The following normative
documents contain provisions which, through reference in this text, constitute
provisions of this ECSS
Standard. For dated references, subsequent amendments
to, or revision of any of these publications do not apply, However, parties to
agreements based on this ECSS Standard are encouraged to investigate the possibility
of applying the more recent editions of the normative documents indicated below.
For undated references, the latest edition of the publication referred to
applies.
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ECSS-S-ST-00-01
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ECSS system – Glossary of terms
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[RN.1]
C. Förste, F. Flechtner, R.
Schmidt, R. König, U. Meyer, R. Stubenvoll, M. Rothacher, F. Barthelmes, H.
Neumayer, R. Biancale, S. Bruinsma, J.-M. Lemoine, and S. Loyer, A Mean Global
Gravity Field Model from the Combination of Satellite Mission and
Altimetry/Gravimetry Surface Data – EIGEN-GL04C, Geophysical Research
Abstracts, Vol.8, 03462, 2006
[RN.2]
D.D. McCarthy and Gerard Petit
(editors), IERS Conventions (2003), IERS Technical Note 32, Verlag des
Bundesamtes für Kartographie und Geodäsie, Frankfurt am Main, 2004
[RN.3]
E.M. Standish, JPL Planetary
and Lunar Ephemerides DE405/LE405, JPL Inter-Office Memorandum IOM 312F-98-048,
Aug.25, 1998
[RN.4]
Picone, J. M., A. E. Hedin, D.
P. Drob and Aikin, A. C., “NRLMSISE-00 Empirical Model of the Atmosphere:
Statistical Comparisons and Scientific Issues”, J. Geophys. Res., 107(A12), doi
10.1029/2002JA009430. 2002, p. 1468.
[RN.5]
Bowman, B. R., Tobiska, W. K.,
Marcos, F. A., Valladares, “The JB2006 Empirical Thermospheric Density Model”,
Journal of Atmospheric and Solar-Terrestrial Physics, Vol. 70, Issue 5, pp.
774-793, 2008, doi:10.1016/j.jastp.2007.10.002.
[RN.6]
Hedin, A.E., E.L. Fleming, A.H.
Manson, F.J. Scmidlin, S.K. Avery, R.R. Clark, S.J. Franke, G.J. Fraser, T.
Tsunda, F. Vial and R.A. Vincent, Empirical Wind Model for the Upper, Middle,
and Lower Atmosphere, J. Atmos. Terr. Phys., 58, 1421-1447, 1996.
[RN.7]
Lewis S. R., Collins M., Read
P.L., Forget F., Hourdin F., Fournier R., Hourdin C., Talagrand O., Huot,
J.-P.,, “A Climate Database for Mars”, J. Geophys. Res. Vol. 104, No. E10, p.
24,177-24,194, 1999.
[RN.8]
Gallagher D.L., P.D. Craven,
and R.H. Comfort. Global Core Plasma model. J. Geophys. Res., 105, A8,
18819-18833, 2000.
[RN.9]
Bilitza, D. and B. Reinisch,
International Reference Ionosphere 2007: Improvements and New Parameters,
Advances in Space Research,, 42, Issue 4, pp. 599-609, 2008.
[RN.10]
Vette J.I., “The AE-8 Trapped
Electron Model Environment”, NSSDC/WDC-A-R&S Report 91-24, NASA-GSFC, 1991.
[RN.11]
Sawyer D.M. and J.I. Vette,
“AP8 Trapped Proton Environment For Solar Maximum and Solar Minimum”, NSSDC
WDC-A-R&S 76-06, NASA-GSFC, 1976.
[RN.12]
A Sicard-Piet, S. A.Bourdarie,
D. M. Boscher, R. H. W. Friedel, M. Thomsen, T. Goka, H.Matsumoto, H.
Koshiishi, “A new international geostationary electron model: IGE-2006, from 1
keV to 5.2 MeV”, Space Weather, 6, S07003, doi:10.1029/2007SW000368, 2008.
[RN.13]
Sicard-Piet A., S. Bourdarie, D.
Boscher, R. Friedel, T. Cayton, Solar Cycle Electron Radiation Environement at
GNSS Like Altitude, session D5.5-04, Proceedings 57th International
Astronautical Congress, Valencia, Sept 2006
[RN.14]
Rodgers D.J, Hunter K.A and
Wrenn G.L, The Flumic Electron Environment Model, Proceedings 8th Spacecraft
Charging Technology Conference, Huntsville Alabama, 2003
[RN.15]
Xapsos, M. A., G.P. Summers,
J.L. Barth, E. G. Stassinopoulos and E.A. Burke, “Probability Model for
Cumulative Solar Proton Event Fluences”, IEEE Trans. Nucl. Sci., vol. 47, no.
3, June 2000, pp 486-490
[RN.16]
Lario et al., Radial and
Longitudinal Dependence of solar 4-13 MeV and 27-37 MeV Proton Peak Intensities
and Fluences: HELIOS and IMP8 Observations, Astrophys Journal, 653:1531-1544,
Dec 20, 2006.
[RN.17]
Bourdarie, S., A. Sicard-Piet,
“Jupiter environment modelling”, ONERA Technical note 120 Issue 1.2, ESA
contract 19735/NL/HB, FR 1/11189 DESP, October 2006
[RN.18]
CREME96:
https://creme96.nrl.navy.mil/
[RN.19]
ISO Model 15390
[RN.20]
Adams J.H., R. Silberberg and
C.H. Tsao, “Cosmic Ray Effects on Microelectronics, Part I: The NearEarth
Particle Environment”, NRL Memorandum Report 4506, Naval Research Laboratory, Washington DC20375-5000,
USA, 1981.
[RN.21]
Desorgher, L., MAGNETOCOSMICS
User Manual 2003, http://reat.space.qinetiq.com/septimess/magcos/
[RN.22]
Smart, D. F., Shea, M.A.,
Calculated cosmic ray cut-off rigidities at 450 km for epoch 1990, Proc. 25th
ICRC, 2, 397-400, 1997.
[RN.23]
Stassinopoulos E.G. and J.H.
King, “Empirical Solar Proton Model For Orbiting Spacecraft Applications”, IEEE
Trans. on Aerosp. and Elect. Systems AES-10, 442, 1973
[RN.24]
D. C. Jensen and J. C. Cain, An
Interim Geomagnetic Field, J. Geophys.Res. 67, 3568, 1962.
[RN.25]
J. C. Cain, S. J. Hendricks, R.
A. Langel, and W. V. Hudson, A Proposed Model for the International Geomagnetic
Reference Field, 1965, J. Geomag. Geoelectr. 19, 335, 1967.
[RN.26]
MASTER-2005 CD, Release 1.0,
April 2006
[RN.27]
NOAA/SEC source of dates for
solar maxima and minima:
ftp://ftp.ngdc.noaa.gov/STP/SOLAR_DATA/SUNSPOT_NUMBERS/maxmin.new
[RN.28]
Roberts C.S., “Coordinates for
the Study of Particles Trapped in the Earth’s Magnetic Field: A Method of
Converting from B,L to R,λ Coordinates”, J. Geophys. Res. 69, 5 089,
1964.
[RN.29]
IGRF-10, the list of
coefficients is given at the IGRF web page on the IAGA web site: http://www.ngdc.noaa.gov/IAGA/vmod/igrf.html
[RN.30]
Alexeev I.I., Kalegaev V.V.,
Belenkaya E.S., Bobrovnikov S.Yu., Feldstein Ya.I., Gromova L.I. (2001), J.
Geophys. Res., V.106, No A11, P. 25,683-25,694
[RN.31]
Tsyganenko, N.A., and D.P.
Stern, Modeling the global magnetic field of the large-scale Birkeland current
sustems, J. Geophys. Res., V. 101, 27187-27198, 1996.