Time

10am - 10:50am

10am-10:50am

10am-10:50am

Month

Monday

Wednesday

Friday

Aug

(25) Lecture 1: First Day of Classes: Overview of syllabus, discussion of generic communication system.

(27) Lecture 2: C2: Overview modulation. Discuss basic usage of integration for comparison and time average of signals.

Aug/Sept

(30) Lecture 3: C2: Evaluate orthogonality, "dc", power and energy.

(1) Lecture: C2: Introduce FT and some of its properties. Present Duality, shifting, convolution, correlation and multiplication properties. Functions of the FT: Dirac Delta, unit step, sine waves, rectangle, Parsevals theorem.

(3) Lecture: (section 2.3) Continue discussion of Fourier Transforms.

HW#1: 2-4 dc, rms and power of a periodic wave, 2-22 Fourier Transform, 2-36 proofs of Fourier Xform, 2-39 FT multiplication rule. (covers sections 2.1-2.2 )

V1: Use MATLAB to determine and plot the magnitude of the FFT of a rectangle function, and a sine wave. The window size for the rectangle function should be 10 times its width and the discrete frequency of the sine wave should be k=4. Where we have cos(2 pi k / N) for a sequence length of N.

Other problems of interest:

2-2, 2-18, 2-35.

Sept

(6) Labor Day, NO CLASS

(8) Lecture: continue discussion of Fourier Transforms. Begin FS: (sections 2.4-2.5) Orthogonal and Fourier Series. Collect Data for V2.

(10) Lecture: (section 2.6) Linear Systems

Sept

(13) Lecture: Identity for getting PSD from Cn, Square Wave synthesis, Bandlimited Signals.

(15) V2 discussion

(17)  Square and Triangle Wave synthesis

HW #2: 2-49 Orthogonal Signals, 2-53 FS of periodic square wave, 2-61 PSD analysis(use MATLAB to PLOT), 2-68 Linear System analysis. (covers sections 2.3-2.6 )

V2: Process class data as a binary spread spectrum signal.

Prob of interest: 2-51,2-64,2-69

Sept

(20) Waveform synthesis

(22) Lecture: Sampling Theory

(24) Lecture: Sampling Theory.

HW #3: 2-55 FS of waveform, 2-82 Sampling, 2-83 DFT zero padding, 2-85 DFT of pulse, 2-84 DFT.

Problems of interest: 2-54, 2-81, 2-86

Sept/Oct

(27) Lecture: DFT

(29) Lecture: Delta Modulation

(1) Fall Break, NO CLASS

Oct

(4) Lecture: Odds and ends of chapter 3: cosine rolloff, differential encoding, circular convolution

HW #4: 3-3 Natural and Flat Top Sampling, 3-4 PAM, 3-50 Delta-mod, 3-56 TDM with cosine-roll off, 3-57 TDM & PAM.

Problems of interest: 3-2, 3-5, 3-6, 3-49, 3-57.

(6) Lecture: DFT based convolution, circular and linear (zero padding).

(8) Lecture: Equivalent Filtering and opamp filter design.

Oct

(11) Lecture: DSBSC modulation and demodulation.

(13)  Lecture: PLL

HW#5: 4-1 Filter, 4-3 DSBSC, 4-5 BPF,4-6 BPF, 4-9 AM, 4-11 spectrum of modulated waveform.

Problems of interest: 4-2,4-4,4-7,4-9,4-10

(15) Review for exam

Oct

(18) EXAM 1 MONDAY NIGHT, 7pm-9pm, Room 257 FPAT (AH), Crib sheet only, photocopy of FTs from Couch 6 text will be provided.) Covers HW #1, #2, #3 and #4.

Lecture: Take problems for review for test.

(20) Lecture: Tie up Chapter 4.

 Lecture: Discussion of filter Design.

(22) AM and Superheterodyne Receiver

Oct

(25) Chapter 5: Discuss AM and SSB and IF.

(27) Quadrature Demodulation

(29) Review of Exam I

HW #6: 4-12 bandpass & quadrature mixing, 4-14 filter analysis, 4-24 PLL, 4-26 PLL, 4-30 PLL.

Problems of interest: 4-12,4-23, 4-25, 4-29, 4-40

Nov

(1) Quadrature.

(3) Lecture:

(5) Lecture: VSB and NTSC

Nov

(8) Lecture: FM, wide band and narrow band, shift keying modulation.

HW#7: 5-5 AM, 5-8 DSBSC, 5-9 DSB, 5-11 Hilbert Transform, 5-12 Weaver’s method of SSB.

V7: Mixer and modulation simulation. Download instructions from EE511 web site.

Problems of interest: 5-6, 5-7, 5-10, 5-12, 5-18.

(10) Lecture: Flat Top Sampling

(12)

Nov

(15) BPSK, QAM, MSK

 HW#8: 5-26 PM, 5-36 PM derivation, 5-41 FM, 5-50 PSK BW, 5-52 DPSK.

Problems of interest: 5-27, 5-29, 5-44, 5-51, 5-52.

(17)

Email: submit visualization as test run for the final project. One submission per group and include all group member names.

V8: Run the baseline final project with just 16 bits of data. For each stage, make a plot of a signal that most represents that stage. For example, the channel04.m might be best represented by its Figure 1.

(19)

Nov

(22)

Do HW 9 as a group, preferably your final project group

HW #9:5-60 BPSK design, MATLAB:  5-66, 5-69, 5-70, 5-71.

Problems of interest: 5-59, 5-66, and 5-75.

(24) NO CLASS

(26) Thanks Giving break, No Class

Nov/Dec

(29)  Lecture: MSK, OFDM and DSSS methods

(1) Review for Exam II

EXAM II, Wednesday 12-1-04, 7pm to 9:30pm, room 323 Robotics Bldg, Open Book and Open Notes.

(3)  LASER QUEST Field Trip. Meet at 10am, play sample game at 10:25 and leave at 10:45am

Dec.

(6)  NO CLASS

Dead Week, Vestigial Sideband, Discussion of Final Project.

Final Project Preliminary Ranking: Send modulator, demodulator and detector.

(8) NO CLASS.

(10) NO CLASS

ECE Day Event

Dec

(13) Finals Week

(15) Final Project Contest Ends at 9pm

(17)