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Applied Nonsingular Astrodynamics
Optimal Low-Thrust Orbit Transfer

$100.00 ( ) USD

Part of Cambridge Aerospace Series

  • Date Published: July 2018
  • availability: This ISBN is for an eBook version which is distributed on our behalf by a third party.
  • format: Adobe eBook Reader
  • isbn: 9781108611084

$ 100.00 USD ( )
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  • This essential book describes the mathematical formulations and subsequent computer simulations required to accurately project the trajectory of spacecraft and rockets in space, using the formalism of optimal control for minimum-time transfer in general elliptic orbit. The material will aid research students in aerospace engineering, as well as practitioners in the field of spaceflight dynamics, in developing simulation software to carry out trade studies useful in vehicle and mission design. It will teach readers to develop flight software for operational applications in autonomous mode, so to actually transfer space vehicles from one orbit to another. The practical, real-life applications discussed will give readers a clear understanding of the mathematics of orbit transfer, allow them to develop their own operational software to fly missions, and to use the contents as a research tool to carry out even more complex analyses.

    • Familiarizes the reader with the mathematics of orbit transfer using singularity-free formulations
    • Practical, real-life applications provide the reader with the tools to develop their own operational software
    • A useful resource in developing simulation software to carry out trade studies for vehicle and mission design
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    Reviews & endorsements

    'This book represents a lifetime of valuable contributions to optimal low-thrust orbit transfer.' John E. Prussing, University of Illinois

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    Product details

    • Date Published: July 2018
    • format: Adobe eBook Reader
    • isbn: 9781108611084
    • contains: 181 b/w illus.
    • availability: This ISBN is for an eBook version which is distributed on our behalf by a third party.
  • Table of Contents

    Preface
    1. The fundamental classic analysis of Edelbaum, Sackett and Malchow, with additional detailed derivations and extensions
    2. The analysis of the six-element formulation
    3. Optimal low-thrust rendezvous using equinoctial orbit elements
    4. Optimal low-thrust transfer using variable bounded thrust
    5. Minimum-time low-thrust rendezvous and transfer using epoch mean longitude formulation
    6. Trajectory optimization using eccentric longitude formulation
    7. Low-thrust trajectory optimization based on epoch eccentric longitude formulation
    8. Mechanics of trajectory optimization using nonsingular variational equations in polar coordinates
    9. Trajectory optimization using nonsingular orbital elements and true longitude
    10. The treatment of the Earth oblateness effect in trajectory optimization in equinoctial coordinates
    11. Minimum-time constant acceleration orbit transfer with first-order oblateness effect
    12. The streamlined and complete set of the nonsingular J2-perturbed dynamic and adjoint equations for trajectory optimization in terms of eccentric longitude
    13. The inclusion of the higher order harmonics in the modeling of optimal low-thrust orbit transfer
    14. Analytic expansions of luni-solar gravity perturbations along rotating axes for trajectory optimization: part 1: the dynamic system
    15. Analytic expansions of luni-solar gravity perturbations along rotating axes for trajectory optimization: part 2: the multipliers system and simulations
    16. Fourth order expansions of the luni-solar gravity perturbations along rotating axes for trajectory optimization
    Index.

  • Author

    Jean Albert Kéchichian, The Aerospace Corporation
    Jean Albert Kéchichian is a retired Engineering Specialist from The Aerospace Corporation. His career has included senior level engineering positions at NASA's Jet Propulsion Laboratory and at Ford Aerospace. His main areas of contribution are in spaceflight guidance and navigation. He is a Fellow of The American Astronautical Society, and his work has regularly appeared in Acta Astronautica, the Journal of Guidance Control and Dynamics, the Journal of the Astronautical Sciences, and the Journal of Spacecraft and Rockets. He holds Degrees in Aeronautical and Mechanical Engineering from l'Université de Liège, University of California, Berkeley, and a Ph.D. in Aeronautics and Astronautics from Stanford University.

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