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Cambridge Aerospace Series

Published online by Cambridge University Press:  25 September 2018

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Type
Chapter
Information
Gas Turbines
Internal Flow Systems Modeling
, pp. ii
Publisher: Cambridge University Press
Print publication year: 2018

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References

Rolfe, J. M. and Staples, K. J. (eds.): Flight SimulationGoogle Scholar
Berlin, P.: The Geostationary Applications SatelliteGoogle Scholar
Smith, M. J. T.: Aircraft NoiseGoogle Scholar
Vinh, N. X.: Flight Mechanics of High-Performance AircraftGoogle Scholar
Mair, W. A. and Birdsall, D. L.: Aircraft PerformanceGoogle Scholar
Abzug, M. J. and Larrabee, E. E.: Airplane Stability and ControlGoogle Scholar
Sidi, M. J.: Spacecraft Dynamics and ControlGoogle Scholar
Anderson, J. D.: A History of AerodynamicsGoogle Scholar
Cruise, A. M., Bowles, J. A., Goodall, C. V., and Patrick, T. J.: Principles of Space Instrument DesignGoogle Scholar
Khoury, G. A. (ed.): Airship Technology, Second EditionGoogle Scholar
Fielding, J. P.: Introduction to Aircraft DesignGoogle Scholar
Leishman, J. G.: Principles of Helicopter Aerodynamics, Second EditionGoogle Scholar
Katz, J. and Plotkin, A.: Low-Speed Aerodynamics, Second EditionGoogle Scholar
Abzug, M. J. and Larrabee, E. E.: Airplane Stability and Control: A History of the Technologies that Made Aviation Possible, Second EditionGoogle Scholar
Hodges, D. H. and Pierce, G. A.: Introduction to Structural Dynamics and Aeroelasticity, Second EditionGoogle Scholar
Fehse, W.: Automatic Rendezvous and Docking of SpacecraftGoogle Scholar
Flack, R. D.: Fundamentals of Jet Propulsion with ApplicationsGoogle Scholar
Baskharone, E. A.: Principles of Turbomachinery in Air-Breathing EnginesGoogle Scholar
Knight, D. D.: Numerical Methods for High-Speed FlowsGoogle Scholar
Wagner, C. A., Hüttl, T., and Sagaut, P. (eds.): Large-Eddy Simulation for AcousticsGoogle Scholar
Joseph, D. D., Funada, T., and Wang, J.: Potential Flows of Viscous and Viscoelastic FluidsGoogle Scholar
Shyy, W., Lian, Y., Liu, H., Tang, J., and Viieru, D.: Aerodynamics of Low Reynolds Number FlyersGoogle Scholar
Saleh, J. H.: Analyses for Durability and System Design LifetimeGoogle Scholar
Donaldson, B. K.: Analysis of Aircraft Structures, Second EditionGoogle Scholar
Segal, C.: The Scramjet Engine: Processes and CharacteristicsGoogle Scholar
Doyle, J. F.: Guided Explorations of the Mechanics of Solids and StructuresGoogle Scholar
Kundu, A. K.: Aircraft DesignGoogle Scholar
Friswell, M. I., Penny, J. E. T., Garvey, S. D., and Lees, A. W.: Dynamics of Rotating MachinesGoogle Scholar
Conway, B. A. (ed.): Spacecraft Trajectory OptimizationGoogle Scholar
Adrian, R. J. and Westerweel, J.: Particle Image VelocimetryGoogle Scholar
Flandro, G. A., McMahon, H. M., and Roach, R. L.: Basic AerodynamicsGoogle Scholar
Babinsky, H. and Harvey, J. K.: Shock Wave–Boundary-Layer InteractionsGoogle Scholar
Tam, C. K. W.: Computational Aeroacoustics: A Wave Number ApproachGoogle Scholar
Filippone, A.: Advanced Aircraft Flight PerformanceGoogle Scholar
Chopra, I. and Sirohi, J.: Smart Structures TheoryGoogle Scholar
Johnson, W.: Rotorcraft Aeromechanics vol. 3Google Scholar
Shyy, W., Aono, H., Kang, C. K., and Liu, H.: An Introduction to Flapping Wing AerodynamicsGoogle Scholar
Lieuwen, T. C. and Yang, V.: Gas Turbine EmissionsGoogle Scholar
Kabamba, P. and Girard, A.: Fundamentals of Aerospace Navigation and GuidanceGoogle Scholar
Cummings, R. M., Mason, W. H., Morton, S. A., and McDaniel, D. R.: Applied Computational AerodynamicGoogle Scholar
Tucker, P. G.: Advanced Computational Fluid and AerodynamicsGoogle Scholar
Boyd, Iain D. and Schwartzentruber, Thomas E.: Nonequilibrium Gas Dynamics and Molecular SimulationGoogle Scholar
Shang, Joseph J. S. and Surzhikov, Sergey T.: Plasma Dynamics for Aerospace EngineeringGoogle Scholar
Sultanian, Bijay K.: Gas Turbines: Internal Flow Systems ModelingGoogle Scholar

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