Room

FPAT 255

11:00am-12:15pm

11:00am-12:15pm

Month

Tuesday

Thursday

8=August

(23) Course description, organization. Introduction to Communications

8=August

(28)  Lecture: Integration, power, energy.

(30) Lecture: Functions of Fourier Transforms, Power Spectral Density

9=September

(4)  Lecture: FT properties and summary

HW #1: 2-4 dc, rms and power of a periodic wave, 2-9 Gain, 2-18 Fourier Transform, 2-36 proofs of Fourier Xform 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 duty cycle of the rectangle function is about 1/10 and the discrete frequency of the sine wave should be k=4. Where we have cos(2 pi k n / N) for a sequence length of N. Let N=256

Other problems of interest:

2-2, 2-4, 2-18, 2-22, 2-35,2-39.

(6) Lecture: PSD, autocorrelation, Fourier Series

9

(11)  Applications of Communications theory to 3D Data Acquisition and image processing.

(13)NO CLASS

9

(18) Research Applications

HW #2: 2-15 FT,2-16 tri-wave FT, 2-28, 2-36 proofs.

V2: Download and follow directions from V2 Word Doc. Process class data as a binary spread spectrum signal. (NO sharing code but you can talk about it all you want with other people).

Problems of interest 2-19,2-20,2-27,2-35

(20) FS, square wave spectra and PSD of linear systems

9

(25) Sampling Theory

HW #3: 2-46 Orthogonal Signals, 2-51 FS of periodic wave, 2-55 (Part a only) FS, 2-63 proof, 2-69 (MATLAB).

Prob of interest: 2-46, 2-49, 2-51,2-53, 2-61, 2-64,2-68, 2-69

(27) Natural and Flat Top Sampling and MATLAB techniques

10=October

(2) Flat top sampling

HW #4: 2-70 PSD, 2-82 Sampling, 2-84 DFT, 2-87 DFT, 2-92 triangle pulse FT.

Problems of interest: 2-54, 2-55, 2-70, 2-71, 2-81, 2-82,2-83, 2-84, 2-85, 2-86, 2-87

(4) TDM, Eye Diagrams, raised cosine filter, Differential coding.

10

(9) Integrate and Dump. Delta Modulation, Analog Filter Design

(11)

HW #5: 3-2, Natural and Flat Top, 3-5 Natural Sampling, 3-6 PAM, 3-49 Delta-mod, 3-54 TDM, 3-57 Hybrid TDM.

HW#5B: Visualization 5 (see EE511 web site)

Problems of interest: 3-2, 3-3, 3-4, 3-5, 3-6, 3-26, 3-40, 3-41, 3-43, 3-44, 3-49, 3-50, 3-54, 3-55, 3-56, 3-57.

10 Midterm

(16) Filter Design

(18)  Review for exam I

HW #6: 3-26 line codes (MATLAB), 3-40 raised cosine, 3-54 TDM, 3-57 TDM

V6 ISI Visualization. See ee511 web page.

10

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

(25)  Active Filtering and DSSC

11=November

(30) DSSC continued

(1) PLL

HW #7: 4-2 complex envelop, 4-4 bandpass filter, 4-10 modulation analysis, 4-12 bandpass and quadrature mixing.

Problems of interest: 4-1,4-2,4-3,4-4, 4-9,4-10, 4-11,4-12

11

(6) Super Heteradyne

(8) NO CLASS

11

(13)  Super Heteradyne, SSB + IF, VSB

HW #8: 4-16 THD, 4-26 PLL, 4-28 PLL, 4-29 PLL

FINAL PROJECT: Send in Baseline files “create, modulator and demodulator”. Wait till you see “07” m files.

Problems of interest: 4-14,4-24,2-26,4-30

(15) Quadrature modulation, Costas Receiver

11

(20) Quadrature detector, PM and FM and Carson’s rule  

HW #9: 5-2 AM, 5-7 DSBSC, 5-9 DSB, 5-10 Hilbert Transform, 5-12 Weavers method of SSB.

Problems of interest: 5-5, 5-8, 5-9, 5-11, 5-12

(22) NO CLASS THANKSGIVING

11

(27) HW #10: 5-18 SSB-AM, 5-19 SSB-AM, 5-23 FM Carsons rule, 5-24 FM, 5-36 PM derivation, 5-52 DPSK

problems of interest 5-26, 5-36, 5-41,5-50, 5-52

(29) EXAM II

12=December

Dead Week

(4)

 HW #11: 5-62 QAM design, MATLAB: 5-66 QPSK, 5-69 MSK type I, 5-70 FFSK, 5-71 MSK Type I

problems of interest: 5-60, 5-66, 5-69, 5-70, 5-71

(6)

12. Finals

(11)

FINAL PROJECT DUE 9pm

(13)