scheme & syllabus for iii and iv semesters b.e ... & syllabus for iii and iv semesters b.e....
TRANSCRIPT
Scheme & Syllabus for III and IV semesters
B.E. – Electronics &Instrumentation Engineering
2015-16
Course
Code
Course Title L T P C
III Semester
MA301 Engineering Mathematics – III 4 0 0 4
EI302 Electronic Devices and Circuits 4 0 0 4
EI303 Network Analysis 4 0 0 4
EI304 Logic Design 4 0 0 4
EI305 Transducer and Instrumentation 4 0 0 4
EI306 Electronic Instrumentation and Measurement Techniques 3 0 0 3
EI307 Analog Electronics Lab 0 0 3 1.5
EI308 Instrumentation Lab 0 0 3 1.5
HS003 Communication Skills-1 0 0 2 1
Total Credits 27
IV Semester
MA401 Engineering Mathematics-IV 4 0 0 4
EI402 Linear ICs and Signal Conditioning Circuits 4 0 0 4
EI403 Process Instrumentation-I 4 0 0 4
EI404 Signals and systems 4 0 0 4
EI405 Advanced Microprocessors 4 0 0 4
EI406 Introduction to VHDL Programming 4 0 0 4
EI407 Digital circuits and VHDL lab 0 0 3 1.5
EI408 Linear Integrated circuits lab 0 0 3 1.5
Total Credits 27
Engineering Mathematics – III (Common to all Branches)
Exam hours: 3 Sub. Code MA301 LTPC:4-0-0-4 Hours / week: 4 Total hours: 52 Course outcomes (Cos) (with mapping shown against the program outcomes - Pos)
1. Introducing Fourier series to learn practical harmonic analysis and learning
Fourier transforms and its inverse. (Po-1, Po-5,
Po-8)
2. Adopting Z-transforms concepts to solve difference equations and solving
algebraic and transcendental equations numerically. (Po-1,
Po-5, Po-8, Po-9, Po-11)
3. Adopting numerical different formulas for solving engineering problems and
exposure to numerical integration through standard rules. (Po-5, Po-
8, Po-9, Po-11)
4. Learning solution of system of homogeneous equations through matrices and
numerical solution of differential equations. (Po-1, Po-5,
Po-8, Po-9, Po-11)
COURSE CONTENTS
PART A
Unit 1 Fourier series: Periodic functions, representation of a periodic function as a Fourier series using Euler’s Formulae. Fourier series of an even & an odd function. Half-range Fourier series and practical harmonic analysis-illustrative examples. Graphs of Fourier series. (7 hours)
Unit 2 Fourier Transforms and Inverse Fourier transforms: – properties of Fourier transform, Evaluation of Complex Fourier, Fourier sine & Fourier cosine transforms. Inverse complex Fourier, Inverse sine & Cosine transforms. Applications of transforms to boundary value problems. (7 hours)
PART B
Unit 3 Z-Transforms: Definition, standard forms, Linearity property, damping rule, shifting rule – Problems. Inverse Z transforms. Solution of Difference equations using Z Transforms. (6 hours)
Unit 4 Numerical Techniques: Solution of algebraic & Transcendental equations by (i) Bisection method, (ii) Newton Raphson method.,(iii) Regula falsi method Solution of non – linear system of equations by using Newton Raphson method. (6 hours)
PART C
Unit 5 Numerical Interpolation / Extrapolation: Finite differences - Forward, backward & Central differences. Interpolation by Newton’s Interpolation formula (both forward & backward), Stirling & Bessel’s interpolation formula for central interpolation. Lagrange’s & Newton’s divided differences formula for un-equal intervals. Some application oriented engineering problems. (7 hours)
Unit 6 Numerical Integration: General quadrature formula with proof and deduction of trapezoidal rule, Simpsons 1/3rd rule, weddles rule and illustrative examples. Gaussian quadrature 3 point formula (6 hours)
PART D
Unit 7 Matrix algebra, Consistency of non homogeneous system of equations using the rank concept,( using elementary row operation), Solution of the system of linear equations by Gauss elimination method, Gauss – Seidel iterative method. Solution of system of homogeneous equations, Finding Eigen values and Eigen vectors of matrices. Physical significance of Eigen values and Eigen vectors in Engineering. (6 hours)
UNIT 8 Numerical solution of ordinary differential equations. Computation of solution by using the following single step methods: Taylor series method, Picard’s method of successive approximation, Runge-Kutta method of fourth order., Solution of first order simultaneous differential equations by R.K. method of fourth order . Predictor and corrector methods (Adams Bashforth method). (7 hours)
Text Book: Dr. B. S. Grewal, Higher Engineering Mathematics, Khanna Publications, 40th edition (2007)
Reference Books: 1. Erwin Kreyezig, Advanced Engineering Mathematics, Tata McGraw Hill Publications,
8th edition (2007) 2. S. C. Chapra and R. Canale, Numerical Analysis for Engineers, Tata McGraw Hill
Publications, 5th edition (2005) 3. Numerical methods for Scientific and Engineering computation by M.K. Jain, SRK Iyengar, R.K. Jain, 5th edition, New age International Publishers.
SUBJECT CODE: EI302 CIE: 50
SUBJECT: ELECTRONIC DEVICES AND CIRCUITS EXAM HOURS: 3
HOURS / WEEK: 4 SEE: 50 TOTAL HOURS: 52
Prerequisites: Basic Electronics
Objectives: Upon completion of this course, student should be able to:
Know the fundamentals of electronic circuits and componentsPO1
Implement amplifier circuits using electronic components PO5
Design and improve the efficiency of power amplifiers. PO1PO4
Design and implement regulated power supplies for electronic device PO3
PART-A 1. DC Biasing-BJTs: Operating point, Fixed-Bias Configuration, Emitter-Bias Configuration,
Voltage-Divider Bias Configuration, Collector Feedback Configuration, Emitter-Follower
Configuration, Common-Base Configuration, Miscellaneous Bias Configuration. 7Hours
2. Bias Stabilization and BJT AC Analysis: Bias Stabilization, Practical Applications,
Introduction toBJT AC Analysis, Application in the AC Domain, BJT Transistor Modeling
6Hours
PART-B
3. BJT and JFET Frequency Response: Introduction, Logarithms, Decibels,Frequency
Considerations, Normalization Process
7Hours
4. BJT and JFET Frequency Response(Continued):Miller Effect Capacitance, High frequency
Response-BJT Amplifier, Multistage Frequency Effects, graphical determination of h-parameters.
6Hours
PART-C
5. Power Amplifiers: Introduction, Series-Fed Class A Amplifier, Transformer-Coupled Class A
Amplifier, Class B amplifier Operation, Class B amplifier Circuits, Amplifier Distortion, Power
Transistor heat Sinking, Class C and Class D Amplifiers.
7Hours
6. Feedback and Oscillator Circuits: Feedback concepts, Feedback connection Types. Practical
feedback circuits, Feedback amplifier-phase and frequency considerations.
6Hours
PART-D
7. Feedback and Oscillator Circuits (Continued): Oscillator Operation, Phase shift oscillator,
Wein bridge Oscillator, Tuned Oscillator circuit, Crystal Oscillator.
6Hours
8. Power Supplies: Introduction, General filter Considerations, Capacitor filter, RC filter, Discrete
Transistor Voltage Regulation, IC voltage regulators, Practical Applications.
7Hours
Text Book:
Electronics Devices and Circuit Theory, Robert L.Boylestad and Louis Nashelsky, ,PHI, 9th
Edition.
Reference Book:
Integrated Electronics: Analog and Digital Circuits, Jacob Millman and Christos C Halkias, ,
TMH, 2001.
SUBJECT CODE: EI303 CIE: 50
SUBJECT: NETWORK ANALYSIS EXAM HOURS: 3
HOURS / WEEK: 4 SEE: 50 TOTAL HOURS: 52
Prerequisites: Basic Electrical Engineering
Objectives: Upon completion of this course, student should be able to
To impart knowledge on passive linear networks, source transformation, DC & AC
network analysis & resonant circuits.PO2,PO1
To introduce students to different theorems of N/Ws& transient behavior of
N/Ws.PO3,PO1
Apply circuit theory techniques to find response of DC & Ac one port and two port
networks using Laplace Transformation PO1,PO4,PO9
PART-A
1: Basic Concepts
Practical sources, Source transformations, Loop and node analysis with linearly dependent and
independent sources for DC and AC networks, Concepts of super node and super mesh
07 Hours
2: Network Topology
Graph of a network, Concept of tree and co-tree, incidence matrix, tie -set, tie-set and cut-set
schedules, Formulation of equilibrium equations in matrix form, Solution of resistive networks,
Principle of duality.
07 Hours
PART-B 3: Network Theorems – 1
Superposition, Reciprocity and Millman’s theorems (Numerical only on independent sources)
06 Hours
4: Network Theorems - II
Thevinin’s and Norton’s theorems; Maximum Power transfer theorem (Numerical only on
independent sources)
06 Hours
PART-C 5: Resonant Circuits
Series and parallel resonance, frequency response of series and Parallel circuits, Q –factor,
Bandwidth.Relevant derivations and numerical.
06Hours
6:Transient behavior and initial conditions
Behavior of circuit elements under switching condition and their Representation, evaluation of
initial and final conditions in RL, RC and RLC circuits for AC and DC excitations.Relevant
derivations and numerical.
07 Hours
PART-D 7: Applications of Laplace Transformation
Step, Ramp and Impulse responses, waveform Synthesis, Solution of networks using Laplace
transforms, Initial and final value theorem and numerical
07 Hours
8: Two port network parameters
Definition of z, y, h and transmission parameters, modeling with these parametersand
relationship between parameters sets. Relevant derivations and numericals.
06 Hours
TEXT BOOK:
Network Analysis, M. E. Van Valkenburg, PHI / Pearson Education, 3rd Edition.
REFERENCE BOOK:
Networks and systems Roy Choudhury, 2nd edition, 2006 Re-print, New Age International
Publications
SUBJECT CODE: EI304 CIE: 50
SUBJECT: LOGIC DESIGN EXAM HOURS: 3
HOURS / WEEK: 4 SEE: 50 TOTAL HOURS: 52
Prerequisites: Basic Electronics
Objectives: Upon completion of this course, student should be able to
Know the fundamentals of digital logic, Understand simplification of Boolean expressions
using various methods(PO1, PO2)
Design and analyze combinational logic circuits(PO1, PO4)
Know the fundamentals of sequential circuits and their applications(PO3)
Design and verification of sequential circuits using various methods(PO2,PO4)
PART-A 1: Principles of combinational logic – I:Review of Boolean algebra, Normal and Canonical
forms (Minterm and maxterm equations), Definition of combinational logic, Generation of
switching equations from truth tables, Karnaugh maps-2, 3 and 4 variables; Completely and
Incompletely specified functions (Don’t Care terms), Simplifying Min term and Max term
equations using K-map, Determination of minimal sum and minimal product expressions using
essential prime implicants and essential prime implicates.
07 Hours
2: Principles of combinational Logic - II Synthesis and Analysis of combinational logic
circuits, code conversion: Binary to gray, Gray to Binary, Binary to BCD, BCD to Binary, BCD
to excess-3 code, etc., Realization of logic circuits using Universal gates (NAND & NOR gates),
VEM for completely specified functions
07 Hours
PART-B 3: Analysis and design of combinational logic
General approach, Adders and subtractors –Binary parallel adder &subtractors, Look ahead
carry full adder, BCD adder and Magnitude comparators. Design BCD to Excess-3 code
converter, Excess – 3 code to Binary converter (using Binary parallel Adder).
06 Hours
4: Analysis and design of combinational logic with MSI Components
Decoders-realization of Canonical expressions, Realization of BCD to Excess-3 code converter
and Excess – 3 code to Binary converter, Encoders, Digital multiplexers – Realization of
Boolean canonical expressions using multiplexers.
06 Hours
PART-C 5: Basic Sequential Circuits and their Applications:
Review of basic latches and their applications: Basic Bi-stable Elements and Latches, SR Latch
and SR latch, Applications of SR and SR Latch, A Switch Debouncer; The gated SR Latch, The
gated D Latch, The Master-Slave Flip-Flops (Pulse-Triggered Flip-Flops): The Master-Slave SR
Flip-Flops, The Master-Slave JK Flip- Flop, T – FF, Edge Triggered Flip-Flop: The Positive
Edge-Triggered D Flip-Flop, Negative-Edge Triggered D Flip-Flop. Characteristic Equations of
all basic sequential circuits.
07 Hours
6: Sequential Circuits – 2
Registers, Counters - Binary Ripple Counters, Synchronous Binary counters, Counters based on
Shift Registers, Design of Synchronous counters, Design of a Synchronous Mod-6 Counter using
clocked JK Flip-Flops, Design of a Synchronous Mod-6 Counter using clocked D, T, or SR Flip-
Flops
07 Hours
PART-D 7: Sequential Design – I
Introduction, Mealy and Moore Models, State Machine Notation for basic latches, Analysis of
Synchronous Sequential Circuit.
06 Hours
8: Sequential Design – II
Construction of state Diagrams: Sequence detectors, Design of a Synchronous Counter using
clocked D, T, SR and JK Flip-Flops based on Mealy and Moore models.
06 Hours
TEXT BOOKS:
1.Digital Principles and Design, Donald D Givone, , Tata McGraw Hill Edition, 2002.
2.Digital Logic Applications and Design, John M Yarbrough, , Thomson Learning, 2001.
REFERENCE BOOK:
2. Digital System Design , Ronald J Tocci, PHI, 2nd edition
SUB CODE: EI305 CIE: 50
SUB: TRANSDUCERS AND INSTRUMENTATION EXAM HOURS: 3
HOURS / WEEK: 4 SEE: 50 TOTAL HOURS: 52
Prerequisites: Basic Electronics, Mathematics
Objectives: Upon completion of this course, student should be able to:
• Will know the sub systems in an instrumentation system and possible ways to reduce errors
in measurement.(PO2,PO4,PO5)
• Know the characteristics of an instrument and be able to classify the system into different
order depending on their mathematical model.(PO3,PO6)
• Will be able to classify the transducers depending on their working principle and selection of
transducers for an application(PO2,PO3,PO6,PO7)
• Can solve numerical problems related to different transducers and instruments.(PO1)
PART-A 1: Introduction
Functional elements of an instrument: analog & digital modes of operation, I/O configuration of
measuring instruments & instrument system- methods of correction for interfering & modifying
inputs Definition of a transducer, Active and Passive Transducers, Primary and Secondary
Transducers, Advantages of Electrical Transducers, Selection of Transducers.
07 Hours
2: Static Characteristics Of Instruments
Definition, Static Calibration, Static Error & correction, accuracy & Precision, linearity,
Resolution & Threshold, Sensitivity, Reproducibility, Repeatability, Range, Span and Bias,
Drift, Dead time & Dead zone, Hysteresis, Stability Problems.
07 Hours
PART-B
3: Time Domain Analysis
Zero Order Instruments, 1st & 2nd Order Instruments – Step, ramp, & Impulse
Responses,(Derivations excluding second order system), Time Domain Specifications: Rise time,
Delay time, Peak Overshoot & Settling time, Problems.
06 Hours
4: Dynamic Characteristics Of Instruments
Definition, Speed of Response, measuring lag, Fidelity, Dynamic Error, dead time, Frequency
response of 1st & 2nd order Systems, Correlation between time and Frequency response of 2nd
Order Instruments, Problems.
06 Hours
PART-C 5: Resistive Transducers
Potentiometers: Characteristics, loading effect, Linearity & sensitivity, advantages &
disadvantages of Resistive potentiometers. strain gauge: theory, Types, Applications,
Thermistors, RTD, problems.
07 Hours
6: Capacitive Transducers
Capacitive Transducers using change in area of plates, distance between plates, & change of
dielectric constants, derivation for sensitivity Linearity by differential arrangement, frequency
response, advantages, disadvantages & applications of Capacitive Transducers, problems.
06 Hours
PART-D 7: Variable Inductance Transducer
Linear variable differential Transformer (LVDT): Principles, characteristics, advantages,
disadvantages, applications, RVDT and problems
06 Hours
8: Special Transducers
Piezo-electric Transducers: Principles of operation, expression for output voltage, piezo-electric
materials, equivalent circuit, Loading effect, charge Amplifier, frequency response, Applications,
and problems.
07Hours
TEXT BOOK:
1. Electrical & Electronic Measurements &Instrumentation ,A.K. Sawhney, 17th edition
REFERENCE BOOKS:
1. Measurement Techniques ,E.O.Doeblin, McGraw Hill publications. 6th edition
2. Transducers and Instrumentation, D.V.S Murthy PHI
SUBJECT CODE: EI306 CIE: 50
SUBJECT: ELECTRONIC INSTRUMENTATION AND MEASUREMENT TECHNIQUES EXAM HOURS:3
HOURS / WEEK: 3 SEE: 50 TOTAL HOURS: 40
Prerequisites: Basic Electronics, Basic Electrical Engineering
Objectives: Upon completion of this course, student should be able to:
• Know behavior of errors and methods to reduce errors for a measurement
process(PO1,PO10)
• Know the operation principle of various electrical/electronic Instruments and photo
devices(PO4,PO10)
• Understand working and applications of various bridges(PO2,PO1)
• Solve numerical related to different instruments and bridges(PO2)
PART-A 1: Introduction
Measurement Errors: Gross errors and systematic errors, Absolute and Relative errors.
Voltmeters: Multi-range voltmeter, Loading, AC voltmeter using Rectifiers – Half Wave and full
wave.
05Hours
2: Digital Instruments
Digital Voltmeters – Introduction, DVM’s based on V – T, V – F and Successive approximation
principles, Resolution and sensitivity, General Specifications, Digital Multi-meters, Digital
frequency meters, Digital Measurement of time.
05 Hours
PART-B 3: Oscilloscopes
Introduction, Basic principles, CRT features, Block diagram, applications, Dual beam and dual
trace CRO concepts, Digital storage oscilloscopes-block diagram.
05 Hours
4: Signal Generators
Introduction, Fixed and variable AF oscillator, Signal generator, AF sine and Square wave
generator, Function generator, Square and Pulse generator.
05 Hours
PART-C 5: DC Potentiometers
Principle of operation, standardization of DC Potentiometer, calibration of Ammeter, Voltmeter
and Wattmeter. 05 Hours
6: DC bridges
Whetstone’s bridge, derivation for sensitivity of quarter, half and full bridges, Kelvin’s Bridge,
Kelvin’s double bridge, Applications and problems.
05 Hours
PART-D 7: AC bridges
Maxwell’s bridge, Maxwell’s inductance-capacitance bridge, Andersons Bridge, Desauty’s
Bridge, Wien’s Bridge (including the analysis of phasor diagram for all), Limitations,
Applications.
05 Hours
8: Photo Transducers and Photo Devices
Transducers-definition, photoelectric transducer, Photovoltaic transducer, Semiconductor photo
devices, Display devices: classificationof display, LED, LCD.
05 Hours
TEXT BOOK:
Electronics & electrical measurements, A K Sawhney ,DhanpatRai& sons, 17th edition.
REFERENCE BOOK:
Modern electronic instrumentation and measuring techniques, Cooper D & A D Helfrick, ,
PHI, 1998.
SUBJECT: CODE: EI307 CIE: 50
SUBJECT: ANALOG ELECTRONICS LAB EXAM HOURS: 3
HOURS / WEEK: 3 SEE: 50 TOTAL SLOTS: 14
Prerequisites: Basic Electronics, Electronic devices & Circuits.
Objectives: Upon completion of this lab, student should be able to:
Understand working of transistor configurations. PO1,PO3
Understand application of diodes. PO1,PO4
Design and test various circuits involving analog electronic components. PO1,PO7
Simulate and analyze circuits using software tools. PO5,PO9
CIRCUIT CONNECTION AND VERIFICATION
1. Determination of operating point for CE configuration.
2. Design of single stage R−C coupled BJT amplifier and determination of the gain-
frequency response, input and output impedances.
3. Design of BJT voltage series feedback amplifier and determine the gain, frequency
response,
4. Testing of full wave and half wave rectifiers using diode(with/without RC filter)
5. Determination of static characteristics of SCR and Diac.
6. Design and testing of the performance of BJT Hartley oscillator.
7. Design and testing of single ended diode clipping circuits.
8. Design and testing of double ended diode clipping circuits.
9. Design and testing of diode clamping circuits (positive clamping and negative clamping).
10. Determination of line and load regulation for voltage regulator using IC.
Following experiments are to be simulated using P-Spice.
1. Familiarization of PSpice software.
2. Characteristics of BJT transistor in CB and CE configuration.
SUBJECT: CODE: EI308 CIE: 50
SUBJECT: INSTRUMENTATION LAB EXAMHOURS: 3
HOURS / WEEK: 3 SEE: 50 TOTAL SLOTS: 14
Prerequisites: Transducers & Measurements
Objectives: Upon completion of this lab, student should be able to: Know the working and characteristics of bridges and Transducers(PO3,PO6)
Know the dynamic characteristics of a system(PO2)
Understand the application of transducer in Instrument devices(PO3,PO4)
Calibrate voltmeters, ammeters and wattmeter with respect to a standard instrument(PO5)
1. Characteristics of first order system (RC Network only).
2. Measurement of resistance by Wheatstone bridge and Determination of
its sensitivity using quarter, half and full bridge configurations.
3. Measurement of Low resistance by Kelvin's Double Bridge.
4.Characteristics of RTD.
5. Characteristics of Thermocouple.
6. Characteristics of Thermistors.
7. Characteristics of L.V.D.T.
8. Characteristics of LDR.
9. Measurement of self inductance by Maxwell's bridge
10.Measurement of self inductance by Anderson’s Bridge.
11.Measurement of load by using strain gages mounted on cantilever beam (quarter, half
and full bridge).
12.Calibration of Ammeter and Voltmeter using DC potentiometer.
III Semester Bridge Course for Diploma Students (Common to all branches of Engineering)
(Audit Course) Subject: Advanced Mathematics - I Subject Code: MATDIP301 Hours / week: 3 Total hours: 40
Course outcomes (Cos) (with mapping shown against the program outcomes - Pos) 1. Understanding basic concepts of differential calculus through mean value
theorem.
(Po-1, Po-3, Po-5) 2. Introduction to polar coordinates and learning partial differentiation
techniques.
(Po-1, Po-5, Po-9, Po-11)
3. Application of partial differentiation and approximations. (Po-1, Po-5, Po-8,
Po-11)
4. Learning multiple integrals and introduction to complex calculus.
(Po-1, Po-5, Po-8, Po-11)
COURSE CONTENTS
PART – A
Unit: 1: Differentiation-I: Review of limit and Continuity, differentiation- Basic formulas,
Sum rule, product rule, quotient rule, chain rule and problems. (5 hours)
Unit: 2: Differentiation-II: Rolle’s Theorem, Lagrange’s Mean value theorem and
Cauchy’s mean value theorem (statements), problems (5
hours)
PART – B Unit: 3: Differentiation-III: Polar curves- angle of intersection between the curves, Pedal
form, Taylor’s series, and Macluaurin’s series of simple functions for single variables.
(5 hours)
Unit 4: Partial differentiation -I: Definition, Illustrative examples on Partial differentiation,
Total differentiation, chain rule, differentiation of composite and implicit functions.
(5 hours)
PART - C
Unit 5: Partial differentiation –II: Jacobians illustrative examples and problems, Maxima
& Minima of a function of two variables, Approximations and Errors simple problems
(5 hours)
Unit 6: Integration: Basic formulas, Illustrative examples, integration of standard
function, Integration by parts, Bernoulli’s rule of Integration.
(5 hours)
PART - D
Unit 7: Integral calculus: Reduction formula for functions
(without proof), Simple problems, Double & triple integration, simple problems with
standardlimits. (5 hours)
Unit 8: Complex Numbers: Definition, Complex numbers as an ordered pair, real and
imaginary part, modulus and amplitude of a complex number, polar form, exponential
form, expressing in the form problems. (5 hours)
Reference Books:
1. Dr. B. S. Grewal, Higher Engineering Mathematics, Khanna Publications,
40th edition (2007).
2. Erwin Kreyezig, Advanced Engineering Mathematics, Tata McGraw Hill
Publications, 8th edition (2007)
Engineering Mathematics – IV (Common to all Branches)
Exam hours: 3 Sub. Code MA 401 LTPC:4-0-0-4 Hours / week: 4 Total hours: 52 Course outcomes (Cos) (with mapping shown against the program outcomes - Pos)
1. Introduction to complex differential calculus and its applications through
conformal mapping. (Po-1, Po-5, Po-9, Po-
11)
2. Adopting residue concept for complex integration and learning basics of
statistics.
(Po-1, Po-5, Po-8, Po-11) 3. Exposure to probability theory and its applications for discrete random variables.
(Po-1, Po-5, Po-11) 4. Learning concepts of continuous random variables and hence adopting Marcov
chain in stochastic process. (Po-1, Po-4, Po-5,
Po-9, Po-11)
COURSE CONTENTS
PART A Unit 1 Functions of a complex variable: Definition of limit, continuity and
differentiability of a function of a complex variable. Analytic functions. Cauchy-Riemann equations in Cartesian and polar forms. Harmonic functions. Construction of an analytic function using Milne-Thomson method (Cartesian & Polar forms). Illustrative examples from Eng. field (6 hours)
Unit 2 Conformal Mapping: Definition of Conformal Transformation and discussion of standard transformations.
.sin,,,2
2 zwz
kzwewzw z Bilinear transformations, Cross
ratio property with proof, illustrative examples. (6 hours) PART B
Unit 3 Complex Integration: – Cauchy’s theorem, Cauchy’s Integral formula, Evaluation of integrals using Cauchy’s integral formula, Zeros of an analytic function, Singularities and Residues, Calculation of residues, Evaluation of real definite integrals. (7 hours)
Unit 4 Statistics: Review of Mathematical Statistics - measures of central tendency and measures of dispersion. Curve fitting by least square method – Straight lines, parabola, and exponential curves. Correlation – Karl Pearson coefficient of correlation and Spearman’s rank correlation coefficient. Regression analysis. Illustrative examples. (7 hours)
PART C Unit 5 Probability: Basic counting principles, sample space, random (6hours)
experiment, definition of probability and probability axioms. Addition and multiplication law of probability, conditional probability, and Bayes’ theorem. Illustrative examples.
Unit 6 Discrete Random Variables: Definitions and properties of PDF & CDF. Theoretical Distributions - Binominal, Poisson Distributions. Expectation and variance. Illustrative examples. (7 hours)
PART D
Unit 7 Continuous Random Variables: Definition and properties, PDF and CDF. Theoretical distribution of a continuous random variable – Exponential, Normal/Gaussian . Expectation and variance of theoretical distribution functions .(6 hours)
UNIT 8 Joint Probability Distribution & Stochastic Processes: Concept of joint probability, Joint distributions of discrete random variables, Independent random variables problems. Joint expectation, co-variance and regression coefficients. Stochastic Processes – Classification, Markov Chains: Introduction, probability vectors, stochastic matrices, fixed points and regular stochastic matrices. (7 hours )
Text Book: 1. Dr. B. S. Grewal, Higher Engineering Mathematics, Khanna Publications, 40th
edition (2007) Reference Books:
2. Erwin Kreyezig, Advanced Engineering Mathematics, Tata McGraw Hill Publications, 8th edition (2007)
3 3. S. C. Chapra and R. Canale, Numerical Analysis for Engineers, Tata McGraw Hill Publications, 5th edition (2005) 4. Numerical methods for Scientific and Engineering computation by M.K. Jain, SRK Iyengar, R.K. Jain, 5th edition, New age International Publishers.
SUBJECT CODE: EI402 CIE: 50
SUBJECT: LINEAR ICs AND SCCs’EXAM HOURS: 3
HOURS / WEEK: 4 SEE: 50 TOTAL HOURS: 52
<, Prerequisites: Basic Electronics
Objectives: Upon completion of this course, students should be able to:
know the fundamentals of Operational amplifier and its characteristics (PO1, PO2)
familiarize with the behavior of opamp with various feedbacks and their applications
(PO2,PO4,PO5)
Design and analyze various op-amp based linear circuits (PO2,PO4)
Design the signal conditioning circuits for basic sensors (PO3, PO5)
PART-A 1. Introduction to OPAMPs:Basic internal circuit of OPAMP (Differential Amplifier), Block
diagram representation of a typical OPAMP, OPAMP terminals and its ideal characteristics
/Specifications; OPAMP in Open loop configuration: Open loop voltage gain, Zero Crossing
detector: Inverting & Non Inverting ZCDs; Positive and Negative voltage level detectors, LM
339-Quad Comparator, Generation of PWM using LM339.
7 Hours 2. OPAMPs with negative feedback and its applications:Inverting and Non Inverting
amplifier: Closed loop voltage gain, Input impedance, Output impedance, Bandwidth with
feedback, Applications: Adder(Multichannel amplifier), Inverting averaging amplifier, Non
Inverting Adder, Voltage follower: Ideal voltage source, Difference amplifier: Subtractor
and design problems.
7 Hours
PART-B 3. OPAMPs with positive feedback and its applications:Effect of noise on comparator
circuits, Design aspects of ZCD with Hysteresis(Schmitt trigger)(, Design aspects of
Voltage level detectors with Hysteresis (both Inverting and Non Inverting), Applications: ON
– OFF control principles( Design problems) and independently adjustable setpoint controller.
6 Hours
4. DC performance and AC performance of OPAMPs:Measurement and effect of OPAMP
Parameters: Input bias current, Input offset current, Input offset voltage, Frequency response
of OPAMP: Open loop and Closed loop configurations. Slew rate and output voltage,
Problems.
6 Hours
PART-C 5. Special Applications of OPAMPsV-I ( both floating load and grounded load) converter and
their Applications: Diode match finder, Zener diode tester, design of high input impedance
DC/AC voltmeter using ammeter, I-V converter and its applications; design of I-V circuit for
Photo based sensor, Precision rectifiers: Half wave and Full wave;, Frequency response of
Integrator, Differentiator and their Design.
6 Hours
6. Waveform GeneratorsMultivibrators using OPAMPs: Free running (square wave generator)
and one shot multivibrators, Triangular wave generator; Phase shift oscillator, Design
problems, 555 Timer: Introduction, Astablemultivibrators and Mon stable multivibrators:
applications and their applications.
7 Hours
PART-D 7. Active Filters: Introduction to Filters: Design aspects of Low pass Butterworth filter; First
order and Second order filters, Design aspects of High pass Butterworth filter; First order
and Second order filters, Higher order filters, Design aspects of Band pass filter and Band
rejection filter. Design Problems.
7 Hours
8. Signal conditioning circuits: Basic differential Amplifiers, differential versus single input
amplifiers, Instrumentation amplifier, Basic Bridge Amplifiers, Balancing and linearization
techniques for the bridges, Design of Signal conditioning circuits for Strain gauge,
Thermistor, RTD, Thermocouple and AD590.
6 Hours
TEXT BOOKS:
1. Operational Amplifiers and Linear Integrated Circuits,Robert. F. Coughlin &Fred.F.
Driscoll, , PHI/Pearson, 2006
2. Op - Amps and Linear Integrated Circuits, Ramakant A. Gayakwad, , 4th edition, PHI
REFERENCE BOOK:
Linear Integrated Circuits, D. Roy Choudhury and Shail B. Jain, , 2nd edition, Reprint 2006, New
Age International
SUBJECT CODE: EI403 CIE: 50
SUBJECT: PROCESS INSTRUMENTATION - 1 EXAM HOURS: 3
HOURS / WEEK: 4 SEE: 50 TOTAL HOURS: 52
<, Prerequisites: Transducer and Instrumentation
Objectives: Upon completion of this course, students should be able to:
Know the principle and operation of various sensors/transducersPO3,PO1
Design and installing different sensors and valves in industries.PO6
Select suitable transducer for given process parameters.PO1,PO2
These advanced sensors are help to increase the productivity and safety as well as decrease
the man power.PO5
PART-A 1: Measurement of Displacement
Principles of measurement of displacement, resistive potentiometer, capacitance pickup, Variable
Inductance and Reluctance Pickup LVDT and ultrasonic transducer.
06 Hours
2: Measurement of Force, Torque & Shaft Power
Introduction to force, Hydraulic Load cell, Pneumatic Load cell, Elastic force Devices,
Transmission Dynamometers, Driving type Dynamometers, Absorption Dynamometers
07 Hours
PART-B 3: Temperature Measurement
Thermal expansion methods-bimetallic thermometers, liquid-in-glass thermometers, pressure
thermometers; thermoelectric sensor - common thermocouples, reference junction consideration,
electrical resistance sensors- conductive sensor (resistance thermometers), bulk semiconductors
sensors(thermistors); junction semiconductor sensors.
07 Hours
4: Radiation Temperature Sensors
Chopped radiation type optical pyrometer, Automatic null balance radiation thermometers
(optical pyrometers). Two color radiation thermometers, Black body-tipped fiber optic radiation
thermometer. Fluro-optic temperature measurement.
06 Hours
PART-C 5: Pressure Measurement
Basic methods of pressure measurement; manometers, elastic transducers(Types of Measuring
Devices Only). low pressure measurement- McLeod gage, Knudsen gage, momentum-transfer
(viscosity) gages, thermal conductivity gages, ionization gages.
07 Hours
6: Flow Measurement-1
Classification of flow meter, Head type flow meters.Constant-area, variable-pressure-drop
meters (obstruction meters).Pitot tubes. Constant pressure-drop, variable area meters
(rotameters). Hot wire and hot film anemometer.
07 Hours
PART-D
7: Flow Measurement-2
Electromagnetic flow meters, Ultrasonic flow meters, Laser Doppler velocimeter; turbine meters,
positive displacement meters (Nutating disc meter, sliding vane type meter). Metering pumps..
Drag force flow meters.
06 Hours
8: Level Measurement
Capacitance level sensor: bare and coated, single point conductivity level sensor, Force balance
differential pressure sensors, displacement level switch, float level switches.
06 Hours
TEXT BOOKS:
1. Measurement systems application and design, ERNEST O DOEBELIN, 6th Edition,
McGraw-Hill.
2. Instrumentation Measurement and analysis, B.C.Nakra and K.K.Chaudhry,
TMH,2002(Units 2 & 5)
REFERENCE BOOKS:
1. Instrumentation Devices & Systems, Rangan, Mani, Sharma, , 2nd Edition TMH.
2. Instrument Engineers Hand book (process measurement) B G LIPTAK, Chilton book
Company
SUBJECT CODE: EI404 CIE: 50
SUBJECT: SIGNALS & SYSTEMS EXAM HOURS: 3
HOURS / WEEK: 4 SEE: 50 TOTAL HOURS: 52
<, Prerequisites: Engineering Mathematics
Objectives: Upon completion of this course, students should be able to:
To understand basic theory of signals & systems with continuous & discrete time.
PO1,PO2
Spectral analysis in CT & DT signals: Fourier Series & Fourier transformPO1,PO3
Understand the concept of Z-transform and their applications in LTI & Discrete
systemsPO3,PO4,PO7
PART-A 1. Introduction:Definitions of a signal and a system, classification of signals, basic Operations
on signals, elementary signals, Systems viewed as Interconnections of operations, properties
of systems. 07 Hours
2. Time-domain representations for LTI systems-1: Impulse response representation,
Concepts of Convolution, Computation of Convolution Sum and its properties.
07 Hours
PART-B
3. Time-domain representations for LTI systems – 2:System representation: Differential and
difference equation Representations, System response by solving differential and difference
equation.
07 Hours 4. Fourier representation for signalsandAnalysis: Introduction, the Fourier series for
continuous time periodic signals and their properties.Numericals on properties.
06 Hours
PART-C 5. Continuous Time Fourier Transforms and applications:Introduction, the Fourier
transform representation for continuous time non- periodic signals and their properties.
Numericals on properties.
06 Hours 6. Discrete Time Fourier series and Discrete Time Fourier transform:Fourier series
representation of discrete time periodic signals and their properties, The Fourier transforms
representation of discrete time non periodic signals and their properties.
07 Hours
PART-D 7. Z-Transforms and applications:Introduction, Z – transform, Region of convergence,
properties of ROC, Properties of Z – transforms and numericals.
06 Hours 8. Inverse Z-transforms and applications:Inverse Z – transforms (PFE metod). Transform
analysis of LTI Systems, unilateral Z-Transform and its application to solve difference
equations.
06 Hours
TEXT BOOKS:
1.Signals and Systems,SimonHaykin and Barry Van Veen, John Wiley & Sons, 2001.Reprint 2002
2.Modern Digital Signal Processing, V. Udayashankara, Second Edition, PHI
REFERENCE BOOK:
Signals and systems, Roborts, TMH, 2004
SUBJECT CODE: EI405 CIE: 50
SUBJECT: ADVANCED MICROPROCESSORS EXAM HOURS: 3
HOURS / WEEK: 4 SEE: 50 TOTAL HOURS: 52
<, Prerequisites: Logic Design
Objectives: Upon completion of this course, students should be able to:
Understand assembly level programming language. PO2
Gain the knowledge about the microprocessor architecture, Instruction set, AMs,
interrupts.PO6
Develop ALPs for different applications.PO7,PO9
Interfacing of processor with various peripherals.PO7,PO9
PART-A 1. The Processor-8086: Register organization of 8086, Architecture of 8086, Signal
Descriptions of 8086, Physical memory organization, Minimum mode 8086 systems and
timings, Maximum mode 8086 systems and timings, mode of operation.
07Hours 2. 8086 Instruction Set: Data transfer, Arithmetic, Bit manipulation, String, Processor
control and Program execution transfer instructions of 8086.
07Hours
PART-B 3. Assembler directives & Instruction Templates: Addressing modes of 8086, Assembler
directives, Machine language instruction format and templates (for only MOV
instruction).
06Hours
4. Assembly Language Programming with 8086: A few machine level programs,
Programming with an assembler, Assembly language example programs.
06Hours
PART-C 5. Special Architectural Features and Related Programming: Introduction to stack,
Stack structure of 8086, Interrupts and Interrupt service routines, Interrupt cycle of 8086,
Non-maskable&maskable interrupts, Interrupt Programming, Macros, Timings and
delays.
06Hours
6. Basic Peripherals and their Interfacing with 8086: Semiconductor memory
interfacing, Dynamic RAM interfacing, Interfacing I/O ports.
07Hours
PART-D 7. Special Purpose Programmable Peripheral Devices and Their Interfacing:
Programmable communication Interface 8251- USART, Programmable Interrupt
Controller 8259 -PIT.
06Hours
8. Multimicroprocessor Systems: Introduction, Interconnection Topologies, Software
aspects of multimicroprocessor Systems, Numeric processor 8087- Architecture, Signal
descriptions, Register set, Exception handling, Interconnections of 8087 with 8086.
07Hours
TEXT BOOK:
Advanced Microprocessors and Peripherals, A.K.Ray and K.M. Bhurchandi, Tata McGraw
Hill, 1st Edition ,1996, (Chapters 1,2,3,4,5,6 and 8)
REFERENCE BOOK:
Microcomputer systems the 8086/8088 family, Architecture, Programming and Design, Yu-
Cheng Liu & Glenn A Gibson, PHI, 2nd
Edition.
SUBJECT CODE: EI406 CIE: 50
SUBJECT: INTRODUCTION TO VHDL PROGRAMMINGEXAM HOURS: 3
HOURS/WEEK: 4 SEE: 50 TOTAL HOURS: 52
<, Prerequisites: Logic Design
Objectives: Upon completion of this course, students should be able to:
Know the fundamentals of VHDL and its features(PO3,PO4)
Develop VHDL code in various modelling styles.(PO2,PO7,PO10)
Develop a synthesizable code for a given logic.(PO7,PO10)
PART-A 1. Introduction:Fundamentals of VHDL, A Brief History of VHDL, Capablities, Basic
Terminology,EntityDecleration,Architecture Body, Identifiers,Data objects, Operators,
Data types.
06 Hours
2. Data –Flow Modeling:Concurrent Signal Assignment statement, Concurrent V/S
Sequential Signal Assignment, Conditional signal Assignment Statement, Selected Signal
Assignment Statement, The Unaffected Value, Block Statement.
07 Hours
PART-B 3. Behavioral Modeling:Entity Declaration, Architecture Body, Process Statement,
Variable Assignment Statement, Signal assignment statement, Wait, If, Case, Null
Statements, Loop Next, Exit, Assertion, Report Statements Inertial delay model and
Transport delay model, Multiple Processes.
07 Hours
4. Structural Modeling and state Machines:Component declaration, Component
Instantiation, State machines
06 Hours
PART-C 5. Generics and Configurations & Advance Features:Generics, Why Configurations,
Configuration Specification, configuration Declaration, Default Rules, Generate
statements, Type Conversions, Attributes.
06 Hours
6. Sub Programs &Advanced HDL Descriptions:Functions, Procedures, Subprogram
overloading, Operator Overloading, Functions File Processing, Examples of File
Processing
07 Hours
PART-D 7. Packages and Libraries:Package Declaration, Package Body, design File, design
Libraries, Implicit Visibility, and Explicit Visibility.
07 Hours
8. Synthesis Basics:Highlights of Synthesis, Synthesis information from Entity and
Module, Mapping Process in the Hardware Domain.
06 Hours
TEXT BOOKS:
1. A VHDL Primer- J.Bhaskar – PHI Publications
2. Introduction to HDL Programming - NazeihM.Botros- Dreamtech Press (Available
through John Wiley – India and Thomson Learning), 2006 Edition
REFERENCE BOOKS:
1. Circuit design with VHDL, VolneiA.Pedroni, PHI
2. VHDL Programming by examples -Douglas perry-Tata McGraw-Hill.
SUBJECT CODE: EI407 CIE: 50
SUBJECT: DIGITAL CIRCUITS AND VHDL LAB EXAM HOURS: 3
HOURS/WEEK: 3 SEE: 50 TOTAL SLOTS: 14
<, Prerequisites: Logic Design and Introduction To VHDL Programming
Objectives: Upon completion of this course, students should be able to:
Realize and develop various Digital Circuits(PO1,PO2)
Design and realization of MSI components using Logic gates(PO2,PO4)
Develop the VHDL code for various Logic gates/devices(PO2,PO3,PO7)
Develop a synthesizable code that can be downloaded and realized on a
hardware(PO2,PO4,PO7)
CIRCUIT CONNECTION AND VERIFICATION
1. Realization of half/full adder and half/full sub tractor using logic gates.
2. Realization of (a) parallel adder/subtractors using 7483 chip,(b) Binary to Gray code converter
and vice versa.
3. MUX/DEMUX use of 74153, 74139 for arithmetic circuits and code converter.
4. Realization of two bit comparator using 7483.
5. Realization of 3-bit Synchronous and Asynchronous counters as a sequential circuit and mod-
n counter design using Flipflops.
6. SIPO, SISO, PISO, PIPO operations using 7495S.
7. Design and testing of ring counter and Johnson counter.
PROGRAMMING
1. Write VHDL code to realize all the logic gates
2. Write a VHDL program for the following combinational designs
a. 2 to 4 decoder
b. 8 to 3 (encoder without priority & with priority)
c. 4 bit binary to gray converter
d. Multiplexer, de-multiplexer, comparator.
3. Write a VHDL code to describe the functions of a Full Adder Using three
modeling styles.
4. Develop the VHDL code for the following flip-flops, SR, D, JK, T.
5. Design 4 bit binary, BCD counters (Synchronous reset and
Asynchronous reset) and “any sequence” counters
SUBJECT CODE: EI408 CIE: 50
SUBJECT: LINEAR INTEGRATED CIRCUITS LAB EXAM HOURS: 3
HOURS/WEEK: 3 SEE: 50 TOTAL SLOTS: 14
<, Prerequisites: LINEAR ICs AND SIGNAL CONDITIONING CIRCUITS
Objectives: Upon completion of this course, students should be able to: • Measure various op-amp parameters(PO3,PO7,PO9)
• Differentiate between various configurations of an op-amp(PO3,PO4)
• Configure an OPAMP for a given application(PO2,PO4)
• Design and analyze the OPAMP/TIMER based linear circuits(PO2,PO4)
1. Measurement of OPAMP parameters
2. Opamp in open loop configuration:
a. Zero Crossing Detector
b. Inverting Positive and Negative voltage level detectors
c. Noninverting Positive and Negative voltage level detectors
3. Opamp in closed Loop configuration( with negative feedback):
Inverting amplifier, Multi channelamplifier as adder and averager
4. Opamp in closed Loop configuration( with positive feedback):
Schmitt trigger; ZCD with hysteresis,
5. Opamp in closed Loop configuration( with positive feedback):
Inverting VLD with Hysterisis and
Noninvering VLD with Hysterisis.
6. Selected applications of Opamp:
V-I and I-V converter
7. Opamp with Diodes:
Half wave and Full wave Precision Rectifier
8. Opamp with capacitors: Integarator and Differentiator
9. Wave form generators using Opamp:
a. AstableMultivibrator using Opamp
b. MonostableMultivibrator using Opamp
10. Wave form generators using timer IC555:
a. AstableMultivibrator
b. MonostableMultivibrator
11. Butterworth Low pass & High pass Filters
12. Basic signal conditioning Circuits:
a. Basic Differential Circuit and Subtractors
b. Instrumentation Amplifier.
IV Semester Bridge Course for Diploma Students (Common to all branches of Engineering)
(Audit Course) Subject: Advanced Mathematics - II Subject Code: MATDIP401 Hours / week: 3 Total hours: 40 Course outcomes (Cos) (with mapping shown against the program outcomes - Pos)
1. Learning different methods for solving initial value problems through linear
equations. (Po-1,
Po-3, Po-5)
2. Skills in identifying different classes of DE’s and solving them.
(Po-3, Po-5, Po-10) 3. To learn standard Laplace transforms and its inverse. (Po-3, Po-5, Po-10)
4. Introduction to vector calculus. (Po-1, Po-5, Po-10)
COURSE CONTENTS
PART – A Unit:1: Differential Equations-I: Solution of first order first degree differential equations-
Variable separable methods, Homogeneous Equations, Exact differential equations
(without I.F direct problems). (5
hours)
Unit 2: Differential Equations-II: Linear & Bernoulli’s differential equations, Differential
equations of second and higher order with constant coefficients (Direct problems) (5
hours)
PART – B Unit 3: Differential Equations-III: Solution of second and higher order equations with
constant coefficient by inverse differential operator method: y = ,
,
,
(Simple problems). ( 5 hours)
Unit 4: Laplace Transforms-I: Definitions, Laplace transforms of elementary functions,
derivatives and integrals (without proof) illustrative examples (5
hours)
PART –C Unit 5: Laplace Transforms-II: Periodic functions, Unit step function, Unit impulse
function
(5 hours)
Unit 6: Laplace Transforms-III: Inverse transforms simple problems, Applications of
Laplace transforms to differential equations. (5
hours)
PART –D
Unit 7: Vector Algebra: vector addition, Multiplication (Dot and Cross product), Triple
products, vector differentiation, velocity, acceleration of a vector point function. (5
hours)
Unit: 8: Vector integration – Evaluation of Line integrals, surface integrals and volume
integrals simple problems, Statement of Green’s theorem, Stokes theorem and Gauss
Divergence theorem, Illustrative examples (5
hours)
Reference Books:
1. Dr. B. S. Grewal, Higher Engineering Mathematics, Khanna Publications,
40th edition (2007).
2. Erwin Kreyezig, Advanced Engineering Mathematics, Tata McGraw Hill
Publications, 8th edition (2007)