COSMIC: Geodetic applications in improving earth's gravity model

Benjamin F. Chao; Erricos C. Pavlis; Chein-way Hwang; Chi Ching Liu; C. K. Shum; Ching Liang Tseng; Ming Yang

doi:10.3319/TAO.2000.11.1.365(COSMIC)

COSMIC: Geodetic applications in improving earth's gravity model

Benjamin F. Chao^*, Erricos C. Pavlis, Chein-way Hwang, Chi Ching Liu, C. K. Shum, Ching Liang Tseng, Ming Yang

^*Corresponding author for this work

Department of Civil Engineering

Research output: Contribution to journal › Article › peer-review

2 Scopus citations

Abstract

The routine GPS tracking data that will be collected for the precise orbit determination of the eight COSMIC spacecraft will contain valuable information about the terrestrial gravity field. Numerical simulations based on current straw-man mission scenarios have shown: (1) For the static model of the gravity field, significant improvement is possible over our present knowledge embodied in the EGM96 model, out to harmonic degree as high as 40. (2) With respect to time-varying gravitational signals, large-scale mass transport processes in the geophysical fluids (e.g., atmosphere and oceans) can be detected or monitored during the mission, providing important global change information. Further sophisticated simulations incorporating more realistic force models will be needed once COSMIC mission scenario and spacecraft design are completely defined.

Original language	English
Pages (from-to)	365-378
Number of pages	14
Journal	Terrestrial, Atmospheric and Oceanic Sciences
Volume	11
Issue number	1
DOIs	https://doi.org/10.3319/TAO.2000.11.1.365(COSMIC)
State	Published - 1 Jan 2000

Keywords

Gravity field
Gravity model
Orbit determination
Satellite tracking

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title = "COSMIC: Geodetic applications in improving earth's gravity model",

abstract = "The routine GPS tracking data that will be collected for the precise orbit determination of the eight COSMIC spacecraft will contain valuable information about the terrestrial gravity field. Numerical simulations based on current straw-man mission scenarios have shown: (1) For the static model of the gravity field, significant improvement is possible over our present knowledge embodied in the EGM96 model, out to harmonic degree as high as 40. (2) With respect to time-varying gravitational signals, large-scale mass transport processes in the geophysical fluids (e.g., atmosphere and oceans) can be detected or monitored during the mission, providing important global change information. Further sophisticated simulations incorporating more realistic force models will be needed once COSMIC mission scenario and spacecraft design are completely defined.",

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T2 - Geodetic applications in improving earth's gravity model

AU - Chao, Benjamin F.

AU - Pavlis, Erricos C.

AU - Hwang, Chein-way

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AU - Shum, C. K.

AU - Tseng, Ching Liang

AU - Yang, Ming

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N2 - The routine GPS tracking data that will be collected for the precise orbit determination of the eight COSMIC spacecraft will contain valuable information about the terrestrial gravity field. Numerical simulations based on current straw-man mission scenarios have shown: (1) For the static model of the gravity field, significant improvement is possible over our present knowledge embodied in the EGM96 model, out to harmonic degree as high as 40. (2) With respect to time-varying gravitational signals, large-scale mass transport processes in the geophysical fluids (e.g., atmosphere and oceans) can be detected or monitored during the mission, providing important global change information. Further sophisticated simulations incorporating more realistic force models will be needed once COSMIC mission scenario and spacecraft design are completely defined.

AB - The routine GPS tracking data that will be collected for the precise orbit determination of the eight COSMIC spacecraft will contain valuable information about the terrestrial gravity field. Numerical simulations based on current straw-man mission scenarios have shown: (1) For the static model of the gravity field, significant improvement is possible over our present knowledge embodied in the EGM96 model, out to harmonic degree as high as 40. (2) With respect to time-varying gravitational signals, large-scale mass transport processes in the geophysical fluids (e.g., atmosphere and oceans) can be detected or monitored during the mission, providing important global change information. Further sophisticated simulations incorporating more realistic force models will be needed once COSMIC mission scenario and spacecraft design are completely defined.

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COSMIC: Geodetic applications in improving earth's gravity model

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