Optimal trajectories for aeroassisted orbital transfer
Abstract
Consideration is given to classical and minimax problems involved in aeroassisted transfer from high earth orbit (HEO) to low earth orbit (LEO). The transfer is restricted to coplanar operation, with trajectory control effected by means of lift modulation. The performance of the maneuver is indexed to the energy expenditure or, alternatively, the time integral of the heating rate. Firist-order optimality conditions are defined for the classical approach, as are a sequential gradient-restoration algorithm and a combined gradient-restoration algorithm. Minimization techniques are presented for the aeroassisted transfer energy consumption and time-delay integral of the heating rate, as well as minimization of the pressure. It is shown that the eigenvalues of the Jacobian matrix of the differential system is both stiff and unstable, implying that the sequential gradient restoration algorithm in its present version is unsuitable. A new method, involving a multipoint approach to the two-poing boundary value problem, is recommended.
- Publication:
-
Budapest International Astronautical Federation Congress
- Pub Date:
- October 1983
- Bibcode:
- 1983buda.iafcZ....M
- Keywords:
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- Aeroassist;
- Optimal Control;
- Orbit Calculation;
- Trajectory Optimization;
- Transfer Orbits;
- Algorithms;
- Earth Orbits;
- Energy Transfer;
- Trajectory Control;
- Astrodynamics