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Course Criteria
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3.00 Credits
(3 credits)(Prereq: ENGR*234 or permission of the instructor) Kinematics of particles: coordinate systems, relative and dependent motions, Kinetics of particles: Newton's Second Law, Kinetics of particles: work and energy methods, Kinetics of particles: impule and momentum methods, Kinetics of rigid bodies: absolute and relative motion, Review of mass moment of intertia, Planar kinetics of rigid bodies: Newton's Second Law, Plnar kinetics of rigid bodies: work and energy methods, Planar kinetics of rigid bodies: impule and momentum methods, Vibrations: free and forced. S
Prerequisite:
Take ENGR*234(6537);
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3.00 Credits
(=PHYS*250)(3 credits) This course introduces students to effective forms of communication in the disciplines of science, technology, engineering, and mathematics. Students learn about available tools for researching and writing academic papers, the proper structure for a journal article, and the publication process. Students are also exposed to the various styles for delivering an oral presentation including effective strategies for each style. Time is also spent on learning best practices for designing and presenting scholarly poster. S
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3.00 Credits
(3 credits)(Prereq: ENGR*234 or permission of the instructor) This course emphasizes the fundamental concepts and application of strength of materials while developing student's analytical problem-solving skills. Offered as needed
Prerequisite:
Take ENGR*234(9702);
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3.00 Credits
(3 credits)(Prereq: CHEM*111/L or permission of the instructor) This introductory course in materials science is designed primarily for engineering students who wish to understand the relationships between a material's structure, processing and properties (electrical, mechanical, and thermal). All levels of structure are considered: from macro structures easily visible to the eye through electronic structure of atoms. F
Prerequisite:
Take CHEM*111 CHEM*111L;
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3.00 Credits
(3)(Prereq: a grade of C or better in PHYS*212 or PHYS*214; or permission of the instructor) This course focuses on the role of renewable power generation in today's electricity power grid. This course has three main sections. The first section introduces the topology and operation of the current power grid. The second section is an in-depth analysis of wind, solar, and hydro, the three major renewable sources in use today, from the electrical engineering perspective. Finally, we conclude with the future of renewable energy; experimental technologies and the challenges of operating the power grid in the 21st century. F
Prerequisite:
Take PHYS*212(PHYS_212) or PHYS*214(4370); Minimum grade C;
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3.00 Credits
(3 credits)(Prereq: MATH*320 or permission of the instructor) This course covers signals and systems in both the time domain and in the frequency domain, including transformations such as Fourier, Laplace, and Z-transforms. Basic signal processing and controls concepts are introduced. Offered as needed
Prerequisite:
Take MATH*320;
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3.00 Credits
(3) (=PHYS 321) (Prereq: ENGR 235 or PHYS 235) This course covers the analysis, modeling and design of electrical circuits that contain electronic devices. Topics include: properties of electronic materials, behavior of devises such as p-n junction diodes, field effect transistors and bipolar junction transistors, operational amplifiers, and transistors in digital circuits. Electronics design principles via a systems approach is emphasized. S.
Prerequisite:
Take ENGR*235(6538) or PHYS*235;
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3.00 Credits
(3 credits)(Prereq: PHYS*211/L with a grade of C or better, or permission of the instructor) Introduction to thermodynamics and heat transfer: properties of liquids and gases, first and second law analysis, introduction to cycles for power and refrigeration, heat flow by conduction and radiation, and convective heat flow and heat exchangers. F
Prerequisite:
Take PHYS*211(PHYS_211) PHYS*211L; Minimum grade C;
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3.00 Credits
(3 credits)(Prereq: ENGR*244 and ENGR*323, or permission of the instructor) This course develops methods for analyzing fluid behavior while at rest or in motion starting from Newton's Laws and control volume concepts. Important representations for fluid kinematics are developed, such as streamlines and students are introduced to the Reynold's Transport theorem. Energy and momentum methods of fluid dynamics problem solving are developed and applied to engineering problems in the design pipe flow systems. S
Prerequisite:
Take ENGR*244 ENGR*323;
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3.00 Credits
(3 credits)(Prereq: Junior standing [completed 60+ credits] or permission of instructor) An advanced laboratory course surveying diverse topics; in the engineering sciences, including statics, dynamics, strength of materials, thermodynamics, and fluid transport; in industrial applications, including sensing, instrumentation, logic, feedback and controls, data acquisition, data reduction, and reporting. S
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