BSc: Signals And Systems

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Signals and Systems

  • Course name: Signals and Systems
  • Code discipline: XYZ
  • Subject area: Electric Engineering

Short Description

This course covers the following concepts: discrete(-time) signals, their impulse and frequency domains; classification of (discrete) systems (bound-input-bound-output, linear and shift-invariant); filters and filtering, finite and infinite impulse response filters; discrete(-time) Fourier transform and fast Fourier transform.

Prerequisites

Prerequisite subjects

Prerequisite topics

Course Topics

Course Sections and Topics
Section Topics within the section
Complex numbers and functions, vector and Hilbert Spaces, computational aspects
  1. Complex numbers and their matrix representation
  2. Vector spaces with dot-product
  3. Metrics and convergence, Hilbert spaces
  4. Algorithms and their computational (space and time) complexity
Discrete Fourier Transform and Fast Fourier Transforms (DFT and FFT)
  1. Circular convolution, eigen vectors and values of the circular convolution
  2. Discrete Fourier Transform (DFT) and its inverse
  3. Circutate filters and filtering
  4. Fast Fourier Transform (FFT),its inverse, and computational aspects of DFT and fast FFT
Discrete-time signals and systems: properties and classification
  1. Kotelnikov-Whittaker–Nyquist–Shannon sampling Theorem.
  2. Discrete signals as sequences, spaces of absolutely summable and bounded sequences.
  3. Auto- and cross-correlation; memoryless, causal and shift-invariant systems
  4. Linear systems, their matrix representation and properties
  5. Convolution and its relations to linear shift-invariant systems
Convolution, Discrete-time Fourier Transformation, filtering
  1. Math preliminaries on complex exponent and Euler formulas.
  2. Introduction of the discrete-time Fourier transform via convolution eigen values and vectors.
  3. Discrete-time Fourier transform as the frequency response of a linear shift-invariant system.
  4. Inverse discrete-time Fourier transform.
  5. DTFT properties (including convolution theorem).
  6. Elements of ideal Filter Design.

Intended Learning Outcomes (ILOs)

What is the main purpose of this course?

The goal of the course is to present mathematical foundations of digital signal processing altogether with practical experience to design finite and infinite impulse response filters. The course is aimed to provide basic mathematical knowledge and practical skills needed for further studies of applied signal processing and digital signal processing from engineering as well as from mathematical perspective.

ILOs defined at three levels

Level 1: What concepts should a student know/remember/explain?

By the end of the course, the students should be able to ...

  • discrete (time) signals and systems, their classification
  • linear shift-invariant systems, filters and filtering
  • Discrete Fourier Transformation (DFT)
  • Fast discrete Fourier Transformation (FFT)
  • Discrete-Time Fourier Transformation (DTFT),

Level 2: What basic practical skills should a student be able to perform?

By the end of the course, the students should be able to ...

  • relations between analog and digital signals (sampling)
  • relations between convolution, correlation, and filtering of discrete signals
  • role of impulse and frequency domains of discrete signals
  • differences between infinite and finite discrete signals
  • role of discrete time Fourier transform and its inverse
  • role of discrete Fourier transform (DFT) and fast DFT (FFT)

Level 3: What complex comprehensive skills should a student be able to apply in real-life scenarios?

By the end of the course, the students should be able to ...

  • basic numerical tools from mathematical package SciLab/Octave
  • classify discrete signals and systems
  • design and implement infinite and finite impulse response filters
  • implement and use discrete time Fourier transform,
  • implement and use discrete Fourier transform and fast DFT.

Grading

Course grading range

Grade Range Description of performance
A. Excellent 104-130 -
B. Good 84-103 -
C. Satisfactory 65-83 -
D. Poor 0-64 -

Course activities and grading breakdown

Activity Type Percentage of the overall course grade
Labs/seminar classes 20
Interim performance assessment 90
Exams 20

Recommendations for students on how to succeed in the course

Resources, literature and reference materials

Open access resources

  • Martin Vetterli, Jelena Kovacevic, and Vivek K Goyal.Foundations of Signal Processing.Cambridge University Press, 2014. ISBN 10703860X
  • Oppenheim, Alan V., and A. S. Willsky. Signals and Systems (2nd ed.) Prentice Hall, 1996. ISBN 0-13-814757-4.
  • Richard G. Lyons.UnderstandingDigitalSignalProcessing. Prentice Hall, 2010. ISBN 978-0137027415

Closed access resources

Software and tools used within the course

Teaching Methodology: Methods, techniques, & activities

Activities and Teaching Methods

Activities within each section
Learning Activities Section 1 Section 2 Section 3 Section 4
Homework and group projects 1 1 1 1
Testing (written or computer based) 1 0 0 0
Reports 1 1 1 1
Discussions 1 1 1 1
Development of individual parts of software product code 0 1 1 1
Midterm evaluation 0 1 1 1

Formative Assessment and Course Activities

Ongoing performance assessment

Section 1

Activity Type Content Is Graded?
Question Prove that each complex number has a square root. 1
Question Prove that the neutral element is unique in a vector space. 1
Question Prove that pixel (Manhattan) and Euclidean norms are equivalent in finite-dimensional real (complex) spaces. 1
Question Is the set of integers complete in the discrete metrics? 1
Question What is space and time complexity of dot product in a complex n-dimensional vector space? 1
Question Prove that each complex number but zero has the inverse. 0
Question Prove that each vector of a vector space has unique opposite element. 0
Question Prove that pixel and the universal norms are equivalent in finite-dimensional real(complex) spaces. 0
Question Is the set of rational numbers complete in the discrete metrics? 0
Question What is space and time complexity of finite matrices multiplication (according to the definition)? 0

Section 2

Activity Type Content Is Graded?
Question Compute circular convolution of given two short integer signals. 1
Question Explain Discrete Fourier Transform as orthogonal vector decomposition. 1
Question Compute DFT and FFT for given short integer signal. 1
Question Prove circular impulse shift property. 0
Question Study commutativity, linearity and associativity of the circular convolution. 0
Question Give matrix representation for the circular convolution for several small dimensions. 0
Question Recall 2-redex fast Fourier transform and draw its matrices for several small dimensions. 0

Section 3

Activity Type Content Is Graded?
Question Give examples of (infinite) absolutely summable/non-summable, bounded/unbounded,etc., signals. 1
Question Is autocorrelation linear system? Is it shift-invariant? 1
Question Prove that a linear system is memoryless iff its matrix is diagonal. 1
Question Prove that a linear system is causal iff its matrix is low-triangle. 0
Question A linear system is shift-invariant iff its matrix consists (exclusively) of diagonals of some constant (individual for each diagonal). 0
Question Prove that product of finite power series is convolution of the finite signals consisting of the coefficients of these series. 0

Section 4

Activity Type Content Is Graded?
Question Do there exists a periodic function with non-commensurable periods? 1
Question Prove that product of two exponents is equal to the exponent with sum of powers. 1
Question Prove conjugate property for DTFT. 1
Question Prove DTFT-correspondence for impulse shift. 0
Question Prove DTFT-correspondence for frequency shift. 0
Question Design a low-band filter with a given spectrum consisting of a single box. 0

Final assessment

Section 1

  1. Build if possible (or prove that it isn’t) ...

Section 2

  1. Assume that a finite signal ...

Section 3

  1. Compute cross-correlation of two box signals.
  2. Study properties (linearity, causality, stability, etc.) of a weighted accumulator

Section 4

  1. Show that exponent with imaginary power is a periodic function, find the smallest period.
  2. Prove sampling and scaling properties for the Dirac Delta function.

The retake exam

Section 1

Section 2

Section 3

Section 4