Optimization of space vehicle trans-atmospheric motion by using the method of sequential linearization


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Abstract

The paper deals with the task of optimizing a space vehicle’s trans-atmospheric motion in order to maximize its terminal velocity at prescribed finite values of the height and trajectory inclination angle. The angle of attack acts as control in a vehicle’s passive motion. To determine the optimal program of the control of angle of attack, the method of sequential linearization is used. Solving the problem of optimizing the vehicle’s trans-atmospheric motion is illustrated by passive climb of a sub-hypersonic vehicle MPV (the first stage of the aerospace system RASCAL designed in the USA). The results of simulating the vehicle motion with optimal control and various initial conditions of the vehicle’s motion and mass are discussed.

About the authors

V. L. Balakin

Samara National Research University

Author for correspondence.
Email: balakin@ssau.ru

Doctor of Science (Engineering), Professor,
University Administration Counselor

Russian Federation

S. A. Ishkov

Samara National Research University

Email: irkt@ssau.ru

Doctor of Science (Engineering), Professor,
Professor of the Department of Space Engineering

Russian Federation

A. A. Khramov

Samara National Research University

Email: khramov@ssau.ru

Candidate of Science (Engineering),
Lecturer of the Department of Space Engineering

Russian Federation

References

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