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Academic Notices
Organizations
Graduate Studies
COURSE
WEBPAGE LINKS
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All courses are 3 credits unless otherwise noted. Graduate Students
should consult the departmental schedule to ascertain which semester a
course
is taught. Last revised July, 2002.
MAE 500, 505, 509, 510, 513 Special Topics in
Advanced Diagnostics for Thermo-Fluids
This courses emphasizes hands-on experience and basic and practical
knowledge. The scope will be
tailored according to the needs of the students. Topics may include
optics, lasers, image acquisition
and processing, light scattering, holographic measurements, laser Doppler
Velocimetry, fluorescence
techniques, flow visualization and hot-wire anemometry. Measurement
quantities may include fluid flow
velocity fields, temperature, pressure, species concentration, as well as
disperse-phase information in
two-phase flows.
Analytical Methods
Methods of solution for practical problems in mechanical and aerospace
engineering, involving partial
differential equations: Fourier series, orthogonal functions, Laplace
transforms, examples of partial
differential equations -- waves and heat conduction equations, method of
separation of variables Bessel
functions, introduction to complex variable theory, application to
potential flow. Extra assignments
required.
Guidance and Control
This course introduces the concepts of guidance, navigation and control
(GN&C) of dynamical vehicles. Guidance
equipment and software is first used to compute the vehicle location
required to satisfy mission requirements,
navigation then tracks the vehicle's actual location, and control then
transports the vehicle to the required location. Theoretical foundations
are
introduced to perform basic GN&C operations. Topics include: review of
rotational kinematics and dynamics, orbital
mechanics, Kalman filtering, GPS tracking and navigation, attitude and
orbit determination, and advanced GN&C techniques. Examples are
given using spacecraft, aircraft, launch and missile vehicles.
Modeling of Turbulent Flow
This course will deal with analytical modeling and prediction of turbulent
flows. Closure hypothesis for
the various terms in the energy, dissipation, and Reynolds stress
equations will be covered. Eddy
viscosity, algebraic stress and second order Reynolds stress models will
be formulated including
compressibility and buoyancy effects. Computation methods for free and
wall bounded shear flows as well
as general two and three dimensional flows will be discussed. Other
theories including renormalization
group and two-point formulations will also be discussed
System Identification
This course covers fundamental systems identification techniques. Topics
covered include: introduction to the
identification process; brief review of mathematical topics necessary for
the course; time-domain approach for
identification of linear
time-invariant systems. This will include continuous and discrete time
models, Markov parameters, ARX, ARMA, ARMAX
and other models; frequency domain method; Eigensystem Realization
Algorithm; and Kalman filters.
Prerequisite: MAE 571
MAE 501-502 Individual Problems (1-6 credits)
For Master of Science candidates. Investigation carried out under the
direction of a member of the
graduate faculty. TUT.
Prerequisite: Permission of instructor and approval of the department
chair.
MAE 503-504 Graduate Seminar I & II (no credit)
A bi-weekly seminar for graduate Mechanical and Aerospace Engineering
students on topics in the
fluids/thermal sciences, systems/design and mechanics/materials areas.
Seminar speakers will be invited
from outside the University as well as from inside the school. SEM.
MAE 507-508 Engineering Analysis 1, 2
Methods for the solution of boundary value and initial value problems
arising in engineering. Specific
topics will be selected on the basis of the interests of the students
enrolled, and may include:
Hilbert space and integral equations, perturbation techniques, potential
theory, Green's functions,
variational formulations, and advanced complex variables. LEC.
Prerequisite: Permission of instructor.
MAE 512 Dynamics of Real Gases
The influence of real gas properties on the nature of high-speed,
high-temperature flows is explored.
Equilibrium properties of gas molecules, atoms, ions and their mixtures
are developed using classical and
statistical thermodynamics. Rate processes characterizing molecular
vibration and chemical reaction are
treated using various combinations of kinetic theory, thermodynamics, and
the relaxation time
approximation. Several familiar gas dynamic flow are investigated
accounting for real gas behavior at
local thermodynamic equilibrium: shock waves, 1D-nozzles, Prandtl-Meyer
expansions, flat-plate boundary
layers. The complications involved in treating nonequilibrium behavior
are also discussed. LEC
Prerequisites: MAE 515, 516, 545, 546 or permission of instructor.
MAE 514 Evaluation of Biomedical Materials
This course serves multidisciplinary teams of students from a variety of
backgrounds. Detailed
discussions review the critical characteristics of specific materials
useful for various types of medical
and dental devices; selection criteria based on function and longevity;
performance testing in-vitro and
in-vivo; evaluation of material breakdown in biological media, and
potential toxicologic consequences;
design of clinical trials; surgical considerations; and regulatory and
legal issues. This course utilizes
each student's primary field of expertise as guide to specific topics of
biomaterials evaluation. A
"case study" midway through the course allows students to actually design
and promote a new implant
device for an unmet medical need, with particular attention to meeting
regulatory and marketing
requirements.
Crosslisted as: BMA 520
MAE 515 Fluid Mechanics 1
Vector and tensor notation; continuity equation; fluid kinematics and
stress/strain relations;
Navier-Stokes equations; general integral formulations; energy equations;
incompressible viscous flows at
low Reynolds numbers; boundary layer approximations. LEC.
MAE 516 Fluid Mechanics 2
A continuation of MAE 515. Laminar boundary layers; linear stability
theory and transition; turbulent
flow; inviscid potential flow; compressible flow. LEC.
Prerequisite: MAE 515 of permission of instructor.
MAE
517 Applied
Orthopaedic Biomechanics
Design of implants and prosthetics in relation to the biomechanics of the
musculoskeletal system. Topics
include bone physiology, testing methods (tension, compression, bending,
torsion, shear, and fatigue,
including nondestructive testing), strain gage application, composite
theory of bone, stress fractures
and fatigue properties in the musculoskeletal systems, fracture healing
external/internal fixation (AO,
Ilizarov etc.), aging and osteoporosis, pathology of osteoarthritis, joint
replacement and arthroplasty,
and spine biomechanics.
MAE 518 Electrodynamics of Fluids
This course is intended to provide an introduction to the electrodynamics
of fluids and particles at the
graduate level. Topics include Maxwell's equations, electromagnetic
forces and energy, elementary
plasma theory, MHD and EHD flows, electromagnetic effects on heat and mass
transfer, dynamics of charged
suspensions, and various applications. LEC.
Prerequisite: Undergraduate courses in electromagnetic theory and fluid
mechanics.
MAE 519 Turbulent Flow
A brief review of fluid mechanics will be followed by an introduction to
the phenomena of instability and
transition to turbulence. The bulk of the course will then focus on the
study of turbulence. Receiving
special emphasis will be the energetics of turbulent flow, the
multiplicity of scales of motion, and the
tendency of turbulent flows toward equilibrium and self?preserving states.
The course should be of
interest to anyone interested in aerodynamics, convective heat transfer
and fluid mechanics. Course
crosslisted as CIE 561. LEC.
Prerequisite: Course in Fluid Mechanics.
MAE 520 Biomechanics of the Musculoskeletal System
Basic aspects of anatomy; forces transmitted in the body; bones as
structural members; joint and muscle
forces. Kinematics of body motions; instantaneous centers of joint
motions; behavior of normal and
abnormal joints; remodeling. Biomaterials; ligaments and tendons.
Functions of orthotics and prostheses;
design considerations. The course includes a weekly seminar and one or
two laboratory sessions. LEC/SEM.
Prerequisite: EAS 205, EAS 206, or equivalent.
MAE 522 Heat Exchanger Design
Classification of heat exchangers, overview of heat exchanger design
procedure, log mean temperature
difference and exchanger effectiveness, number of transfer units analyses,
exchanger pressure drop
analysis, surface basic heat transfer and flow friction characteristics,
experimental correlations and
theoretical solutions, special design considerations to regenerators,
plate-fin, tube-fin and
shell-and-tube exchangers; heat exchanger surface selection and
optimization; flow distribution and
header design; heat exchanger fouling; flow-induced vibrations; and
transient response of heat exchangers. LEC.
Prerequisite: Undergraduate training in mechanical engineering fluid
mechanics and heat transfer.
MAE 523 Theory of Turbomachinery
Similarity considerations; dimensionless performance characteristics;
Reynolds number and scale effects;
thermodynamics and fluid mechanics of turbomachinery; energy transfer in
turbo-machinery; one-, two-,
and three-dimensional analysis of inviscid flow in turbomachinery; loss
mechanisms; performance
characteristics of radial and axial flow fans, pumps, compressors, and
turbines.
MAE 524 Elasticity
A rigorous introduction to the theory and application of classical
elasticity theory. Tensor analysis,
stress, deformation, strain and elastic constitutive equations. The field
equations of elasticity.
Uniqueness theorem. Formulation and solution of boundary value problems,
including bending, torsion,
plane strain and plane stress. Same as CIE 621. LEC.
MAE 525 Plates and Shells
"Exact" theories of plates and shells. Static and dynamic models.
Rational approximations. "Improved"
and classical theories. Relation of approximate plate and shell models to
elasticity solutions.
Boundary value problems in plate and shell theories. Anisotropic and
sandwich plates and shells.
Initially stressed plates. Stability considerations, linear and
non?linear models. Also listed as
CIE 517. LEC.
Prerequisite: MAE 524 or equivalent, or permission of instructor.
MAE 529 Finite Element Structural Analysis
This course is intended to bridge the gap between the theory and
application of finite element modeling.
At the end of the course the student will be able to judge if a problem is
appropriate for finite
element analysis, will know how to determine the model type, will be able
to determine the type of
elements to use and how many, and will have the background to judge the
accuracy of the results obtained.
These practical skills are difficult to acquire in a strictly theoretical
course. Specific topics will
include: fundamentals of FEM, basic input data required, definition of the
problem, the finite element
model, debugging the model, element performance and distortion, use of
refined mesh modeling and
substructuring, dynamic FEM, application for thermal analysis, and
calibrating the accuracy of finite
element models. LEC.
MAE 530 Aerosol Mechanics
Studies of the physical and dynamic behavior of aerosol particles in the
atmospherical environment with
application to gas cleaning, cloud physics, and air-pollution control
problems. Topics discussed
include: the formation of disperse systems; the particle size
distribution function; mechanism of
condensation and coagulation of aerosols; rectilinear and curvilinear
motion of aerosol particles;
theories of convective diffusion, impaction and sedimentation in flow
systems; theories of aerosol
filtration and experimental measurements of particle size distribution and
chemical composition. LEC.
MAE 534 Combustion
Examines the fundamentals of combustion. Topics will include
thermophysical calculations, chemical
kinetics, premixed and diffusion combustion phenomena. Specific subject
matter will range from
homogeneous gas phase combustion to heterogeneous droplet and particle
combustion. The fluid mechanics
of chemically reacting flows will be discussed with an emphasis on
turbulent combustion. A variety of
current applications will be presented. LEC.
Prerequisite: MAE 515 or MAE 546 or equivalent.
MAE 536 Random Vibrations and Stochastic Structural
Dynamics
Review of probability theory. A description of random processes and their
origin. Linear structures
with one and several degrees of freedom. Continuous structures.
Non-linear structures. Also listed as
CIE 520. LEC.
MAE 538 Smart Materials
This course introduces the students to smart materials, which refer to
materials that can sense a certain
stimulus and, in some cases, even react to the stimulus in a positive way
so as to counteract negative
effects of the stimulus. Emphasis is on strain/stress sensors and
actuators. Topics include electrically
conducting materials, piezoelectric and electrostrictive materials,
magnetostrictive materials,
electrorheological and magnetorheological fluids, electrolytic polymer
gels, shape memory materials,
intrinsically smart structural materials, optical fibers and photoelastic
materials. LEC
MAE 539 Heating, Ventilation and Air-Conditioning
Review of psychrometrics; physiological factors; heating and cooling load
calculations; refrigeration
methods and applications to air conditioning; cryogenic methods; fan and
duct analyses; solar energy
applications. LEC.
MAE 540 Computational Fluid Mechanics
Numerical methods currently available for solving various types of field
flow problems. Flow fields
described by elliptic, parabolic and hyperbolic systems of partial
differential equations. Solution
techniques for finite difference methods, particle-in-cell method, method
of characteristics and finite
element method. Computer program development for the numerical solution
of two dimensional
Navier-Stokes equations, boundary layer equations and equations of
supersonic inviscid gas dynamics.
Also listed as CIE 548. LEC.
Prerequisite: Permission of instructor.
MAE 541 Topics in Finite Element Analysis
Advanced topics in finite element analysis including but not necessarily
limited to mathematical
foundations, linear transient analysis, basic non-linear analysis -
material properties and geometric
non-linearities, error estimation and adaptivity, advanced solution
techniques, and special problems
e.g. incompressible materials, thin structures. Course will involve
extensive project work on realistic
applications.
Prerequisite: Consent of instructor.
MAE 542 Engineering Applications of Computational Fluid Dynamics
This course is intended for seniors and beginning graduate students
interested in computer based analysis of
engineering problems in fluid mechanics and heat transfer. Application of
computer analysis to engineering design of
fluid/thermal systems will be emphasized. Students need not have a
graduate level background in fluid mechanics or heat transfer, however, an
undergraduate level is necessary. The general governing equations and
methods to solve them, including;
finite-difference, finite-volume, panel methods, and finite element
methods, will be surveyed. Introduction to the use of state-of-the-art
computer
tools for analysis and graphical representation of results will give the
student a broad view of computational fluid
mechanics for engineerin applications in the fluid/thermal sciences. This
course is particularly suited for Masters of Engineering students.
LEC.
Prerequisite: MAE 335, MAE 336, MAE 376, FORTRAN.
MAE 543 Continuous Control Systems (Lec and Lab)
Transfer function representation of dynamic systems, concepts of feedback
control, block diagrams, computer simulation
of control systems. Analysis and implementation of electro-mechanical,
electronic and hydraulic control systems. Time
domain analysis
with respect to speed of response, overshoot, steady state error, and
stability. Root locus plots, basics of
frequency response in control analysis and dynamic compensation. LEC/LAB
MAE 544 Digital Control Systems (Lec and Lab)
Control of dynamic systems by digital computer. Characterization of
discrete-time systems, discrete state space, Z
transforms, time domain analysis of discrete-time control systems.
Effects of sampling time. Discrete root locus.
Frequency domain methods for compensator design. Laboratory experiences in the computer control
of electromechanical systems with C/C++
programming, LabView and programmable logic controls (PLCs). LEC/LAB
MAE 545 Heat Transfer 1
Development of the equations for mass, momentum, heat and entropy
transport with emphasis on the first and second laws
of thermodynamics. Discussion of the constitutive laws for conduction and
radiation. Conduction: steady-state,
transient, 1-D and
multidimensional, moving boundary; method of Froebenius, separation of
variables, transform techniques, similarity;
approximate physical models and solution methods. Radiation: basic
physical concepts, definition of intensity,
blackbody radiation, properties of real materials, models of radiative
properties, absorbing, emitting and scattering media, enclosure analysis.
LEC.
MAE 546 Heat Transfer 2
Forced convection: governing equations for laminar and turbulent flows,
similarity analysis, flow and heat transfer in tubes, boundary layer
theory,
heat transfer in external flows, temperature dependent properties, and
high
speed applications. Natural convection: Boussinesq and other
approximations,
boundary layer equations for laminar and turbulent flows, similar and near
similar solutions, horizontal and inclined surfaces, transient flows, and
combined forced and natural convection regimes. Condensation and boiling:
physics of the phenomena, correlations. LEC.
Prerequisite: MAE 545 and MAE 515 helpful but not absolutely required.
MAE 547 Radiation Heat Transfer
Physical concepts: photons/electromagnetic waves, intensity, blackbodies,
directionality, spectra. Properties of
real materials: EM theory, dispersion theory. Radiation exchange between
surfaces. Multimode energy transfer.
Fundamentals of absorbing, emitting and scattering media. Exact and
approximate solutions to the equation of radiative transfer. Engineering
approaches to radiation in enclosures. Applications to combustion,
atmospheric radiation and various energy systems.
LEC
MAE 548 Issues in Concurrent Design
(offered alternate Spring semesters with MAE 552-Heuristic Optimization)
Current interest in incorporation of quality and manufacturing concerns in
the early stages of the design process has
resulted in such concepts as Concurrent Engineering, Total Quality
Management, Quality Function Deployment, Robust
Design, Traguchi's Quality Functions, Teaming Approaches for Complex
Design, and many others. The course will address these concepts --
particularly as they pertain to complex engineering systems. Industrial
case studies will be investigated and design
projects incorporating some or all of the above concepts will provide
first-hand experience. As teamwork will be emphasized, good
communication skills are essential. LEC
Prerequisite: Programming and communication skills.
MAE 549 Design of Complex Engineering Systems
The design of complex engineering systems such as aircraft or automobiles
requires the interaction of multiple
designers, design teams, and their associated computer tools. In this
course, methods and tools to model
interactions, cooperation, and communication are investigated using
industrial and social design examples. In addition, issues in
optimization, decision
support, design theory, and concept exploration will be investigated.
No prerequisite.
MAE 550 Optimization in Engineering Design
Optimization techniques with applications in various aspects of
engineering design. Concepts of design variables,
constraints, objective functions, penalty functions, Lagrange multipliers.
Techniques for solving constrained and
unconstrained optimization problems: classical approaches, steepest
descent, conjugate directions, conjugate gradient, controlled random
searches, etc. Discussion of generalized reduced gradient, sequential
linear programming, and recursive quadratic
programming strategies.
Computer implementation of optimization schemes. Applications and
examples in the design of engineering components
and systems. LEC.
Prerequisite: Graduate standing and knowledge of FORTRAN.
MAE 551 Advanced Design Theory
In this course, a number of advanced theories, methods, and approaches to
the design of systems and products are
covered and researched. These topics include but are not limited to
Systematic Design, Total Design, Theory of
Technical Systems, Design Failure Paradigms, Decision-Based Design, Game
Theory, Axiomatic Design, Multiobjective Optimization and Product Family
Design. The topics are discussed and researched in groups using case
studies from both modern and historical design
examples.
MAE 552 Heuristic Optimization
Topics for this class include heuristic-based Optimality Criteria methods,
some newer discrete and integer programming
approaches (e.g. Tabu Search, Genetic Algorithms, Simulated Annealing),
multi-level hierarchical approaches, complex
non-hierarchical
methods (such as are used in multidisciplinary design problems and for
IPPD-Integrated Product and Process
Development), Geometric Programming methods, some Taguchi approaches, and
fuzzy logic. This course addresses
optimization topics not covered in
Optimization in Engineering Design (MAE 550) and does NOT require MAE 550
as a prerequisite.
MAE 553 Inelastic Stress Analysis
Physical basis of inelastic behavior of materials. Careful development of
inelastic constitutive laws --
thermoelastic, viscoelastic, plastic, nonlinear creep, viscoplastic.
Applications -- flexure of beams, torsion of
bars, plane strain, plane stress. LEC.
MAE 554 Road Vehicle Dynamics
Forces and torques generated by tires (under both traction and braking)
and by the relative wind; Two-wheel and
Four-wheel models of a vehicle; simplified stability and control of
transients; steady-state response to external
disturbances; effects of the roll degree of freedom; equations of motion
in body-fixed coordinates; lateral load transfer; Force-Moment analysis;
applications of feedback-control theory to the design of subsystems for
improved performance.
MAE 555 Continuum Mechanics
Definitions of stress, strain, and rotation for finite and infinitesimal
theory; global and local forms of
conservation laws of mass, momentum, moment of momentum, and energy; use
of the second law of thermodynamics in the
development of constitutive laws;
presentation of constitutive laws for isotropic and anisotropic linear
elastic, thermoelastic, linear viscous,
viscoelastic, and plastic materials.
MAE 558 Tribology
An introduction to friction, lubrication and wear. Contact of real
surfaces, mechanics of friction, surface failures,
boundary lubrication, fluid properties, thin film lubrication, thick film
lubrication, bearing and lubricant
selection. LEC.
Prerequisite: Permission of instructor.
MAE 559-560 Thesis (1-6 credits)
For Master of Science candidates. Approval of the thesis advisor is
required for registration. TUT.
MAE 562 Analytical Dynamics
Review of Newtonian mechanics for systems of particles. Lagrange's
equations of motion for conservative and
nonconservative systems. Variational mechanics and Hamilton's principle.
Application to various nonlinear problems
and specifically to the two-body problem and celestial mechanics. The
kinematics and dynamics of rigid bodies ?? Euler's equations of motion.
Application to gyroscopic motion. Introduction to Hamilton's equations of
motion. The linearized theory of small
oscillations and associated matrix formulations. LEC.
MAE
563
Plasticity
Review of basic experiments in solid mechanics, stress, strain,
stress?strain relationships. Plastic behavior. Yield criteria.
Flow law. Limit analysis. Applications to simple structures relevant to
mechanical and aerospace engineering.
Extrusion. Metal forming. LEC.
MAE
564 Manufacturing
Automation
Rapid growth of automation has been a strong motivation for engineers to
acquire skills in the area of Computer Aided
Manufacturing and Design. This course will serve as an introduction to
the theory of automation as related to
manufacturing and design integration. We will look at various hardware,
software and algorithm issues involved in fast and flexible product
development cycles. Following strategies of automated manufacturing
systems will be covered: CAD-CAM: integration,
programming and simulation; Robotics: applications in welding, material
handling and human intensive processes; Reverse Engineering: modeling
product from laser and CMM data of parts; Virtual Environments: industrial
applications of virtual reality and
prototyping; Intelligent Diagnostics: sensor fusion for machine tool
monitoring; Automated Inspection: computer vision and methods of automated
quality control; Design for Manufacturing: issues involved in concurrent
product development.
Prerequisite: MAE 477 or equivalent, background in manufacturing.
MAE 565 Environmental Acoustics
Introductory course in acoustics and acoustical phenomena. Fundamentals
of vibration (wave motion), general treatment
of string and diaphragm motion, acoustic plane and spherical waves,
transmission and absorption, resonators and
filters, speech, hearing
and noise ("noise pollution"), aircraft noise, traffic noise, effects on
man. Laboratory work will consist of
individual experiments, demonstration experiments, and field measurements.
LEC.
Prerequisite: Permission of instructor.
MAE 567 Vibration and Shock 1
Introduction to topics in the analysis of vibrating systems of lumped
parameters. Modal analysis and synthesis.
Matrix and computer procedures. Single degree of freedom free and forced
response. Absorber and isolator design.
LEC.
For students who did not take vibrations as an undergraduate.
MAE 568 Vibration and Shock 2
Continuation of MAE 565. Vibration of distributed parameter and parameter
systems; modal testing; nonlinear systems;
finite elements. LEC.
Prerequisite: MAE 565.
MAE 570 Thermodynamics of Materials
Review of Classical Thermodynamics using the formalism based on the
Entropy Maximum Postulates; and, an introduction
to Statistical Thermodynamics. Application of the basic principles to the
determination of properties of single and
multicomponent systems. Physical models of atomic and molecular behavior
(gas, liquid and solid states), and electric, magnetic and
electromagnetic phenomena. Stability, phase transitions and critical
points. Chemical reactions, structural changes
and surface phenomena. LEC
MAE 571 Systems Analysis 1
Development of mathematical techniques for the analysis of systems in the
time domain. Introduction to state space
concepts. Review of matrices and vectors. Vector spaces. Coordinate
transformation. Jordan canonical form.
State-space representation
of control systems. Solutions of state space equations. Controllability
and observability. Feedback control
structures. LEC.
Prerequisite: Graduate standing.
MAE 573 Graphics in Computer-Aided Design
A course emphasizing the basics of computer-aided design (CAD) for
mechanical engineers. Interactive computing in the
design process. The role of graphics in CAD. Two-dimensional graphics;
computer graphic operations, including curve
generation and splines. Three-dimensional graphics, including data
structures, rotation, translation, reflection, isometric and
perspective projection, hidden line removal, shading, surface generation,
solid modeling concepts, object-oriented
programming. LEC/LAB.
Computer programming projects in C and C++.
MAE 574 Virtual Reality Applications and Research
Virtual reality refers to techniques used to synthesize real world by
recreating its physical, visual and audio models
and representations. In this course we will study this field and review
various applications and research issues
extensively. We will also learn interactive computer graphics programming
techniques using OpenGL which is a preferred graphics programming
API environment. The following broadly describes the topics: concepts in
interactive computer graphics, programming
in OpenGL/GLUT, intro to world tool kit libraries, virtual reality
hardware and software and application and research in virtual
reality.
Prerequisite: MAE 473/573 or equivalent. Students are required to have
good programming knowledge in C or C++.
NOTE: This is not an introductory course in computer graphics.
MAE 577 Computer-Aided Design Applications
Engineering design and analysis using state-of-the-art computer software
tools. Emphasis on the overall product
development cycle and simultaneous engineering, including conceptual
design, variational geometry, representation,
creation and manipulation
of solid models, assembly design integrated kinematic and finite element
analyses, re?design, geometric dimensioning
and tolerancing, and NC programming. LEC/Software component is a part of
this course.
Prerequisite: Permission of instructor.
MAE 578 Cardiovascular Biomechanics
Introduction of the mechanical behavior of the cardiovascular system;
basic physiology; application of engineering
fundamentals to obtain quantitative descriptions; major topics include
rheology of blood, blood flow in arteries and
veins, mechanics of
cardiac muscle, contraction of the heart, and control of the circulation.
LEC.
Prerequisite: First undergraduate courses in fluid and solid mechanics.
MAE 579 Cerebrovascular Hemodynamics
Introduction to the mechanical behavior of the cerebrovascular system;
application of engineering fundamentals and
tools to obtain quantitative descriptions; major topics include
cerebrovascular anatomy, structure and mechanics,
cerebrovascular pathology, cerebrovascular autoregulation, MRI (brain
imaging) MRA (vascular imaging), and MR Flow measurements. Transcranial
Doppler (TCD), Ultrafast CT, Ultrafast Spiral CT and novel flow
measurements. Intracranial & vascular pressure
measurements.
Prerequisite: MAE 478/578
MAE 580 Pulmonary Biomechanics
Introduction of the mechanical behavior of the pulmonary system: basic
physiology; application of engineering
fundamentals to obtain quantitative descriptions; major topics include
mechanics of breathing, air flow in the lung,
alveolar ventilation,
pulmonary circulation, alveolar gas exchange, control of respiration.
LEC.
Prerequisite: First undergraduate courses in fluid and solid mechanics.
MAE 581 Advanced Materials Science
Crystal structure: lattice and basis, types of lattice, reciprocal
lattice, index system for crystals, polytypism.
Crystal binding: Van der Waals, Covalent, ionic, and metallic, equilibrium
lattice constants. Deviation from ideal
crystal structure:
point, line and planar defects, point defects in ionic crystals,
equilibrium point defect density. Effect of defects
on material properties: structure sensitivity. Phases in a n-component
system: phase and phase diagrams for a
n-component systems, phase equilibrium, phase rule, ideal and non-ideal
solid solutions and derivation of their free energy, level rule, ordered
and disordered phases, superlattices. Nucleation and growth: embryo and
nucleus during phase growth and resulting
microstructure. Phase transition: first and second order phase
transition, diffusionless and diffusion-assisted phase transitions.
Concept of degenerate variants: twins as domains in a phase transition and
their effect on mechanical properties,
twin-equivalent phase inferromagnetic
and ferroelectric phases, domains as basis for functional materials.
LEC
Prerequisites: MAE 381 and MAE 382, or equivalent.
MAE 582 Introduction to Composite Materials
Provide a basic understanding of polymeric, metallic, and ceramic
composite materials - manufacturing and mechanical
properties. Behavior of unidirectional and short fiber composites;
analysis of laminated composites; performance of
composites including
fracture, fatigue and creep under various conditions; fracture modes of
composites; manufacturing considerations;
microstructural modeling; experimental characterization. LEC-Fall.
MAE 583 Mechanics and Design Using Composite Materials
An advanced level of structural analysis and design, with an emphasis on
composite materials; general anisotropic
stiffness/compliance relations, their transformations and symmetries;
effective properties for sheet/injection molded
composites; lamination
theory; simplified plate and beam equations, with solutions for
deformation and stress; strength, fracture and
reliability; joining; other topics as time permits. A limited review of
materials concepts is given as needed.
Includes use of available computer methods. LEC
MAE 584 Principles and Materials for Micro-Electro-Mechanical
Systems (MEMS)
Current interest in micro-electro-mechanical systems of MEMS is driven by
the need to provide a physical window to the
micro-electronics systems, allowing them to sense and control motion,
light, sound, heat, and other physical forces.
Such micro-systems that integrate micro-electronics and sensing elements
on the same chip presents an interesting engineering problem in
terms of their design, fabrication, and choice of materials. This course
will address the design, fabrication, and
materials issues involving MEMS. These issues will be addressed within the
context of MEMS for mechanical sensing and actuation, magnetic
devices, thermal devices, automotive applications, and Bio-MEMS for
biomedical applications. LEC
MAE 585 Mechanical Properties of Materials
Relationship between the microstructure of materials and their macroscopic
properties; topics include strength and
modulus, hardness, fatigue, creep and plasticity, abrasion, impact,
elasticity, thermal stresses, strengthening
mechanism, and testing methods.
MAE 586 Fatigue and Fracture Mechanics
Failure by fatigue or brittle fracture of such important structures as
bridges, aircraft, ships, pressure vessels,
etc., is of grave consequence. Many design codes require safety against
such failures. Topics include fatigue
strength of plain or notched specimens and factors affecting it; low cycle
fatigue; fatigue under variable amplitude loading; fatigue of welded
structures; linear elastic stress analysis of cracks; fatigue crack growth
under constant or variable amplitude
loading. Introduction to elastic-plastic fracture mechanics. Also listed
as CIE 586. LEC.
Prerequisite: MAE 311.
MAE 587 Modern Theory of Materials
Fundamentals of modern theories of solids are developed. Topics include
reciprocal lattices, diffraction theory,
electron energy bands and phonon dispersion. LEC.
Prerequisite: PHA 208.
MAE 588 Materials Applications
This course covers structural, electronic, thermal, electrochemical and
other applications of materials in a
cross-disciplinary fashion, due to the multifunctionality of many
materials and the breadth of industrial needs. The
materials include metals, ceramics, polymers, cement, carbon and composite
materials. The topics are scientifically rich and technologically
relevant. Each topic is covered in a tutorial and up-to-date manner.
Prerequisite: MAE 381.
MAE 589 Diffraction, Microscopy and Spectroscopy
Techniques
This course introduces students to the theory and use of the most
important experimental techniques in materials
research. The techniques include X-ray and electron diffraction, optical
and electron microscopy, X-ray and electron
spectroscopy, Raman and
infrared spectroscopy, ion scattering and mass spectroscopy. LEC.
Prerequisite: PHA 208 or permission of instructor.
MAE 590 High Temperature Materials
Ceramics, carbons, metals and composite materials for high temperature
applications (including aerospace applications)
will be covered, with emphasis on ceramics and the relationships among
processing, structure, properties and
applications. LEC.
Prerequisite: MAE 381 or CE 433/534 or permission of instructor.
MAE 591 Project (1-6 credits)
For Master of Science candidates. Approval of advisor required for
registration. TUT.
MAE 592 Experimental Methods for Composite Materials
Brief review of appropriate analytical methods for thermoelastic and
strength properties of laminated and short fiber
composites; experimental evaluation of these properties, emphasizing the
methods unique to composites; specimen
preparation and testing
using suitable fixtures, mechanical testing machine, and data acquisition
system. LEC/LAB.
Prerequisite: Permission of instructor; Spring (odd-numbered years)
MAE 595 Frontiers of Engineering Materials
Designed to provide the students with a broad perspective in the frontiers
of engineering materials. Each engineering
material (or class of materials) covered is at the frontier of technology.
Selections include metals, ceramics,
polymers and composite materials. The processing, structure, properties
and applications of each material are addressed. LEC
MAE 601-602 Individual Problems (1-12 credits)
For Doctor of Philosophy candidates. TUT.
MAE 609 High Performance Scientific Computing I
This course will introduce students to the fundamental ideas of scientific
computing on high performance
architectures. The principal objective of this course is to enable
students to use high performance computers in all
aspects of scientific computing
to support research activities. At the end of the class, you should be
able to: design and implement efficient
algorithms for high performance computing related to a variety of research
areas, use MPI, OpenMP and other special
tools used to program larg
e multi-processor computers, understand the basic operating principles of
these machines, and, analyze the performance
of your codes.
MAE 610 High Performance Scientific Computing II
Introduction to fundamental ideas of scientific computing, with particular
attention given to algorithms that are
well-suited to high performance computer architectures. Concentration on
scientific computing in applications,
including stochastic methods,
FFTs, and finite element and finite difference methods. LEC
Prerequisite: MAE 609
MAE 617 Inviscid Incompressible Flow
Kinematics of fluid motion, stream function. Irrotational flow, velocity
potential. Rotational flow, vortex motion.
Kinematics of fluid flow, equations of motion, Bernoulli's theorem.
Boundary conditions. Momentum integral and
energy integral methods
. Fluid forces, Blasius theorem, virtual mass. Method of singularities,
images, analytical solutions, conformal
transformation, approximate methods. LEC.
Prerequisite: MAE 515 and 516
MAE 618 Viscous Flow
Review of Navier-Stokes equations, classical solutions. Stokes flow over
spheres, bodies of arbitrary shape.
Singularity Methods, effects of Brownian motion. Unsteady viscous flows,
acoustic streaming. Stability of viscous
flows. Triple-deck structur
e, transformation methods for boundary-layer flows. LEC.
Prerequisite: MAE 515 and 516
MAE 631 Compressible Flow
Governing equations for inviscid compressible flow of perfect gases; wave
phenomena in one-dimensional unsteady flows;
basic approximations and applications for steady flows in the subsonic,
transonic, supersonic, and hypersonic regimes,
including flow
similitudes, imperfect gas effects at hypersonic speeds; viscous and
aerodynamic heating effects, including
compressible laminar boundary layers and shock-wave boundary layer
interactions.
Prerequisites: MAE 516 and PHD status.
MAE 659-660 Dissertation (1-12 credits)
For Doctor of Philosophy candidates. TUT
MAE 670 Nonlinear Control
The focus of this course is on nonlinear system analysis, and synthesis of
nonlinear controllers. This includes:
phase plane analysis for second order systems, Lyapunov direct method to
analyze autonomous and non-autonomous
systems, describing function
method to analyze nonlinear systems. The design of controllers robust to
structured and unstructured uncertainties
include: sliding mode controller adaptive controllers, and feedback
linearization control. LEC
MAE 671 Nonlinear Systems
A first course in the theory of nonlinear dynamical systems. Topics
included are: point attractors, limit cycles,
linear and nonlinear resonance, Poincare map, self exciting system,
chaotic attractors in forced oscillators,
stability and bifurcations,
Liapunov stability and structural stability, center manifold theorem,
local bifurcations, incipient instability,
iterated maps and their stabilities, the geometry of recurrence, the
Lorenz system, Lorenz attractor, transition to
chaos, Rossler's band,
Smale's horseshoe map, homoclinical trajectories, bifurcations and chaotic
attractors. LEC
Prerequisite: Graduate standing.
MAE 672 Optimal Control Systems
Parametric optimization. Variational methods in system optimization.
Hamiltonian function. Dynamic programming.
Pontryagin Maximum Principle. Synthesis of linear optimum control
systems. Nonlinear optimum control systems.
LEC.
Prerequisite: MAE 571 or MAE 673.
MAE 673 Structural Dynamics and Control
Modeling of distributed parameter systems using Hamilton's principle.
Discretization using the assumed mode method
and the finite element method. Lypunov based design of controllers.
Linear Quadratic Controller and Robust
Eigenstructure assignment tech
niques. Techniques to quantify degrees of Controllability and
Observability.
MAE 674 Optimal Estimation Methods
Introduction to linear and nonlinear estimation methods with emphasis on
both theory and implementation. Batch and
sequential strategies, real?time and post?experiment estimation are
covered. Includes both parameter estimation and
state estimation. LEC
.
Prerequisite: Some exposure to linear systems, probability, and
optimization is helpful, or permission of instructor.
COURSES (Prefix SYS)
All courses are three credits unless otherwise noted.
SYS 521 Signal and Image Processing
This course deals with modern computer techniques for processing images.
Topics discussed are related to image data
compression for transmission of image data, image restoration and
enhancement and image analysis. The course
demonstrates the application
s of computer techniques in this relatively new field. LEC/LAB.
Prerequisite: Senior standing.
SYS 522 Advanced Image Processing
Edge detection - Man-Hildreth edge operator and other operators;
quantitative criteria for performance study. Image
segmentation ? optimality criterion, context information, color image
segmentation. Texture?Structural and Stochastic
models of texture.
2-D shape coding and representation, as well as some discussion on 3-D
representation. Motion detection, including
optical flow, motion parameters from optical flow and passive navigation.
Character recognition. LEC.
SYS 585 Applied Nonlinear Control
Nonlinear system analysis, and design and application of nonlinear system
controllers: Phase plane analysis for
second order systems, Lyapunov direct method to analyze autonomous and
non-autonomous systems. Describing function
method to analyze nonlinea
r systems. Design of controllers robust to structured and unstructured
uncertainties: sliding mode controller and
adaptive controllers. Feedback linearization control. LEC.
Prerequisite: SYS 435 or permission of instructor
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