Transcript Document

Electrical & Computer Engineering
Electromagnetics Program
David Atkinson &
Jeffrey L. Young
February 24, 2009
What is Electromagnetics?
The study and application of electric and magnetic fields.
Why Should I care?
Electrical Engineering is Applied Electromagnetics
- Circuit Theory
- Kirchhoff ’s Voltage and Current Laws
- Current
- Voltage
- Resistance
- Capacitance
- Inductance
- Electric and Magnetic Energy
- Wave and energy propagation and transmission
Why Electromagnetics?
Electrical Engineering is Applied Electromagnetics
• As devices get smaller and smaller (relative to a wavelength), circuit theory is
less able to adequately describe the performance, or be used 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
Communication Systems, including microwave communications
Antennas and wave propagation
Optical Computing
Electromagnetic Interference, Electromagnetic Compatibility
Biology and Medicine/Medical Imaging
Courses in Electromagnetics: X3X
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ECE 330: Electromagnetic Theory
ECE 331: Electromagnetics Laboratory
ECE 430: Microwave and Millimeter-Wave Circuits
ECE 432: Propagation of Wireless Signals
ECE 434: Antenna Principles and Design
ECE 530: Advanced EM Theory
ECE 531 Advanced Electromagnetic Theory II
ECE 533: Antenna Theory
ECE 536: Wave Propagation and Scattering (WSU)
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
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, Offered every 3rd semester (next: Fall, 2010)
ECE432 Propagation of Wireless Signals (3 cr) 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, guided waves
Prereq: ECE330, Offered every 3rd semester (next: Spring, 2010)
Classes in Electromagnetics
ECE434 Antenna Principles and Design (3 cr)
Maxwell’s equations, vector potential theory, radiation patterns, antenna efficiency
and bandwidth, polarization, dipole and loop antennas, line sources, patch antennas,
lineal arrays, antenna systems, radar equation.
Prereq: ECE 330, Offered every 3rd semester (next: Spring, 2011)
Questions?
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: ECE330, Offered every 3rd semester
ECE531 Advanced Electromagnetic Theory II (3 cr) Boundary value problems in
non-Cartesian systems, diffraction, perturbation techniques, variational techniques,
wave transformations.
Prereq: ECE330, Offered every 3rd semester
ECE533 Antenna Theory (3 cr) Maxwell’s equations, reciprocity, equivalence
theorems, wire antennas, antenna arrays, aperture antennas, analysis and
design techniques, hardware considerations.
Prereq: ECE330, Offered every 3rd semester
Application Areas
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Microwave and Millimeter-Wave Circuits
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1-100 GHz communication circuits and devices
VLSI and mixed signal circuits
Antenna Theory and Design
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Base station and mobile antennas for wireless
communications (900 MHz – 2.0 GHz)
Military and space phased arrays
Bluetooth type embedded antennas
Smart and agile antenna
Wearable antennas
Application Areas
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Electromagnetic Compatibility
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EMI/RFI
Shielding and noise mitigation
EM Propagation and Scattering
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Wireless communication links
Radar cross-section analysis and mitigation
EM induced biological hazards
EM imaging and signature analysis
Hyperthermia cancer treatment
Why Electromagnetics?
• As
use of the electromagnetic frequency spectrum increases, the
need for engineers with practical working knowledge in
electromagnetics continues to grow.
• Electromagnetic engineers design high frequency or optoelectronic
circuits, antennas and transmission media; 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.