Electronic Circuits (EX 154)

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Electronic Circuits EX 154 | IOE Syllabus 2080

Lecture          : 3
Tutorial         : 1
Practical     : 3

Course Objectives:
To introduce the fundamentals of analysis of electronic circuits and to provide basic understanding of semiconductor devices and analog integrated circuits.

1. Diodes (6 hours)
1.1 Physical operation of semiconductor diode characteristics
1.2 Large signal and small signal model of the semiconductor diode
1.3 Zener diode, LED, photodiode, varactor diode, tunnel diodes
1.4 DC power supply: half wave rectifier, full wave (center tapped, bridge) rectifier

2. The bipolar Junction Transistor (9 hours)
2.1 Operation of the npn transistor in the active mode
2.2 Graphical representation of transistor characteristic
2.3 Analysis of transistor circuits at dc
2.4 Graphical DC load line analysis
2.5 Biasing BJT for discrete-circuit design
2.6 Small signal equivalent circuit models of BJT ( & T)
2.7 Transistor as an amplifier ( r, re, gm )
2.8 Basic single-stage BJT amplifier configuration (C-E)
2.9 Small signal analysis of C-E amplifier
2.10 Transistor as a switch – cutoff and saturation
2.11 A general large-signal model of the BJT: The Ebers-Moll model

3. Field-Effect Transistor (9 hours)
3.1 Structure and physical operation of the junction field-effect transistor
3.2 Structure and physical operation of enhancement-type MOSFET
3.3 Current-voltage characteristic of enhancement-type MOSFET
3.4 The depletion-type MOSFET
3.5 MOSFET circuits at dc
3.6 Biasing in MOS amplifier circuits
3.7 MOSFET as an amplifier (common source)
3.8 MOSFET and CMOS as logic circuits

4. The Operational Amplifier and Oscillator (6 hours)
4.1 Basic model; virtual ground concept; inverting amplifier; non-inverting amplifier; integrator; differentiator, summing amplifier and their applications
4.2 Basic feedback theory; positive and negative feedback; concept of stability; oscillator
4.3 Waveform generator using op-amp for square wave, triangular wave, Phase shift oscillator and Wien bridge oscillator for sinusoidal waveform

5. Output Stages and Power Amplifiers (9 hours)
5.1 Classification of output stages
5.2 Class A output stage
5.3 Class B output stage
5.4 Class AB output stage
5.5 Biasing of class AB output stage
5.6 Power BJT’s
5.7 Transformer-coupled push-pull stage
5.8 Tuned amplifiers

6. Power Supplies, Breakdown Diodes, and Voltage Reference (6 hours)
6.1 Unregulated power supply
6.2 Zener regulated power supply
6.3 Zener diodes, bandgap voltage reference, constant current diodes
6.4 Transistor shunt/series voltage regulator
6.5 Improving voltage regulator performance with feedback
6.6 IC voltage regulator

Practical

  1. Familiarization with passive components, function generator and oscilloscope
  2. Measurement of amplitude, frequency, time period using oscilloscope
  3. Diode characteristics, rectifiers, zener diodes
  4. Bipolar junction transistor characteristics and single stage amplifier
  5. Power amplifiers
  6. Field effect transistor characteristics and single stage amplifier
  7. BJT, PMOS, NMOS and CMOS as switch
  8. Inverting, non-inverting, summing and subtractor amplifier using Op-amp
  9. Relaxation oscillator and sinusoidal oscillator
  10. IC, series and shunt voltage regulators
  11. Project presentation

Mark Distribution

ChapterWorkload (hrs)Marks *Remarks
168 
2912 
3912 
468 
5912 
668
Total4560 
*There may be minor deviation in mark distribution.

Reference

  1. A. S. Sedra and K.C. Smith, (2011). “Microelectonic Circuits” 6th Edition, Oxford University Press.
  2. Robert Boylestad and Louis Nashelsky, (2007). “Electronic Device and Circuit Theory”, PHI; 9th Edition.
  3. Thomas L. Floyd, (2007) “Electronic Devices”, 8th Edition, Pearson Education Inc.
  4. Jacob Millman, C. Halkias, C.D Parikh, (2010). “Integrated Electronics” 2nd Edition McGraw Hill Education P. Ltd.
  5. David A. Bell, (2010). “Electronic Devices and Circuits”, 5th Edition, Oxford Press

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