Time | 12 - 1 PM |
Place | Lecture: 250 Simrall; Lab: 332 Simrall |
Instructor |
Joseph Picone Office: 413 Simrall Office Hours: 11-12 MWF (others by appt.) Email: picone@cavs.msstate.edu |
Teaching Assistant |
Stephen G. Leong Office: 314 Simrall Office Hours: 11-12, 1-2 MWF (others by appt.) Email: sgl3@cavs.msstate.edu |
Class Alias | ece_4773@cavs.msstate.edu |
URL | http://www.cavs.msstate.edu/research/isip/publications/courses/ece_4773 |
Required Textbook(s) | S.J. Orfandis,
Introduction to Signal Processing,
Prentice-Hall, ISBN 0-13-209172-0, 1996.
J.H. McClellan, et al, Computer-Based Exercises for Signal Processing Using MatLAB 5, Prentice-Hall, ISBN 0-13-789009-5, 1998. R. Chassaing, et al, Digital Signal Processsing: Laboratory Experiments Using C and the TMS320C31 DSK, John Wiley and Sons, Inc., ISBN 0-47-129362-8, 1999. |
Prerequisite | R.E. Ziemer, W.H. Tranter, and D.R. Fannin, Signals and Systems: Continuous and Discrete (Third Edition), MacMillan Publishing Company, 1993. |
Reference Textbook(s) | J.G. Proakis and D.G. Manolakis,
Digital Signal Processing: Principles, Algorithms,
and Applications, ISBN: 0-13-373762-4, 1992.
A.V. Oppenheim, R.W. Schafer, and J.R. Buck, Discrete-Time Signal Processing, Prentice-Hall, ISBN: 0-13-754920-2, 1999. J. Buck, et al, Computer Explorations in Signals and Systems Using MATLAB, Prentice-Hall, ISBN: 0-13-732868-0, 1997. Other Library Resources |
Suggested Matlab Textbook | D.C. Hanselman and B.L. Littlefield, Mastering MATLAB: A Comprehensive Tutorial and Reference, 1/e, Prentice-Hall, ISBN: 0-13-191594-0, 1996. |
Mid-Term Exam | 25% |
Final Exam | 25% |
DSP Projects | 25% |
Matlab Projects | 25% |
Final DSP Project | 50% |
Class | Date | Section(s) | Topic(s) | |
1 | 08/23 | 1.1 | Organization, Introductions, and Demos | |
2 | 08/25 | 1.2-1.3, 1.7 | Why DSP? | |
3 | 08/27 | 1.3-1.5 | The Sampling Theorem | |
4 | 08/30 | 1.6-1.8 | Analog Reconstructors | |
5 | 09/01 | 2.1, 2.2 | A/D Converters; Uniform Quantization | |
6 | 09/03 | 2.3, 2.4 | Implementation Issues | |
7 | 09/08 | 2.5 | Analog and Digital Dither | |
8 | 09/11 | 3.1-3.3 | Discrete-Time Systems | |
9 | 09/13 | 3.4, 3.5 | Difference Equations | |
10 | 09/15 | 4.1 | Block Processing Methods | |
11 | 09/17 | 4.2 | Sample Processing Methods | |
12 | 09/20 | 5.1, 5.2 | Definition of the z-Transform | |
13 | 09/22 | 5.1, 5.2 | Properties of the z-Transform | |
14 | 09/24 | 5.5 | The Inverse z-Transform / Ethics | |
15 | 09/27 | 5.3, 5.4 | Frequency Response and Stability | |
16 | 09/29 | 6.1, 6.2 | Transfer Functions | |
17 | 10/01 | 6.3 | Response to Periodic Signals | |
18 | 10/04 | 6.4 | Digital Resonators and Other Simple Filters | |
19 | 10/06 | 6.5 | Deconvolution and Invertibility | |
20 | 10/08 | 7.1 - 7.6 | Filter Realizations | |
21 | 10/11 | 8.1.1, 8.1.2 | Digital Waveform Generators | |
22 | 10/13 | 8.1.3 | Wavetable Generators | |
23 | 10/15 | Chps. 1-6 | Mid-Term Exam | |
24 | 10/18 | 8.2.1, 8.2.2 | Delays, Echoes, and Phasing | |
25 | 10/20 | 8.2.3 | Digital Reverberation | |
26 | 10/22 | 8.2.4, 8.2.5 | Multitap Delays and Compressors / Ethics | |
27 | 10/25 | 8.3.1 - 8.3.3 | Noise Reduction | |
28 | 10/27 | 8.3.4 | Signal Averaging | |
29 | 10/29 | 8.3.5 | Golay Filters | |
30 | 11/01 | 9.1 | Frequency Resolution and Windowing | |
31 | 11/03 | 9.2, 9.3 | Interpolation | |
32 | 11/05 | 9.4-9.6 | Modulo-N DFTs, Inverse DFT | |
33 | 11/08 | 9.7 | The Discrete Fourier Series | |
34 | 11/10 | 9.7 | Circular Convolution | |
35 | 11/12 | 9.8 | Fast Fourier Transforms | |
36 | 11/15 | 9.9 | Fast Convolution | |
37 | 11/17 | 10.1, 10.2 | FIR Filter Design Using Frequency Sampling | |
38 | 11/19 | 10.3, 10.4 | FIR Filter Design Using Optimization / Ethics | |
39 | 11/22 | 11.1 | The Bilinear Transform | |
40 | 11/24 | 11.6 | Analog Prototypes | |
41 | 11/29 | 11.2-11.5 | Parametric Equalizers | |
42 | 12/01 | 12.1, 12.2 | Interpolation/Decimation | |
43 | 12/03 | 12.5, 12.6 | Oversampling A/D Converters | |
44 | 12/06 | N/A | Linear Prediction | |
45 | 12/08 | N/A | Signal Modeling | |
46 | 12/16 | Cumulative | Final Exam (8 - 11 AM) |