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GOCE long-wavelength gravity field recovery from 1s-sampled kinematic orbits using the acceleration approach

Publikation: Beitrag in Buch/Bericht/Sammelwerk/KonferenzbandAufsatz in KonferenzbandForschungPeer-Review

Autorschaft

  • T. Reubelt
  • O. Baur
  • M. Weigelt
  • M. Roth

Externe Organisationen

  • Universität Stuttgart
  • Austrian Academy of Sciences
  • University of Luxembourg
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Details

OriginalspracheEnglisch
Titel des SammelwerksGravity, Geoid and Height Systems - IAG Symposium GGHS2012, Proceedings
Herausgeber/-innenUrs Marti, Pascal Willis, Chris Rizos
Herausgeber (Verlag)Springer Verlag
Seiten21-26
Seitenumfang6
ISBN (elektronisch)9783319108360
PublikationsstatusVeröffentlicht - 2014
Extern publiziertJa
VeranstaltungInternational Association of Geodesy Symposium on Gravity, Geoid and Height Systems, GGHS 2012 - Venice, Italien
Dauer: 9 Okt. 201212 Okt. 2012

Publikationsreihe

NameInternational Association of Geodesy Symposia
Band141
ISSN (Print)0939-9585

Abstract

The acceleration approach is an efficient and accurate tool for the estimation of the lowfrequency part of GOCE (Gravity field and steady-state Ocean Circulation Explorer) gravity fields from GPS-based satellite-to-satellite tracking (SST). This approach is characterized by second-order numerical differentiation of the kinematic orbit. However, the application to GOCE-SST data, given with a 1s-sampling, showed that serious problems arise due to strong amplification of high frequency noise. In order to mitigate this problem, we developed a tailored processing strategy in a recent paper which makes use of an extended differentiation scheme acting as low-pass filter, and empirical covariance functions to account for the different precision of the components and the inter-epoch correlations caused by orbit computation and numerical differentiation. However, also a more “bruteforce” strategy can be applied using the standard unextended differentiation scheme and data-weighting by error propagation of the provided orbit variance-covariance matrices (VCMs). It is shown that the direct differentiator shows a better approximation and the exploitedmethod benefits from the stochastic information contained in the VCMs compared to the former strategy. A strong dependence on the maximum resolution, the arc-length and the method for data-weighting is observed, which requires careful selection of these parameters. By comparison with alternative GOCE hl-SST solutions we conclude that the acceleration approach is a competitive method for gravity field recovery from kinematic orbit information.

ASJC Scopus Sachgebiete

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GOCE long-wavelength gravity field recovery from 1s-sampled kinematic orbits using the acceleration approach. / Reubelt, T.; Baur, O.; Weigelt, M. et al.
Gravity, Geoid and Height Systems - IAG Symposium GGHS2012, Proceedings. Hrsg. / Urs Marti; Pascal Willis; Chris Rizos. Springer Verlag, 2014. S. 21-26 (International Association of Geodesy Symposia; Band 141).

Publikation: Beitrag in Buch/Bericht/Sammelwerk/KonferenzbandAufsatz in KonferenzbandForschungPeer-Review

Reubelt, T, Baur, O, Weigelt, M, Roth, M & Sneeuw, N 2014, GOCE long-wavelength gravity field recovery from 1s-sampled kinematic orbits using the acceleration approach. in U Marti, P Willis & C Rizos (Hrsg.), Gravity, Geoid and Height Systems - IAG Symposium GGHS2012, Proceedings. International Association of Geodesy Symposia, Bd. 141, Springer Verlag, S. 21-26, International Association of Geodesy Symposium on Gravity, Geoid and Height Systems, GGHS 2012, Venice, Italien, 9 Okt. 2012. https://doi.org/10.1007/978-3-319-10837-7_3
Reubelt, T., Baur, O., Weigelt, M., Roth, M., & Sneeuw, N. (2014). GOCE long-wavelength gravity field recovery from 1s-sampled kinematic orbits using the acceleration approach. In U. Marti, P. Willis, & C. Rizos (Hrsg.), Gravity, Geoid and Height Systems - IAG Symposium GGHS2012, Proceedings (S. 21-26). (International Association of Geodesy Symposia; Band 141). Springer Verlag. https://doi.org/10.1007/978-3-319-10837-7_3
Reubelt T, Baur O, Weigelt M, Roth M, Sneeuw N. GOCE long-wavelength gravity field recovery from 1s-sampled kinematic orbits using the acceleration approach. in Marti U, Willis P, Rizos C, Hrsg., Gravity, Geoid and Height Systems - IAG Symposium GGHS2012, Proceedings. Springer Verlag. 2014. S. 21-26. (International Association of Geodesy Symposia). doi: 10.1007/978-3-319-10837-7_3
Reubelt, T. ; Baur, O. ; Weigelt, M. et al. / GOCE long-wavelength gravity field recovery from 1s-sampled kinematic orbits using the acceleration approach. Gravity, Geoid and Height Systems - IAG Symposium GGHS2012, Proceedings. Hrsg. / Urs Marti ; Pascal Willis ; Chris Rizos. Springer Verlag, 2014. S. 21-26 (International Association of Geodesy Symposia).
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title = "GOCE long-wavelength gravity field recovery from 1s-sampled kinematic orbits using the acceleration approach",
abstract = "The acceleration approach is an efficient and accurate tool for the estimation of the lowfrequency part of GOCE (Gravity field and steady-state Ocean Circulation Explorer) gravity fields from GPS-based satellite-to-satellite tracking (SST). This approach is characterized by second-order numerical differentiation of the kinematic orbit. However, the application to GOCE-SST data, given with a 1s-sampling, showed that serious problems arise due to strong amplification of high frequency noise. In order to mitigate this problem, we developed a tailored processing strategy in a recent paper which makes use of an extended differentiation scheme acting as low-pass filter, and empirical covariance functions to account for the different precision of the components and the inter-epoch correlations caused by orbit computation and numerical differentiation. However, also a more “bruteforce” strategy can be applied using the standard unextended differentiation scheme and data-weighting by error propagation of the provided orbit variance-covariance matrices (VCMs). It is shown that the direct differentiator shows a better approximation and the exploitedmethod benefits from the stochastic information contained in the VCMs compared to the former strategy. A strong dependence on the maximum resolution, the arc-length and the method for data-weighting is observed, which requires careful selection of these parameters. By comparison with alternative GOCE hl-SST solutions we conclude that the acceleration approach is a competitive method for gravity field recovery from kinematic orbit information.",
keywords = "Data weighting, GOCE, Gravity field, Kinematic orbits, Orbit variances, Satellite-to-satellite tracking",
author = "T. Reubelt and O. Baur and M. Weigelt and M. Roth and N. Sneeuw",
note = "Publisher Copyright: {\textcopyright} Springer International Publishing Switzerland 2014.; International Association of Geodesy Symposium on Gravity, Geoid and Height Systems, GGHS 2012 ; Conference date: 09-10-2012 Through 12-10-2012",
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editor = "Urs Marti and Pascal Willis and Chris Rizos",
booktitle = "Gravity, Geoid and Height Systems - IAG Symposium GGHS2012, Proceedings",
address = "Germany",

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Download

TY - GEN

T1 - GOCE long-wavelength gravity field recovery from 1s-sampled kinematic orbits using the acceleration approach

AU - Reubelt, T.

AU - Baur, O.

AU - Weigelt, M.

AU - Roth, M.

AU - Sneeuw, N.

N1 - Publisher Copyright: © Springer International Publishing Switzerland 2014.

PY - 2014

Y1 - 2014

N2 - The acceleration approach is an efficient and accurate tool for the estimation of the lowfrequency part of GOCE (Gravity field and steady-state Ocean Circulation Explorer) gravity fields from GPS-based satellite-to-satellite tracking (SST). This approach is characterized by second-order numerical differentiation of the kinematic orbit. However, the application to GOCE-SST data, given with a 1s-sampling, showed that serious problems arise due to strong amplification of high frequency noise. In order to mitigate this problem, we developed a tailored processing strategy in a recent paper which makes use of an extended differentiation scheme acting as low-pass filter, and empirical covariance functions to account for the different precision of the components and the inter-epoch correlations caused by orbit computation and numerical differentiation. However, also a more “bruteforce” strategy can be applied using the standard unextended differentiation scheme and data-weighting by error propagation of the provided orbit variance-covariance matrices (VCMs). It is shown that the direct differentiator shows a better approximation and the exploitedmethod benefits from the stochastic information contained in the VCMs compared to the former strategy. A strong dependence on the maximum resolution, the arc-length and the method for data-weighting is observed, which requires careful selection of these parameters. By comparison with alternative GOCE hl-SST solutions we conclude that the acceleration approach is a competitive method for gravity field recovery from kinematic orbit information.

AB - The acceleration approach is an efficient and accurate tool for the estimation of the lowfrequency part of GOCE (Gravity field and steady-state Ocean Circulation Explorer) gravity fields from GPS-based satellite-to-satellite tracking (SST). This approach is characterized by second-order numerical differentiation of the kinematic orbit. However, the application to GOCE-SST data, given with a 1s-sampling, showed that serious problems arise due to strong amplification of high frequency noise. In order to mitigate this problem, we developed a tailored processing strategy in a recent paper which makes use of an extended differentiation scheme acting as low-pass filter, and empirical covariance functions to account for the different precision of the components and the inter-epoch correlations caused by orbit computation and numerical differentiation. However, also a more “bruteforce” strategy can be applied using the standard unextended differentiation scheme and data-weighting by error propagation of the provided orbit variance-covariance matrices (VCMs). It is shown that the direct differentiator shows a better approximation and the exploitedmethod benefits from the stochastic information contained in the VCMs compared to the former strategy. A strong dependence on the maximum resolution, the arc-length and the method for data-weighting is observed, which requires careful selection of these parameters. By comparison with alternative GOCE hl-SST solutions we conclude that the acceleration approach is a competitive method for gravity field recovery from kinematic orbit information.

KW - Data weighting

KW - GOCE

KW - Gravity field

KW - Kinematic orbits

KW - Orbit variances

KW - Satellite-to-satellite tracking

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BT - Gravity, Geoid and Height Systems - IAG Symposium GGHS2012, Proceedings

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A2 - Willis, Pascal

A2 - Rizos, Chris

PB - Springer Verlag

T2 - International Association of Geodesy Symposium on Gravity, Geoid and Height Systems, GGHS 2012

Y2 - 9 October 2012 through 12 October 2012

ER -

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