Analogue Electronics (CMOS Design) 4 (U04026)

? Credit Points : 10 ? SCQF Level : 10 ? Acronym : EEL-4-ELLSI

This course aims to equip students to enter the field of VLSI design by providing them with an understanding of the fundamental principles of digital and analogue CMOS VLSI circuit design, and the knowledge and skills required to analyse and design such circuits. Students will be introduced to some of the main CAD support tools.

Entry Requirements

? Pre-requisites : Microelectronics 3, Electronic Engineering 3

Subject Areas

Home subject area

Electronics, (School of Engineering and Electronics, Schedule M)

Delivery Information

? Normal year taken : 4th year

? Delivery Period : Not being delivered

? Contact Teaching Time : 3 hour(s) per week for 9 weeks

All of the following classes

Type	Day	Start	End	Area
Lecture	Monday	10:00	10:50	KB
Lecture	Wednesday	10:00	10:50	KB
Lecture	Thursday	10:00	10:50	KB

Summary of Intended Learning Outcomes

After successful completion of this course the student will
be able to:
- use IDS equations in circuit calculations;
- describe static and dynamic MOSFET circuit realisations of the main digital logic functions;
- explain CMOS latch design and synchronous system clocking;
- create scalable layout for simple digital MOS circuits;
- identify parasitic components and explain their importance for circuit modelling;
- explain simple fault modelling, test coverage and how test patterns can be produced;
- describe the main methods of design for testability;
- explain the operation & use of analog circuit building blocks;
- use large signal models to calculate and design transistor biasing;
- use small signal models to identify dominant pole, calculate gain and bandwidth and analyse transfer function for simple analog amplifiers;
- describe the main sources of noise and distortion in MOS analog circuits;
- estimate transistor noise spectral density and circuit signal to noise;
- use SPICE to simulate MOS circuits;
- describe types of analysis available in SPICE and explain level 1 MOSFET models; use SPICE to investigate the effects of variation (bias voltage, temperature, process parameter spreads) and understand their importance for circuit operation, performance and yield.