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Course Criteria
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0.00 Credits
An introductory course in basic algebra with applications. Topics include fundamental operations, fractions, exponents, radicals, factoring, linear equations and systems, linear inequalities and quadratic equations. 0 semester hours
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3.00 Credits
A survey course in selected topics from college algebra and elementary functions. This course satisfies the Core Curriculum Basic Skills mathematics requirement. Topics include set notion, number systems, rules of algebra, operations with polynomials, factoring, linear equations and inequalities, solving polynomial equations, linear systems, and functions. Prerequisite: "C" or better inMath 100 or Mathematics Placement Exam. 3 semester hours
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3.00 Credits
Selected topics from college algebra and the elementary functions covered at a slower pace than Math C105. Prerequisite: Math 100 or Placement Exam. 3 semester hours
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3.00 Credits
This course will introduce undergraduate engineering majors to three important interrelated areas of Mechanical Engineering (thermodynamics, fluid mechanics and heat transfer). The increased emphasis placed on energy in our society makes it necessary for all engineers to have a basic understanding of thermal engineering. Prerequisites: Permission of the instructor. 3 semester hours
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3.00 Credits
A study of the properties of materials of importance to engineers. Structure-property- processing relationships. Mechanical, physical and electrical properties of metals, ceramics and polymers. Prerequisite: Chemistry 103. 3 semester hours
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3.00 Credits
Continuation of first course in fluid mechanics. Introduces the student to more advanced topics including laminar and turbulent boundary layer theory, lift and drag, subsonic and supersonic compressible flow, introduction to turbo-machinery and introduction to computational fluid mechanics. Prerequisites: Permission of the instructor. 3 periods; 3 semester hours; 1 design semester hour
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3.00 Credits
Applications of thermodynamic principles to engineering problems. Analysis of power and refrigeration cycles. Availability and irreversibility. Mathematical relations between properties. Non-reacting mixtures. Psychrometrics. Combustion principles. Prerequisite: Permission of the instructor. 3 lecture hours; 3 semester hours; 1 design semester hour
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3.00 Credits
Free and forced vibrations. Damped and un-damped, single and multiple-degree-offreedom systems. Vibration measuring instruments. Normal mode analysis including matrix methods. Lagrange's equations. Approximate and computer methods of analysis. Pre-requisite: Permission of the instructor. 3 lecture hours; 3 semester hours; 1 design semester hour
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3.00 Credits
This course focuses on the study of modern industrial materials and the process of developing creative solutions through conceptual analysis and synthesis on different advanced and automated manufacturing processes. The course will help students to learn the emerging topics in the material and manufacturing industries. The topics cover the study on today's popular industrial materials, material selections and industrial applications, and their related manufacturing techniques in US industry. Topics also include the introduction of quality control (QC) process that is important to the production with the high quality. The course has two class projects which will guide and help students to learn the ways of preparing for professional research and keep track of the latest technologies in modern materials, advanced and automated manufacturing processes. Pre-requisites: Engineering 111, Mechanical Engineering 223. 3 lecture hours; 3 semester hours
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3.00 Credits
Advanced topics in applied fluid mechanics. Review of continuity, momentum, and energy equations for viscous, incompressible fluid; voracity and circulation concepts and theorems. Selected topics from the following areas: Complex potential, conformal mapping and applications. Airfoil and wing theory. Boundary layer theory; similarity solutions for laminar flows, integral techniques for turbulent flows. Compression and expansion waves in compressible flows; oblique shock waves, Prandtl-Meyer flow. Propagating waves and applications; shock tube, transients in duct systems. Pre-requisite: Undergraduate Fluid Mechanics, Mechanical Engineering 309. 3 lecture hours; 3 semester hours
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