Run by School of Computer Science and Electronic Engineering
10 Credits or 5 ECTS Credits
Organiser: Dr Cristiano Palego
Overall aims and purpose
This module aims to provide an introduction to analogue electronic instrumentation circuits and techniques to improve performance in analogue amplifier circuits.
• Diode and bipolar transistor models and equivalent circuits • Bipolar transistor amplifier circuits: Common emitter, Common Base, Common Collector • Multi-stage amplifiers: Cascode amplifier, Class B driver, Operational amplifier • Introduction to instrumentation circuits and components: Amplifier characteristics, negative feedback. Operational amplifier circuits, Comparators, Analogue to digital conversion. • Introduction to signal conditioning: Filters properties, Passive filter design, and Active filter design. • Elementary signal capture methods: Bridge circuits, Differential amplifiers, Oscillators and resonance. • Instrumentation circuit design issues: Design rules, CAD software, Component technologies and properties. Interference and EMC, Thermal management, Power supply considerations.
Learning outcomes mapped to assessment criteria
Have a detailed understanding bipolar transistor amplifier circuits and the physical and environmental parameters that influence circuit operation.
|Ability to identify biasing arrangements and quantify operating points of circuits. Ability to quantify the operation, gain and frequency response of an ampifier circuit. Ability to design simple bipolar transistor amplifiers.||Ability to quantitatively analyse the gain, input and output impedances of a circuit. Ability to outline the advantages and disadvantages of different amplifier configurations. Ability to design simple multi-stage amplifiers||Ability to design a wide range of bipolar transistor amplifier circuits to a given specification. Demonstrate the use of different circuit configurations to overcome physical or environmental changes|
Have a detailed understanding of the use of analogue circuitry for signal conditioning based around signal amplification and filtering concepts.
|Ability to analyse basic filter and amplifying instrumentation circuits. Ability to recognise conceptual circuit configurations.||Ability to design a specific filter or amplifier circuit from a given specification||Ability to evaluate a given problem and derive an appropriate filter and or amplifier specification justifying choices made in the design.|
Analyse a broad range of analogue circuits based primarily around operational amplifiers. Expected to be able to design simple instrumentation systems.
|Ability to identify conceptual circuit configurations and describe the basic operation of circuits containing operational amplifiers. An elementary quantitative analysis of the circuit should be demonstrated. Ability to recognise conceptual circuit configurations||Ability to outline the operation of a simple operational amplifier circuit. Ability to quantitatively analyse in detail the operation of a circuit containing operational amplifiers and explain why certain circuit configurations have been chosen. Ability to outline the design of an analogue circuit using recognised circuit configurations and building blocks.||Ability to design a wide range of analogue circuits to a given specification. Demonstrate the use of different circuit configurations and building blocks to meet the specification|
|Closed Book Examination||100|
Teaching and Learning Strategy
1 hour lectures, twice weekly over 12 weeks
- Self-Management - Able to work unsupervised in an efficient, punctual and structured manner. To examine the outcomes of tasks and events, and judge levels of quality and importance
- Exploring - Able to investigate, research and consider alternatives
- Critical analysis & Problem Solving - Able to deconstruct and analyse problems or complex situations. To find solutions to problems through analyses and exploration of all possibilities using appropriate methods, rescources and creativity.
Subject specific skills
- Apply underpinning concepts and ideas of engineering;
- Apply knowledge and understanding of the specialist cognate area of electronic engineering in an international context;
- Apply knowledge and understanding of the specialist cognate area of computer systems engineering in safety-critical areas;
- Assess and choose optimal methods and approaches for the specification, design, implementation and evaluation of engineering solutions, especially ones that include embedded microprocessors
- Solve problems logically and systematically;
- Assess and choose optimal methods and approaches for the specification, design, implementation and evaluation of engineering solutions.
Courses including this module
Compulsory in courses:
- W3H6: BA Music and Electronic Engineering year 2 (BA/MEE)
- H612: BEng Computer Systs Eng (3 yrs) year 2 (BENG/CSE)
- H61B: BEng Computer Sys Engineering (4yr with Incorp Foundation) year 2 (BENG/CSE1)
- H610: BENG Electronic Engineering (3 yrs) year 2 (BENG/ELE)
- H62B: BEng Electronic Engineering (4yr with Incorp Foundation) year 2 (BENG/ELE1)
- H621: BEng Electronic Engineering with International Experience year 2 (BENG/ELEIE)
- H64B: BSc Computer Sys Engineering (4yr with Incorp Foundation) year 2 (BSC/CSE1)
- H6W3: BSc Electronic Engineering and Music year 2 (BSC/EEM)
- H611: BSc Electronic Engineering year 2 (BSC/ELE)
- H63B: BSc Electronic Engineering (4yr with Incorp Foundation) year 2 (BSC/ELE1)
- H661: MEng Control and Instrumentation Engineering year 2 (MENG/CIE)
- H617: MEng Computer Systs Eng (4 yrs) year 2 (MENG/CSE)
- H619: MEng Computer Systems Engineering (with International Exper) year 2 (MENG/CSEIE)
- H601: MEng Electronic Engineering (4 yrs) year 2 (MENG/EE)
- H618: MEng Electronic Engineering with International Experience year 2 (MENG/EEIE)