Oklahoma State University

593

MAE 5833 Transient Simulation of Thermal Systems Prerequisites: Graduate Standing or consent of instructor. Description: This course provides an introduction to the transient simulation of building thermal systems. Learned material is reinforced in lab sections as well as in a semester project. Credit hours: 3 Contact hours: Lecture: 2 Lab: 2 Levels: Graduate Schedule types: Lab, Lecture, Combined lecture and lab Department/School: Mech & Aerospace Engr MAE 5843 Conduction Heat Transfer Prerequisites: ENSC 3233. Description: Advanced heat transfer analysis and design, with primary emphasis on conduction. Credit hours: 3 Contact hours: Lecture: 3 Levels: Graduate Schedule types: Lecture Department/School: Mech & Aerospace Engr MAE 5853 Computational Heat Transfer Prerequisites: MAE 3233, graduate standing, knowledge of FORTRAN. Description: Computational techniques for the solution of two- dimensional heat transfer, fluid flow and related processes in problems of practical interest. A general-purpose computer program used to demonstrate the capabilities of the numerical method through a wide variety of engineering problems. Credit hours: 3 Contact hours: Lecture: 3 Levels: Graduate Schedule types: Lecture Department/School: Mech & Aerospace Engr MAE 5863 Building Heat Transfer and Simulation Prerequisites: MAE 3223, MAE 3233, ENSC 3233. Description: Conduction, convection and radiation heat transfer applied to building thermal simulation. Solar radiation. Credit hours: 3 Contact hours: Lecture: 3 Levels: Graduate Schedule types: Lecture Department/School: Mech & Aerospace Engr MAE 5873 Advanced Indoor Environmental Systems Prerequisites: MAE 4703. Description: Heating, air-conditioning, ventilation and refrigeration systems. System and component analysis, design and simulation. Credit hours: 3 Contact hours: Lecture: 3 Levels: Graduate Schedule types: Lecture Department/School: Mech & Aerospace Engr MAE 5913 Advanced Aerodynamics Prerequisites: ENSC 3233 or equivalent. Description: Aerodynamics of the subsonic, transonic, supersonic, and hypersonic flow regimes. Derivation of governing equations and fundamental principles. Analytical and computational analysis methods. Recent developments. Credit hours: 3 Contact hours: Lecture: 3 Levels: Graduate Schedule types: Lecture Department/School: Mech & Aerospace Engr

MAE 5923 Guidance and Control of Aerospace Vehicles Prerequisites: MAE 4053 or ECEN 4413 or equivalent.

Description: Navigation, guidance and attitude control of aircraft, launch vehicles and spacecraft. Inertial navigation mechanizations and error analysis. Stability augmentation systems. Credit hours: 3 Contact hours: Lecture: 3 Levels: Graduate Schedule types: Lecture Department/School: Mech & Aerospace Engr MAE 5933 Aeroelasticity Prerequisites: Graduate standing or consent of instructor. Description: Interaction between fluid dynamic, inertial and elastic forces. Development of analytical and computational methods for analysis. Application to a broad range of problems in engineering. Credit hours: 3 Contact hours: Lecture: 3 Levels: Graduate Schedule types: Lecture Department/School: Mech & Aerospace Engr MAE 5943 Unsteady Aerodynamics and Aeroacoustics Prerequisites: ENSC 3233 or equivalent. Description: Development of governing fluid dynamic equations for unsteady flows; linear unsteady aerodynamics for isolated and cascaded lifting surfaces; acoustics in moving media; three-dimensional duct acoustics; sound generation from isolated airfoils, cascaded airfoils, rotor-stator interactions, multiple pure-tone sources, propellers and jets. Credit hours: 3 Contact hours: Lecture: 3 Levels: Graduate Schedule types: Lecture

Department/School: Mech & Aerospace Engr MAE 5953 Aerospace Systems Engineering Prerequisites: MAE 3253 or equivalent.

Description: Aircraft and spacecraft design from a systems perspective, covering basic systems engineering, cost and weight estimation, basic vehicle performance and trade study analysis, safety and reliability, lifecycle analysis, subsystem integration, risk analysis and management, system realization, and multi-disciplinary optimization (MDO). Additional topics include requirements identification and development, and program planning and control. Credit hours: 3 Contact hours: Lecture: 3 Levels: Graduate Schedule types: Lecture Department/School: Mech & Aerospace Engr