_ 560 Semiconductor Device Design. (3) 611 Linear Circuit Analysis I. (3)
Theory, development and discussion of equivalent circuit models of Laplace and Fourier transform methods of analysis of linear lumped
transistor devices, negative resistance, semi-conductor devices and constant systems under transient and steady state conditions; feed-
praetersonic devices based on electronic processes in solid state , back amplifiers; filter networks; stability and physical realizability.
elements. High and low frequency, as well as the Ebers-Moll and Prereq: EE 520.
charge control switching models and their application in computerized
electronic circuit analysis will be developed. Prereq: CS 220; EE 461   Linear Circuit Analysis    
{ or cqmvalenh Continuation of EE 611 with an introduction to non-linear systems.
3 · · · P : EE 611.
g 562 Electronzcs and Communzcatzons II. (3) meg
  Feedback amplifiers, tuned and untuned amplifiers; oscillators, AM     Control Theory  
in and U`H`F energy Three class h°“rs' Pr°r°q° EE 461* State-space ngodeling of control syisteréns; variational techniques; system
; . . . op imiza ion y maximum prmcip e, ynamic programming; ami ton-
_   Electronlcs and Communications     Jacobi equations, design of linear optimal systems; computational
. Timing, scanning, nigger, iegic and pulse circuits; video and broad- methods for solving boundary value problems- Prer€q= EE 611·
band R-F amplifiers. Three class hours. Prereq: EE 461. S d C Z S  
  614 ample -Data ontro ystems.
I   Electrical Engineering Laboratory V-   Z transfomis, Nyquist criterion, Bode and root locus plots, error
Q Laboratory practice and experiment exercises relating to studies in constants, finite settling-time design, sensitivity, state variables. Three
i EE 564. Lecture, one hour; laboratory, three hours. Concur: EE 564. class hours per week. Prereq: EE 520 or consent of instructor.
5 66 Magnetic Amplifiers. ( 3) 615 Stability Theory of Control Systems. (3)
Wave-form analysis of circuits with nonlinear magnetic elements; Stability theorems are studied with emphasis on application to closed-
saturable reactors and self-saturating magnetic amplifiers in steady- loop control systems. Three class hours per week. Prereq: EE 572.
6 state and transient operation; some characteristics of semiconductor _ _
diodes including Zener types; effects of negative and positive feed-   Advanced Toplcs zn Control,  
i back °n magnetic amph£Hs‘ Three class h°urs' Prereq: EE 415 Current research and design practices in control devices and systems.
Q . . M b tdt'.Th l h k.P :EE613,
* 569 Mzcrowave and Coherent Optics 611), me   0;“}:;,,,ct;$? C ass mrs per Wee meq
` Measurement. ( 3) .
, Theory and practice of measurement of coherent microwave and 621 Introduction to Antennas" _  
Optical radiation from waveguides, lasers, and antennas, including F¤¤d¤m€¤t¢§1 A¤t€¤¤8 concepts. Array Theory, Linear Radiators,
_ analysis of errors. Laboratory measurement of frequency, power, L°°P$» H€l'“S· Mutual Couplmgv R€H€ct°"s· M¤¤¤¤¤¤m¤¤* Th€°’Y·
impedance, polarization and pattems of coherent waves. Two class Three °1“sS h°“'s per WE°k· Prereqi EE 567*
hours, three laboratory hours per week. Prereq: EE 468.   Advanced Antennas  
V   Electrical C()nfrOZ3     Traveling wave concepts,. line sources, Huygen’s Principle,_Babinet’s
,; Analysis and design of non-linear feedback control systems. Phase §m·ic;pl°’ fynthesls tecgmlquex travelhng wave antenna d?slg§’.l?m?`
l plane, describing function and piecewise linear techniques are de- ga rave   wav? an§nnas’ nondmli mlgn a"?y§€ué°;{gmn’ n Gum
V veloped. Stability of non-linear feedback systems is studied. Prereq: mgrams' me C ass cms per WEE ‘ r€rEq' '
EE 507. . .
. 623 Lznes and Wave Guides. (3)
  Logical Design of Analog and Digital Sy$tem$_   Opin-wire ar;d coaxial lines, standing waxies, stub m%chinIg; im-
Computation elements; analysis and synthesis of systems, Boolean {EZ argc; gags gggatmm rechmgu ar an umu ar wave gm es` mmm
functions and applications to relay and electronic circuits; circuit ’ ’ '
logic, memory elements; prime implicate synthesis of iterative net- · ~
works; sequential circuits, digital devices. Lecture and recitation,   S3l’d‘St“t€ Electronlcsx  
un-ee n0m·s_ pl-E1-eq; EE g2]_ ose an Fermi statistics. Semiconductor theory; solid-state devices;
electrical properties of insulators; theory and applications of magnetic
581 Advanced Logiccll Design,   materials, invluding ferrites. Lecture and recitation, three hom-S,
Boolean Matrices; Boolean trees, design of sequential circuits. Design . . .
a digital and hybrid computers. Prereq: EE 580.   El€fCfT;)TT1£1gTl€t1C PTOp¢1g¢1tlO71 (Ind SCdft€TlTlg.  
eory o eectromagnetic wave propagation in anisotropic an
E   Molecular Engineering.   inhomogeneous media; ionospheric radio propagation; waves in
. . plasmas. Prereq: EE 627 or consent of rnstructor.
Molecular approach to the behavior of gaseous conductors, semi-
conductors, dielectrics and magnetic materials; emphasis on modern · · ·
semi-conductor electronic devices such as masers, lasers, Esaki diodes,   MICTOWGV? Englncenng'   l
Zener diodes, and micromodules. Lecture, two hours; lab, three hours. Gcijneratnora, dellaecgogi and measuigzmleint of mit;-owave energy; vacaum
Prereq: EE 420, 457_ tu es at utra— ig requencies, t e ystron, t e magnetron, trave ing
wave tube and ferrite devices. Lecture, two hours; laboratory, three
  Independent PrObZemS_   hours. Prereq or concur: EE 468.
For electrical engineers. A problem, approved by the Chairman of · ·
the Department, provides an objective of study and research. May   Electromagnetlc Flcldén   1
be repeated to a maximum of six credits. Prereq: 2.5 standing. Advanced studies in electromagnetic fields; radiation and propagation
of electromagnetic waves; propagation in anisotropic media; diffrac-
P”-"'€’¢7uL‘>`it¢’ f0' graduate work: Siudfnti desififlg tv fllké any of tion theory; electrodynamics of moving media. Prereq: EE 468.
the following courses should have a thorough working knowledge of
chemistry, phymbs and mathematics. For maior work, a candidate must · ·
hold a bachel01·’s degree in Electrical Engineering or its equivalent.   Discrete Infonnatwn Theory   _ _  
» ‘ Entropy, Markov sources, algebra of codes, classification of codes,
· · ·» Shannon’s theorems, compact codes, linear codes, error detection and
601 Electromagnetic Energy Conversion I' (J ) error correction, syndrome vectors. Three class hours per week. Prereq:
Generalized electric machine theory; parameter determination. Energy Consent gf jnsgmctm-_
conversion in continuous media including magnetohydrodynamics.
l P¤¢¥¤=1= C¤¤S¢¤* 0* i¤S*¤¤¢*°*· 632 D1screte Informatzon Theory II. (3)
~ · · Plotkin, Gilbert and other bounds, Hamming codes, Reed-Muller l
  Electronldgnetlc Energy Conversion     and other linear codes, cyclic codes, Bose—Chandhuri codes,
COHfi¤¤3fi0¤ of EE 601 with special ¤`€f€1”€¤¤¤ to €¤€1‘gY conversion sequential decoding, convolution encoding. Three class hours per week.
l in nonlinear media; numerical methods; irregular boundaries. Prereq: Prereq: EE 631.
Consent of instructor.
633 Advanced Information Theory. (3)
l   Electric Power TTanSm1S$lOn·   Shannon type information theory regarding channel capacity, entropy,
The theory underlying the calculation and operation of long dis- band·limited systems for both memory and memoryless channels.
tance transmission circuits. Special attention to relay control. Recita- Three class hours per week. Prereq: EE 511, STA 523 or consent of
tion, 3 hours. Prereq: EE 538. instructor.
293 '