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Course Criteria
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3.00 Credits
Presents approach to kinematics of particles in linear and curvilinear motion. Includes kinematics of rigid bodies in plane motion. Teaches Newton's second law, work-energy and power, impulse and momentum, and problem solving using computers. Prerequisite: EGR 140. Lecture 3 hours per week.
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3.00 Credits
Teaches concepts of stress, strain, deformation, internal equilibrium, and basic properties of engineering materials. Analyzes axial loads, torsion, bending, shear and combined loading. Studies stress transformation and principle stresses, column analysis and energy principles. Prerequisite: EGR 140. Lecture 3 hours per week.
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3.00 Credits
Teaches fundamentals of electric circuits. Includes circuit quantities of charge, current, potential, power and energy. Teaches resistive circuit analysis; Ohm's and Kirchoff's laws; nodal and mesh analysis; network theorems; RC, RL and RLC circuit transient response with constant forcing functions. Teaches AC steady- state analysis, power, three-phase circuits. Presents frequency domain analysis, resonance, Fourier series, inductively coupled circuits, Laplace transform applications, and circuit transfer functions. Introduces problem solving using computers. Prerequisite: MTH 174 and PHY 241. Lecture 3 hours per week.
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1.00 Credits
Teaches principles and operation of laboratory instruments such as VOM, electronic voltmeters, digital multimeters, oscilloscopes, counters, wave generators and power supplies. Presents application to circuit measurements, including transient and steady-state response of simple networks with laboratory applications of laws and theories of circuits plus measurement of AC quantities. Corequisite: EGR 251. Laboratory 3 hours per week.
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3.00 Credits
Presents the concept of linear continuous-time and discrete-time signals and systems. Covers topics including Laplace transforms and Laplace transform analysis of circuits, time and frequency domain representation of linear systems, methods of linear systems analysis including convolution and Laplace transforms, frequency domain representation of signals including frequency response, filters, Fourier series, and Fourier transforms. Utilizes online data and related computational analysis support to assist with the representation, analysis and applications of signals and systems models. Other topics covered include differential and difference equations, signal modulation and demodulation, Fourier analysis of discrete-time systems, Parseval's theorem, ideal filters, sampling, Laplace Transfer Function representation, and introduction to the z- Transform. Lecture 3 hours per week.
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4.00 Credits
Teaches number representation in digital systems; Boolean algebra; design of digital circuits, including gates, flip-flops, counters, registers, architecture, microprocessors, and input-output devices. Lecture 3 hours. Laboratory 2 hours. Total 5 hours per week.
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1.00 Credits
Utilizes high-level software, such as Matlab?, to formulate and analyze computer models of complex Engineering signals and systems. Topics covered include vector manipulation, plotting, function creation, complex numbers, difference equations, convolution, Fourier Series, DTMF modulation and demodulation, analog filters, frequency response, and sampling and reconstruction. Corequisite: EGR 261 - Signals and Systems. Laboratory 3 hours per week.
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2.00 Credits
Covers purpose and interpretation of the National Electrical Code, as well as various charts, code rulings, and wiring methods. Prepares the student to take the journeyman-level exam. Lecture 2 hours per week.
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3.00 Credits
See General Usage Courses.
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3.00 Credits
See General Usage Courses.
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