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Unit information: Radio Frequency Engineering (M) in 2016/17

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Unit name Radio Frequency Engineering (M)
Unit code EENGM6500
Credit points 10
Level of study M/7
Teaching block(s) Teaching Block 1 (weeks 1 - 12)
Unit director Professor. Morris
Open unit status Not open
Pre-requisites

EENG36000

Co-requisites

None

School/department Department of Electrical & Electronic Engineering
Faculty Faculty of Engineering

Description

The aim is to provide an introduction to the theoretical and practical aspects of RF and microwave circuit design. This includes a detailed study of RF transistor amplifier design, covering RF transistor behaviour and selection; Smith Chart design of small-signal amplifiers using lumped-element and stub matching techniques; and RF power amplification and linearity considerations in RF systems.

  • Components at RF, resonant circuits; Q factor, Fixed Q, High Q and low Q impedance matching; Semiconductors at RF and BJT models at RF; s-parameters.
  • Small-signal RF amplifier design: bias networks, stability and matching.
  • Smith chart matching network design.
  • Amplifier design using Smith charts: stability, gain control and matching network design.
  • Low-noise design: choice of bias point and noise figure.
  • Principles of microwave systems; microwave amplifier design; Transmitter architectures; Amplifier distortion: modelling, intercept point, harmonic and inter-modulation distortion.
  • Large-signal RF amplifier types and classes.

Intended learning outcomes

Having completed this unit, students will be able to:

  1. Design bias circuits for class A RF amplifiers
  2. Explain the relationship between Q factor and system bandwidth
  3. Describe and model component (R,L and C) behaviour at RF
  4. Design L, π , T and multiple L type matching networks
  5. Use s-parameter data
  6. Develop BJT models at RF
  7. Read and interpret a Smith chart
  8. Use a Smith chart to design L, π, and T matching networks
  9. Use a Smith chart to design single stub matching networks
  10. Apply simple amplifier distortion models and calculate intercept point
  11. Describe the different classes of RF power amplifier (A,B,C,D,E,F and S)
  12. Design a small signal RF amplifier
  13. Design a low noise RF amplifier
  14. Design a multiple stage RF amplifier
  15. Describe the main amplifier linearisation techniques
  16. Design and simulate circuits using RF CAD simulation tools

Teaching details

Combination of lectures and laboratory sessions

Assessment Details

Report on laboratory, 20% (ILO 16)

Exam, 2 hours, 80% (ILOs 1-15)

Reading and References

  • Bowick, C., RF Circuit Design, 2nd edition (TK 6553 BOW)
  • Reinhold, Ludwig and Gene Bagdanov, RF Circuit Design Theory and Applications, Prentice Hall, 2009, ISBN:1-13-135505-7

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