Room

RGAN 203

11:00am-11:50am

11:00am-11:50am

11:00am-11:50am

Month

Monday

Wednesday

Friday

8=August

(22) Course description, organization. Lecture 1: Introduction to Communications

(24)  Lecture 2: Signal functions, Integration, orthogonality.

8=August

(27)  Lecture 2A: power, energy signals.

HW #0: Send email to lgh@engr.uky.edu from an email address you would like to receive course information. Just put ee511 in subject.

(29) Lecture 3: Fourier Transforms

V1: Use MATLAB to determine and plot the magnitude of the FFT of a rectangle function, and a sine wave. The duty cycle of the rectangle function is about 1/10 and the discrete frequency of the sine wave should be k_c=8. Where we have

f(t)=cos(2p k_c n / N)

for a sequence length of N. Let N=1024

(31)  Lecture 4: FT functions

HW #1: 2.2 Dirac delta functions, 2.9 E&P signals, 2.26 signal synthesis, 2.30 FT,

Problems of interest: 2.2, 2.6, 2.9, 2.10, 2.26, 2.27, 2.30

9=September

(3) NO CLASS LABOR DAY

(5) V2 preview.

(7) NO CLASS

9

(10) Lecture 5: Fourier Series

HW #2A: 2.31, 2.35, 2.38, 2.39

Problems of interest: 2.31, 2.33, 2.35, 2.38, 2.39

(12) Lecture 6: Orthogonality PSD, autocorrelation, LTI

HW#2B: V2: AM modulation and demodulation. Download and follow directions from V2 Word Doc.

(14) Lecture 7: Linear Time-Invariant Systems

9

(17) Lecture 7B: Hilbert Transform

(19) Lecture 8 and 8B: Filter Design and Nodal Analysis

HW #3B:V3 Double Side Band Suppressed Carrier Modulation

(21) Lecture 7C complex envelope and 9 DFT

HW #3A: 2.40, 2.44, 2.49, See web site for HW3 nodal analysis problem ( use fo=40Khz, Q=10 and Ao=-1 and C=0.001uf).

Problems of interest: 2.40, 2.41, 2.42, 2.44, 2.49, 2.50

9

(24) Lecture 9: DFT

(26) Lecture 10: Sampling Theory

HW #4A:V4 FM Modulation

(28) Lecture 11 and 12: Natural Sampling

HW #4B: 2.68, 2.73, 2.74

Problems of Interest: 2.67, 2.68, 2.72, 2.73, 2.74

10=October

(1)  Lecture 12: Flat Top Sampling. Discussion of Flat Top Project

(3) Review for exam. Did square wave laser demo.

(5) EXAM 1: 1 crib sheet both sides, FT table will be provided. No text books, no notes, no communication devices.

10

(8) Lecture 13: Double Side Band Suppressed Carrier (DSBSC)

(EOD)Project A: Flat Top Sampling Model: Will count ¼ of your final project grade.

(10)  DSBSC continued

HW #5A:

 V5 Spread Spectrum Modulation/Demodulation. Just send m files as you did in V4. No write up is necessary

(12) Lecture 14: AM

HW #5B: 3.2, 3.3, 3.13

Problems of intererest: 3.1, 3.5, 3.14, 3.19

10 Midterm

(15) Lecture 15: SSB

(17)  Lecture 16 & 17: Super Heterodyne and VSB.

HW #6A: Computer Exercises: 3.2

(19)  Lecture 18 & 19: Weavers Method, FM & PM

HW #6B: 3.1, 3.3, 3.14, 3.19

OOPS: 3.3 repeat

Problems of interest: 3.1, 3.3, 3.7, 3.14, 3.18, 3.19

10

(22)  Lecture 19 & 20: more FM

(24)  Lecture 21: FM/AM demodulation

(26)

HW #7: 3.24, 3.28, 3.32, 3.37

Problems of interest: 3.21, 3.28, 3.32, 3.36, 3.37

11=November

(29) PLL

(31) Quadrature modulation, Costas Receiver

(2) EXAM 2: open book, open notes, no communication devices.

11

(5) Lecture 22: PLL

(7)Lecture 22B: Quadrature and Costas Receiver

HW #8: V8 Compare Performance of AM, DSBSC, FM and DSSS Modulation and Demodulation with the same Channel. Find maximum frequency of each that will have zero error.

(9)

11

(12) 

(14) HW #9A: 3.42, 3.47, 3.52

Problems of Interest: 3.42, 3.44, 3.47, 3.49, 3.52, 3.53

(16)

11

(19) 

(21) NO CLASS, THANKSGIVING

(23) NO CLASS THANKSGIVING

12

(26)

(28)

(30) EXAM 3: open book, open notes, no communication devices.

12=December

Dead Week

(3)

(5)

FINAL PROJECT: Send in (at least) the Baseline files “create, modulator and demodulator”. You will need a group name and members. Send these to me and I will post on the web.

(7)

12. Finals

(10)

(12) FINAL PROJECT DUE 9pm

(14)