Electronic Engineering 3 (U00439)

? Credit Points : 20 ? SCQF Level : 9 ? Acronym : EEL-3-ELENE

Circuit Theory and Techniques. This course aims to build on the material presented in second year and to give the students an intuitive feel for the basic building blocks of analogue circuits. To teach them how to model discrete and integrated bipolar junction transistor (BJT) based analogue circuits using small signal hybrid- models. Signals and Systems: This course aims to provide an insight into time domain and frequency domain analysis techniques for time domain and frequency domain analysis techniques for both continuous- and discrete-time linear systems. At the end of the module students will have acquired sufficient expertise in these concepts to analyse simple feedback control systems and sampled-data filtering systems. Matlab

Entry Requirements

? Pre-requisites : Electronics 2 Maths 2 (details TBA) Laplace (TBA)

Subject Areas

Home subject area

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

Delivery Information

? Normal year taken : 3rd year

? Delivery Period : Semester 1 (Blocks 1-2)

? Contact Teaching Time : 6 hour(s) per week for 11 weeks

First Class Information

Date	Start	End	Room	Area	Additional Information
19/09/2006	09:00	10:00			Daniel Rutherford LT1 WK2 only

Summary of Intended Learning Outcomes

Circuit Theory and Techniques. Common emitter and common base discrete BJT amplifiers with and without series emitter feedback, by passed or unbypassed. A two, n-p-n BJT cascode amplifier. A two, n-p-n BJT transistor differential amplifier with passive collector loads and tail resistor. The above differential amplifier with a 2 or 3 transistor current mirror setting the tail current. The above differential amplifier with a 2 or 3 pnp BJT current mirror active collector load. The above differential amplifier followed by a p-n-p Darlington pair `high gain' stage and emitter follower stage (i.e. a basic operational amplifier). Comparators with hysteresis (normal and transient). Relaxation oscillators based on digital Schmitt gates, operational amplifiers and 555 timers. Perfect operational amplifier based integrators and know when they can be used, (i.e. in feedback loops such as phase locked loops and in integrate and dump matched filters). DC stabilised integrators. Three operational amplifier based instrumentation amplifiers. Signals and Systems: A student should be able to: evaluate the Fourier and Laplace transforms of simple waveforms and provide a physical interpretation of these transforms; explain the role of these transforms in evaluating the response of a linear system to a particular signal and calculate the response of a simple system to a simple waveform using transform techniques; recall the convolution integral and its properties and evaluate the response of a simple linear system to a simple waveform using the integral; sketch the frequency response of a system from its pole/zero map and draw the Bode plots of first, second and third order systems; sketch the impulse and step responses of first and second order systems from their transfer functions; explain negative feedback and evaluate the steady-state error of a simple control system; recall the sampling theorem.