Introducing POMME Potsdam Magnetic Model of the Earth Star camera calibration Ring current field...
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Introducing POMME Potsdam Magnetic Model of the Earth • Star camera calibration • Ring current field • Static and annually varying external fields • Internal field Stefan Maus smaus@gfz- potsdam.de Stefan Maus, George Balasis, Hermann Lühr and Martin Rother, GFZ Mioara Mandea, IPGP
Transcript of Introducing POMME Potsdam Magnetic Model of the Earth Star camera calibration Ring current field...
Introducing POMME Potsdam Magnetic Model of the Earth
• Star camera calibration• Ring current field• Static and annually varying external fields• Internal field
Stefan [email protected]
Stefan Maus, George Balasis,
Hermann Lühr and Martin Rother, GFZ
Mioara Mandea, IPGP
POMME main field model
Internal field:
• Gauss coefficients gnm
to degree 15 tgn
m to degree 15
ttgnm to degree 10
External field:• Dst dependent external
dipole aligned with internal field dipole
• Gauss coefficients knm to
degree 2 in Geocentric Solar Magnetic (GSM) coordinatesStar camera angle:
• corrections for 6 time intervals
Oersted data before/after median filter
Residuals against initial field model
Calibration for the angle between the star sensor and the vector magnetometer
Fluxgate vector magnetometer
Starsensor
Z residuals against Pomme 1.4
Dst dependence of earlier field models
Dst dependence of Pomme
Dst versus induced RC field of Pomme
Magneto-sphere
A constant external field in GSM: Annual variation seen by an Earth fixed observer at
0 degree longitude, 30 degree latitude
A constant external field in GSM: Comparison with CO2’s external field
(observer at 0 degree longitude, 30 degree latitude)
Main field model power spectrum
Model with 3rd time derivative
Conclusions
Stefan [email protected]
Data errors: Important to take instrument errors, star camera mis-alignment and F-Region currents into account
New features in POMME: • Includes co-estimated star camera angles for CHAMP• Imposed realistic Dst dependence of RC field• Describes magnetospheric fields in GSM coordinates• Includes secular acceleration
See: www.gfz-potsdam.de/pb2/pb23/SatMag/model.html
Examples of Instrument Problems
Examples of genuine magnetic disturbances
Diamagnetic effect at 20:00 local time
Night sideF region currents
E - Region
B
Regions of enhanced plasma density
E - Region
B
Regions of enhanced plasma density
E - Region
B
Regions of enhanced plasma density
CHAMP electron density, 23-23 Oct 2001, 20 LT
Diamagnetic effect at 20:00 local time
Satellites POGO (1967-1971)
MAGSAT (1979-1980)– 350 – 650 km altitude– mission duration: 6 months
Oersted (since 1999)SAC-C (since 2001)
– 600 – 800 km altitude
CHAMP (since 2000) – 450 km altitude, decending– 5 year mission
