GOCE gravitational gradients along the orbit

Carl Christian Tscherning; M. Veicherts; J. Bouman; S. Fiorot; M. Fuchs; T. Gruber; E. Schrama; P. Visser

doi:10.1007/s00190-011-0464-0

GOCE gravitational gradients along the orbit

Carl Christian Tscherning, M. Veicherts, J. Bouman, S. Fiorot, M. Fuchs, T. Gruber, E. Schrama, P. Visser

63 Citationer (Scopus)

Abstract

GOCE is ESA's gravity field mission and the first satellite ever that measures gravitational gradients in space, that is, the second spatial derivatives of the Earth's gravitational potential. The goal is to determine the Earth's mean gravitational field with unprecedented accuracy at spatial resolutions down to 100 km. GOCE carries a gravity gradiometer that allows deriving the gravitational gradients with very high precision to achieve this goal. There are two types of GOCE Level 2 gravitational gradients (GGs) along the orbit: the gravitational gradients in the gradiometer reference frame (GRF) and the gravitational gradients in the local north oriented frame (LNOF) derived from the GGs in the GRF by point-wise rotation. Because the V_XX, V_YY, V_ZZ and V_XZ are much more accurate than V_XY and V_YZ, and because the error of the accurate GGs increases for low frequencies, the rotation requires that part of the measured GG signal is replaced by model signal. However, the actual quality of the gradients in GRF and LNOF needs to be assessed. We analysed the outliers in the GGs, validated the GGs in the GRF using independent gravity field information and compared their assessed error with the requirements. In addition, we compared the GGs in the LNOF with state-of-the-art global gravity field models and determined the model contribution to the rotated GGs. We found that the percentage of detected outliers is below 0. 1% for all GGs, and external gravity data confirm that the GG scale factors do not differ from one down to the 10^-3 level. Furthermore, we found that the error of V_XX and V_YY is approximately at the level of the requirement on the gravitational gradient trace, whereas the V_ZZ error is a factor of 2-3 above the requirement for higher frequencies. We show that the model contribution in the rotated GGs is 2-35% dependent on the gravitational gradient. Finally, we found that GOCE gravitational gradients and gradients derived from EIGEN-5C and EGM2008 are consistent over the oceans, but that over the continents the consistency may be less, especially in areas with poor terrestrial gravity data. All in all, our analyses show that the quality of the GOCE gravitational gradients is good and that with this type of data valuable new gravity field information is obtained.

Originalsprog	Engelsk
Tidsskrift	Journal of Geodesy
Vol/bind	85
Udgave nummer	11
Sider (fra-til)	791-805
ISSN	0949-7714
DOI	https://doi.org/10.1007/s00190-011-0464-0
Status	Udgivet - nov. 2011

Emneord

Det Natur- og Biovidenskabelige Fakultet
Gelatin

Adgang til dokumentet

10.1007/s00190-011-0464-0

Citationsformater

@article{4179798dae9f4cad8bf6a7c5c26b8705,

title = "GOCE gravitational gradients along the orbit",

abstract = "GOCE is ESA's gravity field mission and the first satellite ever that measures gravitational gradients in space, that is, the second spatial derivatives of the Earth's gravitational potential. The goal is to determine the Earth's mean gravitational field with unprecedented accuracy at spatial resolutions down to 100 km. GOCE carries a gravity gradiometer that allows deriving the gravitational gradients with very high precision to achieve this goal. There are two types of GOCE Level 2 gravitational gradients (GGs) along the orbit: the gravitational gradients in the gradiometer reference frame (GRF) and the gravitational gradients in the local north oriented frame (LNOF) derived from the GGs in the GRF by point-wise rotation. Because the VXX, VYY, VZZ and VXZ are much more accurate than VXY and VYZ, and because the error of the accurate GGs increases for low frequencies, the rotation requires that part of the measured GG signal is replaced by model signal. However, the actual quality of the gradients in GRF and LNOF needs to be assessed. We analysed the outliers in the GGs, validated the GGs in the GRF using independent gravity field information and compared their assessed error with the requirements. In addition, we compared the GGs in the LNOF with state-of-the-art global gravity field models and determined the model contribution to the rotated GGs. We found that the percentage of detected outliers is below 0. 1% for all GGs, and external gravity data confirm that the GG scale factors do not differ from one down to the 10-3 level. Furthermore, we found that the error of VXX and VYY is approximately at the level of the requirement on the gravitational gradient trace, whereas the VZZ error is a factor of 2-3 above the requirement for higher frequencies. We show that the model contribution in the rotated GGs is 2-35% dependent on the gravitational gradient. Finally, we found that GOCE gravitational gradients and gradients derived from EIGEN-5C and EGM2008 are consistent over the oceans, but that over the continents the consistency may be less, especially in areas with poor terrestrial gravity data. All in all, our analyses show that the quality of the GOCE gravitational gradients is good and that with this type of data valuable new gravity field information is obtained.",

keywords = "Faculty of Science, Gelatin",

author = "Tscherning, {Carl Christian} and M. Veicherts and J. Bouman and S. Fiorot and M. Fuchs and T. Gruber and E. Schrama and P. Visser",

year = "2011",

month = nov,

doi = "10.1007/s00190-011-0464-0",

language = "English",

volume = "85",

pages = "791--805",

journal = "Journal of Geodesy",

issn = "0949-7714",

publisher = "Springer",

number = "11",

}

TY - JOUR

T1 - GOCE gravitational gradients along the orbit

AU - Tscherning, Carl Christian

AU - Veicherts, M.

AU - Bouman, J.

AU - Fiorot, S.

AU - Fuchs, M.

AU - Gruber, T.

AU - Schrama, E.

AU - Visser, P.

PY - 2011/11

Y1 - 2011/11

N2 - GOCE is ESA's gravity field mission and the first satellite ever that measures gravitational gradients in space, that is, the second spatial derivatives of the Earth's gravitational potential. The goal is to determine the Earth's mean gravitational field with unprecedented accuracy at spatial resolutions down to 100 km. GOCE carries a gravity gradiometer that allows deriving the gravitational gradients with very high precision to achieve this goal. There are two types of GOCE Level 2 gravitational gradients (GGs) along the orbit: the gravitational gradients in the gradiometer reference frame (GRF) and the gravitational gradients in the local north oriented frame (LNOF) derived from the GGs in the GRF by point-wise rotation. Because the VXX, VYY, VZZ and VXZ are much more accurate than VXY and VYZ, and because the error of the accurate GGs increases for low frequencies, the rotation requires that part of the measured GG signal is replaced by model signal. However, the actual quality of the gradients in GRF and LNOF needs to be assessed. We analysed the outliers in the GGs, validated the GGs in the GRF using independent gravity field information and compared their assessed error with the requirements. In addition, we compared the GGs in the LNOF with state-of-the-art global gravity field models and determined the model contribution to the rotated GGs. We found that the percentage of detected outliers is below 0. 1% for all GGs, and external gravity data confirm that the GG scale factors do not differ from one down to the 10-3 level. Furthermore, we found that the error of VXX and VYY is approximately at the level of the requirement on the gravitational gradient trace, whereas the VZZ error is a factor of 2-3 above the requirement for higher frequencies. We show that the model contribution in the rotated GGs is 2-35% dependent on the gravitational gradient. Finally, we found that GOCE gravitational gradients and gradients derived from EIGEN-5C and EGM2008 are consistent over the oceans, but that over the continents the consistency may be less, especially in areas with poor terrestrial gravity data. All in all, our analyses show that the quality of the GOCE gravitational gradients is good and that with this type of data valuable new gravity field information is obtained.

AB - GOCE is ESA's gravity field mission and the first satellite ever that measures gravitational gradients in space, that is, the second spatial derivatives of the Earth's gravitational potential. The goal is to determine the Earth's mean gravitational field with unprecedented accuracy at spatial resolutions down to 100 km. GOCE carries a gravity gradiometer that allows deriving the gravitational gradients with very high precision to achieve this goal. There are two types of GOCE Level 2 gravitational gradients (GGs) along the orbit: the gravitational gradients in the gradiometer reference frame (GRF) and the gravitational gradients in the local north oriented frame (LNOF) derived from the GGs in the GRF by point-wise rotation. Because the VXX, VYY, VZZ and VXZ are much more accurate than VXY and VYZ, and because the error of the accurate GGs increases for low frequencies, the rotation requires that part of the measured GG signal is replaced by model signal. However, the actual quality of the gradients in GRF and LNOF needs to be assessed. We analysed the outliers in the GGs, validated the GGs in the GRF using independent gravity field information and compared their assessed error with the requirements. In addition, we compared the GGs in the LNOF with state-of-the-art global gravity field models and determined the model contribution to the rotated GGs. We found that the percentage of detected outliers is below 0. 1% for all GGs, and external gravity data confirm that the GG scale factors do not differ from one down to the 10-3 level. Furthermore, we found that the error of VXX and VYY is approximately at the level of the requirement on the gravitational gradient trace, whereas the VZZ error is a factor of 2-3 above the requirement for higher frequencies. We show that the model contribution in the rotated GGs is 2-35% dependent on the gravitational gradient. Finally, we found that GOCE gravitational gradients and gradients derived from EIGEN-5C and EGM2008 are consistent over the oceans, but that over the continents the consistency may be less, especially in areas with poor terrestrial gravity data. All in all, our analyses show that the quality of the GOCE gravitational gradients is good and that with this type of data valuable new gravity field information is obtained.

KW - Faculty of Science

KW - Gelatin

U2 - 10.1007/s00190-011-0464-0

DO - 10.1007/s00190-011-0464-0

M3 - Journal article

SN - 0949-7714

VL - 85

SP - 791

EP - 805

JO - Journal of Geodesy

JF - Journal of Geodesy

IS - 11

ER -

GOCE gravitational gradients along the orbit

Abstract

Emneord

Adgang til dokumentet

Fingeraftryk

Citationsformater