correlated noise in delay–Doppler maps both show more variation than might be expected over these regions.
3418-3429
Foti, Giuseppe
d77b7bb4-b489-4fce-b5d7-d2f983c8509f
Gommenginger, Christine
f0db32be-34bb-44da-944b-c6b206ca4143
Unwin, Martin
ff2a649c-769f-4dc0-8fc1-ea9f53efc351
Jales, Philip
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Tye, Jason
0780a313-fb2d-48d6-b75b-437ab86e6bf4
Rosello, Josep
1db07492-5873-4d31-9d24-0d9cc12c47f3
1 July 2017
Foti, Giuseppe
d77b7bb4-b489-4fce-b5d7-d2f983c8509f
Gommenginger, Christine
f0db32be-34bb-44da-944b-c6b206ca4143
Unwin, Martin
ff2a649c-769f-4dc0-8fc1-ea9f53efc351
Jales, Philip
c41ba391-3d8e-439a-9342-8835ac0b9c33
Tye, Jason
0780a313-fb2d-48d6-b75b-437ab86e6bf4
Rosello, Josep
1db07492-5873-4d31-9d24-0d9cc12c47f3
Foti, Giuseppe, Gommenginger, Christine, Unwin, Martin, Jales, Philip, Tye, Jason and Rosello, Josep
(2017)
An assessment of non-geophysical effects in spaceborne GNSS Reflectometry data from the UK TechDemoSat-1 mission.
IEEE Journal of Selected Topics in Applied Earth Observations and Remote Sensing, 10 (7), .
(doi:10.1109/JSTARS.2017.2674305).
Abstract
An assessment of non-geophysical effects in spaceborne global navigation satellite system reflectometry (GNSS-R) data from the UK TechDemoSat-1 (TDS-1) mission is presented. TDS-1 was launched in July 2014 and provides the first new spaceborne GNSS-R data since the pioneering UK-disaster monitoring constellation experiment in 2003. Non-geophysical factors evaluated include ambient L-band noise, instrument operating mode, and platform-related parameters. The findings are particularly relevant to users of uncalibrated GNSS-R signals for the retrieval of geophysical properties of the Earth surface. Substantial attitude adjustments of the TDS-1 platform are occasionally found to occur that introduce large uncertainties in parts of the TDS-1 GNSS-R dataset, particularly for specular points located outside the main beam of the nadir antenna where even small attitude errors can lead to large inaccuracies in the geophysical inversion. Out of eclipse however, attitude adjustments typically remain smaller than 1.5°, with larger deviations of up to 10° affecting less than 5% of the overall sun-lit data. Global maps of L1 ambient noise are presented for both automatic and programmed gain modes of the receiver, revealing persistent L-band noise hotspots along the Equator that can reach up to 2.5 dB, most likely associated with surface reflection of signals from other GNSS transmitters and constellations. Sporadic high-power noise events observed in certain regions point to sources of human origin. Relevant conclusions of this study are that platform attitude knowledge is essential and that radiometric calibration of GNSS-R signals should be used whenever possible. Care should be taken when considering using noise measurements over the equatorial oceans for calibration purposes, as ambient noise and correlated noise in delay–Doppler maps both show more variation than might be expected over these regions.
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Accepted/In Press date: 26 January 2017
e-pub ahead of print date: 31 May 2017
Published date: 1 July 2017
Organisations:
National Oceanography Centre, Marine Physics and Ocean Climate
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Local EPrints ID: 411094
URI: http://eprints.soton.ac.uk/id/eprint/411094
ISSN: 1939-1404
PURE UUID: 4366cc7b-0f56-4b1f-81e8-367ff0a893ba
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Date deposited: 14 Jun 2017 16:31
Last modified: 15 Mar 2024 14:33
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Author:
Giuseppe Foti
Author:
Christine Gommenginger
Author:
Martin Unwin
Author:
Philip Jales
Author:
Jason Tye
Author:
Josep Rosello
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