15.

Michel C.

Satellite orbits and missions. France: Springer-Verlag, 2005. 544 p.

16.

Sandip T.A.

,

Shashikala A.G.

Simplified orbit determination algorithm for low earth

orbit satellite using space borne GPS navigation sensor // Artificial Satellite. 2014.

Vol. 49. No. 2. P. 81–99.

17.

Kelso T.S.

Orbital coordinate systems. Part III // Satellite Times. 1996. Vol. 2. No. 3.

P. 78–79.

18.

Токарева О.С.

Обработка и интерпретация данных дистанционного зондирова-

ния Земли. Томск: Изд-во ТПУ, 2010. 148 с.

19.

Anil K.M.

,

Varsha A.

Satellite technology, principles and applications. Manhattan:

John Wiley & Sons, 2011. 694 p.

20.

Fortescue P.

,

Swinerd G.

,

Stark J.

Spacecraft system engineering. Manhattan: John

Wiley & Sons, 2011. 752 p.

21.

Пантелеев В.Л.

Теория фигуры Земли. Курс лекций. М., 2000. URL:

http://www.astronet.ru/db/msg/1169819/node1.html

(дата обращения: 05.03.2015).

22.

Hedgley

D.R.Jr

.

An exact transformation from geocentric to geodetic coordinates for

nonzero altitudes. NASA TR R-458, March, 1976.

23.

Gerhard B.

Methods of celestial mechanics. Vol. II. Application to planetary systems,

geodynamics and satellite geodesy. Berlin, Heidelberg: Springer-Verlag, 2005. 448 p.

24.

Brian D.H.

,

Daniel T.V.

Essential MATLAB for engineers and scientists. Elsevier

Ltd, 2007. 428 p.

25.

Охоцимский Д.Е.

,

Сихарулидзе Ю.Г.

Основы механики космического полета. М.:

Наука, 1990. 445 с.

26.

Белецкий В.В.

Очерки о движении космических тел. М.: Книжный дом

“ЛИБРОКОМ”, 2013. 432 с.

REFERENCES

[1] Zarubin V.S. Temperaturnye polya v konstruktsii letatel’nykh apparatov [The

Temperature Fields in the Structure of an Aircraft]. Moscow, Mashinostroenie Publ.,

1966. 216 p.

[2] Spacecraft thermal control handbook, еd. by D.G. Gilmor, vol. 1, El Segundo,

California, Aerospace Press, 2002. 836 p.

[3] Karam R.М. Satellite thermal control for system engineer. American Institute of

Aeronautics and Astronautics, 1998. 280 p.

[4] Bess T.D., Smith G.L

.

Atlas of wide field of view outgoing long wave radiation

derived from Nimbus 7.

Earth radiation budget data set

—

November 1978 to October

1985

. NASA Ref. Publ., no. 1186. Aug. 1987. 174 p.

[5] Smith G.L., Rutan D., Bess T.D. Atlas of albedo and absorbed solar radiation derived

from Nimbus 6.

Earth radiation budget data set

—

July 1975 to May 1978

. NASA

Ref. Publ., no. 1230. 1990. 120 p.

[6] Bess T.D., Smith G.L. Atlas of wide field of view outgoing long wave radiation

derived from Nimbus 7.

Earth radiation budget data set

—

November 1985 to October

1987

. NASA Ref. Publ., no. 1261. June 1991. 52 p.

[7] Smith G.L., Rutan D., Bess T.D. Atlas of albedo and absorbed solar radiation derived

from Nimbus 7.

Earth radiation budget data set

—

November 1985 to October 1987

.

NASA Ref. Publ., no. 1281. 1992. 58 p.

[8] Wiley J.L., James R.W. Space Mission Analysis and Design. California, Microcosm

Press, 2005. 504 p.

[9] Meyer Rudolf X. Elements of space technology for aerospace engineers. San Diego,

Academic Press, 1999. 329 p.

[10] Bate Roger R., Mueller Donald D., Jerry E. Fundamentals of astrodynamics. N.Y.,

Dover publications, 1971. 455 p.

112

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