Abstract This paper reassesses the classical circumferential-thrust problem, in which a spacecraft orbiting around a primary body is subjected to a propulsive acceleration of constant modulus, whose direction is in the plane of the parking orbit and orthogonal to the spacecraft-primary line. In particular, a new formulation is proposed to obtain a reduction in the number of differential equations required for the study of the spacecraft propelled trajectory. The mathematical complexity of the problem may be further reduced assuming that both the propulsive acceleration modulus and the spacecraft distance from the primary body are sufficiently small. In that case, an approximate model is able to accurately describe the characteristics of the propelled trajectory when the parking orbit is circular. Finally, using the data obtained by numerical simulations, the approximate model is extended to generate a set of semi-analytical equations for the analysis of a classical escape mission scenario.
Highlights The classical circumferential-thrust problem is reassessed. A new formulation obtains a reduction in the mathematical complexity. The accuracy of the model is increased with numerical data in an escape mission.
Analysis of spacecraft motion under constant circumferential propulsive acceleration
Acta Astronautica ; 105 , 1 ; 278-284
2014-09-24
7 pages
Aufsatz (Zeitschrift)
Elektronische Ressource
Englisch
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