200 | 300 | 400 | Graduate Courses

Engineering Mechanics
(Administered by the Department of Aerospace Engineering)
Thomas J. Rudolphi, Chair of Department
Distinguished Professors: R. B.Thompson
Professors: Chimenti, Holger, Inger, McDaniel, Pierson, Rajagopalan, Rothmayer, Rudolphi, Schmerr, Tannehill, Tsai, Zachary
Professors (Adjunct): Hsu
Distinguished Professors (Emeritus):
D. Thompson, Young
Professors (Emeritus): Akers, Greer, Iversen, Jenison, McConnell, Munson, Rizzo, Rogge, Rohach, Weiss, Wilson
Associate Professors: Dayal, Hilliard, Hindman, Lu, Mann, Mitra, Sarkar, Sherman, Sturges
Associate Professors (Adjunct): Biner, Cox, Roberts
Associate Professors (Collaborators): Flatau
Associate Professors (Emeritus): Hermann, Seversike, Trulin, Vogel
Assistant Professors: Bastawros, Chavez, Haan, Jacobson
Assistant Professors (Adjunct): Byrd, Gray, Kellogg, Legg, Wolter

Undergraduate Study
The courses in mechanics are intermediate between those in physics and mathematics and the professional and design courses of the several engineering curricula. In the work of this department the student is expected to acquire an understanding of the principles underlying the technique of analysis and a knowledge of those properties of materials which influence the manner and extent of their use for engineering purposes. Physical properties of engineering materials are studied in the classroom and are evaluated in the laboratory. General laws, such as those of Newton, are given mathematical expression and are made suitable for use in the solution of specific problems in machine and structural design, and in the flow and measurement of fluids.

Graduate Study
The department offers work for the degrees master of science, master of engineering, and doctor of philosophy with major in engineering mechanics, and minor work to students taking major work in other departments.

The master of science degree requires a thesis and a minimum of 8 research credits. It has strong research emphasis and is recommended for students who anticipate entering a doctoral program later. At least 30 credits of acceptable graduate work are required for the degree.

The master of engineering degree does not require either research credits or a thesis. However, at least two credits of acceptable creative component and at least 26 credits of acceptable graduate coursework are required. A minimum of 30 credits of acceptable graduate work is required for the degree. The program is intended to give students additional instruction at the graduate level to better qualify them for advanced professional engineering work. By careful selection of electives and perhaps additional courses during the senior undergraduate year, students should be able to qualify for the master of engineering degree with an additional year of full-time study after receiving their baccalaureate degree in one of the several engineering curricula.

Credits for creative component will be obtained by registering for E M 599. A written report and an oral presentation will be given to the student’s graduate committee.

The normal prerequisite to major graduate work is the completion of a curriculum substantially equivalent to that required of undergraduate students in engineering at this university. However, because of the diversity of interests in graduate work in engineering mechanics, it is possible for a student to qualify for graduate study even though undergraduate or prior graduate training has been in a discipline other than engineering—e.g., physics or mathematics.

Courses open for nonmajor graduate credit: All 300- and 400-level courses except 490.

Courses Primarily for Undergraduate Students
E M 274. Statics of Engineering. (3-0) Cr. 3. F.S.SS. Prereq: Credit or enrollment in Math 166; credit or enrollment in Phys 111 or 221. Vector and scalar treatment of coplanar and noncoplanar force systems. Resultants, equilibrium, friction, centroids, second moments of areas, principal second moments of area, radius of gyration, internal forces, shear and bending moment diagrams.
H. Honors. F.S.

E M 324. Mechanics of Materials. (3-0) Cr. 3. F.S.SS. Prereq: 274. Plane stress, plane strain, stress-strain relationships, and elements of material behavior. Application of stress and deformation analysis to members subject to centric, torsional, flexural, and combined loadings. Elementary considerations of theories of failure, buckling. Nonmajor graduate credit.

E M 327. Mechanics of Materials Laboratory. (0-3) Cr. 1. F.S.SS. Prereq: Credit or enrollment in 324. Experimental determination of mechanical properties of selected engineering materials. Experimental verification of assumptions made in 324. Use of strain measuring devices. Preparation of reports. Students who are not present for the first laboratory meeting of their own sections may qualify for continuation in the course only by attending the first laboratory meeting of some other section of the course. Nonmajor graduate credit.

E M 345. Dynamics. (3-0) Cr. 3. F.S.SS. Prereq: 274, credit or enrollment in Math 266 or 267. Particle and rigid body kinematics, Newton’s laws of motion, kinetics of plane motion, rigid body problems using work-energy, linear, and angular impulse-momentum principles, vibrations. Nonmajor graduate credit.

E M 350. Introduction to Nondestructive Evaluation Engineering. (3-0) Cr. 3. S. Prereq: 324, Math 266, Phys 222. Introduction to the fundamentals of ultrasonic, eddy current, and x-ray testing. The generation, transmission, scattering, and reception of ultrasonic waves and x-rays in an NDE inspection. Safety issues. The connection between NDE, fracture mechanics, and reliability. Probability of detection and its impact on failure. The use of NDE in design. Nonmajor graduate credit.

E M 362. Principles of Nondestructive Testing. (Same as Mat E 362.) See Materials Engineering. Nonmajor graduate credit.

E M 362L. Nondestructive Testing Laboratory. (Same as Mat E 362L.) See Materials Engineering. Nonmajor graduate credit.

E M 378. Mechanics of Fluids. (2-2) Cr. 3. F.S.SS. Prereq: 274. Properties of fluids. Fluid statics. Kinematics and kinetics of fluid flow. Mass, momentum, and energy conservation laws; dimensional analysis; flow in pipes and channels. Selected laboratory experiments. Nonmajor graduate credit.

E M 417. Experimental Mechanics. (2-2) Cr. 3. F. Prereq: 324. The use of strain gages and brittle coating with applications to practical engineering problems. Strain gage based transducers, recording and output devices. Selected laboratory experiments. Nonmajor graduate credit.

E M 424. Intermediate Mechanics of Materials. (3-0) Cr. 3. F.S. Prereq: 324. Stresses, strains, deflections and angular twist of symmetrical and unsymmetrical members subjected to combined loading. Analysis of contact stress problems and shrink fit problems. Dynamic load effects, fatigue and fracture mechanics introduction. Stress analysis of connections. Nonmajor graduate credit.

E M 425. Introduction to the Finite Element Method. (3-0) Cr. 3. S. Prereq: 324, Math 266 or Math 267. Introduction of finite element analysis through applications to one-dimensional, steady-state problems such as elastic deformation, heat and fluid flow, consolidation, beam bending, and mass transport. Transient heat conduction and wave propagation. Two-dimensional triangular and quadrilateral elements. Plane problems of torsion, thermal and potential flow, stress analysis. Simple computer programs for one- and two-dimensional problems. Nonmajor graduate credit.

E M 444. Mechanical Vibrations. (2-2) Cr. 3. F. Prereq: 324, 345. Elementary vibration analysis, single and multiple degrees of freedom, energy methods, free and forced vibrations, viscous damping, transmissibility, matrix methods, modal analysis. Selected laboratory experiments. Numerical methods of solution. Nonmajor graduate credit.

E M 451. Engineering Acoustics. (Same as M E 451.) (2-2) Cr. 3. S. Prereq: Phys 221 and Math 266 or 267. Sound sources and propagation. Noise standards and effects of noise on people. Principles of noise and vibration control used in architectural and engineering design. Characteristics of basic noise measurement equipment. Experience in use of noise measuring equipment, sound power measurements, techniques for performing noise surveys, evaluation of various noise abatement techniques applied to common noise sources. Selected laboratory experiments. Nonmajor graduate credit.

E M 490. Independent Study. Cr. arr. Prereq: Permission of instructor.
H. Honors

Courses Primarily for Graduate Students, Open to Qualified Undergraduate Students
E M 510. Continuum Mechanics. (3-0) Cr. 3. F. Prereq: Math 385. Presentation of the basic equations of engineering mechanics: conservation of mass, conservation of momentum, conservation of energy; principles of selection of constitutive equations; constitutive relations for classical elastic materials and classical fluids; simple rheological models for viscoelastic materials; introduction to Cartesion tensors.

E M 514. Advanced Mechanics of Materials. (Same as Aer E 514.) (3-0) Cr. 3. F. Prereq: 324. Theory of stress and strain, stress-strain relationships. Limitations of flexure and torsion formulas, unsymmetrical bending, curved beams, cross-shear, shear center. Torsion of thin-walled noncircular sections. Theories of failure, membrane stresses in shells, thick-walled cylinders.

E M 516. Mechanics of Deformable Solids. (3-0) Cr. 3. S. Prereq: E M 510. Fundamental mechanics of linear elasticity, formulation and solution of simple elastostatic boundary value problems. Kinematics of small deformations, constitutive equations for isotropic and anisotropic media. Field equations for elastic solids, plane strain/plane stress and some classic canonical solutions. Constitutive models of inelastic/plastic solids and selected problems of elastoplasticiy, contact mechanics, fracture mechanics and defects in crystalline solids.

E M 517. Experimental Mechanics. (Same as Aer E 517.) (3-1) Cr. 4. Alt. S., offered 2005. Prereq: E M 510 or 514 or 516. Fundamental concepts for force, displacement, stress, and strain measurements. Strain gages, full field deformation measurements with laser interferometry and digital image processing. Advanced experimental concepts at the micro and nano scale regimes.

E M 518. Waves in Elastic Solids with Applications to Ultrasonic Nondestructive Evaluation. (3-0) Cr. 3. F. Prereq: Math 385. Propagation of bulk waves, surface waves, and guided waves in isotropic and anisotropic elastic media. Transmission and reflection of waves at plane and curved interfaces. Radiation of sources with application to ultrasonic transducer beam modeling. Elastic wave scattering from cracks and inclusions. Reciprocity principles and their use in the development of an ultrasonic measurement model. Characterization and measurement of material attenuation.

E M 525. Finite Element Analysis. (Same as Aer E 525.) (3-0) Cr. 3. S. Prereq: 425, Math 385. Variational and weighted residual approach to finite element equations. Emphasis on two- and three-dimensional problems in solid mechanics. Isoparametric element formulation, higher order elements, numerical integration, imposition of constraints and penalty, convergence, and other more advanced topics. Use of two- and three-dimensional computer programs. Dynamic and vibrational problems, eigenvalues, and time integration. Introduction to geometric and material nonlinearities.

E M 526. Boundary Element Methods in Engineering. (3-0) Cr. 3. Alt. F., offered 2003. Prereq: 514 or 516. Introductory boundary element methods through plane problems. Singular integrals, Cauchy principal values, integral representations and boundary integrals in one dimension. Direct and indirect formulations. Plane potential and elastostatic problems. Higher order elements, numerical integration. Regularizations. Body forces and infinite regions. Specialized fundamental solutions, half-plane and axisymmetric problems. Diffusion and wave problems. Coupling with finite elements.

E M 544. Mechanical Vibrations. (2-2) Cr. 3. Alt. S., offered 2004. Prereq: 324, 345. Elements of lumped parameter linear systems, kinematics of vibrations, equations of motion for free and forced vibrations, energy methods, resonance, damping, multiple degrees of freedom, mechanical impedance, isolation and absorption of vibrations with impulsive and arbitrary excitation of linear systems, primary and residual shock spectra. Vibration of continuous systems.

E M 548. Advanced Engineering Dynamics. (3-0) Cr. 3. Alt. S., ofered 2005. Prereq: 345, Math 266 or 267. Dynamics of particles and rigid bodies. Generalized coordinates. Lagrangian equations of motion. Equations of motion in terms of Eulerian angles, motion of a gyroscope.

E M 550. Fundamentals of Nondestructive Evaluation. (Same as M S E 550.) (3-2) Cr. 4. S. Prereq: 324, Math 385. Basic physics of ultrasonic, radiographic, and electromagnetic NDE measurements. Principles and uses of other quantitative techniques in nondestructive evaluation. Signal processing and evaluation methods. Laboratory experiments in ultrasonics, eddy current, and x-ray radiography methods of NDE.

E M 551. Signal Processing in Mechanics. (Same as M E 551.) See Mechanical Engineering.

E M 552. Advanced Acoustics. (3-0) Cr. 3. Alt. F., offered 2003. Prereq: 451. Theoretical acoustics: wave propagation in fluids; acoustic radiation, diffraction and scattering; and architectural acoustics. Applications of basic acoustic theory in noise control and acoustic radiation. Introduction to selected numerical methods in acoustics.

E M 564. Fracture and Fatigue. (Same as M S E 564 and M E 564.) (3-0) Cr. 3. F. Prereq: 324 and either Mat E 211 or 272. Materials and mechanics approach to fracture and fatigue. Fracture mechanics, brittle and ductile fracture, fracture and fatigue characteristics. Fracture and fatigue tests, thermal fracture, mechanics and materials designed to avoid fracture or fatigue.

E M 569. Mechanics of Composite and Combined Materials. (Same as M S E 569 and Aer E 569.) (3-0) Cr. 3. Alt. S., offered 2005. Prereq: 324. Mechanics of fiber-reinforced materials. Macromechanical behavior of lamina and laminates. Strength and interlaminar stresses of laminates. Failure criteria. Micromechanics of lamina. Stress analysis of laminates. Thermal moisture and residual stresses.

E M 570. Wind Engineering. (Same as Aer E 570.) (3-0) Cr. 3. F. Prereq: 378, 345. Atmospheric circulations, atmospheric boundary layer wind, bluff-body aerodynamics, aeroelastic phenomena, wind-tunnel and full-scale testing, wind-load code and standards, effect of tornado and thunderstorm winds, design applications.

E M 590. Special Topics. Cr. 1 to 4 each time taken. Prereq: Permission of instructor.
G. Random Vibrations
H. Mechanics of Thin Films and Adhesives
I. Mechanics of Cellular and Porous Media
J. Other

E M 599. Creative Component. Cr. arr.

Courses for Graduate Students
E M 690. Special Topics. Credit 1 to 6 each time taken. Prereq: Permission of instructor.
N. Advanced Experimental Methods
O. Advanced Wave Propagation
P. Advanced Materials
Q. Advanced Computational Methods
R. Reliability and Failure
S. Other

E M 697. Engineering Internship. Cr. R. Prereq: Permission of DOGE (Director of Graduate Education), graduate classification. One semester and one summer maximum per academic year professional work period. Offered on a satisfactory-fail grading basis only.

E M 699. Research.