_ EC09 403:
ELECTRONIC CIRCUITS
Objectives
To impart the basic idea of constructing passive devices
To develop the skill of analysis and design of various circuits using electronic
devices.
Module I (20 hours)
Resistors: concepts of fixed & variable resistors, metal film resistors, wire wound resistors - construction, power rating & tolerance
Capacitors: different types, Construction of mica and ceramic capacitors (disc & tubular), colour code, electrolytic (Teflon) capacitors
Inductors: construction of single layer, multilayer and variable inductors, principle of low power transformers
Diode applications - diode clipping and clamping circuits, voltage multiplier circuits, Rectifiers: Half wave and full wave rectifiers – derivation of rectifier specifications like PIV, DC output voltage, ripple factor, efficiency, rectification factor – analysis of filters with rectifiers – L, C, LC and pi filters
Regulators - zener diode regulator - emitter follower output regulator - series pass transistor feedback voltage regulator - short circuit protection and fold back limiting - load and line regulation curves
BJT circuit models - small signal low frequency and small signal high frequency models of BJT : hybrid model, T model and hybrid ð model - effect of temperature on BJT model parameters - equivalent circuits of CC, CB and CE configurations - current gain - voltage gain - input and output impedances
Module II (18 hours)
The amplifier gain function –Low frequency and high frequency responses- Use of open circuit and short circuit time constants in finding the cut-off frequencies-Low and high frequency response of common emitter amplifier - Emitter followers.
Feedback amplifiers-the general feedback structure – voltage shunt - voltage series – current series and current shunt feedback configurations - effects of negative feed-back-Analysis of negative feedback amplifiers –Stability-study of stability using Bode Plots.
Power amplifiers - class A, B, AB, C, D & S power amplifiers - harmonic distortion - efficiency - wide band amplifiers - broad banding techniques - low frequency and high frequency compensation - cascode amplifier - broad banding using inductive loads – Darlington pairs
Module III (17 hours)
Analysis of UJT Characteristics and relaxation Oscillator
JFET – structure and VI characteristics - biasing of JFET -- analyses of common source and common drain amplifier configurations - biasing in ICs
Positive feedback and oscillators - analysis and design of RC phase shift, Wien - bridge, Colpitt’s, Hartley and crystal oscillators - stabilization of oscillations
Differential Amplifiers-The BJT differential pair-Large and small signal operation- Large and small signal operation-Non ideal characteristics of the differential amplifier- Differential amplifier with active load- concept of CMRR - methods to improve CMRR - Frequency response analysis.
Module IV (17 hours)
Pulse response switching characteristics of a BJT - BJT switches with inductive and capacitive loads - non saturating switches - emitter follower with capacitive loading -
Bistable multivibrator – principles & analysis-fixed bias and self biased transistor bistable circuittriggering methods-Schmitt trigger analysis of emitter coupled circuit. Monostable and astable multivibrators - collector coupled monoshot - emitter coupled monoshot - triggering the monoshot - collector coupled and emitter coupled astable multivibrator – analysis of sweep circuits-principles of miller and bootstrap circuits
Text Books
6. Neamen , Electronic Circuits – Analysis & Design, McGraw Hill
7. Millman J. & Taub H., Pulse, Digital & Switching Waveforms, Tata McGraw Hill
8. Boylestad R. & Nashelsky L., Electronic Devices & Circuit Theory, Pearson Education
9. Sedra A.S & Smith K.C., Microelectronic Circuits, Oxford University Press
Reference Books
6. Milman & Halkias, Integrated Electronics, McGraw Hill
7. Gray & Meyer, Analysis and Design of Analog Integated Circuits; John Wiley
8. Schilling D.L. & Belove C., Electronic Circuits, McGraw Hill,
9. Spencer & Ghausi, Introduction to Electronic Circuit Design; Pearson Education
Internal Continuous Assessment (Maximum Marks-30)
60% - Tests (minimum 2)
30% - Assignments (minimum 2) such as home work, problem solving, group discussions, quiz,
literature survey, seminar, term-project, software exercises, etc.
10% - Regularity in the class
Note: One of the assignments shall be simulation of circuits using any SPICE tool.
University Examination Pattern
PART A: Short answer questions (one/two sentences) 5 x 2 marks=10 marks
All questions are compulsory. There should be at least one question from each module and not more than two questions from any module.
PART B: Analytical/Problem solving questions 4 x 5 marks=20 marks
Candidates have to answer four questions out of six. There should be at least one question from each module and not more than two questions from any module.
PART C: Descriptive/Analytical/Problem solving questions 4 x 10 marks=40 marks
Two questions from each module with choice to answer one question.
Maximum Total Marks: 70
Objectives
To impart the basic idea of constructing passive devices
To develop the skill of analysis and design of various circuits using electronic
devices.
Module I (20 hours)
Resistors: concepts of fixed & variable resistors, metal film resistors, wire wound resistors - construction, power rating & tolerance
Capacitors: different types, Construction of mica and ceramic capacitors (disc & tubular), colour code, electrolytic (Teflon) capacitors
Inductors: construction of single layer, multilayer and variable inductors, principle of low power transformers
Diode applications - diode clipping and clamping circuits, voltage multiplier circuits, Rectifiers: Half wave and full wave rectifiers – derivation of rectifier specifications like PIV, DC output voltage, ripple factor, efficiency, rectification factor – analysis of filters with rectifiers – L, C, LC and pi filters
Regulators - zener diode regulator - emitter follower output regulator - series pass transistor feedback voltage regulator - short circuit protection and fold back limiting - load and line regulation curves
BJT circuit models - small signal low frequency and small signal high frequency models of BJT : hybrid model, T model and hybrid ð model - effect of temperature on BJT model parameters - equivalent circuits of CC, CB and CE configurations - current gain - voltage gain - input and output impedances
Module II (18 hours)
The amplifier gain function –Low frequency and high frequency responses- Use of open circuit and short circuit time constants in finding the cut-off frequencies-Low and high frequency response of common emitter amplifier - Emitter followers.
Feedback amplifiers-the general feedback structure – voltage shunt - voltage series – current series and current shunt feedback configurations - effects of negative feed-back-Analysis of negative feedback amplifiers –Stability-study of stability using Bode Plots.
Power amplifiers - class A, B, AB, C, D & S power amplifiers - harmonic distortion - efficiency - wide band amplifiers - broad banding techniques - low frequency and high frequency compensation - cascode amplifier - broad banding using inductive loads – Darlington pairs
Module III (17 hours)
Analysis of UJT Characteristics and relaxation Oscillator
JFET – structure and VI characteristics - biasing of JFET -- analyses of common source and common drain amplifier configurations - biasing in ICs
Positive feedback and oscillators - analysis and design of RC phase shift, Wien - bridge, Colpitt’s, Hartley and crystal oscillators - stabilization of oscillations
Differential Amplifiers-The BJT differential pair-Large and small signal operation- Large and small signal operation-Non ideal characteristics of the differential amplifier- Differential amplifier with active load- concept of CMRR - methods to improve CMRR - Frequency response analysis.
Module IV (17 hours)
Pulse response switching characteristics of a BJT - BJT switches with inductive and capacitive loads - non saturating switches - emitter follower with capacitive loading -
Bistable multivibrator – principles & analysis-fixed bias and self biased transistor bistable circuittriggering methods-Schmitt trigger analysis of emitter coupled circuit. Monostable and astable multivibrators - collector coupled monoshot - emitter coupled monoshot - triggering the monoshot - collector coupled and emitter coupled astable multivibrator – analysis of sweep circuits-principles of miller and bootstrap circuits
Text Books
6. Neamen , Electronic Circuits – Analysis & Design, McGraw Hill
7. Millman J. & Taub H., Pulse, Digital & Switching Waveforms, Tata McGraw Hill
8. Boylestad R. & Nashelsky L., Electronic Devices & Circuit Theory, Pearson Education
9. Sedra A.S & Smith K.C., Microelectronic Circuits, Oxford University Press
Reference Books
6. Milman & Halkias, Integrated Electronics, McGraw Hill
7. Gray & Meyer, Analysis and Design of Analog Integated Circuits; John Wiley
8. Schilling D.L. & Belove C., Electronic Circuits, McGraw Hill,
9. Spencer & Ghausi, Introduction to Electronic Circuit Design; Pearson Education
Internal Continuous Assessment (Maximum Marks-30)
60% - Tests (minimum 2)
30% - Assignments (minimum 2) such as home work, problem solving, group discussions, quiz,
literature survey, seminar, term-project, software exercises, etc.
10% - Regularity in the class
Note: One of the assignments shall be simulation of circuits using any SPICE tool.
University Examination Pattern
PART A: Short answer questions (one/two sentences) 5 x 2 marks=10 marks
All questions are compulsory. There should be at least one question from each module and not more than two questions from any module.
PART B: Analytical/Problem solving questions 4 x 5 marks=20 marks
Candidates have to answer four questions out of six. There should be at least one question from each module and not more than two questions from any module.
PART C: Descriptive/Analytical/Problem solving questions 4 x 10 marks=40 marks
Two questions from each module with choice to answer one question.
Maximum Total Marks: 70
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