Fading statistics and sensing accuracy of ocean scattered GNSS and altimetry signals
Fading statistics and sensing accuracy of ocean scattered GNSS and altimetry signals
This paper starts with a brief review of scattering statistics theory for diffusely scattered radar signals. Following, global navigation satellite systems reflected (GNSS-R) signals are used to demonstrate the results of non-coherent signal averaging on the mean and standard deviation of the signal power fluctuations. The retrieved signal fading statistics of GNSS-R signals detected in low Earth orbit have been analyzed as a function of consecutive uncorrelated measurements (or looks) and instrument antenna gain and compared to the theoretical description presented by Ulaby, Moore and Fung for a radar remote sensing configuration. The results of this analysis include empirically determined error distributions that provide a reference to asses the potential accuracy of GNSS-R model based retrieval methods, and to what extent increasing the instrument antenna gain will improve the retrieval accuracy. Additionally, in assessing the potential of using GNSS-R signals for ocean remote sensing, it is useful to compare the signal characteristics with those of existing radar altimeter instruments. With this in mind, a fitting accuracy and parameter retrieval analysis has been undertaken using observed fading noise from successful space based altimeters. The noise observed on real waveforms has been added to a simulated ideal waveform with the intent to study the accuracy of ocean observables using a Monte Carlo simulation. By adding observed noise to ideal model waveforms in this way, it is possible to quantitatively asses the fitting errors with respect to noise variance contained in the least-squares model fitting sensing technique. Finally, the key differences between the traditional approach and the GNSS-R approach are then analyzed with regard to identifying the critical adjustments required in using GNSS-R signals for ocean remote sensing.
208-220
Gleason, Scott
f451ce73-9d7f-4425-b475-f88d8d1a2430
Gommenginger, Christine
f0db32be-34bb-44da-944b-c6b206ca4143
Cromwell, David
0e781623-7ab3-4ee3-b56f-d493258a697a
15 July 2010
Gleason, Scott
f451ce73-9d7f-4425-b475-f88d8d1a2430
Gommenginger, Christine
f0db32be-34bb-44da-944b-c6b206ca4143
Cromwell, David
0e781623-7ab3-4ee3-b56f-d493258a697a
Gleason, Scott, Gommenginger, Christine and Cromwell, David
(2010)
Fading statistics and sensing accuracy of ocean scattered GNSS and altimetry signals.
Advances in Space Research, 46 (2), .
(doi:10.1016/j.asr.2010.03.023).
Abstract
This paper starts with a brief review of scattering statistics theory for diffusely scattered radar signals. Following, global navigation satellite systems reflected (GNSS-R) signals are used to demonstrate the results of non-coherent signal averaging on the mean and standard deviation of the signal power fluctuations. The retrieved signal fading statistics of GNSS-R signals detected in low Earth orbit have been analyzed as a function of consecutive uncorrelated measurements (or looks) and instrument antenna gain and compared to the theoretical description presented by Ulaby, Moore and Fung for a radar remote sensing configuration. The results of this analysis include empirically determined error distributions that provide a reference to asses the potential accuracy of GNSS-R model based retrieval methods, and to what extent increasing the instrument antenna gain will improve the retrieval accuracy. Additionally, in assessing the potential of using GNSS-R signals for ocean remote sensing, it is useful to compare the signal characteristics with those of existing radar altimeter instruments. With this in mind, a fitting accuracy and parameter retrieval analysis has been undertaken using observed fading noise from successful space based altimeters. The noise observed on real waveforms has been added to a simulated ideal waveform with the intent to study the accuracy of ocean observables using a Monte Carlo simulation. By adding observed noise to ideal model waveforms in this way, it is possible to quantitatively asses the fitting errors with respect to noise variance contained in the least-squares model fitting sensing technique. Finally, the key differences between the traditional approach and the GNSS-R approach are then analyzed with regard to identifying the critical adjustments required in using GNSS-R signals for ocean remote sensing.
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Published date: 15 July 2010
Organisations:
Marine Physics and Ocean Climate
Identifiers
Local EPrints ID: 162371
URI: http://eprints.soton.ac.uk/id/eprint/162371
ISSN: 0273-1177
PURE UUID: af23ce87-2175-4faa-ae7a-3904e280a4e1
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Date deposited: 19 Aug 2010 13:24
Last modified: 14 Mar 2024 02:02
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Author:
Scott Gleason
Author:
Christine Gommenginger
Author:
David Cromwell
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