Course syllabus

Jump to today

Course-PM

EME102 Active microwave circuits lp3 VT22 (7.5 hp)

Course is offered by the department of Microtechnology and Nanoscience

Contact details

Course purpose

The aim of this course is to learn how to design active microwave circuits; such as amplifiers, oscillators, multipliers, and mixers.

Schedule

TimeEdit

Course literature

David M Pozar, Microwave engineering, 4th edition, Wiley,
2011, (ISBN: 978-0-470-63155-3).

Lecture notes
Scientific and technical papers

Optional: Guillermo Gonzalez, Microwave Transistor Amplifiers: Analysis and Design 

E-books available from Chalmers’ library

Steve Cripps, RF Power Amplifiers for Wireless Communications, Second Edition, 2006
(E-book ISBN 9781596930193)

Course design

The course treats analysis and design of microwave circuits, particularly amplifiers but also oscillators and nonlinear circuits like mixers and multipliers.

Topics: Two-port theory, impedance matching, stability, noise/gain optimisation, amplifier design, oscillation conditions, wideband amplifiers, the Bode-Fano criteria, high power amplifiers, microwave oscillators, mixers, multipliers, and nonlinear simulation techniques.

The course contains two lab exercises

  1. Design of a microwave-transistor amplifier using modern commercial soft-ware
  2. Assembly of the designed amplifier and measurement to verify the simulated performance

The course contains two home assignments

  1. Design of a noise optimized small-signal amplifier
  2. Exercise in large-signal modeling and nonlinear simulations, carried out in groups of 2

Organisation

Lectures 28 hours (Dan Kuylenstierna, Vincent Desmaris)

Tutorials 28 hours (Marttin Mattsson)

Laboratory work 8 hours (Martin Mattsson)

Home assignments X hours (Daniel Cristian Lopez)

 

Lecture

Date

Topic

Literature/note

Room

1

18/1

Course information, introduction, Transistors, transistor modeling  at a glance

11.2-11.4

Luftbryggan

2

20/1

Twoport parameters, Smith chart, Impedance matching

4.1-4.4, 4.5, 5

Zoom

3

25/1

Small-signal amplifier design, unilateral, stability, Signal flow graphs

12.1-12.3

Zoom

4

27/1

Small-signal amplifier design, bilateral design, constant-gain circles,

12.1-12.3

Zoom

5

1/2

Noise in twoport networks, Low noise amplifier design

10.1-10.2, 12.3, Hand outs

Fasrummet

6

3/2

Low noise amplifier design 

12.3, Hand outs

Fasrummet

7

8/2

Modeling of semiconductor devices

 11.2-11.3, hand-outs

Fasrummet

8

10/2

Power amplifiers

12.5, Cripps 2.1-2.4 & 3.1-3.4

Fasrummet

9-10

22/2

Nonlinear simulation techniques &
Mixers and frequency multipliers

10.3-10.4, 
Maas 1.1-1.3 & 3.1-3.3, 13.4-13.5 (Maas 6-7, 10-11)

Fasrummet

11

24/2

Guest Lecture:

 

“Sub-Terahertz Communication: A Key Enabling Technology for 6G”, Mingquan Bao, Ph. D. at Ericsson AB

Kollektorn

12

1/3

Oscillators

13.1-13.3, Gonzales Oscillators 2.1-2.5

Fasrummet

13

3/3

Challenges in amplifier design: Bandwidth, Multiple-stage amplifiers,

12.4,
hand-outs

Fasrummet

14

8/3

Resource time

 May be used for lab

 


 

Learning objectives and syllabus

Learning objectives:

  1. Analyse two-port networks with respect to gain, noise, stability and VSWR
  2. Apply two-port representations for embedding, de-embedding and interconnecting components
  3. Apply equivalent transistor models for representation of microwave transistors
  4. Design and characterise a RF/microwave amplifier circuit (gain, noise, power, bandwidth, VSWR)
  5. Design a RF/microwave oscillator for low phase noise
  6. Extract small-signal transistor model parameters from S parameter measurements
  7. Extract large-signal transistor-model parameters from transistor DC characteristics and bias dependent small-signal S parameters
  8. Design and analyse nonlinear circuits such as mixers and frequency multipliers

Link to the syllabus on Studieportalen.

Examination form

Successful completion of this module is based on:

  • Passed written examination (open book) held on line
  • Completion of two lab exercises
  • Home assignment (amplifier design)
  • Home assignment large-signal modeling and nonlinear simulation

Final grade is based on sum of results from home assignments (total 20p) and exam (total 60p): 3 (≥32p), 4(≥48p) and 5 (≥64p). The home assignments and the exam must both be passed individually, i.e., >40% on each home assignment and >24p on the exam. The exam will be held on line and supervised over zoom.

Be aware that all deadlines for home assignments and lab-preparations are sharp. A late home-assignment is not rewarded any points. On-time lab preparatory exercise is a prerequisite for doing the lab.

Academic Integrity

Academic integrity will be carefully followed up and all cases where any student may be suspected to have acted against the rules of academic integrity will be reported to the director of studies. If you are unsure about what is good academic integrity and what is not, you can find more information at

https://student.portal.chalmers.se/en/chalmersstudies/policy-documents/Pages/Academic-integrity-honesty.aspx

 

Course summary:

Date Details Due