satellite,
attitude motion,
systems of stabilization.
UDC:
629.7, 538.23
Subject:
Space flight mechanics, spacecraft attitude motion, satellites orientation systems.
Main publications:
Sarychev V. A., “Uproschenie skhemy sistemy gravitatsionnoi stabilizatsii sputnika”, Kosmicheskie issledovaniya, 2:1 (1964), 33–45
Sarychev V. A., “Usloviya ustoichivosti sistemy gravitatsionnoi stabilizatsii sputnikov s girodempfirovaniem”, Astronautica Acta, 14:4 (1969), 299–310
Sarychev V. A., Sazonov V. V., “Spin-stabilized satellites”, Journal of Astronautical Sciences, 24:4 (1976), 291–310
Sarychev V. A., “Equilibria of a double pendulum in a circular orbit”, Acta Astronautica, 44:1 (1999), 63–65
Sarychev V. A., Guerman A., Paglione P., “Stability of equilibria for a satellite subject to gravitational and constant torques”, Journal of Guidance, Control, and Dynamics, 31:2 (2008), 386–394
S. A. Gutnik, V. A. Sarychev, “Research into the dynamics of a system of two connected bodies moving in the plane of a circular orbit by applying computer algebra methods”, Zh. Vychisl. Mat. Mat. Fiz., 63:1 (2023), 145–153; Comput. Math. Math. Phys., 63:1 (2023), 106–114
2020
2.
S. A. Gutnik, V. A. Sarychev, “Mathematical simulation of satellite motion with an aerodynamic attitude control system influenced by active damping torques”, Zh. Vychisl. Mat. Mat. Fiz., 60:10 (2020), 1777–1786; Comput. Math. Math. Phys., 60:10 (2020), 1721–1729
S. A. Gutnik, V. A. Sarychev, “Application of computer algebra methods to investigation of stationary motions of a system of two connected bodies moving in a circular orbit”, Zh. Vychisl. Mat. Mat. Fiz., 60:1 (2020), 80–87; Comput. Math. Math. Phys., 60:1 (2020), 74–81
V. A. Sarychev, S. A. Gutnik, “Investigation of equilibria stability conditions of the satellite subject to gravitational and aerodynamic torques. General case”, Keldysh Institute preprints, 2015, 033, 25 pp.
2014
5.
V. A. Sarychev, S. A. Gutnik, “Dynamics of satellite subject to gravitational and aerodynamic torques. Investigation of equilibria”, Keldysh Institute preprints, 2014, 039, 36 pp.
V. A. Sarychev, S. A. Gutnik, A. Silva, L. Santos, “Dynamics of gyrostat satellite subject to gravitational torque. Stability analysis”, Keldysh Institute preprints, 2013, 025, 36 pp.
2012
7.
V. A. Sarychev, S. A. Gutnik, A. Silva, L. Santos, “Dynamics of gyrostat satellite subject to gravitational torque. Investigation of equilibria”, Keldysh Institute preprints, 2012, 063, 35 pp.
V. A. Sarychev, S. A. Gutnik, “Dynamics of an axisymmetric satellite under influence of gravitational and aerodynamic torques”, Keldysh Institute preprints, 2011, 012, 28 pp.
9.
V. A. Sarychev, S. A. Gutnik, “Dynamics of an axisymmetric gyrostat satellite. Study of equilibria and their stability”, Keldysh Institute preprints, 2011, 011, 28 pp.
2006
10.
V. A. Sarychev, S. A. Mirer, A. A. Degtyarev, “Relative equilibria and stability of a satellite when the center of pressure of aerodynamic forces is on one of the satellite's principal central plane of inertia”, Keldysh Institute preprints, 2006, 001, 27 pp.
2005
11.
A. A. Degtyarev, S. A. Mirer, V. A. Sarychev, “Relative equilibria and stability of a gyrostat-satellite when the vector of the gyrostatic moment is parallel to the principal central plane of inertia of the satellite”, Keldysh Institute preprints, 2005, 106, 31 pp.
2004
12.
A. A. Degtyarev, E. K. Duarte, S. A. Mirer, V. A. Sarychev, “Investigation of equilibria of the satellite subjected to action of the gravitational and aerodynamic moments”, Keldysh Institute preprints, 2004, 049, 29 pp.
13.
A. A. Degtyarev, S. A. Mirer, V. A. Sarychev, “Relative equilibria and stability of a gyrostat-satellite when the vector of the gyrostatic moment is parallel to the principal central axis of inertia of the satellite”, Keldysh Institute preprints, 2004, 046, 26 pp.
1996
14.
S. A. Mirer, V. A. Sarychev, “On Stationary Motions of a String Suspended Rigid Body”, Keldysh Institute preprints, 1996, 096
1989
15.
V. A. Sarychev, V. I. Pen'kov, M. Yu. Ovchinnikov, “A mathematical hysteresis model based on a magneto-mechnical analogy”, Matem. Mod., 1:4 (1989), 122–133