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Electromagnetic Engineering

Electromagnetic Engineering. ECE292 Sophomore Seminar 18 March 2008. What is Electromagnetics?. The study and application of electric and magnetic fields. Electrical Engineering is Applied Electromagnetics :. - Circuit Theory - Kirchhoff’s Voltage and Current Laws - Current - Resistance

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Electromagnetic Engineering

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  1. Electromagnetic Engineering ECE292 Sophomore Seminar 18 March 2008

  2. What is Electromagnetics? The study and application of electric and magnetic fields Electrical Engineering is Applied Electromagnetics: • - Circuit Theory • - Kirchhoff’s Voltage and Current Laws • - Current • - Resistance • - Capacitance • - Inductance • - Voltage • Electric and Magnetic Energy • Power, Electric Machines • Antennas, Waves and Wave Propagation, Optics • and Optical Computing

  3. Why Electromagnetics? Electrical Engineering is Applied Electromagnetics • As devices get smaller and smaller, and frequencies get higher and higher, • circuit theory is less able to adequately describe the performance or to • predict the operation of circuits. • At very high frequencies, transmission line and guided wave theory must • be used - high speed electronics, micro/nano electronics, integrated circuits. • Other applications of Electromagnetics - • Fiber Optics • Microwave Communication Systems • Antennas and wave propagation • Optical Computing • Electromagnetic Interference, Electromagnetic Compatibility • Biology and Medicine/Medical Imaging

  4. Why Electromagnetics? • As use of the electromagnetic frequency spectrum increases, the • demand for engineers who have practical working knowledge • in the area of electromagnetics continues to grow. • Electromagnetic engineers design high frequency or optoelectronic • circuits, antennas and waveguides; design electrical circuits that • will function properly in the presence of external interference • while not interfering with other equipment. • The electromagnetics technical specialty prepares future engineers • for employment in industry in the areas of radar, antennas, fiber • optics, high frequency circuits, electromagnetic compatibility • and microwave communication.

  5. Faculty * Dave Atkinson * Jeff Young * Dennis Sullivan Others include Fred Barlow, Aicha Elshabini, Dave Egolf, and Rick Wells

  6. Examples of Electromagnetics

  7. Classes in Electromagnetics ECE330 Electromagnetic Theory (3 cr) Vector Math, Charge and current, fields as forces, work, potential, and electromotive force, Faraday’s Law, Gauss’s and Ampere’s Law, Material Modeling, Waves. Prereq: Math 275, 310, and Phys 212. Coreq: ECE331 Semesters: Fall, Spring ECE331 Electromagnetics Laboratory (1 cr) Lab experiments and computer simulations. One 3-hr lab per week. Prereq: Math 275, 310, and Phys 212. Coreq: ECE330 Semesters: Fall, Spring

  8. Classes in Electromagnetics ECE430 Microwave Millimeter Wave Circuits (3 cr) Telegrapher’s and wave equations; characteristic impedance, wave velocity and wave number; physical transmission lines, including coax, microstrip and stripline; circuit analysis techniques, reflection coefficient and power flow, impedance analysis, impedance matching techniques and Smith Chart; S-parameters, Wilkinson power dividers, circulators and hybrid couplers; transformers and filters Prereq: ECE330 Semesters: Fall, 2009; Spring, 2011 ECE432 Applications of Electromagnetic Theory Maxwell’s equations; Poynting’s vector and Poynting’s Theorem; Wave equation with solutions (vector and scalar, homogeneous and inhomogeneous), Helmholtz equation; plane waves, reflection and refraction; introduction to classical electrodynamics, radiation from accelerated charges, introduction to antenna theory, transmission lines, waveguides and fiber optics, etc. Prereq: ECE330 Semesters: Fall, 2008; Spring, 2010

  9. Classes in Electromagnetics ECE433 Antenna Theory (3 cr) Maxwell’s Equations, Potential Theory, Poynting Theorem, EM Radiation and the Far-Field, Reciprocity, Pattern, Gain, Directivity, Efficiency, Beamwidth, Bandwidth, Side-Lobe Level, Line Sources, Lineal Phased Arrays, Antenna Structures: Dipoles, Loops, Helix, Horns, Patches Prereq: ECE330 Semesters: Spring, 2009; Spring, 2011

  10. Classes in Electromagnetics ECE530 Advanced Electromagnetic Theory (3 cr) Maxwell’s equations, potential theory, wave propagation and scattering, canonical problems, guided wave theory, antenna concepts, boundary value problems. Prereq: ECE432 Semester: Fall ECE533 Antenna Theory (3 cr) Maxwell’s equations, reciprocity, equivalence theorems, wire antennas, antenna arrays, aperture antennas, analysis and design techniques, hardware considerations. Prereq: ECE432 Semester: Spring

  11. Classes in Electromagnetics ECE536 Wave Propagation and Scattering (3 cr) ECE538 Electromagnetic Simulation (3 cr) ECE539 Advanced Topics in Electromagnetics (3 cr) Prereq: ECE530

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