Introduction to fluid flow concepts and equations; characteristics of a fluid; mass and momentum conservation equations; fluid statics including buoyancy; Reynolds¿ Transport Theorem; Bernoulli's equation; viscous effects; Couette and Poiseuille flow; pipe and internal flow systems; fluid power systems; external boundary layers; flow over objects and associated lift and drag forces.  Corequisite: APMA 3140 or equivalent. 

Boundary layers: similarity, Blasius and momentum integral methods. Ideal Flows: Kelvin's circulation theorem; complex potential; superposition; Kutta-Joukowski; thin airfoils; finite wings; lifting lines. Gas dynamics: sound waves; normal and oblique shocks; Prandtl-Meyer expansion; quasi 1D flows; converging-diverging nozzles; choked flows; diffusers; Rayleigh line and Fanno line flows. Prerequisites: MAE 2100 and MAE 3210

Application of experimental methods for thermal-fluid behavior. Topics include fluid properties, pressure and buoyancy, jet momentum, dimensional analysis, pipe flow, data analysis, particle image velocimetry, and measurement uncertainty. The laboratory experience will include activities to reinforce principles from Thermodynamics (MAE 2100) and Fluid Mechanics (MAE 3210).  Corequisite: MAE 3210 OR MAE 3215 

Analyzes the design of elements under combined stresses; bending and torsional stresses in thin-walled beams; energy and other methods applied to statically determinate and indeterminate aerospace structural elements; buckling of simple structural members; and matrix and finite element analysis. Prerequisite: MAE 2310 or CE 2310.

Introduces numerical modeling concepts used in engineering simulation tools like computational fluid dynamics and structural mechanics analysis software. Topics covered include discretization methods of partial differential equations, numerical solutions of linear matrix equations, and relaxation techniques for solving stiff equation sets. As part of the course, students will use Matlab, CFD, and mechanical analysis tools.

Special topics in aerospace engineering

Introduces physical-chemical/microstructural and working mechanical properties, along with practical applications, for materials of wide interest on aerospace materials. Includes common metal, polymer, ceramic, and composite materials. Topics include standard materials names/designations; standard forming methods; usual strengthening means; temperature and temperature-history effects. Prerequisite CHEM 1410 or 1610 or CHEM 1810: Corequisite MAE 2310 or CE 2310.

Applies mechanical analysis to the basic design of machine elements; basic concepts in statistics and reliability analysis, advanced strength of materials, and fatigue analysis; and the practical design and applications of materials to fastening systems, weldments, power screws, springs, journal and anti-friction bearings, gears, brake clutches and flexible power transmission elements. Prerequisites: MAE 3310.

Presents general concepts of dynamical systems modeling and provides mathematical tools to develop and analyze models that describe input/output behaviors of physical systems. Topics include basic elements of mechanical systems, transfer functions, frequency response, stability and poles, resonance and natural frequency, transient and time constant, steady state and DC gain, block diagrams. Prerequisites: MAE 2320 and APMA 2130

Introduces definitions and concepts and includes a review of longitudinal static stability; rigid body dynamics: general equations of motion, rotating coordinate systems; small disturbance theory; atmospheric flight mechanics, stability derivatives; motion analysis of aircraft; static and dynamic stability; aircraft handling qualities; and an introduction to flight control systems and automatic stabilization. Prerequisite: MAE 2320.