EE3053: SIGNALS, SYSTEMS & SIGNAL PROCESSING (2022-2023)

Last modified: 31 Jul 2023 11:19

Course Overview

How can the dynamic behaviour of a mechanical mass-spring-damper system be similar to an electrical resistance-capacitance-inductance circuit? Motivated by this question, this course introduces the signals – systems framework that helps in describing the dynamic behaviour of systems for a variety of inputs (signals). Useful analysis tools both in the frequency- and the time-domain are also introduced. In the later part of the course, these concepts will be used to understand basic signal processing in the form of both analogue and digital filter design.

Course Details

Study Type	Undergraduate	Level	3
Term	First Term	Credit Points	15 credits (7.5 ECTS credits)
Campus	Aberdeen	Sustained Study	No
Co-ordinators	Dr Sumeet S Aphale

Qualification Prerequisites

Either Programme Level 3 or Programme Level 4

What courses & programmes must have been taken before this course?

Engineering (EG) (Studied)
One of EF1504 Engineering Mathematics 1 (Foundation) (Passed) or EG1006 Engineering Mathematics 1 (Passed) or EG1503 Engineering Mathematics 1 (Passed) or EG1504 Engineering Mathematics 1 (Passed)
Any Undergraduate Programme (Studied)
One of EG2001 Engineering Mathematics 2 (Passed) or EG2005 Engineering Mathematics 2 (Passed) or EG2010 Engineering Mathematics 2 (Passed) or EG2012 Engineering Mathematics 2 (Passed)

What other courses must be taken with this course?

None.

What courses cannot be taken with this course?

None.

Are there a limited number of places available?

Course Description

The syllabus includes the following topics:

1. Signals: Classification, Properties, Basic Signal Construction, Sampling, Time and frequency-domain representation, Convolution, auto and cross-correlation

2. Systems: Classification, Properties, Impulse Response of LTI systems, LTI system response to arbitrary inputs, Revise Fourier and Laplace transforms, DFT, LTI systems in frequency domain

3. Filters: A/D – D/A conversion, Quantization and Round-off, Noise classifications, Typical filter characteristics and specifications, FIR and IIR filters, Analog and Digital filter design

4. Applications: RLC Circuit Analysis using Laplace Transforms, Phase Locked Loop

Contact Teaching Time

Information on contact teaching time is available from the course guide.

Teaching Breakdown

More Information about Week Numbers

Details, including assessments, may be subject to change until 30 August 2024 for 1st term courses and 20 December 2024 for 2nd term courses.

Summative Assessments

Homework assignment (30%)

Lab report (30%)

Design Exercise (40%)

Formative Assessment

There are no assessments for this course.

Course Learning Outcomes

Knowledge Level	Thinking Skill	Outcome
Factual	Remember	ILO’s for this course are available in the course guide.