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A professionally oriented seminar with faculty, university administration, and alumni speakers. Topics include: starting career options; career development; safety; switching companies and careers; working for oneself; graduate school.

A working knowledge of the principles and methods of computer simulation for the analysis and design of complex systems. Emphasis on the development of the basic methods required for next-event simulations. Techniques required for validating and verifying computer simulations.

Introduction to principles of human factors (ergonomics). The necessity for considering the human aspect of design of tools, machines, systems of people and machines; the literature, and how to use it; how to quantify data about people.

The fundamental principles and applications of heat transfer by conduction, convection, and radiation. Steady state and transient conduction, numerical methods in conduction, convection in internal and external flows, radiation exchange between surfaces. Design of heat exchangers. Prerequisites: M&I-ENG 230 and 340.

Modeling, analysis, and simulation of dynamic systems. Models for the dynamics of systems from different disciplines derived using differential equations and then transformed into state-space and input/output forms, and finally simulated. Relevant concepts from Laplace Transform, linear algebra, and complex variables covered. The models analyzed for transient response and frequency response properties.

The fundamentals of fluid mechanics. Fluid statics, control volume analysis for fluid dynamic systems, viscous flow in ducts, boundary layer flows, and an introduction to dimensional analysis and similarity. Computer-based design problems. Prerequisite: M&I-ENG 230, MATH 233, M&I-ENG 310 (M&I-ENG 310 may be taken concurrently).

Principles of machine element design principally from a functional perspective, including safety, endurance, strength, and usage. Design project explores other issues.

Kinetics and Kinematics of particles and rigid bodies. Newton's laws, work-energy and impulse-momentum principles, laws of linear and angular momentum, conservation of momentum, planar motion of rigid bodies, and introduction to vibration of single-degree-of-freedom systems.