Analytical algorithm of energy and time quasioptimal turn of a spacecraft under arbitrary boundary conditions

IF 0.4 Q4 MATHEMATICS

Izvestiya of Saratov University Mathematics Mechanics Informatics Pub Date : 2021-05-25 DOI:10.18500/1816-9791-2021-21-2-213-226

Y. Sapunkov, A. V. Molodenkov

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Abstract

. The optimal attitude maneuver control problem without control constraints is studied in the quaternion statement for an axially symmetric spacecraft as a rigid body under arbitrary boundary conditions on angular position and angular velocity of a spacecraft. The performance criterion is given by a functional combining the time and energy used for the attitude maneuver. Using substitutions of variables, the original problem is simpliﬁed (in terms of dynamic Euler equations) to the optimal slew problem for a rigid body with a spherical mass distribution. The simpliﬁed problem contains one additional scalar diﬀerential equation. In the class of generalized conical motions, the traditional optimal slew problem is modiﬁed to obtain analytical solutions for motion equations. The solutions contain arbitrary constants and two arbitrary scalar functions (generalized conical motion parameters). The proposed approach ﬁts well with the Poinsot concept that any arbitrary angular motion of a rigid body around a ﬁxed point can be considered as some generalized conical motion of a rigid body. Moreover, for the cases of analytic solvability of the classical problem of optimal reversal spherically symmetric spacecraft, when restrictions are imposed on the edge conditions of the problem (plane Euler turn, conical motion) solutions of the classical and modiﬁed tasks are completely the same. An optimization problem is formulated and solved with respect to these functions, the second derivatives of which serve as controls in the optimization problem. The resulting analytical solution of the modiﬁed problem can be treated as an approximate (quasioptimal) solution of the traditional optimal slew problem under arbitrary boundary conditions. The quasioptimal algorithm of the optimal turn of a spacecraft is given. Numerical example showing the closeness of the solutions of the traditional and modiﬁed optimal slew problems for an axially symmetric spacecraft is given.

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任意边界条件下航天器能量和时间准最优转弯的解析算法

．研究了在任意航天器角位置和角速度边界条件下，作为刚体的轴对称航天器在四元数条件下无控制约束的最优姿态机动控制问题。通过结合姿态机动所用时间和能量的函数给出了性能准则。通过变量替换，将原问题简化为具有球面质量分布的刚体的最优回转问题(根据动态欧拉方程)。简化后的问题包含一个附加的标量微分方程。在广义圆锥运动中，对传统的最优回转问题进行了改进，得到了运动方程的解析解。解包含任意常数和两个任意标量函数(广义圆锥运动参数)。所提出的方法很好地符合Poinsot概念，即刚体围绕固定点的任意角运动都可以视为刚体的某种广义圆锥运动。此外，对于最优反转球对称航天器经典问题的解析可解情况，当对问题的边缘条件(平面欧拉转弯、圆锥运动)施加限制时，经典任务的解与修正任务的解完全相同。以这些函数的二阶导数作为优化问题的控制项，构造并求解了优化问题。修正问题的解析解可以看作任意边界条件下传统最优回转问题的近似(拟最优)解。给出了航天器最优转弯的准最优算法。给出了轴对称航天器传统最优回转问题与改进最优回转问题解的密切性。

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