Orbital Mechanics for Engineering Students

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Orbital Mechanics for Engineering Students
Orbital Mechanics for Engineering Students cover.jpg
Third edition
AuthorHoward D. Curtis
SeriesElsevier Aerospace Engineering Series
Subject Orbital mechanics
Published2010 (Butterworth-Heinemann)
Pages792 (4th ed.)
ISBN 978-0-08-102133-0 (4th ed.)

Orbital Mechanics for Engineering Students is an aerospace engineering textbook by Howard D. Curtis, in its fourth edition as of 2019. [1] The book provides an introduction to orbital mechanics, while assuming an undergraduate-level background in physics, rigid body dynamics, differential equations, and linear algebra. [2] [3]

Topics covered by the text include a review of kinematics and Newtonian dynamics, the two-body problem, Kepler's laws of planetary motion, orbit determination, orbital maneuvers, relative motion and rendezvous, and interplanetary trajectories. [3] The text focuses primarily on orbital mechanics, but also includes material on rigid body dynamics, rocket vehicle dynamics, and attitude control. [2] [3] Control theory and spacecraft control systems are less thoroughly covered. [3]

The textbook includes exercises at the end of each chapter, and supplemental material is available online, including MATLAB code for orbital mechanics projects. [2]

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References

  1. Curtis, Howard D. (2019). Orbital Mechanics for Engineering Students (4th ed.). Butterworth-Heinemann. ISBN   978-0-08-102133-0.
  2. 1 2 3 Hall, Christopher; Sandfry, Ralph A. (March 2008). "Review of Orbital Mechanics for Engineering Students". Journal of Guidance, Control, and Dynamics. 31 (2): 445–446. Bibcode:2008JGCD...31..445H. doi:10.2514/1.34514.
  3. 1 2 3 4 Jablonski, Alexander M. (June 2005). "Book Review: Orbital Mechanics for Engineering Students". Canadian Aeronautics and Space Journal. 51 (2): 87. Bibcode:2005CaASJ..51...87J. doi:10.5589/q05-005.