Mechanical and Aerospace Engineering
Mackenzie Building 3135
Telephone: 613-520-5684
Fax: 613-520-5715
www.mae.carleton.ca
The Department
Chair of the Department: Jonathan Beddoes
Associate Chair (Graduate Studies): Andrei Artemev
The following graduate degree programs are offered by the
Department of Mechanical and Aerospace Engineering:
- Masters of Applied Science Aerospace Engineering
- Masters of Applied Science Biomedical Engineering
- Masters of Applied Science Materials Engineering
- Masters of Applied Science Mechanical Engineering
- Masters of Engineering Aerospace Engineering
- Masters of Engineering Materials Engineering
- Master of Engineering Mechanical Engineering
- Doctor of Philosophy Aerospace Engineering
- Doctor of Philosophy Mechanical Engineering
The requirements for completion of the Aerospace, Materials
and Mechanical Engineering degrees are summarized in the
Ottawa-Carleton Institute for Mechanical and Aerospace
Engineering section of this calendar.
The M.A.Sc. in Biomedical Engineering is offered in
cooperation with the Department of Systems and Computer
Engineering, the School of Computer Science and the Department
of Physics. For further information, see the Ottawa-Carleton
Institute for Biomedical Engineering section in this
Calendar.
Research in the Department spans the spectrum of mechanical
and aerospace engineering, with a focus on:
- applied dynamics
- aerodynamics and fluid mechanics
- aero-structures
- bio-medical engineering
- combustion and heat transfer
- materials and manufacturing processes
- solid and fracture mechanics
- robotics, controls, guidance and navigation
- digital image processing
- space and satellite technologies
Cross-disciplinary research within Mechanical and Aerospace
Engineering focuses on specific application issues, research on
advancing gas turbine technology being one major and
longstanding example. The department's gas turbine technology
program originated nearly 40 years ago with some of the
department's first faculty members, who had extensive gas
turbine industrial experience. This research effort is arguably
one of the largest and most effective university-based gas
turbine technology research groups today. This research
includes the following core topics:
- internal aerodynamics
- combustion
- system design and performance,
- high temperature materials and coatings technology
- repair and overhaul methods and procedures
This research is supported with collaboration from external
research institutions, major Canadian and foreign suppliers,
manufacturers, users, and repair and overhaul companies.
Other cross-disciplinary application-specific research areas
include:
- unmanned aerial vehicle technology including design,
performance, aerodynamics, and navigation and control,
- simulation of vehicle performance,
- vehicle simulation for training, including graphics
database management, projection, kinematic and dynamic
modeling, washout, and control of motion platforms
- fatigue and fracture mechanics research
- bio-medical engineering and design of medical
devices
- two-phase flows in applications ranging from heat pipes
to refrigeration cycles
- design and implementation of numerical methods for
stress analysis, heat transfer, computational fluid
dynamics, materials processing and vehicle simulation
- rotorcraft, structures, dynamics, aerodynamics and
aeroelasticity
Extensive activity and expertise in computer-aided analysis
supports this research, including computational fluid dynamics
and finite and boundary element methods, computer-aided design
and computer-integrated manufacturing.
The Department maintains extensive laboratories equipped
with a wide range of specialized equipment. Research facilities
include several wind tunnels including a transonic blowdown
wind tunnel, a Bridgman vacuum furnace, fully operational gas
turbine engines, servo-hydraulic materials testing equipment,
extensive machine shop capability and an air plasma spray
facility. To complement this research equipment, faculty
maintain strong collaborative research links with many external
government and industrial research centres allowing access to
additional specialized equipment and facilities.
Several computer networks support departmental research,
with an extensive array of design, analysis and simulation
software. Access is also available to the High Performance
Computing Virtual Laboratory (HPCVL) jointly operated by
Carleton University, The Royal Military College, Queen's
University and the University of Ottawa. In 2002, HPCVL was
ranked among the fastest 200 computers in the world, and is
upgraded on an ongoing basis.
Graduate Courses
Not all of the following courses are offered in a given
year. Consult the Ottawa-Carleton Joint Institute for
Mechanical and Aerospace Engineering (OCIMAE) website for
course offerings: www.ocimae.ca.
University of Ottawa course numbers (in parentheses) follow
the Carleton course number and credit information.
- MECH 5000 [0.5 credit] (MCG 5300)
- Fundamentals of Fluid Dynamics
- Differential equations of motion. Viscous and inviscid
regions. Potential flow: superposition; thin airfoils;
finite wings; compressibility corrections. Viscous flow:
thin shear layer approximation; laminar layers; transition;
turbulence modeling. Convective heat transfer: free versus
forced convection; energy and energy integral equations;
turbulent diffusion. Also offered at the undergraduate
level, with different requirements, as AERO 4302, for which
additional credit is precluded.
- MECH 5001 [0.5 credit] (MCG 5301)
- Theory of Viscous Flows
- Navier-Stokes and boundary layer equations; mean flow
equations for turbulent kinetic energy; integral
formulations. Stability, transition, turbulence, Reynolds
stresses; separation. Calculation methods, closure schemes.
Compressibility, heat transfer, and three-dimensional
effects.
- MECH 5003 [0.5 credit] (MCG 5303)
- Incompressible Non-Viscous Flow
- The fundamental equations and theorems for non-viscous
fluid flow; solution of two-dimensional and axisymmetric
potential flows; low-speed airfoil and cascade theory; wing
lifting-line theory; panel methods.
- MECH 5004 [0.5 credit] (MCG 5304)
- Compressible Non-Viscous Flow
- Steady isentropic, frictional, and diabatic flow; shock
waves; irrotational compressible flow, small perturbation
theory and similarity rules; second-order theory and
unsteady, one-dimensional flow.
- MECH 5008 [0.5 credit] (MCG 5308)
- Experimental Methods in Fluid Mechanics
- Fundamentals of techniques of simulation of fluid
dynamic phenomena. Theoretical basis, principles of design,
performance and instrumentation of ground test facilities.
Applications to aerodynamic testing.
- MECH 5009 [0.5 credit] (MCG 5309)
- Environmental Fluid Mechanics Relating to Energy
Utilization
- Characteristics of energy sources and emissions into
the environment. The atmosphere; stratification and
stability, equations of motion, simple winds, mean flow,
turbulence structure and dispersion near the ground. Flow
and dispersion in groundwater, rivers, lakes and oceans.
Physical and analytical modeling of environmental
flows.
- MECH 5100 [0.5 credit] (MCG 5310)
- Performance and Economics of Aircraft
- Aircraft performance analysis with emphasis on factors
affecting take-off, landing and economic performance; high
lift schemes; operating economics.
- MECH 5101 [0.5 credit] (MCG 5311)
- Dynamics and Aerodynamics of Flight
- Static stability theory. Euler's equations for rigid
body motion; the linearized equations of motion; stability
derivatives and their estimation. Longitudinal and lateral
dynamic response of an aircraft to control and disturbance.
Also offered at the undergraduate level, with different
requirements, as AERO 4308, for which additional credit is
precluded.
- MECH 5104 [0.5 credit] (MCG 5314)
- Ground Transportation Systems and Vehicles
- Performance characteristics, handling and directional
stability, ride comfort and safety of various types of
ground vehicle systems including road vehicles,
terrain-vehicle systems, guided transport systems, and
advanced ground transport technology.
- MECH 5105 [0.5 credit] (MCG 5315)
- Orbital Mechanics and Space Control
- Orbital dynamics and perturbations due to the Earth's
figure, the sun, and the moon with emphasis on mission
planning and analysis. Rigid body dynamics applied to
transfer orbit and on-orbit momentum management and control
of spacecraft. Effects of flexible structures on a
spacecraft control system.
- MECH 5106 [0.5 credit] (MCG 5121)
- Space Mission Analysis and Design
- Review of solar system and space exploration. Space
mission design and geometry. Analysis of orbit design,
transfers, interplanetary trajectories. Effect of
environment on spacecraft design. Space propulsion and
launch vehicle design. Launch sequence, windows, cost.
Reusable launch systems.
Also offered at the undergraduate level, with different
requirements, as AERO 4802.
- Precludes additional credit for MAAE 4906 (Section B)
if taken between 1994-1995 and 2003-2004 inclusive, MECH
5805 taken between 2002-2003 and 2003-2004 inclusive, MAAE
5700 (Section L) taken between 1994-1995 and 1996-1997
inclusive, and MAAE 5805 taken between 1999-2000 and
2001-2002 inclusive.
- MECH 5107 [0.5 credit] (MCG 5317)
- Experimental Stress Analysis
- Introduction to theory of elasticity. Photo-elasticity:
types of polariscopes, two- and three-dimensional stress
fields, frozen patterns. Photoelastic coatings. Strain
gauges; gauge factors, sensitivity, calibration, and
temperature compensation. Moire fringes, brittle lacquers,
mechanical strain gauges.
- MECH 5201 [0.5 credit] (MCG 5321)
- Methods of Energy Conversion
- Technical, economic and environmental aspects of
present and proposed large-scale systems of energy
conversion.
- MECH 5202 [0.5 credit] (MCG 5122)
- Smart Structures
- Structural dynamics principles: modal analysis and wave
propagation. Linear time invariant systems: feedback,
feedforward, SISO, MIMO, digital and adaptive filters.
'Smart' Structures: multifunctional materials, collocation
principles, geometric filtering, and control authority.
Applications in aero-acoustics and aeroelasticity.
- Precludes additional credit for MECH 5807 (if taken
2001-2002 to 2003-2004).
- MECH 5300 [0.5 credit] (MCG 5330)
- Engineering Acoustics
- Review of acoustic waves in compressible fluids;
acoustic pressure, intensity and impedance; physical
interpretation and measurement; transmission through media;
layers, in-homogeneous media, solids; acoustic systems;
rooms, ducts, resonators, mufflers, properties of
transducers; microphones, loudspeakers, computational
acoustics.
- MECH 5301 [0.5 credit] (MCG 5331)
- Aeroacoustics
- The convected wave equation; theory of subsonic and
supersonic jet noise; propeller and helicopter noise; fan
and compressor noise; boundary layer noise, interior noise;
propagation in the atmosphere; sonic boom; impact on
environment.
- MECH 5302 [0.5 credit] (MCG 5332)
- Instrumentation Techniques
- An introduction for the non-specialists to the concepts
of digital and analog electronics with emphasis on data
acquisition, processing and analysis. Topics covered
include operational amplifiers, signal processing, digital
logic systems, computer interfacing, noise in electronic
systems. Hands-on sessions illustrate theory and
practice.
- MECH 5304 [0.5 credit] (MCG 5334)
- Computational Fluid Dynamics of Compressible
Flows
- Solution techniques for parabolic, elliptic and
hyperbolic equations developed for problems of interest to
fluid dynamics with appropriate stability considerations. A
staged approach to solution of full Euler and Navier-Stokes
equations is used. Grid generation techniques appropriate
for compressible flows are introduced.
- MECH 5400 [0.5 credit] (MCG 5344)
- Gas Turbine Combustion
- Combustion fundamentals and gas turbine combustor
design. Combustion fundamentals include fuel evaporation,
chemistry of combustion, chemical kinetics and emissions
formation and introduction to computational combustion
modelling. Combustor design addresses the interrelationship
between operational requirements and combustion
fundamentals.
- Precludes additional credit for MECH 5800 (MCG 5480)
when MECH 5800 was offered with this topic.
- MECH 5401 [0.5 credit] (MCG 5341)
- Turbomachinery
- Types of machines. Similarity: performance parameters;
characteristics; cavitation. Velocity triangles. Euler
equation: impulse and reaction. Radial pumps and
compressors: analysis, design and operation. Axial pumps
and compressors: cascade and blade-element methods;
staging; off-design performance; stall and surge. Axial
turbines. Current design practice. Also offered at the
undergraduate level, with different requirements, as MECH
4305, for which additional credit is precluded.
- MECH 5402 [0.5 credit] (MCG 5342)
- Gas Turbines
- Interrelationship among thermodynamic, aerodynamic, and
mechanical design. Ideal and real cycle calculations. Cycle
optimization; turbo-shaft, turbojet, turbofan. Component
performance. Off-design performance; matching of
compressor, turbine, nozzle. Twin-spool matching.
- MECH 5403 [0.5 credit] (MCG 5343)
- Advanced Thermodynamics
- The course covers three major topics: review of
fundamentals from a consistent viewpoint, properties and
equations of state, and applications and special topics.
The third topic includes an introduction to statistical
thermodynamics.
- MECH 5407 [0.5 credit] (MCG 5347)
- Conductive and Radiative Heat Transfer
- Analytical, numerical and analog solutions to
steady-state and transient conduction heat transfer in
multi-dimensional systems. Radiative heat exchange between
black, grey, non-grey diffusive and specular surfaces,
including effects of athermanous media.
- MECH 5408 [0.5 credit] (MCG 5348)
- Convective Heat and Mass Transfer
- Analogies between heat, mass and momentum transfer.
Forced and free convection relations for laminar and
turbulent flows analytically developed where possible and
otherwise deduced from experimental results, for simple
shapes and in heat exchangers. Mass transfer theory and
applications.
- MECH 5500 [0.5 credit] (MCG 5350)
- Advanced Vibration Analysis
- General theory of continuous and discrete
multi-degree-of-freedom vibrating systems. Emphasis on
numerical techniques of solving complex vibrating systems,
with selected applications from aerospace, civil, and
mechanical engineering.
- MECH 5501 [0.5 credit] (MCG 5125)
- Advanced Dynamics
- Developing and applying the governing equations of
motion for discrete and continuous mechanical systems.
Includes Newton-Euler and Lagrangian formulations;
classical and finite element approaches for continuous
systems; and linear stability, frequency response, and
propagation solution methods.
- Precludes additional credit for MECH 5500 (if taken
2001-2002, 2002-2003).
- MECH 5502 [0.5 credit] (MCG 5352)
- Optimal Control Systems
- Review of transfer function and state-space system
descriptions. Elements of the optimal control problem.
Variational calculus. Optimal state feedback control.
Riccati equations. Optimal observers and Kalman-Bucy
Filters. Extension to discrete time systems including an
introduction to dynamic programming. Practical applications
are emphasized throughout the course.
- MECH 5503 [0.5 credit] (MCG 5353)
- Robotics
- The history of and introduction to robotics
methodology. Robots and manipulators; homogeneous
transformation, kinematic equations, solving kinematic
equations, differential relationships, motion trajectories,
dynamics. Control; feedback control, compliance,
servomotors, actuators, external and internal sensors,
grippers and vision systems. Microprocessors and their
application to robot control. Programming.
- MECH 5504 [0.5 credit] (MCG 5354)
- Guidance, Navigation and Control
- Guidance system classification, flight control systems,
targeting, target tracking, sensing. Modern multivariable
control analysis; design requirements, sensitivity,
robustness, perturbations, performance analysis. Modern
filtering and estimation techniques. Terrestrial
navigation; tactical air navigation (TACAN), star trackers
Guidance mission and performance. Aircraft, missile and
spacecraft guidance and control.
- MECH 5505 [0.5 credit] (MCG 5355)
- Stability Theory and Applications
- Fundamental concepts and characteristics of modern
stability definitions. Sensitivity and variational
equations; linear variational equations; phase space
analysis; Lyapunov's direct method. Autonomous and
nonautonomous systems; stability in first approximation;
the effect of force type on stability; frequency
method.
- MECH 5506 [0.5 credit] (MCG 5356)
- Neuro and Fuzzy Control
- Knowledge-based controllers. Fuzzy control:
mathematics, relations, operations, approximate reasoning.
Fuzzy knowledge base control and structure. Fuzzification,
inference engine, defuzzification. Nonlinear, adaptive
fuzzy control systems. Stability, Neuro-control:
processing, learning. Adaptation of artificial neural
systems: associative memories, algorithms, applications,
and network implementation. Neurofuzzy systems: industrial
applications.
- Precludes additional credit for EACJ 5709 (ELG
5196).
- MECH 5507 [0.5 credit] (MCG 5124)
- Advanced Kinematics
- Algebraic-geometry applications: kinematic calibration
of serial and in-parallel robots; kinematic synthesis of
planar, spherical, spatial mechanisms. Various
DH-parametrisations, Jacobian formulations. Topics in:
projective geometry; Cayley-Klein geometries;
Pl<0x00FC>cker line coordinates; Gröbner bases;
Grassmannians; kinematic mapping; Burmester theory.
Emphasis on practical applications.
- MECH 5601 [0.5 credit] (MCG 5361)
- Creative Problem Solving and Design
- Problem-solving processes and how they can be applied
in engineering design. Emphasis on learning methodologies
rather than accumulating information. Techniques can be
successfully applied in any engineering specialty. (Also
listed as IDES 5301.)
- MECH 5602 [0.5 credit] (MCG 5362)
- Failure Prevention (Fracture Mechanics and
Fatigue)
- Design of engineering structures to ensure against
failure due to fatigue or brittle fracture. Nature of
fatigue and brittle fracture; selection of suitable
material, geometry, and inspection procedures for the load
and environmental conditions.
- MECH 5603 [0.5 credit] (MCG 5381)
- Lightweight Structures
- Structural behaviour. Fundamentals of basic elasticity.
Energy methods of structural analysis. Bending, shear, and
torsion of open and closed multicell structures. Bending of
plates. Structural idealization and its effects on open and
closed sections. Structural stability.
- MECH 5604 [0.5 credit] (MCG 5364)
- Computational Metallurgy
- Development of microstructure in alloys in
solidification processes and post-solidification
processing. Nucleation and growth of solid phase. Formation
of a dendrite structure, macro and micro segregations. Pore
formation in castings. Thermodynamic and kinetics of phase
transformations and structure evolution in solid
alloys.
- MECH 5605 [0.5 credit] (MCG 5365)
- Finite Element Analysis I
- An introduction to the finite element methodology, with
emphasis on applications to heat transfer, fluid flow and
stress analysis. The basic concepts of Galerkin's method,
interpolation, numerical integration, and isoparametric
elements are taught using simple examples.
- MECH 5606 [0.5 credit] (MCG 5366)
- Finite Element Analysis II
- Time marching heat flow problems with linear and
nonlinear analysis. Static plasticity. Time-dependent
deformation problems; viscoplasticity, viscoelasticity, and
dynamic analysis. Isoparametric elements and numerical
integration are used throughout.
- MECH 5607 [0.5 credit] (MCG 5367)
- The Boundary Element Method (BEM)
- Integral equations. The BIE for potential theory and
for elastostatics in two-dimensions. Boundary elements and
numerical integration schemes. Practical applications.
- MECH 5609 [0.5 credit] (MCG 5123)
- Microstructure and Properties of Materials
- Essential microstructural features of metals and
alloys: crystal structure, dislocations, grain boundaries.
The importance of these features in controlling mechanical
properties is emphasized. Analytical techniques observing
microstructure in metals and other materials: TEM, SEM,
electron diffraction, spectrometry.
- Precludes additional credit for MECH 5804 (if taken
2002-2003, 2003-2004)
- MECH 5700 [0.5 credit] (MCG 5345)
- Surfaces and Coatings
- Surface characteristics of solid materials and surface
degradation/failure mechanisms including wear, fretting,
oxidation, corrosion, and erosion are introduced. Coating
methods including PVD, CVD, laser, thermal spray and
electrochemical deposition are discussed in the context of
failure prevention measures.
- MECH 5701 [0.5 credit] (MCG 5369)
- Metallic Phases & Transformations
- Thermodynamics of crystals, phase diagrams, principles
of alloy phases, thermal analysis. Transformation rate and
mechanisms. Short and long range diffusional
transformations, diffusionless transformations. Phase
transformations in engineering systems.
Precludes additional credit for MECH 5608 if taken during
2001-2002 or during 2005-2006.
- Prerequisite: MECH 2700 or the equivalent.
- MECH 5704 [0.5 credit] (MCG 5374)
- Integrated Manufacturing Systems (CIMS)
- Topics essential to CIMS including computer graphics,
geometric modeling, numerically controlled machining, and
flexible manufacturing. The fundamental data structures and
procedures for computerization of engineering design,
analysis and production. Also offered at the undergraduate
level, with different requirements, as MECH 4704, for which
additional credit is precluded.
- MECH 5705 [0.5 credit] (MCG 5375)
- CAD/CAM
- Computer aided design and manufacturing methodology
through hands-on experience and state-of-the-art software.
Topics include mathematical representation, solid modeling,
drafting, mechanical assembly, mechanism design and CNC
machining. CAD data exchange standards, rapid prototyping,
concurrent engineering and design for X are also
discussed.
- MECH 5800 [0.5 credit] (MCG 5480)
- Special Topics in Mechanical and Aerospace
Engineering
- Topic will vary from year to year.
- MECH 5801 [0.5 credit] (MCG 5489)
- Special Topics in Mechanical and Aerospace
Engineering
- Topic will vary from year to year.
- MECH 5802 [0.5 credit] (MCG 5483)
- Special Topics in Mechanical and Aerospace
Engineering
- Topic will vary from year to year.
- MECH 5803 [0.5 credit] (MCG 5488)
- Special Topics in Mechanical and Aerospace
Engineering
- Topic will vary from year to year.
- MECH 5804 [0.5 credit] (MCG 5384)
- Special Topics in Mechanical and Aerospace
Engineering
- Topic will vary from year to year.
- MECH 5805 [0.5 credit] (MCG 5482)
- Special Topics in Mechanical and Aerospace
Engineering
- Topic will vary from year to year.
- MECH 5806 [0.5 credit] (MCG 5486)
- Special Topics in Mechanical and Aerospace
Engineering
- Topic will vary from year to year.
- MECH 5807 [0.5 credit] (MCG 5387I)
- Special Topics in Mechanical and Aerospace
Engineering
- Topic will vary from year to year.
- MECH 5808 (0.5 credit) (MCG 5376)
- Special Topics in Mechanical and Aerospace
Engineering
- Topic will vary from year to year.
- MECH 5809 [0.5 credit] (MCG 5382)
- Special Topics in Mechanical and Aerospace
Engineering
- Topic will vary from year to year.
- MECH 5906 [0.5 credit] (MCG 5395)
- Directed Studies
- MECH 5908 [1.5 credits] (MCG 5398)
- Independent Engineering Study
- Students pursuing a master's degree by course work
carry out an independent study, analysis, and solution of
an engineering problem or design project. The results are
given in the form of a written report and presented at a
departmental seminar. Carried out under the general
direction of a faculty member.
- MECH 5909 [2.0 credits]
- M.A. Sc. Thesis
- MECH 6909 [8.5 credits]
- Ph.D. Thesis
Other Courses of Particular Interest
Civil and Environmental Engineering
CIVE 5101, CIVE 5102, CIVE 5103, CIVE 5204, CIVE 5304, CIVE
5602
Mathematics and Statistics
MATH 4806 Numerical Analysis
MATH 5806
Physics
PHYS 4407 Statistical Physics
PHYS 5101
Systems and Computer Engineering
SYSC 5001, SYSC
5004, SYSC 5005, SYSC 5401, SYSC 5402, SYSC 5502, SYSC 5503
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