CONTROL SYSTEMS

THE SPACECRAFT ANGULAR VELOCITY ESTIMATION

IN THE ORBITAL STABILIZATION MODE BY THE RESULTS

OF THE LOCAL VERTICAL SENSOR MEASUREMENTS

∗

N.E. Zubov

1

,

2

,

E.A. Mikrin

1

,

2

,

A.S. Oleynik

1

,

3

,

V.N. Ryabchenko

1

,

2

,

D.E. Efanov

1

1

OAO Korolev Rocket and Space Corporation Energiya,

Korolev, Moscow region, Russian Federation

e-mail:

Nikolay.Zubov@rsce.ru

2

Bauman Moscow State Technical University, Moscow, Russian Federation

e-mail:

nezubov@bmstu.ru

3

Moscow Institute of Physics and Technology (State University),

Dolgoprudnyy, Moscovskaya oblast, Russian Federation

Implementation of the orbital orientation mode is based on the use of sensor

equipment, measuring the spacecraft position angles relative to the coordinates

system and the angular velocity of spacecraft rotation relative to inertial space.

In case the latter fails the orbital stabilization implementation is impossible.

Consequently, it is required to make on-board estimation algorithms for a angular

velocity vector in real-time by the results of measurements using an angular position

sensor. The exact pole placement method was used to obtain the analytic solution of

the estimation algorithm synthesis for angular velocity of the spacecraft rotation in

the orbital stabilization mode by the results of local vertical sensor measuring. The

mathematical simulation results are presented and the possibility of the developed

algorithm implementation is assessed in real-time. The simulation results confirm

high efficiency of the algorithm operation.

Keywords

:

spacecraft, exact pole placement method, local vertical sensor, angular

velocity, estimation algorithm.

Introduction.

The problem of building up and stabilizing orbital

navigation mode [1–3] is one of the most common in spacecraft (SC)

flights practice regardless of their target mission. As a rule, implementation

of the above mentioned mode is based on the use of sensor equipment

measuring SC position angles relative to the reference coordinate system

and SC angular rotation velocity with respect to inertial space. In case the

latter fails the implementation of orbital stabilization is impossible, thus,

it is essential to build on-board estimation algorithms for angular velocity

vector by the results of angular position sensor measurements in real time.

The characteristic feature of many SC is the usage of a local vertical

builder (IKV) [4] as a measurement device of angular roll position, which

measures only two angles (angles of roll and pitch). The present article

is devoted to the analytical synthesis of SC angular velocity estimation

algorithm in the orbital stabilization mode by the results of local vertical

∗

The research was funded by Russian National Fund grant (project N 14-11-000460).

ISSN 0236-3933. HERALD of the BMSTU. Series “Instrument Engineering”. 2014. No. 5

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