Aerospace and Ocean Engineering
www.aoe.vt.edu/
E-mail: aoe@vt.edu
University Exemplary Department
R.W. Walters, Head
W.L. Neu, Assistant Head
Jack E. Cowling Professor: R. L. Simpson
Fred D. Durham Professor: J. A. Schetz
Professors: R. W. Barnwell1; A. J. Brown; W. J. Devenport; C.D. Hall; B. Grossman; Z. Gurdal1; O. F. Hughes; R. K. Kapania; J. F. Marchman III; W. H. Mason; R.W. Walters
Associate Professors: W. C. Durham; N. Hovakimyan; W. L. Neu; J. J. Wang
Assistant Professors: M. Patil; H. Schaub; C.A Woolsey
Adjunct Professors: W.L. Hallauer, Jr.
Professors Emeritus: E. Cliff; A.K. Jakubowski, E.R. Johnson; C.L. Yates
AE Career Advisor: J. F. Marchman
OE Career Advisor: W. L. Neu
1 Joint with Engineering Science and Mechanics
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Overview
- The aerospace and ocean engineering department offers two bachelor of science degree programs which share a broad range of common interests. Students in the department may major in either aerospace engineering or ocean engineering. Many of the course requirements for these degrees are common because the two curricula share a broad range of common interests. Both programs offer a wide range of technical electives. Students with an interest in both majors may enroll in a double degree program.
- The objectives of both of the department's programs include the preparation of students for entry level positions and graduate study in the fields of aerospace engineering and ocean vehicle engineering. The department seeks to provide students with a strong background in fundamentals, including theoretical, experimental, and computational aspects of science and engineering which will facilitate lifelong learning and the ability to pursue advanced study. It also seeks to provide students with a broad education in the aerospace and ocean vehicle fields with coverage of the areas of fluid dynamics, vehicle dynamics and control, propulsion, and structures, including an emphasis on design and synthesis in a team environment.
- The department's curricula are both vehicle oriented, with an emphasis on aircraft and spacecraft in the aerospace program and on ships of all types in the ocean engineering program. The department's systems engineering approach to these technologies makes them increasingly applicable to other fields such as the automobile industry, high speed train design, and other transportation related areas. Departmental graduates find positions in these fields as well as with the aerospace industry, NASA, the Department of Defense, the ship building industry, and maritime agencies. Employers range from large, multi-national corporations to small consulting firms.
- Classroom studies utilize the students' personal computers and departmental computers. Laboratory classes use the department's outstanding experimental facilities which include a large, research quality subsonic wind tunnel with a twenty four foot long, six-by-six foot cross section test area and state of the art automated control and data collection systems, a 100 foot long towing tank, a Mach 4 supersonic wind tunnel, a Mach 7 hypersonic wind tunnel, a water tunnel, a full scale U. S. Navy A-6 flight simulator and several other facilities.
- The department participates in the Cooperative Education Program which gives qualified students valuable industrial experience while working toward their engineering degrees. The department's required design courses often include multidisciplinary and even international team projects which include travel to universities in other parts of the world.
- The department also offers programs of study leading to the M. Engr., M.S., and Ph.D.
- AOE students must meet all university Core Curriculum requirements and only certain "free" electives and courses designated as "P/F Only" may be taken on a Pass/Fail basis. Lists of approved electives including technical, math, Core, and other electives are available in the department office and on the department's web page.
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Aerospace Engineering Program
First Year |
First Semester |
CHEM 1074 |
CHEMISTRY FOR ENGR |
3
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CHEM 1084 |
CHEM FOR ENGR LAB |
1
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EF 2984 |
ENGR EXPLORATION |
2
|
ENGL 1105 |
ENGLISH I |
3
|
MATH 1114 |
LINEAR ALGEBRA |
2
|
MATH 1205 |
CALCULUS I |
3
|
ELECTIVE** |
|
3
|
|
Credits
|
17
|
Second Semester |
EF 1016 |
INTRO ENGINEERING II |
2
|
ENGL 1106 |
ENGLISH II |
3
|
MATH 1206 |
CALCULUS II |
3
|
MATH 1224 |
VECTOR GEOMETRY |
2
|
PHYS 2305 |
PHYSICS I |
4
|
ELECTIVE** |
|
3
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Credits
|
17
|
Second Year |
First Semester |
AOE 2074 |
COMP METHODS |
3
|
AOE 2104 |
INTRO AERO ENGR |
3
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ESM 2104 |
STATICS |
3
|
MATH 2224 |
MULTI VAR CALC |
3
|
PHYS 2306 |
PHYSICS II |
4
|
ELECTIVE** |
|
1
|
|
Credits
|
17
|
Second Semester |
AOE 3094 |
AOE MATERIALS |
3
|
AOE 3104 |
AIRCRAFT PERFORMANCE |
*3
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ESM 2204 |
MECH DEFORM BODIES |
3
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ESM 2304 |
DYNAMICS |
3
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MATH 2214 |
DIFFERENTIAL EQUATIONS |
3
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ELECTIVE** |
|
3
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Credits
|
18
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Third Year |
First Semester |
AOE 3014 |
AERO/HYDRODYNAMICS |
3
|
AOE 3024 |
THIN-WALL STRUCTURES |
3
|
AOE 3034 |
VEH. VIB & CONTROL |
3
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MATH 4564 |
OPER METH FOR ENGR |
3
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ME 3134 |
FUND OF THERMODYN |
3
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ELECTIVE**OR AOE 4134 |
ASTROMECHANICS |
3
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Credits
|
18
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Second Semester |
AOE 3054 |
EXPER. METHODS |
3
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AOE 3114 |
COMPRES. AERODYNAMICS |
3
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AOE 3124 |
AERO STRUCTURES |
3
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AOE 3134
OR AOE 4140 |
STABIL & CONTROL
SPACECRAFT DYN & CONT. |
3
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MATH ELECTIVE+ |
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3
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ELECTIVE** |
|
3
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Credits
|
18
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Fourth Year |
First Semester |
AOE 3044 |
BOUND LAYER & HEAT TR |
3
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AOE 4065 |
DESIGN I *** |
3
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AOE 4134 OR (OPPOSITE OF JUNIOR YR. CHOICE) ELECTIVE** |
ASTROMECHANICS |
3
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AOE 4154 |
AERO ENGR LABORATORY |
1
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AOE 4234 |
AERO PROPULSION |
3
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TECHNICAL ELECTIVES++ |
|
3
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Credits
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16
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Second Semester |
AOE 4066 |
DESIGN II *** |
3
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ELECTIVES** |
|
6
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TECHNICAL ELECTIVES++ |
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6
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Credits
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15
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Ocean Engineering Program
First Year |
First Semester |
CHEM 1074 |
CHEMISTRY FOR ENGR |
3
|
CHEM 1084 |
CHEM FOR ENGR LAB |
1
|
EF 2984 |
ENGR EXPLORATION |
2
|
ENGL 1105 |
ENGLISH I |
3
|
MATH 1114 |
LINEAR ALGEBRA |
2
|
MATH 1205 |
CALCULUS I |
3
|
ELECTIVE** |
|
3
|
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Credits
|
17
|
Second Semester |
EF 1016 |
INTRO ENGINEERING II |
2
|
ENGL 1106 |
ENGLISH II |
3
|
MATH 1206 |
CALCULUS II |
3
|
MATH 1224 |
VECTOR GEOMETRY |
2
|
PHYS 2305 |
PHYSICS I |
4
|
ELECTIVE** |
|
3
|
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Credits
|
17
|
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Second Year |
First Semester |
AOE 2074 |
COMP METHODS |
3
|
AOE 2204 |
INTRO OCEAN ENGR |
3
|
ESM 2104 |
STATICS |
3
|
MATH 2224 |
MULTI VAR CALC |
3
|
PHYS 2306 |
PHYSICS II |
4
|
ELECTIVE** |
|
1
|
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Credits
|
17
|
Second Semester |
AOE 3094 |
AOE MATERIALS |
3
|
AOE 3204 |
NAVAL ARCHITECTURE |
*3
|
ESM 2204 |
MECH DEFORM BODIES |
3
|
ESM 2304 |
DYNAMICS |
3
|
MATH 2214 |
DIFFERENTIAL EQUATIONS |
3
|
ELECTIVE** |
|
3
|
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Credits
|
18
|
Third Year |
First Semester |
AOE 3014 |
AERO/HYDRODYNAMICS |
3
|
AOE 3024 |
THIN-WALL STRUCTURES |
3
|
AOE 3034 |
VEH. VIB & CONTROL |
3
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MATH 4564 |
OPER METH FOR ENGR |
3
|
ME 3134 |
FUND OF THERMODYN |
3
|
ELECTIVE** |
|
3
|
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Credits
|
18
|
Second Semester |
AOE 3054 |
EXPER. METHODS |
3
|
AOE 3224 |
OCEAN STRUCTURES |
3
|
AOE 3264 |
RESIST & PROPUL OF SHIPS |
3
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AOE 4214 |
OCEAN WAVE MECHANICS |
3
|
AOE 4244 |
MARINE ENGINEERING |
3
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STAT 4604 |
STATISTICS FOR ENGR. |
3
|
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Credits
|
18
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Fourth Year |
First Semester |
AOE 3044 |
BOUND LAYER & HEAT TR |
3
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AOE 4334 |
SHIP DYNAMICS |
3
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AOE 4065 |
SHIP DESIGN I |
3
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AOE 4254 |
OE LABORATORY |
1
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TECHNICAL ELECTIVES++ |
6
|
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Credits
|
16
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Second Semester |
AOE 4066 |
SHIP DESIGN II |
3
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ELECTIVES** |
|
9
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TECHNICAL ELECTIVES++ |
3
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Credits
|
15
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* A minimum grade of C-minus must be earned in AOE 3104 by the time the student has completed 72 hours credit and before taking any other 3 OR 4000 level AOE required course except 3094.
** Electives include 6 credits each from Core Areas 2 and 3, 1 credit from Core Area 6, and 3 credits from Core Area 7 (the area 7 course may double count with area 2 or 3). The AOE Department requires that Econ 2005 be one of the courses taken in Area 3. These elective credits must also include a 1-3 credit computer programming course in C++ or Fortran selected from the following: CS 1044, ECE 1574, EF 2314, EF 2324. Other C++ or Fortran courses may be approved by your advisor.
*** AE majors may take either aircraft or spacecraft design
+ Choice of Math 4574 or Math/AOE 4404 or Stat 4604
++ The AOE Department requires 9 credits of technical electives of which 6 credits must be an AOE course and the remaining 3 may be selected from a list of 3000 level and higher AOE and other approved technical courses.
- 136 credits are required for the AE or the OE degree.
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Undergraduate Course Descriptions (AOE)
2074 (ESM 2074): COMPUTATIONAL METHODS
Solving engineering problems using numerical methods and software, truncation and round-off error, root finding, linear and polynomial regression, interpolation, splines, numerical integration, numerical differentiation, solution of linear simultaneous equations, numerical solutions of ordinary differential equations. Co: MATH2224. (3H,3C)
2104: INTRODUCTION TO AEROSPACE ENGINEERING An overview of aerospace engineering from a design perspective; introductory aerodynamics, lift, drag, and the standard atmosphere; aircraft performance, stability, and control; propulsion; structures; rocket and spacecraft trajectories and orbits. Pre: ENGE 1114, PHYS 2305. (3H,3C)
2204: INTRODUCTION TO OCEAN ENGINEERING An overview of ocean engineering from a design perspective. Ship types and geometry; stages of ship design; introductory hydrostatics and stability; hydrodynamics; resistance and propulsion; oceanography and waves; loads on ships; ship structural analysis. Pre: ENGE 1114 , PHYS 2305. (3H,3C)
2974: INDEPENDENT STUDY
Variable credit course.
2984: SPECIAL STUDY
Variable credit course.
2994: UNDERGRADUATE RESEARCH
Variable credit course.
3014: AERO/HYDRODYNAMICS
Two-dimensional potential flow, stream function, velocity
potential, flow superposition, circulation and lift, airfoil
characteristics. Two-dimensional airfoil theory and panel
methods. Three-dimensional lifting line theory and vortex
lattice solutions for finite wings.
Pre: 3104 or 3204.
(3H,3C)
I.
3024: THIN-WALLED STRUCTURES
Review of mechanics of materials. Stresses in stiffened shell beams. Deformation analysis by energy methods. Multicell beams. Introduction to the matrix stiffness method including truss and beam elements. Pre: ESM2204. (3H,3C) I.
3034: VEHICLE VIBRATION AND CONTROL
Free and forced motions of first order system. Free and forced motions of second order systems both undamped and damped. Frequency and time response. Introduction to control, transfer functions, block diagrams, and closed loop system characteristics. Higher order systems. Pre: ESM2304. (3H,3C) I.
3044: BOUNDARY LAYER AND HEAT TRANSFER
Concepts of viscous flows and physical properties equations of laminar motion with heat and mass transfer; exact and approximate solutions; finite-difference methods; transition to turbulence; analysis in turbulent flows. Conduction and convective heat transfer. Pre: 3014, ME 3134, MATH 4564. (3H,3C) I.
3054: AOE EXPERIMENTAL METHODS
Principles of measurement and measurement systems;
standards, accuracy, uncertainty and statistical concepts.
Practical electronics, detectors, transducers and
instruments for aerospace and ocean engineering. Signal
conditioning systems and readout devices; digital data
acquisition, structures, structural dynamics, fluid
dynamics, materials and wind-tunnel testing.
Pre: 3014, 3024, 3034.
(1H,6L,3C)
II.
3094: MATERIALS & MANUFACTURING FOR AERO & OCEAN ENGINEERS
This course introduces the student of Aerospace and/or
Ocean Engineering to the fundamental properties of
materials typically required for structural design. The
performance characteristics of metals, ceramics, polymers,
and composites are presented and contrasted. Foundation
principles underlying materials manufacturing are also
presented with the goal of providing an understanding of
how processing affects material properties and
performance.
Pre: CHEM 1074.
Co: ESM 2204, PHYS 2305.
(3H,3C)
3104: AIRCRAFT PERFORMANCE
Performance of aircraft. Analysis of fluid statics and dynamics affecting aircraft performance. Hydrostatics of the standard atmosphere and development of basic equations of fluid dynamics. Lift and drag. Aircraft static performance. Rates of climb, endurance, range, take off and landing, and turn performance. Co: ESM 2304. (3H,3C) II.
3114: COMPRESSIBLE AERODYNAMICS
Inviscid, compressible gas dynamics. Continuity, momentum
and energy equations, shock waves, Prandtl-Meyer expansions.
One-dimensional steady and unsteady flow, Rayleigh line,
Fanno line, Shock Tubes. Method of Characteristics,
supersonic thin airfoil theory and conical flow.
Pre: 3014, ME 3134.
(3H,3C)
II.
3124: AEROSPACE STRUCTURES
Aspects of structural analysis pertinent to the design of flight vehicles: aeroelastic divergence, environmental loads,aerospace materials, buckling of thin walled compression members, and introduction to matrix structural dynamics. Pre: 3024. (3H,3C) II.
3134: STABILITY AND CONTROL
Equations of vehicle motion. Linearized analysis. Estimation of stability derivatives, longitudinal and lateral-directional static stability, and control requirements. Dynamic characteristics including stability and mode shapes. Pre: 3034. (3H,3C) II.
3204: NAVAL ARCHITECTURE
Buoyancy of ocean vehicles. Hull geometry, line drawings, coefficients of form. Hydrostatic calculations, development of a computer program for hydrostatic analysis. Review and calculations. Intact and damaged stability of ocean vehicles. Large angle stability. Stability criteria. Viscocity. Stress in a fluid. Basic laws of fluid dynamics. Pre: MATH 2224. Co: ESM 2304. (3H,3C)
3224: OCEAN STRUCTURES
Overview of surface ship, submarine and offshore structural systems, materials and loadings. Application of beam and plate bending and buckling theories. Frame and finite element structural analysis. Pre: 3024. (3H,3C) II.
3264: RESISTANCE AND PROPULSION OF SHIPS
Methods of estimating ship resistance; propulsion devices and their efficiencies; Resistance components; Froude scaling of model test data; Methodical series; Planing hulls; Propellors; Waterjets; Propeller design; Computer methods; Advanced marine vehicles. Pre: 3204, 3014. (3H,3C)
4004: COMPUTER-AIDED CONTROL SYSTEM DESIGN
Computer-aided design and analysis of control systems for high-order linear systems. Stability and performance design criteria. Root locus, PID, lead/lag, and pole-placement design methods. Introduction to modern state-space modeling methods. Design problems involving aircraft, ship, space, and ground-vehicle systems. Pre: 3034. (3H,3C)
4024 (ESM 4734): AN INTRODUCTION TO THE FINITE ELEMENT METHOD
The finite element method is introduced as a numerical method of solving the ordinary and partial differential equations arising in fluid flow, heat transfer, and solid and structural mechanics. The classes of problems considered include those described by the second-order and fourth-order ordinary differential equations and second-order partial differential equations. Both theory and applications of the method to problems in various fields of engineering and applied sciences will be studied. (3H,3C) I,II.
4034: COMPUTATIONAL STRUCTURAL ANALYSIS
Static and vibratory response of framed structures. The matrix eigenvalue problem for buckling and free vibrations. Static response of laminated composite plates by the finite element method. Pre: 3124 or 3224. (3H,3C) II.
4054 (CEE 4444) (ESM 4444): STABILITY OF STRUCTURES
Introduction to the methods of static structural stability analysis and their applications. Buckling of columns and frames. Energy method and approximate solutions. Elastic and inelastic behavior. Torsional and lateral buckling. Use of stability as a structural design criterion. Pre: 3024, (CEE 3404. (3H,3C) I,II.
4064 (CEE 4364): FLUID FLOWS IN NATURE
Course designed to build upon and broaden a basic traditional engineering knowledge of fluid flows into areas concerning a variety of natural occurrences and phenomena that involve fluid motions in important ways. Drag of sessil systems and motile animals, gliding and soaring, flying and swimming, internal flows in organisms, low Reynolds number flows, fluid-fluid interfaces, unsteady flows in nature and wind engineering. Pre: 3104 or CEE 3304 or ESM 3024 or ME 3404. (3H,3C)
4065-4066: DESIGN
Analysis and design of various space, aeronautical and marine vehicles and systems. Senior standing required. (2H,3L,3C) I,II.
4084 (ESM 4084): ENGINEERING DESIGN OPTIMIZATION
Use of mathematical programming methods for engineering design optimization including linear programming, penalty function methods, and gradient projection methods. Applications to minimum weight design, open-loop optimum control, machine design, and appropriate design problems from other engineering disciplines. Pre: MATH 2224. (3H,3C) II.
4114: APPLIED COMPUTATIONAL AERODYNAMICS
Development of computational methods for application to
wing aerodynamic problems. Incompressible airfoil codes.
Panel methods and vortex lattice methods. Finite difference
techniques. Transonic and supersonic applications.
Pre: 3044, 3114.
(3H,3C)
II.
4124: CONFIGURATION AERODYNAMICS
Aerodynamic design of flight vehicles, with emphasis on nonlinear flowfields and configuration concepts. Aerodynamic analysis and design for transonic, supersonic, hypersonic foils, and low speed high alpha flight. Includes case studies of classic configurations and aerodynamic design papers. Pre: 3014, 3114. (3H,3C)
4134: ASTROMECHANICS
Application of Newton's Laws to the dynamics of spaceflight. Two-body problem, Kepler's Laws, energy and time relations, orbit specification and determination. Orbital maneuver and transfer, patched conic approximations, relative motion, and elements of optimal maneuvering. Pre: ESM2304. (3H,3C) I.
4140: SPACECRAFT DYNAMICS AND CONTROL
Space missions and the way pointing requirements affect attitude control systems. Rotational kinematics and attitude determination algorithms. Modeling and analysis of the attitude dynamics of space vehicles. Rigid body dynamics, effects of energy dissipation. Gravity gradient, spin, and dual spin stabilization. Rotational maneuvers. Environmental torques. Impacts of attitude stabilization techniques on mission performance. Pre: 4134, 3034. (3H,3C)
4144: AIRCRAFT AUTOMATIC FLIGHT CONTROL
Introduction and history of aircraft automatic flight
control. Mathematical models of linear systems elements.
Bode amplitude and phase plots of longitudinal and lateral
control system analysis. Inputs and system performance
assessment. Multiloop flight control systems. Applications
to representative aircraft.
Pre: 3134, MATH 4564.
(3H,3C)
II.
4154: AEROSPACE ENGINEERING LABORATORY
Wind tunnel laboratory experiments related to subsonic and supersonic aerodynamics. Continuation of AOE 3054 for Aerospace Engineering students. Writing of technical laboratory reports; design of experiments. Pre: 3054, 3114, 3124, 3134. (3L,1C) I.
4164: SPECIAL TOPICS IN VEHICLE PERFORMANCE
Three dimensional point-mass equations of motion over flat and spherical Earth. Aerodynamic and propulsive modeling. Numerical integration of equations of motion. Analytic approximations and solutions. Energy state models. Advanced topics. Pre: 3104, 3134. (3H,3C)
4174 (ME4174): SPACECRAFT PROPULSION
Spacecraft propulsion systems and their applications in orbital, interplanetary, and interstellar flight. Rocket propulsion fundamentals; advanced mission analysis; physics and engineering of chemical rockets, electrical thrusters, and propellant less systems (tethers and sails); spacecraft integration issues. Pre: 4234 or ME 4234. (3H,3C)
4184 (ESM 4184): DESIGN AND OPTIMIZATION OF COMPOSITE STRUCTURES
Design aspects of laminate constitutive relations, coupling and decoupling of in-plane and out-of-plane elastic response. Tailoring of laminated composite materials to meet design requirements on stiffness and strength through the use of graphical and numerical optimization techniques. Introduction to integer programming: branch-and-bound method and genetic algorithms. Stacking sequence design of laminated composite beams and plates via integer programming. Pre: 3024 or ESM 3084, CEE 3404. (3H,3C) II.
4204: OCEAN ACOUSTICS
Basic problems and techniques of underwater acoustics; sonar equations, sound propagation in the ocean, generation and detection of underwater sound, background and self noise, reverberation, target strength, applications. Pre: MATH 4564. (3H,3C) II.
4214: OCEAN WAVE MECHANICS
Introduction to theory of wave motion in different water
depth regions, including wave generation and propagation.
Description of wave statistics and spectral representation
for realistic ocean conditions. Wave forces on stationary
structures. Nonlinear waves, wave properties, and methods
of analysis.
Pre: 3014, MATH 4564.
(3H,3C)
I.
4224: PROBABILISTIC ANALYSIS OF OCEAN SYSTEMS
Representation of random phenomena for ocean systems (waves, vehicle motions, wave-induced loads). Concepts of correlation (for vector processes), power spectra, probability density, envelope processes. Responses of linear dynamic systems, statistics of responses, exceedance probability, extremes. Extension to nonlinear systems. Pre: 3234, MATH 4564. (3H,3C) I.
4234 (ME4234): AEROSPACE PROPULSION SYSTEMS
Design principles and performance analysis of atmospheric and space propulsion engines and systems. Application of thermodynamics, compressible fluid flow and combustion fundamentals to the design of gas turbine and rocket engines and components, including inlets, turbo machines, combustors, and nozzles. Matching of propulsion system to vehicle requirements. Pre: (3114, ME 3134) or (ME 3404, ME 3124). (3H,3C) I.
4244 (ME4244): MARINE ENGINEERING
Analysis of major ship propulsion devices (propellers, water jets). Integration with propulsion plant and machinery. Characteristics of marine steam turbines, nuclear power plants, marine diesels, and marine gas turbines. Shafting system, bearings, and vibration problems. Pre: ME 3134. (3H,3C) I.
4254: OCEAN ENGINEERING LABORATORY
Continuation of AOE 3054 for Ocean Engineering students using facilities and instrumentation pertinent to ocean engineering. Writing of technical laboratory reports; design of experiments. Pre: 3054. (1H,2L,1C) I.
4274: COMPUTER BASED DESIGN OF OCEAN STRUCTURES
Computer-based structural models for combined finite element analysis, limit state analysis and optimization. Torsion of thin-walled structures. Buckling of stiffened panels and cylinders. Eigenvalue methods for buckling and vibration. Incremental plastic collapse; other progressive collapse. Ultimate strength of large structural modules. Pre: 3224. (3H,3C) II.
4334: SHIP DYNAMICS
Analysis of motions of rigid body vehicles in water, including influence of added mass and buoyancy. Sea keeping motion responses in waves, wave-induced structural loads, random response analysis via spectral analysis, and extreme response analysis. Introduction to hydro elasticity and maneuvering. Pre: 3014, 3034, 4214, MATH 4564. (3H,3C)
4404 (MATH 4404): APPLIED NUMERICAL METHODS
Interpolation and approximation, numerical integration, solution of equations, matrices and eigenvalues, systems of equations, approximate solution of ordinary and partial differential equations. Applications to physical problems. Partially duplicates 4554 and 3414. Mathematics majors or minors cannot take both 4404 and 3414. X-grade allowed. Pre: MATH 4564, ESM 2074. (3H,3C)
4974: INDEPENDENT STUDY
Variable credit course.
4984: SPECIAL STUDY
Variable credit course.
4994: UNDERGRADUATE RESEARCH
Variable credit course.
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