Communication and Media Engineering

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Advanced Digital Signal Processing

Prerequisite

- Basics of continuous-time and discrete-time signals and systems (impulse response, step response,frequency response)
- Fourier Series, Fourier Transformation, Laplace Transformation, z-Transformation
- Lecture "Digital Signals and Systems" EMI(403)

Teaching methods Lecture/Lab
Learning target / Competences

The students acquire:

- Profound knowledge of digital signal processing systems

- Ability to implement modern signal processing concepts

Duration 2
Hours per week 5.0
Overview
Classes 75 h
Individual / Group work: 105 h
Workload 180 h
ECTS 5.0
Requirements for awarding credit points

Advanced Digit. Signal Processing: written exam K90

DSP Lab must be passed.

Responsible person

Prof. Dr. Christian Reich

Frequency annually (SS+WS)
Usability

Master's degree program CME

Lectures

Advanced Digit. Signal Proc.

Type Lecture
Nr. EMI414
Hours per week 4.0
Content

Transform Analysis of Linear Time-Invariant Systems: Frequency Response Components, All-Pass Filters, Minimum-Phase Systems.

IIR Filter Design: Approximation of Differential Equation, Impulse and Step Invariance Design, Bilinear Transformation.

IIR Filter Structures: Noncanonical and Canonical Direct Form, Transposed Direct Form, Parallel Form, Cascade Form. Finite Precision Numerical Effects.

FIR Filter Design Techniques: Fourier Approximation, Windowing, Optimum Equiripple Approximation.

Discrete Fourier Transform (DFT): Linear and Circular Convolution, Fast Fourier Transform (FFT) Algorithms.

Multirate Processing: Downsampling, Decimation Filter, Upsampling, Interpolation Filter.

Adaptive Signal Processing: Configuration in different Applications, Optimum Filter, Least-Mean-Squares Algorithm.

 

Literature

Oppenheim, Alan V.; Schafer, Ronald W.: Discrete-Time Signal Processing. Pearson, 2013.

Digita Signal Processing Lab Work

Type Lab
Nr. EMI415
Hours per week 1.0
Content

Experiment 1: A-to-D and D-to-A-Conversion
- Aliasing Effect
- Mirror Components
- (sin x)/x-Distortion
- Quantization Effects: Estimation of Signal-to-Noise-Ratio
- Nonlinearity of D-to-A-Converter
- Subjective Listening Tests

Experiment 2: Finite Impulse Response (FIR-) Filters
- Filter Design Using the Fourier Approximation
- Modification by Using Window Functions
- Optimum Design (Parks-McClellan-Algorithm)
- Finite Precision Effects
- Design of Hilbert Filters (Wideband Phase Shifters)

Experiment 3: Fast Fourier Transformation
- Speed Measurements
- Spectral Analysis, Windows to reduce Leakage Effects
- Comparison of direct and fast Implementation of Correlation
- Comparison of direct and fast Convolution

 

Literature

"User's Guides" for the Experiments

 

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