s y btech electronics engg syllabus (1)

Veermata Jijabai Technological Institute

Effective from Academic year 2010-11 1

VEERMATA JIJABAI TECHNOLOGICAL INSTITUTE [ Autonomous Institute affiliated to University of Mumbai ]

SYLLABUS

FOR

S.Y. B. TECH.

(Electronics Engineering)

VEERMATA JIJABAI TECHNOLOGICAL INSTITUTE,

[V.J.T.I.]

MATUNGA, MUMBAI 400 019.

[ YEAR 2010-2011 ]



Scheme of Teaching and Evaluation

S Y B Tech (Electronics Engineering) (Semester III)

Theory Courses

Course Code

Course Name Hr/Week Credits Examination Scheme

(Evaluation in % Weightage)

L T P TA IST ESE Total ESE (W) (hrs)

MA0205 Engineering Math I 3 1 - 4 10 30 60 100 3 EC0201 Electronic Circuit Analysis

& Design-I 3 1 - 4 10 30 60 100 3

EC0202 Digital Design-I 3 1 - 4 10 30 60 100 3 EC0203 Electrical Technology 3 - - 3 10 30 60 100 3 EC0204 Numerical Techniques 3 - - 3 10 30 60 100 3

Total 15 3 - 18

Laboratory Courses

Course Code



L T P TA

ESE (O / P)

Total ESE (P)

(hrs)

EC1201 Basic Electronic Circuits Lab

- - 3 1.5 50 50 100

EC1202 Digital Combinational Circuits Lab

- - 3 1.5 50 50 100

EC1203 Electrical Engineering Practice

- - 3 1.5 50 50 100

EC1204 Computational Techniques Lab

- - 3 1.5 50 50 100

Total - - 12 6

Co-curricular Activities

Course Code

Course Name Hr/Week Credits

L T P

CC4231 Industry-Academia Interaction

- - 2 A/NA

CC4232 E-Library/ Internet - - 3 -

Total - - 5 -

Total for Semester

L T P Total Hours Credits

15 3 17 35 24

Abbreviations: L: Lectures, T: Tutorial, P: Practical, TA: Teacher Assessment, ESE (P): End Semester Practical Examination, ESE (O): End Semester Oral Examination, IST: In Semester Test/s, ESE (W): End Semester Written Examination, ESE (W) (hrs): End Semester Written Examination duration, ESE (O) (hrs): End Semester Examination Practical (duration), A/NA: Attended/Not Attended

Notes: TA for Theory and Laboratory courses shall carry 25 marks. IST: One mid semester test (40 marks of two hour duration) and two surprise Tests/Quizzes (5% weightage each). ESE (W) shall be of 100 marks of 3 hours, ESE (P) and ESE (O) shall be decided as per course requirement. ESE (O) and ESE (P) shall together carry 25 marks. Industry - Academia Interaction: Wednesday afternoon slot will be used. Module or broad subject outline will be decided by the course coordinator. Lectures as per module in the defined areas of eminent personalities from industry or academia will be arranged. Assessment will be done on the attendance of the students for the module. (More than 60%: Attended, otherwise: Not Attended. E- Library/ Internet: Every course must have at least one assignment or case-study which requires exhaustive internet search/support.



Scheme of Teaching and Evaluation

S Y B Tech (Electronics Engineering) (Semester IV)

Theory Courses

Course Code



L T P TA IST ESE Total ESE (W) (hrs)

MA0206 Engineering Math II 3 1 - 4 10 30 60 100 3 EC0205 Electronic Circuit Analysis

and Design - II 3 1 - 4 10 30 60 100 3

EC0206 Principles of Microprocessor Systems

3 1 - 4 10 30 60 100 3

EC0207 Digital Design - II 3 - - 3 10 30 60 100 3 EC0208 Electrical Network

Analysis 3 - - 3 10 30 60 100 3

CE0221 Environmental Studies 3 - - 3 10 30 60 100 3

Total 18 3 - 21

Laboratory Courses

Course Code



L T P TA

ESE (O / P)

Total ESE (P)

(hrs)

EC1205 Electronic Design Lab - - 3 1.5 50 50 100 EC1206 Digital Sequential Circuits

Lab - - 3 1.5 50 50 100

EC1207 Microprocessor Systems I Lab

- - 3 1.5 50 50 100

EC1208 Electrical Networks Lab - 3 1.5 100 - 100

Total - - 12 6

Co-curricular Activities

Course Code

Course Code Course Code

Course Code

L T P

CC4241 Industry-Academia Interaction

- - 2 A/NA

Total - - 2 -

Total for Semester

L T P Total Hours Credits

18 3 14 35 27

Abbreviations: L: Lectures, T: Tutorial, P: Practical, TA: Teacher Assessment, ESE (P): End Semester Practical Examination, ESE (O): End Semester Oral Examination, IST: In Semester Test/s, ESE (W): End Semester Written Examination, ESE (W) (hrs): End Semester Written Examination duration, ESE (O) (hrs): End Semester Examination Practical (duration), A/NA: Attended/Not Attended

Notes: TA for Theory and Laboratory courses shall carry 25 marks. IST: One mid semester test (40 marks of two hour duration) and two surprise Tests/Quizzes (5% weightage each). ESE (W) shall be of 100 marks of 3 hours, ESE (P) and ESE (O) shall be decided as per course requirement. ESE (O) and ESE (P) shall together carry 25 marks. Industry - Academia Interaction: Wednesday afternoon slot will be used. Module or broad subject outline will be decided by the course coordinator. Lectures as per module in the defined areas of eminent personalities from industry or academia will be arranged. Assessment will be done on the attendance of the students for the module. (More than 60%: Attended, otherwise: Not Attended.



Programme Name : S.Y. B. Tech. (Electronics) SEMESTER – III

Course Code : MA0205

Course Title : ENGINEERING MATHEMATICS – I

Course Contents Module 1 Complex Variables

1.1 Function of complex variable. Analytic function, Necessary and sufficient conditions

for f(Z) to be analytic Cauchy-Riemann equations in polar coordinates. 1.2 Milne-Thomson method to determine analytic function f(Z) when its real or imaginary

part or its combination is given. 1.3 Harmonic function, orthogonal trajectories. Transformations 1.4 Conformal mapping, linear bilinear mapping with geometrical interpretation. Cross

ratio 1.5 Fixed points and standard transformations such as Rotation and magnification

translation, inversion.

Module 2 Laplace Transforms

2.1 Functions of bounded variation 2.2 Laplace transforms of standard functions such as

terfatatatet atn ,sinh,cos,sin,,,1

2.3 Linear property of Laplace transforms. 2.4 First shifting theorem, Second shifting theorem

tfdt

dLduufLt

tfLtfLtftL n

nt

n ,,,,0

2.5 Change of scale property: Unit step functions, Heaviside, Dirac delta functions,

Periodic functions and their Laplace transforms. 2.6 Inverse Laplace transform using linear property, theorems, partial fractions and

convolution theorem. 2.7 Application to solve ordinary differential equations with one dependent variable.

Module 3 Fourier Series 3.1 Orthogonal orthonormal sets, Expressions of a function in Series of orthogonal

functions.



3.2 Dirchlet’s conditions. 3.3 Fourier series of periodic function with period l2,2 3.4 Dirchlet’s theorem, even and odd functions. 3.5 Half range expansions, Parseval’s relations. 3.6 Complex form of Fourier series. 3.7 Fourier integral and Fourier transform.

Module 4 Matrices 4.1 Types of matrices 4.2 Adjoint (Adjugate) of a matrix. 4.3 Elementary transformations of matrix 4.4 Linear dependent and independent of rows/columns over a field 4.5 Rank of a matrix. 4.6 Reduction to a normal form. 4.7 Partitioning of matrix: System of homogeneous and non-homogeneous equations,

their consistency and solution. Text Books

1. Advance Engineering Mathematics: H K Dass, S Chand & Co. 3rd edition 2. Complex Variables & Applications: Churchil, Mc Graw Hill, 2003, 7th Edition

Reference Books

1. Theory of functions of complex variables, Shanti Narayan, S chand & Co, 2006. 2. Applied Mathematics - III, G. V. Kumbhojkar- Jamnadas & Co. – 7th Edition-2009.



Programme Name : S Y B Tech (Electronics) SEMESTER – III

Course Code : EC0201

Course Title : ELECTRONICS CIRCUIT ANALYSIS AND DESIGN - I

Course Contents

1. Semiconductor Materials and Diodes

Review of Semiconductor Materials and Properties, The PN Junction, Introduction to Semiconductor Diode Theory. Diode Circuits: DC Analysis and Models, AC Equivalent Circuits, Other Diode Types – Solar Cell, Photodiode, Light–Emitting Diode, Schottky Barrier Diode, Zener Diode, Temperature Effects, Understanding Manufacturer’s Specifications.

2. Diode Circuits

Design of Rectifier Circuits, Half Wave Rectification, Full Wave Rectification, Filter, Ripple Voltage and Diode Current, Voltage Doubler Circuit, Zener Diode Circuits, Clipper and Clamper Circuits, Multiple–Diode Circuits, Photodiode and LED Circuits.

3. The Bipolar Junction Transistor

Basic Bipolar Junction Transistor, Transistor Structures, NPN Transistor : Forward–active Mode Operation, PNP Transistor : Forward–active Mode Operation, Circuit Symbols and Conventions, Current–Voltage Characteristics, Non ideal Transistor Leakage Currents and Breakdown, DC Analysis of Transistor Circuits, Common–Emitter Circuits, Load Line and Modes Of Operation, Common Bipolar Circuits: DC Analysis, Basic Transistor Applications – Switch, Amplifier, Bipolar Transistor Biasing – Single Base Resistor Biasing, Voltage Divider Biasing and Bias Stability, Integrated Circuit Biasing, Multistage Circuits.

4. Basic BJT Amplifiers

Analog Signals and Linear Amplifiers, The Bipolar Linear Amplifier, Graphical Analysis and AC

Equivalent Circuit, Small Signal Hybrid – Equivalent Circuit of the Bipolar Transistor, Hybrid –

Equivalent Circuit Including the Early Effect, Expanded Hybrid – Equivalent Circuit, Other Small – Signal Parameters And Equivalent Circuits, Basic Transistor Amplifier Configurations, Common Emitter Amplifiers, AC Load Line Analysis, Common Collector Emitter Follower Amplifier, Common Base Amplifier, The Three Basic Amplifier configurations: Summary and Comparison, Multistage Amplifiers, Power Considerations, Environmental Thermal Considerations in Transistor Amplifiers, Manufacturers’ Specifications.

5. The Field Effect Transistor

Junction Field–Effect Transistor, MOS Field–Effect Transistor, MOSFET DC Circuit Analysis, Basic MOSFET Applications: Switch, Digital Logic Gate and Amplifier. Temperature effects in MOSFETs, Input Protection in MOSFET. The Power FET (VMOS).

6. Basic FET Amplifiers

The MOSFET Amplifier, Basic Transistor Amplifier Configurations, the Common Source Amplifier, The Source Follower Amplifier, The Common Gate Configuration, The Three Basic Amplifier Configuration: Summary and Configuration, Single – Stage Integrated Circuit MOSFET Amplifiers, Multistage Amplifiers, Basic JFET Amplifiers



Text Books

1. Donald A. Neamen, Electronic Circuit Analysis and Design, Second edition, McGraw Hill International edition 2001

2. Martin Roden , Gordon Carpenter, William Wieserman, Electronic Design, Fourth edition, Shroff Publishers, 2002

Reference Book

1. Donald Schilling & Charles Belove, Electronic Circuits Discrete and Integrated, Third edition, McGraw Hill International edition, 1989





Course Title : DIGITAL DESIGN - I

Course Contents

1. Introduction to Digital Systems

Analog VS Digital systems, digital devices, integrated circuits, programmable logic devices, digital design levels, software aspects of digital design.

2. Number Systems and Codes

Positional number systems, Binary and Hexadecimal number systems, general positional number systems conversions, arithmetic operations, representation of negative numbers, arithmetic operations on signed numbers, binary and gray codes, character codes, codes for detecting and correcting errors.

3. Logic Circuits

Logic signals and gates, Boolean Algebra, theorems, combinational circuit analysis, combinational circuit synthesis – minimization, Karnaugh Maps, sum of products and product of sums expressions and their minimization, programmed minimization methods – Quine McCluskey minimization algorithm, timing hazards – static and dynamic hazards, introduction to VHDL hardware description language.

4. Combinational Logic Design Practices

Documentation standards, Circuit timing, Combinational PLDs. Design using SSI and MSI devices Decoders, Encoders, Three state buffers, Multiplexers, Parity circuits, Comparators, Adders, Subtractors, ALUs, Combinational multipliers. Using VHDL and PLDs Combinational circuit design examples – barrel shifter, simple floating – point encoder, cascading comparator.

5. Logic Families

CMOS logic; MOS transistors review, basic CMOS inverter circuit, CMOS NAND and NOR gates, fan – in, fan – out, Electrical behavior of CMOS circuits, propagation delay, power consumption, multi source busses, CMOS logic families, bipolar logic introduction, review of BJT, TTL NAND and NOR gates, fan – in, fan – out, Electrical behavior of TTL circuits, propagation delay, power consumption. CMOS / TTL interfacing, Introduction to Emitter – coupled logic. Interpreting Manufacturers’ data sheets

6. Sequential Logic Principles

Bistable elements, Latches and flip–flops, S-R latch, D latch, Edge triggered D flip–flop, Master/slave flip–flops, T flip–flop.

Text Books

1. John F. Wakerley, Digital Design Principles and Practices, fourth edition, Pearson Education India, 2008.

2. Stephen Brown & Zvonko Vranesic, Fundamentals of Digital logic with VHDL design, first edition, McGraw Hill International edition, 2000.



Reference Books

1. Robert K. Dueck, Digital Design with CPLD Applications and VHDL, Thomson Asia Pte. Ltd., Singapore, 2001.

2. Alan B. Marcovitz, Introduction to logic design, first edition, McGraw Hill International edition 2002.

3. James Bignell & Robert Donovan, Digital Electronics, fourth edition, Thomson Asia Pte. Ltd., Singapore, 2001.

4. Moris & Miller (Eds), Designing with TTL Integrated Circuits: Prepared by Staff of Texas Instruments, McGraw Hill International edition, 1981





Course Title : ELECTRICAL TECHNOLOGY

Course Contents

1. Measuring Instruments

Review of Permanent Magnet Moving Coil (PMMC), Moving Iron Instruments, Electrodynamometer, Electrostatic Instruments, Rectifier type Instruments. Extension of ranges of voltmeters and ammeters. Principle of Power Factor and Frequency meter. Use of Current and Potential Transformers.

2. Measurement of R, L and C

Measurement of low, medium & high resistances – Wheatstone & Kelvin bridge, Ohmmeter, Megger. A.C. bridge circuits for measurement of inductance & capacitance-Maxwell’s, Hay’s & Anderson’s bridge, Schering bridge.

3. Potentiometers

Principles of DC and AC Potentiometers and their applications.

4. Magnetic Properties of Materials

The magnetic dipole movement, diamagnetism. The origin of permanent magnetic dipoles in matter, Paramagnetism, Ferromagnetism.

5. Three Phase Induction Motors

Rotating magnetic field, construction & principle of operation, slip, rotor frequency, development of equivalent circuit, torque equation, maximum torque, torque – speed characteristics, speed control. Starting methods, motor ratings.

6. Stepper Motor

Principle of working, characteristics and applications.

Text Books

1. Sawhney A K, A Course in Electrical and Electronic Measurements and Instrumentation, Dhanpatrai and Sons, 1993.

2. Golding, Electrical Measurements and Measuring Instruments, Wheeler Publishing, fifth edition, 1994.

Reference Books

1. Nagrath & Kothari, Electrical Machines, Tata McGraw Hill, second edition, 1997

2. Dekker A J, Electrical Engineering Materials, Prentice Hall of India, twelfth reprint, 1987.

3. Srinivasan M P, Stepping Motors, CEDT: Indian Institute of Science, 1985.





Course Title : NUMERICAL TECHNIQUES

Course Contents

1. Errors in Numerical Computation

Error types, analysis and estimation. Error propagation.

2. Roots of Equations

Bracketing Methods – The Bisection method, The False position method. Open Methods – The Newton-Raphson method, The Secant method. (relevant engineering applications)

3. Systems of Linear Algebraic Equations

Gauss-Elimination method – Technique, pitfalls, improvement. Gauss-Jordan method. LU decomposition and matrix inversion. Gauss-Seidel method. (relevant engineering applications)

4. Curve Fitting

Interpolation – Newton’s divided difference, Lagrange Interpolating polynomials. Approximation - Least square approximation technique, linear regression, and polynomial regression. (relevant engineering applications)

5. Numerical Differentiation

Methods based on interpolation and finite differences. (relevant engineering applications)

6. Numerical Integration

The Trapezoidal rule, Simpson’s 1/3 rule, Simpson’s 3/8 rule. (relevant engineering applications)

7. Solution to Ordinary Differential Equations

Taylor series method, Picard’s method of successive approximation. Runge – Kutta methods – Euler’s method, Euler’s predicator-corrector method, Runge-kutta method of second and fourth order. Boundary – value problems, Eigen value problems (concepts only). (relevant engineering applications)

8. Optimization

One-dimensional unconstrained - Golden-section Search, quadratic Interpolation, Newton’s method. Multidimensional unconstrained – Direct method, Gradient method. Linear programming - Graphical solution and simplex method. (relevant engineering applications and transportation problems)

Text Books

1. Seven C Chapra , Raymond P Canale, Numerical Methods for Engineers, Fourth Edition, Tata McGraw Hill, 2002.

2. Robert J Schilling, Sandra L Harris, Applied Numerical Methods for Engineers (Using MATLAB and C), first edition, Thomson Asia Pvt. Ltd., 2002





Course Title : BASIC ELECTRONIC CIRCUITS LAB

Course Contents

1. Diode Circuits

Analysis of Rectifier Circuits, Half Wave Rectification, Full Wave Rectification, Filter, Ripple Voltage, use of Zener Diode for regulation, Analysis of Clipper and Clamper Circuits.

2. Basic BJT Circuits

Current–Voltage Characteristics, DC Analysis of Transistor Circuits, Load Line and Modes Of Operation, Analog Signals and Linear Amplifiers, The Bipolar Linear Amplifier, Graphical

Analysis and AC Equivalent Circuit, Small Signal Hybrid – Equivalent Circuit of the Bipolar

Transistor, Hybrid – Equivalent Circuit Basic Transistor Amplifier Configurations, Common Emitter Amplifiers, AC Load Line Analysis, Common Collector Emitter Follower Amplifier, Common Base Amplifier, Multistage Amplifiers, Power Considerations, Environmental Thermal Considerations in Transistor Amplifiers, understanding manufacturers’ Specifications.

3. Basic FET Amplifiers

Basic JFET Amplifiers, the MOSFET Amplifier, Basic Transistor Amplifier Configurations, the Common Source Amplifier, The Source Follower Amplifier, The Common Gate Configuration, Analysis of The Power FET (VMOS) circuit.

Text Books







Course Title : DIGITAL COMBINATIONAL CIRCUITS LAB

Course Contents

1. Logic circuits

Logic signals and gates, combinational circuit analysis and synthesis – minimization, Karnaugh Maps, sum of products and product of sums expressions and their minimization, Quine McCluskey minimization algorithm implementation, understanding timing hazards – static and dynamic hazards, introduction to VHDL hardware description language

2. Combinational logic design practices

Design using SSI and MSI devices Decoders, Encoders, Three state buffers, Multiplexers, Parity circuits, Comparators, Adders, Subtractors, ALUs, Combinational multipliers. Using VHDL Combinational circuit design examples – multiplexor, de-multiplexor, decoder, encoder, 4 bit adder, 4 bit subtractor, 4 bit simple ALU, barrel shifter.

3. Logic families

Electrical behavior of CMOS circuits, propagation delay, power consumption, study of CMOS logic characteristics TTL logic characteristics, TTL NAND and NOR gates, fan – in, fan – out, Electrical behavior of TTL circuits, propagation delay, power consumption. CMOS / TTL interfacing, Interpreting Manufacturers’ data sheets

4. Sequential logic principles

Bistable elements, Latches and flip–flops, S-R latch, D latch, Edge triggered D flip–flop, Master/slave flip–flops, T flip–flop.

Text books

1. John F. Wakerley, Digital Design Principles and Practices, fourth edition, Pearson Education India, 2008.

2. Stephen Brown & Zvonko Vranesic, Fundamentals of Digital logic with VHDL design, first edition, McGraw Hill International edition, 2000.

Reference Books

1. Robert K. Dueck, Digital Design with CPLD Applications and VHDL, Thomson Asia Pte. Ltd., Singapore, 2001.

2. Moris & Miller (Eds), Designing with TTL Integrated Circuits: Prepared by Staff of Texas Instruments, McGraw Hill International edition, 1981





Course Title : ELECTRICAL ENGINEERING PRACTICE

Course Contents

1. Overview of measuring instruments

a) Construction and working principle of measuring instruments (PMMS, Moving Iron, Electrodynamometer, Electrostatic, Rectifier Type Instruments, Potentiometer)

b) Extending the range of Ammeter by using higher value of resistance in series c) Extension of range of Voltmeter

2. Measurement of Resistance

a) VI method b) Megger

3. Study of Bridges for measurement of unknown resistance

a) Wheatstone Bridge

Wheatstone bridge is an instrument for making comparison measurement and operates on null indication principle

b) Maxwell Induction Bridge This bridge circuit measures an inductance by comparing with a variable standard self induction

4. To study the principle and applications of AC & DC potentiometer

a) Calibration of Voltmeter, Ammeter, Wattmeter b) Measurement of unknown resistance and power

5. Stepper Motor

a) Characteristics & applications.

Text Books

1. Sawhney A.K., A Course in Electrical & Electronic Measurements & Instrumentation, Dhanpatrai and Sons, 1993

2. Golding, Electrical Measurements & Measuring Instruments, Wheeler Publishing, fifth edition, 1994

3. Srinivasan M. P., Stepping Motors, CEDT: Indian Institute of Science, 1985





Course Title : COMPUTATIONAL TECHNIQUES LAB

Course Contents

1. Roots of Equations

Bracketing Methods – The Bisection method, The False position method. Open Methods – The Newton-Raphson method, The Secant method

2. Systems of Linear Algebraic equations

c) Gauss-Elimination method – Technique, pitfalls, improvement. Gauss-Jordan method.

LU decomposition and matrix inversion. Gauss-Seidel method.

3. Curve fitting

Interpolation – Newton’s divided difference, Lagrange Interpolating polynomials. Approximation - Least square approximation technique, linear regression, and polynomial regression

4. Numerical differentiation

Methods based on interpolation and finite differences.

5. Numerical Integration- (including relevant engineering applications)

The Trapezoidal rule, Simpson’s 1/3 rule, Simpson’s 3/8 rule

6. Solution to Ordinary differential equations

Taylor series method, Runge – Kutta methods , Euler’s predicator-corrector method, Runga-kutta method of second and fourth order. Boundary – value problems.

7. Optimization

One-dimensional unconstrained - Golden-section Search, Newton’s method. Multidimensional unconstrained –Gradient method. Linear programming - Graphical solution and simplex method, transportation problem.

Text Books

1. Seven C. Chapra , Raymond P. Canale, Numerical Methods for Engineers ,Fourth Edition, Tata McGraw Hill, 2002

2. Robert J. Schilling , Sandra L. Harris, Applied Numerical Methods for Engineers (Using MATLAB and C), first edition, Thomson Asia Pte. Ltd., 2002



Programme Name : S.Y. B. Tech. (Electronics) SEMESTER – IV

Course Code : MA0206

Course Title : ENGINEERING MATHEMATICS - II

Course Contents Module 1 Vector Calculus and Analysis

1.1. Scalar and vector point functions, Directional derivative, Curl and Divergence,

Conservative, Irrotational and Solenoid field. 1.2. Line integral, Green’s theorem for plane regions and Properties of Line integral. 1.3. Stoke’s theorem, Gauss’s divergence theorem(without proof) related identities

and deductions Module 2 Matrices

Brief revision of vectors over a real field, inner product, norm linear independence and orthogonality of vectors. Characteristic polynomial, characteristic equation, characteristic roots and characteristic vectors of a square matrix, properties of characteristic roots and vectors of different types of matrices such as orthogonal matrix, Hermitian matrix, Skew-Hermitian matrix, diagonable matrix, Similar matrices. Cayley Hamilton’s theorem (without proof), Functions of a square matrix, Minimal polynomial and Derogatory matrix. Quadratic forms, congruent and orthogonal reduction of quadratic form, rank, index, signature and class value of quadratic form.

Module 3 Complex Variables

3.1 Line integral of a function of complex variable, Cauchy’s theorem for analytic function. Cauchy’s Goursat theorem(without proof), properties of line integral, Cauchy’s integral formula and deductions

3.2 Singularities and poles: Taylor’s and Laurent’s development (without proof), Residue at isolated singularity and its evaluation.

3.3 Residue theorem application to evaluate real integrals of type

dxxfdf ,,sin,cos

2

0

Text Books

1. Complex variables and applications: Churchil, Mc Graw Hill- 2003, 7th Edition 2. Advanced Engineering Mathematics. H. K. Dass S. Chand & Co. Ltd- 3rd Edition

Reference Books

1 Theory of functions of complex variables, Shanti Narayan, S Chand & Co 2. Engineering Mathematics- T. Veerarrajan Tata McGraw-Hill- IInd Edition 3. Elements of applied Mathematics, P.N. Wartikar, PVG Prakashan,2nd Edition Poona 1964.



Programme Name : S Y B Tech (Electronics) SEMESTER – IV


Course Title : ELECTRONICS CIRCUIT ANALYSIS AND DESIGN - II

Course Contents

1. Frequency Response of Amplifiers

Amplifier Frequency Response, System Transfer Functions, S – Domain Analysis, First – Order Functions, Bode Plots, Short–Circuit and Open–Circuit Time Constants, Frequency Response: Transistor Amplifiers with Circuit Capacitors, Frequency Response: Bipolar Transistor, Frequency Response: The FET, High Frequency Response of Transistor Circuits. Sinusoidal Oscillators: The phase shift Oscillator, The Wien Bridge Oscillator, The Tuned Circuit Oscillator, The Colpitts Oscillator and Hartley Oscillator.

2. Output Stage and Power Amplifiers

Power Amplifiers, Power Transistors – Power BJTs, Power MOSFETs, Heat Sinks, design of heat sinks, Classes Of Amplifiers – Class–A Operation, Class–B Operation, Class–AB Operation, Class–C Operation, Class–A Power Amplifiers, Class–AB Push Pull Complementary Output Stages.

3. Differential and Multistage Amplifiers

The Differential Amplifier, Basic BJT Differential Pair, Basic FET Differential Pair, Differential Amplifier with Active Load, BICMOS Circuits, Gain Stage and Simple Output Stage, Simplified BJT Operational Amplifier Circuit, Differential Amplifier Frequency Response. The Darlington Amplifier and Cascade Amplifier.

4. Feedback and Stability

Introduction to Feed Back, Basic Feedback Concepts, Ideal Close–Loop Gain, Gain Sensitivity Bandwidth Extension, Noise Sensitivity, Reduction of Nonlinear Distortion, Ideal Feedback Topologies, Series–Shunt, Shunt–Series, Series–Series, Shunt–Shunt Configurations, Voltage (Series – Shunt) Amplifiers, Current (Shunt – Series) Amplifiers, Trans Conductance (Series – Series) Amplifiers, Trans Resistance (Shunt – Shunt) Amplifiers, Loop Gain, Stability of The Feedback Circuit, The Stability Problem, Bode Plots: One – Pole, Two – Pole, and Three – Pole Amplifiers, Nyquist Stability Criterion, Phase and Gain Margins, Frequency Compensation Basic Theory, Closed Loop Frequency Response, Miller Compensation.

Text Books


2. Martin Roden, Gordon Carpenter, William Wieserman, Electronic Design, Fourth edition, Shroff Publishers, 2002

Reference Books

1. Donald Schilling and Charles Belove, Electronic Circuits Discrete and Integrated, Third edition, McGraw Hill International edition, 1989

2. Adel Sedra and Kenneth Smith, Microelectronic Circuits, Fourth edition, Oxford University Press, 1998





Course Title : PRINCIPLES OF MICROPROCESSOR SYSTEMS

Course Contents

1. Introduction

Introduction to Microprocessors, Microcomputers and Assembly Language.

2. Microprocessor Architecture and Microcomputer Systems

Microprocessor Architecture and its operations, Input and output (I/O) devices.

3. 8085 Microprocessor Architecture and Memory Interfacing

The 8085 architecture, Instruction cycles, machine cycles and T states. Concept of wait states. Minimum system design. Memory interfacing with timing considerations. Clock, Reset and buffering circuits. Testing and troubleshooting memory interface circuits.

4. 8085 Assembly Language Programming

The 8085 programming model, Instruction classification, Instruction and Data format, process of writing, assembly and execution of simple assembly language programs.

5. 8085 Instructions

Data transfer operations, Arithmetic & Logic operations, Branch operations, Writing assembly language programs, Debugging a program.

6. Programming Techniques

Looping, Counting and indexing, counters and timers, Code conversion, BCD arithmetic and 16 bit data operations. Software Development Systems and Assemblers.

7. Stack and Subroutines

Concept of Stack and subroutines, parameter passing techniques, Re-entrant and recursive subroutines.

8. I/O Data Transfer Techniques

Basic interfacing concepts, Interfacing input and output devices with examples, Memory mapped I/O and I/O mapped I/O. Testing and troubleshooting I/O interface circuits. I/O data transfer classification, Programmed I/O, Interrupt driven program controlled I/O, Hardware I/O (Direct Memory Access).

9. Interrupts

Requirements, Single level interrupt, Multi level interrupt, Vectored interrupt. 8085 interrupt structure and operation. 8259A programmable interrupt controller features and operation – single and cascaded.

10. Programmable Interface Devices

Features and operating modes of working of 8155 multifunction device, 8255A programmable peripheral interface, 8254, programmable interval timer. Direct memory access (DMA) and DMA



controller 8237, 8279 programmable keyboard/display interface.

11. Serial I/O and Data Communication

Basics concepts in serial I/O, 8085 serial I/O lines.

12. Microprocessor Applications

Interfacing scanned multiplexed displays and liquid crystal display, interfacing matrix keyboard, Introduction to emulators and logic analyzers.

Text Books

1. Ramesh S Gaonkar, Microprocessor Architecture, Programming and Applications with the 8085, fourth edition, Penram International Publishing (India), 2000.

2. Microprocessors and Programmed Logic, second edition, Prentice Hall of India, 1987.

Reference Books

1. Intel Corporation, 8085AH data manual



Course Contents

1. Sequential Logic Design

Clocked synchronous state machine analysis, Clocked synchronous state machine design, designing state machines using state diagrams, state machine synthesis using transition lists, decomposing state machines, feedback sequential circuits, VHDL sequential circuit design features.

2. Sequential Logic Design Practices

Sequential circuit documentation standards, use of latches and flip–flops in examples like switch de-bouncing, bus holder circuit, counters – ripple and synchronous, MSI counters and applications, decoding binary counter states, counters in VHDL. Shift registers, structure, MSI shift registers, serial / parallel conversion, shift register counters, ring counters, Johnson counters, linear feedback shift register counters, shift registers in VHDL. Synchronous design methodology, impediments to synchronous design, synchronizer failure and metastability. Design examples like a few simple machines, and traffic light controller, done in VHDL.

3. Memory, CPLDs and FPGAs

Types of memory devices, Read-Only Memory (ROM), Read / write memory, Static RAM, Dynamic RAM, Introduction to Xilinx XC9600 CPLD family and Xilinx XC 4000 FPGA family.

4. Additional Topics

Computer Aided Design (CAD) tools, Concept of design for testability, concept of digital system reliability, introduction to transmission lines, reflections and termination.

Text Books

1. John F Wakerley, Digital Design Principles and Practices, third edition updated, Pearson Education Singapore, 2002.

2. Stephen Brown and Zvonko Vranesic, Fundamentals of Digital Logic with VHDL Design, first edition, McGraw Hill International edition, 2000.

Reference Books

1. John M. Yarbrough, Digital Logic Applications and Design, first edition, Thomson Asia Pte. Ltd., Singapore, 2001



Course Title : DIGITAL DESIGN - II





Course Title : ELECTRICAL NETWORK ANALYSIS

Course Contents

1. Review

DC and AC circuits.

2. Mesh and Node Analysis

Mesh and Node Analysis of circuits with independent and dependent sources.

3. Linearity, Superposition and Source Transformation

Linearity, Superposition, Current & Voltage Source Transformation.

4. Network Theorems

Thevenin’s and Norton’s Theorem (with independent and dependent sources), Maximum power transfer theorem.

5. Circuit Analysis

Introduction to Graph Theory. Tree, link currents, branch voltages, cut set and tie set. Mesh and Node Analysis, Gauss Elimination Technique, Duality.

6. Time and Frequency Response of Circuits

First and second Order Differential equations, initial conditions. Evaluation and analysis of Transient and Steady state responses using Classical Technique as well as by Laplace Transform (for simple circuits only). Transfer function, Concept of poles and zeros. Frequency response of a system (concepts only).

7. Two - port Networks

Concept of two- port network. Driving point and Transfer Functions, Open Circuit impedance (Z) parameters, Short Circuit admittance (Y) parameters, Transmission (ABCD) parameters. Inverse Transmission (A’B’C’D’) parameters. Hybrid (h) parameters. Inter Relationships of different parameters. Interconnections of two - port networks. T and Pi representation. Terminated two - port networks.

8. Fourier Series

Orthogonal basis functions, Representation of a signal in terms of weighted Orthogonal basis functions, Calculation of weights (coefficients) in MSE sense, Extension to periodic signal in terms of Fourier Series Representation. Complex and Trigonometric Fourier series, Properties of Fourier series, Power Spectral Density

9. The Fourier Transform (FT)

Definition and Properties, FT of basic signals, FT of periodic signals, Energy Spectral Density.

Text Books

1. A Sudhakar and S P Shyammohan, Circuits and Networks, Tata McGraw Hill, thirteenth reprint, 2000.

2. William H Hayt, Jack E Kemmerly and Steven M Durbin, Engineering Circuit Analysis, McGraw Hill International, sixth edition, 2002.

Reference Books

1. Artice M Davis, Linear Circuit Analysis, Thomson Asia Pvt. Ltd., Singapore, first edition, 2001



2. M. E. Van Valkenburg, Network Analysis, Prentice Hall of India, third edition.

3. Raymond A DeCarlo and Pen-Min Lin, Linear Circuit Analysis, Oxford University Press, second edition, 2001.

Programme Name : S.Y. B. Tech. (Electronics) SEMESTER – IV

Course Code : CE0221

Course Title : ENVIORNMENTAL STUDIES

Course Contents

Unit 1: The Multidisciplinary nature of environmental studies

Definition, scope and importance, Need for public awareness.

Unit 2: Natural Resources

Renewable and non renewable resources: a) Natural resources and associated problems

Forest resources: Use and over-exploitation, deforestation, case studies, Timber extraction, mining, dams and their effects on forests and tribal people.

Water resources: Use and over-utilization of surface and ground water, floods, drought, conflicts over water, dam’s benefits and problems.

Mineral Resources: Use and exploitation, environmental effects of extracting and using mineral resources, case studies.

Food Resources: World food problems, changes caused by agriculture and over grazing, effects of modern agriculture, fertilizers- pesticides problems, water logging, salinity, case studies.

Energy Resources: Growing energy needs, renewable and non-renewable energy sources, use of alternate energy sources, case studies

Land Resources: Land as a resource, land degradation, man induces land slides, soil erosion, and desertification.

b) Role of individual in conservation of natural resources.

c) Equitable use of resources for sustainable life styles.

Unit 3: Eco Systems

Concept of an eco system

Structure and function of an eco system.

Producers, consumers, decomposers.

Energy flow in the eco systems.

Ecological succession.



Food chains, food webs and ecological pyramids.

Introduction, types, characteristic features, structure and function of the following eco systems:-

Forest ecosystem

Grass land ecosystem

Desert ecosystem.

Aquatic eco systems(ponds, streams, lakes, rivers, oceans, estuaries)

UNIT 4: Biodiversity and it’s Conservation

Introduction-Definition: genetics, species and ecosystem diversity.

Biogeographically classification of India.

Value of biodiversity: consumptive use, productive use, social, ethical, aesthetic and option values

Biodiversity at global, national and local level.

India as a mega diversity nation.

Hot-spots of biodiversity.

Threats to biodiversity: habitats loss, poaching of wild life, man wildlife conflicts.

Endangered and endemic spaces of India.

Conservation of biodiversity: in-situ and ex-situ conservation of biodiversity.

UNIT 5: Environmental Pollution

Definition Causes, effects and control measures of:- a. Air pollution

b. Water pollution

c. Soil pollution

d. Marine pollution

e. Noise pollution

f. Thermal pollution

g. Nuclear hazards

Solid waste Management: Causes, effects and control measures of urban and industrial wastes Role of an individual in prevention of pollution Pollution case studies Disaster management: Floods, earth quake, cyclone and land slides

Unit 6: Social issues and the Environment

Form unsustainable to sustainable development



Urban problems related to energy

Water conservation, rain water harvesting, water shed management

Resettlement and rehabilitation of people; its problems and concerns, case studies

Environmental ethics: issues and possible solutions

Climate change, global warming, acid rain , ozone layer depletion, nuclear

accidents and holocaust, case studies.

Wasteland reclamation

Consumerism and waste products

Environment protection Act

Air(prevention and control of pollution)Act

Water((prevention and control of pollution)Act

Wildlife protection act

Forest conservation act

Issues involved in enforcement of environmental legislations

Public awareness

Unit 7: Human population and the environment

Population growth and variation among nations

Population explosion- family welfare programme

Environment and human health

Human rights

Value education

HIV/AIDS

Women and child welfare

Role of information technology in environment and human health

Case studies

Unit 8: Field work

Visit to a local area to document environment assets river/ forest/ grassland/ hill/mountain. Visit to a local polluted site-urban/rural/industrial/agricultural. Study of common plants, insects, birds. Study of simple ecosystems-pond, river, hills lopes, etc(field work equal to 5 lecture works)



Text Books

1. Textbook of Environmental studies, Erach Bharucha, UGC 2005

2. Fundamental concepts in Environmental Studies, D D Mishra, S Chand & Co Ltd 2010





Course Title : ELECTRONIC DESIGN LAB

Course Contents

1. Frequency Response of Amplifiers

Amplifier Frequency Response, Bode Plots, Transistor Amplifiers with Circuit Capacitors, Frequency Response: JFET Amplifier, High Frequency Response of Transistor Circuits. Sinusoidal Oscillators: The phase shift Oscillator, The Wien Bridge Oscillator, The Tuned Circuit Oscillator, The Colpitts Oscillator and Hartley Oscillator. .

2. Output Stage and Power Amplifiers

Power Amplifiers, design of heat sinks, Class–A Power Amplifiers, Class–AB Push Pull Complementary Output Stages.

3 Differential and Multistage Amplifiers

The Differential Amplifier, Differential Amplifier with Active Load, BICMOS Circuits, Gain Stage and Simple Output Stage, Differential Amplifier Frequency Response. The Darlington Amplifier and Cascode Amplifier.

4 Feedback and Stability

Feedback Topologies, Series–Shunt, Shunt–Series, Series–Series, Shunt–Shunt Configurations, Voltage (Series – Shunt) Amplifiers, Current (Shunt – Series) Amplifiers, Trans Conductance (Series – Series) Amplifiers, Trans Resistance (Shunt – Shunt) Amplifiers, The Stability Problem, Bode Plots, Nyquist Stability Criterion, Phase and Gain Margins, Frequency Compensation, Closed Loop Frequency Response..

Text Books



Reference Books

1. Donald Schilling & Charles Belove, Electronic Circuits Discrete and Integrated, Third edition, McGraw Hill International edition, 1989

2. Adel Sedra & Kenneth Smith, Microelectronic Circuits, Fourth edition, Oxford University Press, 1998





Course Title : DIGITAL SEQUENTIAL CIRCUITS LAB

Course Contents

1. Sequential logic design practices

Design of sequential circuits from latches and flip–flops in examples like switch de-bouncing, counters – ripple and synchronous, MSI counters and applications, decoding binary counter states. Implementing counters in VHDL. Design of Shift registers, Working with MSI shift registers, serial / parallel conversion, shift register counters, ring counters, Johnson counters, linear feedback shift register counters. Implementing shift registers in VHDL. Design examples of simple machines, like traffic light controller, implemented in VHDL

Text Books

1. John F. Wakerley, Digital Design Principles and Practices, third edition updated, Pearson Education Singapore, 2002.

2. Stephen Brown & Zvonko Vranesic, Fundamentals of Digital Logic with VHDL Design, first edition, McGraw Hill International edition, 2000.

Reference Books

1. John M. Yarbrough, Digital Logic Applications and Design, first edition, Thomson Asia Pte. Ltd., Singapore, 2001

Course Contents

1. 8085 Assembly Language Programming

The 8085 programming model, Instruction and Data format, process of writing, assembly and execution of simple assembly language programs like 8 bit and 16 bit addition and subtraction of hexadecimal numbers. Debugging programs. Programs based on Data transfer operations, Arithmetic & Logic operations, Branch operations. .

2. Programming Techniques

Programs based on Looping, Counting and indexing, counters and timers, Code conversion, BCD arithmetic operations.

3 Stack and Subroutines

Stack and subroutines, parameter passing techniques.

4 I/O data transfer techniques

Interfacing input and output devices with examples of usage of 8255A. 5 Interrupts

Single level interrupts, Multi level interrupts, Vectored interrupts.

6. 8085 Microprocessor and Memory Interfacing

Instruction cycles, machine cycles and T states, wait states. Memory interfacing with timing considerations. Clock, Reset and buffering circuits.

7. Microprocessor Applications



Course Title : MICROPROCESSOR SYSTEMS I LAB



Text Books

1. Ramesh S. Gaonkar, Microprocessor Architecture, Programming and Applications with the 8085, fourth edition, Penram International Publishing (India), 2000.

2. Kenneth Short, Microprocessors and Programmed Logic, second edition, Pearson Education, 1987



Course Title : ELECTRICAL NETWORKS LAB

Course Contents

1. Mesh & Node Analysis

Mesh & Node Analysis of circuits with independent & dependent sources.

2. Linearity, Superposition & Source Transformation

Linearity, Superposition, Current & Voltage Source Transformation..

3 Network Theorems

Thevenin’s & Norton’s Theorem, Superposition theorem, Maximum power transfer theorem.

4 Circuit Analysis

Introduction to Graph Theory. Tree, link currents, branch voltages, cut set & tie set. Mesh & Node Analysis, Gauss Elimination Technique, Duality

5 Time & Frequency Response of Circuits

First & second Order Differential equations, analysis of transient and steady state responses using Classical Technique as well as by Laplace Transform (for simple circuits only). Frequency response of a system.

6. Two – port Networks

Concept of two- port network. Driving point & Transfer Functions, Open Circuit impedance (Z) parameters, Short Circuit admittance (Y) parameters, Transmission (ABCD) parameters. Inverse Transmission (A’B’C’D’) parameters. Hybrid (h) parameters. Inter Relationships of different parameters. Interconnections of two - port networks. T & Pi representation. Terminated two - port networks.

Text Books

1. A. Sudhakar & S. P. Shyammohan, Electrical Circuits and Network Analysis, Tata McGraw Hill, third edition, Aug 2007.

2. William. H. Hayt, Jack E. Kemmerly & Steven M. Durbin, Engineering Circuit Analysis, McGraw Hill International, sixth edition, 2002.

Reference Books

1.

M. E. Van Valkenburg, Network Analysis, Prentice Hall of India, third edition

s y btech electronics engg syllabus (1)

Documents

ese o hrs

t p total hours credits

end semester oral examination

course requirement

course coordinator

semester tests

examination duration

mid semester test