Inhalt
[ 536DASCDSPU19 ] UE Digital Signal Processing
|
|
|
| Es ist eine neuere Version 2023W dieser LV im Curriculum Master's programme Computational Mathematics 2023W vorhanden. |
|
 |
| Workload |
Education level |
Study areas |
Responsible person |
Hours per week |
Coordinating university |
| 1,5 ECTS |
B3 - Bachelor's programme 3. year |
Computer Science |
Mario Huemer |
1 hpw |
Johannes Kepler University Linz |
|
|
|
| Detailed information |
| Original study plan |
Bachelor's programme Artificial Intelligence 2019W |
| Objectives |
Digital signal processing nowadays is present in almost every consumer electronics device, vehicle, industrial machinery, et cetera. This lecture provides an introduction in the field of digital signal processing. Main topics are discrete-time signals and linear time-invariant systems, their representations and mathematical treatment in the time and frequency domain. Furthermore, important signal transforms like wavelet transforms and the discrete cosine transform are discussed.
|
| Subject |
- Analog Signals and Systems (Introduction incl. Fourier transform)
- Sampling, Sampling Theorem
- Discrete Time Signals
- Important Signals
- Correlation
- Spectral Representation of Discrete Time Signals: DTFT, DFT, FFT, Short time Fourier transform
- Digital Filters: Analysis and Design of FIR and IIR Filters
- Further Signal Transforms
- Wavelet Transform
- Discrete Cosine Transform
- Time-Frequency-Distributions
|
| Criteria for evaluation |
Homework to be uploaded and evaluated
|
| Methods |
- Demonstration of examples
- Matlab examples
- Homework
|
| Language |
English |
| Study material |
- Lecture Slides
- Alan V. Oppenheim, Ronald W. Schafer, Discrete-Time Signal Processing: Pearson New International Edition, Pearson Education Limited 2014.
|
| Changing subject? |
No |
|
|
|
| On-site course |
| Maximum number of participants |
35 |
| Assignment procedure |
Direct assignment |
|
|
|
