applied mathematics - iv etma-202
TRANSCRIPT
Applied Mathematics - IV
ETMA-202
S. No. FIRST TERM No. of Lectures
UNIT-I
Partial Differential Equations
1 Solution of PDE with constant coefficient 2
2 Solution of Homogeneous PDE 2
3 Solution of Non-homogeneous PDE 1
4 Method of seperation of variables 1
5 Solution of Wave equation using seperation of variables 1
6 Solution of one dimensional heat equation 1
7 Solution of Laplace equation 1
8 solution of initial and boundary value problems 2
9 Assignment based on PDE
UNIT-II
Probability and Statistics
10 Probability definition, addition law of probability,multiplication
law of probability. 2
11 Conditional probability, Bayes theorem 1
12 Random variable, discrete probability distribution 1
13 Continuous probability distribution, expectation 1
14 Binomial distribution, Poisson distribution 2
SECOND TERM
15 Normal distribution 2
16 Moments, Moment generating function 1
17 Skewness, Kurtosis 2
18 Assignment based on Probability & Statistics
UNIT-III
Curve fitting, Correlation & Regression and Sampling
19 Principle of least square method, curve fitting for linear and
parabolic curve. 2
20 Correlation, Karl Pearson's correlation coefficient. 1
21 Rank correlation coefficient 2
22 Regression analysis, Lines of regression, angle between lines of
regression and properties of regression coefficient 2
23 Sampling distribution, testing of hypothesis, level of
significance 1
24 Sampling distribution of mean and variance 1
25 Chi-square distribution, Student's t-distribution 2
26 F-distribution, Fisher's Z-distribution 1
UNIT-IV
Linear Programming 27 Introduction, formulation of problem 1
28 Graphical method 2
29 Canonical and standard form of LPP 1
Assignment based on curve fitting, correlation & regression,sampling
THIRD TERM 30 Simplex method 2
31 Duality concept, Dual simplex method 2
32 Transportation and assignment problem 2
Assignment based on linear programming
Text Books:
[T1] B. S. Grewal,”Higher Engineering Mathematics” Khanna Publications.
[T2] N.M. Kapoor, “Fundamentals of Mathematical Statistics”, Pitambar Publications
References Books:
[R1] E. kresyzig,” Advance Engineering Mathematics”, Wiley publications
[R2] Miller and Freund, “ Probability and statistics for Engineers” , PHI
[R3] Gupta and Kapoor, “ Fundamentals of Mathematical Statistics” Sultan Chand and Sons
[R4] G. Hadley, “Linear Programming”, Narosa.
[R5] Schaum’s Outline on Probability and Statistics” Tata McGraw-Hill
[R6] Gupta and Manmohan, “ Problems in Operations Research”, Sultan Chand and Sons.
[R7] R.K. Jain and S.R.K. Iyengar,”Advanced Engineering Mathematics “Narosa Publications.
Communication Systems Paper Code: ETEC-208
Credits: 4
Total lecture/ Tutorial classes available: 44
S. No. TOPICS TO BE COVERED No. of
L+ T
1st Term
1 Overview of Communication System and Communication
Channels; 1
Introduction to Analog Communication and Digital
Communication; Modulation: Definition, Needs of Modulation,
Types of Modulation;
1
2 Amplitude Modulation: Definition, Principle, Spectrum,
Efficiency, Modulation Index, AM Envelope; 2
3 Generation of AM Waves; 1
4 Demodulation of AM Waves; 1
5
TRF Receivers; Superheterodyne Receiver; AM Receivers &
Receiver Parameters: Sensitivity, Selectivity, Dynamic Range,
Fidelity;
2
6 Principle and Generation of DSBSC Waves, Coherent Detection of
DSBSC Waves; 1
7
Generation of SSB Waves; AM SSB Full Carrier; AM SSB Reduced
Carrier; Demodulation of SSB Waves; Vestigial Sideband Modulation
(VSB);
2
8
Phase Modulation (PM) and Frequency Modulation (FM): Basic
Definition and Principle; Narrowband Frequency Modulation
and Wideband Frequency Modulation;
2
9 Generation and Demodulation of FM Waves; 3
10 Frequency Division Multiplexing (FDM); 1
11 Noise Theory: Introduction to Noise, Types of Noise, Addition
of Noise due to Several Sources in Series and Parallel; 2
2nd Term
12 Noise Sources; Equivalent Noise Bandwidth; Signal to Noise
Ratio; 1
13 Noise Figure; Calculation of Noise Figure; Noise Temperature; 2
14 Sampling Theory; Aliasing Effect; Practical Sampling; 2
15 Aperture Effect; Uniform and Non Uniform Quantization; 1
16 Signal to Quantization Noise Ratio, Companding; 2
17 Pulse Amplitude Modulation (PAM), Pulse Time Modulation (PTM),
and Pulse Code Modulation (PCM): Generation and Demodulation; 3
18 Time Division Multiplexing (TDM); Differential Pulse Code
Modulation (DPCM); 2
19 Delta Modulation (DM); Adaptive Delta Modulation;
1
20 Amplitude, Frequency and Phase Shift Keying; Differential Phase
Shift Keying; 2
21 MSK, QPSK and QAM Modulation and Detection; BER/SER
Calculation; 2
3rd Term
22 Introduction to Information Theory: Measurement of Information,
Mutual information 1
23 Shannon’s Theorem; Channel Coding and Channel Capacity
Theorem; 2
24 Huffman Code; Lempel-ziv code; 1
25 Error Control Coding: Parity Codes, Hamming Codes, Block Codes,
Syndrome decoding, 2
26 CRC Codes; Introduction to Convolution Coding. 1
TEXT BOOKS: [T1] Taub & Schilling, “Principles of Communication Systems”, TMH, 1998.
[T2] Simon Haykins, “Communication Systems”, John Wiley, 1998.
REFERENCE BOOKS: [R1] Kennedy, G., “Electronic Communication Systems”, McGraw-Hill, 2008, 4th ed.
[R2] V. Chandra Sekar “Analog Communication”, Oxford University Press, Incorporated, 2010
[R3] John G Proakis, M.Salehi and G.Bauch “Modern Communication System Using MATLAB” Cengage
Learning, 3rd edition, 2013
[R3] J. C. Hancock, “An Introduction to the Principles of Communication Theory”, TMH, 1998.
Computer Organization and Architecture Paper Code: ETCS-204
Credits: 4
Total lecture/ Tutorial classes available: 44
S.No. CONTENTS Total No. of
Lectures/Tutorials
Ist TERM
Unit-1 (Artithmetic and Register transfer
language)
1.
Unsigned notation, Signed notation, Binary coded
decimal, floating point numbers 2
2
IEE 754 floating point standard, Micro-operation 2
3
Bus and Memory transfers, Bus architecture,
Bus Arbitration 4
4 Arithmetic logic, Shift micro-operation, Arithmetic
Logic Shift Unit 2
Unit-II (Instruction set architecture & computer
organization)
5 Levels of programming Languages, Assembly
language instructions 2
6
8085 Instruction set architecture, Instruction codes
Computer Registers 3
7
Computer Instructions, Timing & control,
Instruction cycle 3
IInd TERM
8
Memory Reference Instructions, Input-Output and
Interrupts 2
Unit-III (Control Design)
9
Instruction sequencing and interpretation,
Hardwired & micro programmed (control unit) 2
10.
Microprogrammed computers, microcoded CPU:
Pentium processor 2
11 Specifying a CPU, Design and implementation of
simple CPU,General register organization 3
12 Stack organization, instruction formats,
Addressing modes 4
13 Internal architecture of 8085 microprocessor 2
Unit-IV (Memory &input/output organization)
14 Memory Technology, Main memory (RAM and
ROM chips,Virtual memory, High speed memories 3
IIIrd TERM
15 Asynchronous Data Transfer, Programmed I/O
Interrupts 4
16 Direct memory access, Serial communication
UARTS
RS-232-C &RS-422 Standard
4
Text Books:
[T1] J. D. Carpinelli, “Computer Systems Organization and Architecture”, Pearson Education, 2006.
[T2] J. P. Hayes, “Computer Architecture and Organization”, McGraw Hill, 1988.
Reference Books:
[R1] J. L Hennessy and D. A. Patterson, “Computer Architecture: A quantitative approach”, Morgon
Kauffman, 1992.
[R2] W. Stallings, “Computer organization and Architecture”, PHI, 7th ed, 2005.
[R3] B. Parhami, “Computer Architecture: From Microprocessors to Supercomputers”, Oxford
University press, 2006.
Database Management Systems Paper Code: ETCS-208
Credits: 4
Total lecture/ Tutorial classes available: 42
S.No. CONTENTS No. of Lectures
Ist TERM
Unit-1
1. Database-System Applications, Purpose of Database
Systems, Views of Data, Data Independence, Database
System Architecture – levels, Mapping,
2
2. Database users and DBA, Entity – Relationship model, 2
3. ER model constraints, Types of keys, Design issues, E-R
Diagram with examples
3
4. Extended E-R features- Generalization, Specialization,
Aggregation, Translating E-R model into Relational model.
3
Unit-2
5. The relational Model, The catalog, Types, Relational
Algebra
2
6. Fundamental operations, Additional Operations 3
7. SQL fundamentals, DDL,DML,DCL PL/SQL Concepts,
2
IInd TERM
8. Cursors, Stored Procedures, Stored Functions, Database
Integrity – Triggers.
3
Unit-3
9. Functional Dependencies: Use of functional Dependencies,
Types of functional Dependencies, Canonical cover,
extraneous attribute
3
10. Non-loss Decomposition, Dependency Preservation First,
Second Normal Forms
3
11. Third Normal Forms, Boyce/Codd Normal Form, Multi-
valued Dependencies and Fourth Normal Form, Join
Dependencies and Fifth Normal Form.
4
Unit-4
12. ACID properties, serializability of Transaction, Testing for
Serializability and concurrency control,
2
13. Lock based concurrency control:2Phase Locking protocol,
Deadlock prevention, detection & recovery
3
14. Time stamping methods 1
Text Books:
[1] Abraham Silberschatz, Henry F. Korth, S. Sudharshan, “Database System Concepts”, 5th Edition, Tata
McGraw Hill, 2006
[2] Elmsari and Navathe, “Fundamentals of Database Systems”, 6th Ed., Pearson, 2013
References Books: [1] C.J.Date, A.Kannan, S.Swamynathan, “An Introduction to Database Systems”, 8th Edition, Pearson
Education, 2006.
[2] J. D. Ullman, “Principles of Database Systems”, 2nd Ed., Galgotia Publications, 1999.
[3] Vipin C. Desai, “An Introduction to Database Systems”, West Publishing Co.,
IIIrd TERM
15. Database recovery management: log based recovery.
2
16. Overview of Physical Storage Media, File Organization,
Indexing and Hashing, B+ tree Index Files, Query
Processing Overview, Measure of query cost, Catalog
Information for Cost Estimation, Selection Operation,
Sorting, Join Operation, Materialized views, Database
Tuning.
4
B. Tech. 4th Sem (CSE)
Objected Oriented Programming
Paper Code: ETCS-210 ( Lesson Plan)
First Tem
S.No. Topic Lectures
1 Programming Paradigms: Monolythic Programming, Procedural
Programming, structural and Object Based Programming 1
2 Introduction to OOPs: Introducing Object Oriented Approach related to
other paradigms (Functional, Data Decomposition) 2
3 Object Oriented Languages: Charateristics and Features of Object
Oriented Languages 1
4 Basic Terms and Ideas: Abstraction , encapsulation, Information Hiding,
Inheritance, Polymorphism 2
5
Review of C: Difference between c and C++, new , delete &
differentiating it with malloc and calloc methods of C, differences
between cin, cout
2
6 Classes and Objects: Abstract data type, state identity and behaviour of
object, Defining a class, creating objects 2
7 Constructors and Destructors: Objective of Constructors and their types,
constructor overloading, Destructors 3
8 Object Instantiation: Instantiation of objects, Default parameter value, in-
line functions 2
9
Static and Constant Keyword: Static data members, static member
functions, constant data members, constant member functions, constant
objects, abstract class
3
Second Term
10 Garbage Collection:C++ Garbage collection 1
11 Inheritance: Features of Inheritance, types of inheritance, access
specifiers, public, private and protected derivations,class heriarcy 3
12 Aggregation and Containership: Aggregation, Composition vs
Classification 2
13 Polymorphism: Types of Polymorphism- Compile time & Run time,
Method Polymorphism 4
14 Operator Overloading: overloading operators 2
15 Templates: Generic functions and classes 3
16 Exception Handling: Compile time & run time errors. Keywords used for
exception handling, try, catch and throw, rethrowing an exception 3
Third Term
17 Namespaces: features of namespaces, creating and using own
namespaces 1
18 File Handling: Persistant objects, stream and files, opening and closing a
file, reading from afile and writing to afile, different file operations 3
19
Standard Template Library: overview of standard template library,
containers, alogorithm and function objects,iterators, allocators, string,
streams
2
20 Manipulators, vectors, valarray, slice, generalized numeric algorithm. 2
Total Lectures 44
Text Books:
[T1] Rumbaugh et. al. “Object Oriented Modelling & Design”, Prentice Hall
[T2] A.R.Venugopal, Rajkumar, T. Ravishanker “Mastering C++”, TMH
Reference Books:
[R1] A.K. Sharma, “Object Oriented Programming using C++”, Pearson
[R2] G . Booch “Object Oriented Design & Applications”, Benjamin,Cummings.
[R3] E.Balaguruswamy, “Objected Oriented Programming with C++”, TMH
[R4] S. B. Lippman & J. Lajoie, “C++ Primer”, 3rd Edition, Addison Wesley, 2000.
[R4] R. Lafore, “Object Oriented Programming using C++”, Galgotia.
[R5] D . Parasons, “Object Oriented Programming with C++”,BPB Publication.
[R6] Steven C. Lawlor, “The Art of Programming Computer Science with C++”, Vikas Publication.
Theory of Computation Paper Code: ETCS-206
Credits: 4
Total teaching weeks in semester: 14
Total lecture classes available: 42
S.No. Contents No. of Lectures First Term
Unit -I
1. Overview: Alphabets, Strings & Languages, Chomsky
Classification of Languages 2
2. Finite Automata, Deterministic finite Automata (DFA) &
Nondeterministic finite Automata (NDFA), Equivalence of
NDFA and DFA, Minimization of Finite Automata.
4
3. Moore and Mealy machine and their equivalence. 2
4. Regular expression and Kleen’s Theorem(with proof), Closure
properties of Regular Languages. 3
5. Pumping Lemma for regular Languages (with proof). 2
Unit -II
6. Context free grammar, Derivation trees, Ambiguity in grammar
and its removal, Simplification of Context Free grammar. 2
7. Chomsky Normal Form & Greibach Normal Form. 2
8. Pumping Lemma for Context Free languages, Closure properties
of CFL (proof). 2
Second Term
9. Push Down Automata (PDA), Deterministic PDA, Non
Deterministic PDA ,Equivalence of PDA and CFG. 3
10. Overview of LEX and YACC.
2
Unit -III
11. Turing machines, Computing Partial Function with Turing
Machine. 2
12. Variants and equivalence of Turing Machine. 2
13. Nondeterministic Turing Machines, Universal Turing Machine. 2
14. Church’s Thesis. 2
15. Recursive and recursively enumerable languages. 2
16. Halting problem, Undecidability, Examples of Undecidable
problem. 2
Unit -IV
17. Introduction to Complexity classes, Computability and
Intractability, time complexity. 2
Third Term
18. P, NP, Co-NP, Proof of Cook’s Theorem, Space Complexity,
SPACE, PSPACE, Proof of Savitch’s Theorem, L , NL , Co-NL
complexity classes.
4
Text Books:
[T1] Hopcroft, John E.; Motwani, Rajeev; Ullman, Jeffrey D “Introduction to Automata Theory,
Languages, and Computation”, Third Edition, Pearson.
[T2] Sipser, Michael, ”Introduction to the theory of Computation”, Third Edition, Cengage.
References Books:
[R1] Martin J. C., “Introduction to Languages and Theory of Computations”, Third Edition, TMH.
[R2] Papadimitrou, C. and Lewis, C.L., “Elements of the Theory of Computation”, PHI.
[R3] Daniel I.A. Cohen, ”Introduction to Computer Theory”,Second Edition, John Wiley.
LESSON PLAN FOR IV SEMESTER (2014-2015)
SUBJECT : COMPUTER ORGANIZATION & ARCHITECTURE PAPER CODE: ETCS-204
TOTAL LECTURE CLASS AVAILABLE:43 L T C
3 0 3
S.No. Topics to be covered No. of lectures assigned
1st TERM
1 Unsigned notation, signed notation, binary coded decimal,
floating point numbers, IEEE 754 floating point standard
2
2 Micro-operation 2
3 Bus and Memory Transfers 2
4 Bus Architecture, Bus Arbitration 1
5 Arithmetic Logic 2
6 Shift Micro operation 1
7 Arithmetic Logic Shift Unit 1
8 Levels of programming languages 1
9 Assembly language instructions 2
10 8085 instruction set architecture 1
11 Instruction Codes 1
12 Computer Registers 1
13 Computer Instructions 1
2nd TERM
14 Timing & Control, Instruction Cycle 2
15 Memory Reference Instructions 1
16 Input-Output and Interrupts 1
17 Instruction sequencing & interpretation 1
18 Hardwired & Micro Programmed 1
19 Micro-programmed computers 1
20 Micro-coded CPU: Pentium processor. Specifying a CPU,
Design & implementation of simple CPU 3
21 General Register Organization, Stack Organization 2
22 Instruction Formats, Addressing Modes 2
23 Internal architecture of 8085 microprocessor. 1
24 Memory Technology, Main Memory (RAM and ROM Chips)
2
25 Virtual memory, High-speed memories 2
3rd TERM
26 Asynchronous Data Transfers 1
27 Programmed I/O, interrupts 1
28 Direct memory Access 1
29 Serial communication 1
29 UARTs, RS-232-C & RS-422 standard 2
ACADEMIC PLAN FOR FOURTH SEMESTER (For Academic Year 2014-15)
Subject: ANALOG ELECTRONICS-II SUBJECT Code: ETEC-204
Total Teaching Weeks in Semester: 14 Total Lectures: 42 Total Tutorials: 14
Sl.
No.
Topics to be covered Total
Lectures
Total
Tutorials
First Term
1 Introduction to operational amplifier, Block diagram of op-amp. 1 1
2 Differential Amplifier using BJT, DC analysis of differential amplifier. 1
3 AC analysis of differential amplifier, CMRR. 1
4 Constant current bias, Circuit for improving CMRR, Current mirror,
Wilson & Widlar current mirrors.
1 1
5 Pin diagram of 741IC, Characteristics of ideal op-amp, Equivalent circuit
of op-amp, Ideal voltage transfer curve.
1
6 Open loop op-amp configurations, DC characteristics of op-amp. 1
7 AC characteristics of op-amp 1 1
8 Op-amp with negative feed back, Inverting amplifier, Virtual ground 1
9 Non inverting amplifier, Differential amplifier using single and two op-
amps.
1
10 Instrumentation amplifier using op-amp. 1 1
11 Voltage follower, Adders, difference amplifier. 1
12 Voltage to current converter with floating & grounded load, current to
voltage converter
1
13 Practical integrator & differentiator. 1 1
14 Basic comparators, Inverting &non inverting Schmitt trigger circuits 1
15 Clippers & clampers 1
16 Peak detector, Precision rectifiers(half wave &full wave) 1 1
17 Log amplifier 1
18 Antilog amplifier 1
Second Term
19 Introduction to oscillators, Basic Principles, Barkhausen Criteria for
oscillation, Conditions for oscillation, Phase shift oscillator (determine
frequency and β)
1 1
20. Wein bridge oscillator (determine frequency and β) 1
21. Hartley & Colpitts oscillator, Crystal oscillator. 1
22. Square wave generator (determine period). 1 1
23. Triangular wave generator(determine period), Saw tooth generator 1
24. Monostable and bistable multivibrator 1
25. Idealistic & realistic response of filters, (LPF, HPF, BPF, BRF),
Butterworth and Chebyshev approximation of filter functions.
1 1
26. First order and 2nd order low pass filter. 1
27. Sallen- Key filter. 1
28 First order and 2nd order high pass filter. 1 1
29. Band pass and band reject filter 1
30. Notch filter, All pass filter 1
31. Functional block diagram of 555 timer 1 1
32. Application of 555timer as astable multivibrator. 1
33. Application of 555timer as monostable multivibrator. 1
34. Operational transconductance amplifier, Internal structure of OTA 1 1
35. OTA integrator and differentiator 1
36. OTA –C filters &OTA based circuits
Third Term
37. Introduction to current conveyor. 1 1
38. Applications of IC Analog multiplier. 1
39. IC PLL 1
40. PLL applications 1 1
41. IC VCO 1
42. IC Voltage regulators. 1
Text Books: [T1] S Salivahanan, V S Kanchana Bhaaskaran, “Linear Integrated Circuits” TMH.
[T2] Op - Amps And Linear Integrated Circuits, Ramakant A Gayakwad,PHI.
Reference Books: [R1] D. Roy Choudhary, Shail B Jain, “Linear Integrated Circuits” New Age Publisher, 1999.
[R2] M.Rashid , “Microelectronic Circuit”, Cengage Learning Publication.
[R3] Sedra & Smith, “Micro Electronic Circuits” Oxford University Press, 2000
[R4] David A Bell, “Operational Amplifiers and Linear IC’s”, PHI.
Lesson Plan
Subject: Network analysis and synthesis Paper Code: ETEC-206
First Term
1 Review of signals & systems and their classification 1
2 Periodic waveforms and signal synthesis 3
3 Properties and applications of Laplace transform of complex waveform 3
4 Concept of generalized frequency 1
5 Circuit representation & their response in terms of generalized frequency 2
6 System modeling in terms of differential equations 2
7 First - order differential equation , second order differential equation and their solution by
classical method
3
8 Classical Method of solution: Transient analysis of R,L,C, series and parallel circuits for
impulse ,step, ramp, sinusoidal and exponential signals
3
9 Laplace Transform approach: transient Response of R,L,C, series and parallel circuits for
impulse, step, ramp, sinusoidal and exponential signals
4
Second Term
1 Two Port Networks: Introduction of two port parameters and there interconversion 2
2 Interconnection of 2 two port networks 2
3 Open circuit and short circuit impedances 2
3 ABCD constants and relation between image impedances and short circuit and open circuit
impedances
4
4 General network functions: Concept of network functions (Driving point and transfer
function)
2
5 Concept of minimum phase analysis of lattice T and Bridged T networks 1
6 Concept of poles and Zeros 1
7 Hurwitz Polynomial 1
8 Positive real function and synthesis of LC,RC,RL networks in Foster’s I and II, Cauer’s I and II
Forms
3
Third Term
1 Introduction of Passive filter and their classification 1
2 Frequency response 1
3 Characteristic impedance of low pass and high pass prototype section 2
ACADEMIC PLAN FOR IV SEMESTER 2014 – 2015
Subject: Communication Systems Subject Code: ETEC - 208 BRANCH: ECE Credits: 4 Total Teaching Weeks in semester: 15 weeks Total Lecture classes available: 44
S.No. TOPICS TO BE COVERED Lecture Number
Ist term 1. Course Basics
1 (a) Introduction to Communication system
(b) Basic forms of information signals
(c) Communication Channels and their mathematical models 2
2. Random Variables 3
(a) Definition and basic concept
(b) PDF/CDF, Probability density functions 4
(c) Types of distributions, 5
(d) Joint PDF/CDF, Marginalised PDF/CDF 6
3. Random Process 7
(a) Definition and basic concept
(b) Types and examples 8
(c) Stationarity conditions, SSS, WSS, Ergodicity 9
4. Introduction to Hilbert transform 10
5. Bandpass representation of signals 11
6. Fundamentals of Analog transmission systems 12
(a) Need of modulation
(b) Power relations of modulated signals 13
(c) In phase and Quadrature phase representations
7. Analog Modulation of carriers 14
8. Amplitude modulation 15
(a) DSB - SC modulation
(b) DSB - SC demodulation 16
(c) DSB - AM modulation 17
(d) DSB - AM demodulation 18
IInd term 8. (e) SSB - SC modulation 19
(f) SSB - SC demodulation 20
(g) VSB modulation 21
(h) VSB demodulation 22
9. Angle Modulation basics and types 23
(a) Basic principle
(b) Types of Angle modulation 24
10. Frequency Modulation and Phase modulation
25 (a) Generation and detection of FM/PM waves
1. Direct Method - VCO
2. Indirect Method - Armstrong Method 26
(b) Demodulation of FM/PM modulated signals 27
1. Components used
2. FM Discriminator, Slope detector 28
3. Slope detector continued, Introduction to feedback demodulators
(c) Feedback demodulators 29
1. Phase Locked Loop - Basics
2. Phase Locked Loop - working example 30
3. Frequency compressive feedback demodulators 31
(d) Frequency demodulation, Pre-emphasis, De-emphasis 32
11. Radio Receivers – functions, characteristics and classification 33
12. Superheterodyne Receivers 34
(a) Basic Principle and components
(b) Working example of superheterodyne receiver 35
13. Mixers, AGC, Tonal interference, etc. 36
IIIrd term 14. Noise Theory
37 (a) Types of Noise
(b) Addition of Noise due to series and parallel connections
(c) Generalised Nyquist theorem for thermal noise
38 (d) Calculation for thermal noise for a single noise source
(e) RC Circuits & Multiple Noise sources
(f) Equivalent Noise Bandwidth 39
(g) SNR, Noise-Figure, Noise Temperature, Calculation of Noise Figure
15. Behaviour of Communication system in presence of Noise 40
16. Performance of AM systems in presence of noise 41
(a) Performance of DSB-AM under noise
(b) Performance of DSB-SC under noise 42
(c) Performance of SSB-SC under noise
17. Performance of Angle Modulation systems in presence of Noise 43
(a) Small noise case, comparison of FM and PM systems in noise
(b) Noise triangle, detailed analysis of noisy Angle modulated systems 44
SUBJECT: ELECTROMAGNETIC FIELDS THEORY
CLASS: 2nd YEAR SUBJECT CODE: ETEE-210 TOTAL TEACHING WEEKS: 15 WEEKS L T CREDITS TOTAL LECTURE CLASSES : 40 3 0 3
S. No. Topics to be Covered No. of
Lectures
No. of Tutorials
I MID TERM TEST (6 Weeks)
Unit I: Introduction & Electrostatics (10hrs)
1.
2.
3.
4.
5.
6.
7.
8.
Scalar and vector field, Dot & cross product
Coordinated system: Cartesian, Cylindrical and Spherical (conversion to each other)
Vector representation of Surface, Physical Representation gradient, divergence and curl
Transformation of vector in different coordinates system, Dirac-delta Function
Electric field due to point, line & surface charge, Electrostatic Potential
Solution of Laplace & Poisson’s equation in 1-D, M-method of image applied to plane boundaries
Field Mapping, conformal transformation, Electric Flux density, Boundary Conditions
Capacitance: Rectangular, Cylindrical & spherical geometries, Electrostatic Energy
1
2
2
1
1
1
1
1
UNIT II Magneto statics
9.
10.
11.
Magnetic Induction and Faraday’s Law, Magnetic Flux Density, Magnetic Field Strength H, Ampere Law
Gauss Law in the Differential Vector Form, Permeability, Energy Stored in a Magnetic Field,
Ampere’s Law for a Current Element
2
2
1
II MID TERM TEST ( 6 Weeks)
UNIT II-B: Magneto statics (10hrs)
12.
13.
14.
15.
Volume Distribution of Current, Ampere’s Law Force Law
Vector Potential, The Far Field of a Current distribution
Equation of Continuity for Time Varying Fields, Inconsistency of Ampere’s Law
Maxwell’s Equations, Conditions at a Boundary Surface
1
1
1
2
Text Book:
1. Mathhew N. O. Sadiku, Element of Electromagnetic, Oxford University Press
2. E.C. Jordon, K.G. Balman, EM wave & Radiation system, PHI
3. David J. Griffiths's, Introduction to Electrodynamics, Addison-Wesley
Reference Book
1. W H Hayt, Engineering Electromagnetic, TMH
2. J.D. Kraus, Electromagnetic, TMH
3. J R Reitz, Foundation of Electromagnetic Theory
UNIT III: Electromagnetic Waves (10hrs)
16.
17.
18.
19.
20.
21.
Displacement current, Plane wave equation and its solution in conducting & non-conducting media
Phasor notation, Phase Velocity & Group velocity
Depth of Penetration, conductor & Dielectric
Impedance of Conducting medium,
Polarization, Reflection and Refraction of plane wave at plane boundaries
Poynting Vector & Poynting Theorem
2
2
1
1
2
2
3rd Term
UNIT IV: TRANSMISSION LINES (10hrs)
22.
23.
24.
25.
26.
27.
28.
29.
Transmission Line equation, characteristic impedance, Distortion-Less lines, Input impedance of a loss less line Computation of primary and secondary constant Open & Short circuited lines, Standing waves and Reflection losses Impedance matching, input impedance of transmission lines Loading of lines, RF lines, Relation between Reflection coefficient and voltage standing wave ratio Lines of Different lengths ( , , ) lines
Losses in transmission lines, Smith chart and Application Impedance matching Single stub, Double stub
2
1
1
1
1
1
2
1
Lecture Plan for Semester-IV (2014-15)
Subject: Applied Mathematics-IV Subject code: ETMA-202
Total teaching weeks in Semester: 15 weeks Credits: 04
S. No. Contents No. of
Lectures
FIRST TERM
UNIT-I
1 PARTIAL DIFFERENTIAL EQUATIN: Linear partial differential
equations with constant coefficient 2
2 Homogeneous and non homogeneous linear equatins 2
3 Method of separation of variables 2
4 Laplace equation in Cartesian coordinates only with initial and boundary
value 2
5 Wave equation in Cartesian coordinates only with initial and boundary
value
2
6 Heat flow equation in Cartesian coordinates only with initial and boundary
value 2
UNIT II
7 PROBABILITY THEORY: Definition addition and multiplication law of
probability
1
8 Conditional probability 1
9 Baye’s theorem 2
SECOND TERM
10 Random variable: discrete probability distribution 1
11 Continuous probability distribution 1
12 Expectation, moment and moment generating function 1
13 Skewness and kurtosis 1
14 Binomial distribution 1
15 Poisson distribution 1
16 Normal distribution 1
UNIT III
17 CURVE FITTING: Principal of least square Method of least square 1
18 Curve fitting for linear and parabolic curve 1
19 Correlation coefficient and Rank correlation 2
20 Line of regression and properties of regression coefficients 2
21 Sampling distribution: Testing of hypothesis and level of significance 1
22 Sampling distribution of mean and variance 1
23 Chi-square distribution 1
24 Student’s T-distribution 1
25 F-distribution 1
26 Fisher’s Z-distribution 1
THIRD TERM, UNIT IV
27 LINEAR PROGRAMMING: Introduction and formulation of problem 2
28 Graphical Method 1
29 Canonical and Standard form of LPP 1
30 Simplex method 2
31 Duality concept and Dual simplex method 1
32 Transportation problem 2
33 Assignment problem 2
Total 46
Lecture Plan(w.e.f. 2014-2015)
Subject: Network Analysis and Synthesis Sub. Code: ETEC-206L T C3 1 4
FIRST TERM
UNIT- I L T
1 Signals & systems and their classification 11
2 Periodic waveforms and signal synthesis 2
3 Properties and applications of Laplace transform of complex waveforms 3 1
4 Concept of generalized frequency 21
5 Circuit representation & their response in terms of generalized frequency 2
UNIT- II
6 System modeling in terms of differential equation using classical method 2 1
7 Transient response of RLC circuits for impulse step and ramp signal by classical
method3 1
8 Classical method for solving network problems for sinusoidal and exponential
signals (Unit-II to be continued in II–Term…..)3 1
F I R S T M I N O R E X A M
SECOND TERM
9 Unit – II (continued ………)Applications of Laplace transform to linear differential equations. 1
110 Applications of Laplace transform to network problems 2
UNIT- III
11 Introduction of two port parameters and their interconversion 3 1
12 Interconnection of two 2- port networks 21
13 Open circuit and short circuit impedances 1
14 ABCD constants 2
115 Relation between image impedances and short circuit and open circuit
impedances.2
UNIT- IV
16 Concepts of Network functions (driving point & transfer function) 1
117 Introduction to minimum phase analysis of Lattice T and Bridged T networks 1
18 Concept of poles & zeros 1
19 Hurwitz polynomial
(Unit-IV to be continued in III–Term…..)1 –
S E C O N D M I N O R E X A M
THIRD TERM
20 Unit – IV (continued ………)
Positive real function2 1
21 Synthesis of LC, RC, RL Networks in Foster’s I and II forms 21
22 Synthesis of LC, RC, RL Networks Cauer’s I & II forms 1
23 Introduction of passive filter and their classification, frequency response. 2 1
24 Characteristic impedance of low pass and high pass proto type section 1
Lecture Plan(w.e.f. 2014-2015)
Subject : Power System-I Sub. Code : ETEE-206
L T C3 1 4
FIRST TERM L T
UNIT - I
1 Introduction, block diagram of electric power system 1
12
Single line diagram, power system elements- transformer, synchronous machine,
transmission line, bus bar , circuit breaker1
3Configuration and types of conductors, Catenary curve, calculation of sag &
tension1
4 Effect of wind & ice loading, sag template, vibration dampers 2
25 Introduction & type of overhead insulators, application of insulators, potentialdistribution over a string of insulators
2
6 Methods of equalizing the Potential 2
UNIT II
7Phenomenon of Corona, Corona loss, factors affecting corona, interference,
Methods of reducing corona, bundled conductors, Skin & Proximity effect3 1
8Inductance of single phase single & double circuit lines, Inductance of three
phase single & double circuit lines (symmetrical & unsymmetrical)3 1
9Capacitance of single phase transmission line, Capacitance of three phase singlecircuit & double circuit lines(Unit II to be continued in Second Term)
3 1
F I R S T M I N O R E X A M
SECOND TERM
10Unit – II (continued ………)Transposition of transmission line conductors, surge impedance loading, ferranti
effect1
211 Modelling & performance analysis of short, medium & long transmission lines 2
12 Analysis of travelling wave use of Beweley Diagram 2
UNIT III
13Types of cables, dielectric stress, heating of cables, Grading of cables, dielectric
loss, insulation resistance3
1
14 Capacitance of single & three phase cables 2
15 Per unit system, symmetrical components 2
216 Calculation of symmetrical & unsymmetrical faults 2
17 Use of current limiting reactors 1
UNIT IV
18 Introduction of power flow analysis 1
119
Formulation of Y bus matrix, Power flow equations & classification of buses
UNIT IV to be continued in Third Term3
S E C O N D M I N O R E X A M
THIRD TERM
20Unit – IV (continued ………)
Data for load flow, Gauss-Seidal method2
221 Acceleration factor of convergence, Newton Raphson method 2
22 Fast decoupled load flow, Comparison of power flow methods 3
Lecture Plan(w.e.f. 2014-2015)
Sub: Electrical and Electronic Measuring Instruments Sub. Code- ETEE-208L T C3 1 4
FIRST TERM L T
UNIT - I
1 Instrument Transformers: CT and PT Ratio and phase angle errors 2
22 Measurement of Power: Single phase and three phase dynamometer wattmeter, LPF and UPF 2
3 Expression for deflecting and control torques 1
4 Extension of range of wattmeter using instrument transformers 1
5 Type of P.F. Meters, dynamometer and moving iron type, Single phase and three phase meters 216 Frequency meters, Resonance type and Weston type, synchoroscopes 1
7 Measurement of Energy : Single phase and three phase induction type energy meter 1
18 Driving and braking torques, errors and compensations, testing by phantom loading 1
9 Trivector meter, maximum demand meters 1
UNIT - II
10 Potentiometers and Bridges: Principle of operation and types of D. C. / A.C potentiometers,application of DC/AC potentiometers
2
211 Bridges for measuring low, medium and high resistance 2
12 Carey Foster’s bridge, Kelvin’s double bridge 1
13 Megohm bridge, Megger(Unit – II to be continued in II – Term)
1
F I R S T M I N O R E X A M
SECOND TERM
14 Unit – II (continued ......)A.C. Bridges: Measurement of inductance and capacitance, Maxwell’s bridge
1
215 Hay’s bridge, Anaderson’s bridge 1
16 Owen’s bridge, Heaviside Bridge and its modifications 2
17 Desauty bridge. Wien’s bridge, Schering Bridge 2
UNIT - III
18 Introduction of various display devices, LCD, LED and plasma display, 21
19 Resolution, sensitivity and accuracy specifications 1
20 CRO & its applications, triggered CRO, sampling oscilloscope 21
21 Recorders: requirement of recording data, selection of recorder for a particular application 1
22 Analog, graphic, strip chart, galvanometeric, circular chart, XY, digital recorders, single pointand multipoint recorders
2
2
23 Types of Printers, Drum type printer, dot matrix type printer 1
24 Ink-jet and Laser jet printers 1
UNIT - IV
25 Electronic Voltmeter : Solid state voltmeter, RMS and average reading voltmeters 126 Rectifier type voltmeter, vector voltmeter, A.C. voltage measurements
(Unit – IV to be continued in III – Term)1
S E C O N D M I N O R E X A M
THIRD TERM27 Unit – IV (continued ......)
Current measurement using electronic instruments, multi range ammeter2
128 Measurement of Power at Audio and Radio Frequencies 1
29 Diode Sensor based instruments, Analog and Digital Multimeters 1
230 Digital Measurement of time, frequency, phase, pH, capacitance, Counters 2
31 Function Generator: Sine, Square and Triangular wave generator 2
Lecture Plan(w.e.f. 2014-2015)
Subject : Control Systems Sub. Code : ETEE-212L T C3 1 4
FIRST TERM L T
UNIT - I
1 Basics, Types & Classification of control systems, configurations etc. 1
12 Open loop/closed loop systems, merits and demerits, applications 1
3Input-output relationship, transfer function, finding transfer function of typical
Electrical/Electronics/mechanical etc. Systems1
4 Block diagrams, reduction techniques to find overall transfer function 2
15
Signal flow graphs, Mason’s Gain formula, Application for obtaining transfer
function1
6 Control system components: Electrical/Mechanical, servo motor/steppermotor/ Tacho Generator/Synchros/Mag.amp. servo amplifier
3 1
UNIT - II
7 Time Domain performance Specifications, transient response of first order &second order systems
4 1
8 Steady state errors, static error constants in unity feedback systems,limitations of time-domain analysis
11
9 Response with P, PI & PID controllers 3
F I R S T M I N O R E X A M
SECOND TERM
UNIT - III
10 Polar, Inverse Polar plots 11
11 Frequency domain specifications & performance of LTI systems 1
12 Bode’s plot, gain margin & phase margin, relative stability 3 1
13Co-relation between time-domain and frequency domain responses, closedloop response from open loop response, limitations of freq. domain analysis
22
14 Minimum/non-minimum phase systems 1
UNIT – IV
15 Concepts, absolute, asymptotic, conditional & marginal stability 2
216 Routh-Hurwitz criterion of stability and its applications 2
17 Nyquist’s criterion of stability and its applications 2
18Root locus technique and its applications
(Unit – IV to be continued in III – Term)3 1
S E C O N D M I N O R E X A M
THIRD TERM
19Unit – IV (continued ………)
Concepts of compensation, series, parallel, series parallel, compensation2
1
20 Feedback compensations 2
21 Lag/Lead/Lag-lead networks for compensation and their characteristics 21
22 Compensation using P, PI & PID Controllers 2
Lecture Plan(w.e.f. 2014-2015)
Subject: Electrical Machines-II Sub. Code: ETEE-202L T P3 1 2
FIRST TERM L TUNIT-I
1. Constructional features, Production of rotating magnetic field and working of 3-phase Induction motor
21
2. Phasor diagram and equivalent circuit 13. Power and torque equations, torque and slip relations 1 14. No load and blocked rotor tests and efficiency 15. Speed control by rotor resistance, injected EMF, frequency variation and pole
changing2
16. Starting and starters – DOL, Y/∆ and autotransformer 17. Deep bar and double cage rotor motors. Cogging and crawling 1 18. Induction Generator – its operation and phasor diagram 2
UNIT-II9. Constructional features and armature windings of Synchronous Alternators 2
110. EMF Equation, winding coefficients and harmonics in induced EMF 111. Armature reaction, O.C. and S.C. Tests 1
112. Voltage Regulation and its determination by synchronous impedance method, MMF
method and Potier’s triangle method(Unit-II to be continued in II–Term…..)
2
F I R S T M I N O R E X A MSECOND TERM13. Unit – II (continued ………)
Parallel operation of alternators and their operation on infinite bus2
114. Two reaction theory 115. Power expressions for cylindrical and salient pole machines 2
116. Performance Characteristics 1
UNIT-III17. Principle of operation and methods of starting of Synchronous Motor 3 118. Phasor diagram, Torque-angle characteristics and V-curves. 2
119. Hunting and damping, Synchronous condenser 220. Introduction to 1-phase synchronous motors, Reluctance and Hysteresis motors. 3 1
UNIT-IV21. 1-phase Induction Motor: Double revolving field theory 2
122. Equivalent circuit, Phasor diagram, No load and blocked rotor tests(Unit-IV to be continued in III–Term…..)
2
S E C O N D M I N O R E X A MTHIRD TERM23. Unit – IV (continued ………)
Starting Methods of 1–phase Induction Motor: Split phase -capacitor start and twovalue capacitor motors
2
24. Introduction and principle of 1-phase AC series motor and AC servo motor 2 225. Introduction and principle of stepper motor and permanent magnet AC motor 2
Lecture Plan(w.e.f. 2014-2015)
Subject: Electro-Magnetic Field Theory Sub. Code: ETEE-210L T C3 0 3
FIRST TERMUNIT-I
1 Introduction: Review of scalar and vector field, Dot and Cross products, Coordinate Systems-Cartesian, cylindrical and Spherical. Vector representation of surface
2
2 Physical interpretation of gradient divergence and curl, 13 Transformation of vectors in different co-ordinate systems, dirac-delta function. 1
4 Electrostatics: Electric field due to point-charges, line charges and surface charges 15 Electrostatic potential, Solution of Laplace and Poisson’s equation in one dimension 16 M-method of image applied to plain boundaries, field mapping and conformal transformation, 27 Electric flux density, Boundary conditions, Capacitance: calculation of capacitance for simple
rectangular, cylindrical and spherical geometries. Electrostatic energy.2
Unit-II8 Magnetic Induction and Faraday’s Law, Magnetic Flux Density, Magnetic Field Strength H, 29 Ampere, Gauss Law in the Differential Vector Form, Permeability 110 Energy Stored in a Magnetic Field, Ampere’s Law for a Current Element,. 1
11 Volume Distribution of Current, Ampere’s law, Force law(Unit – II to be continued in II – Term)
1
F I R S T M I N O R E X A MSECOND TERM12 Unit – II (continued ………)
Magnetic Vector Potential, The Far Field of a Current Distribution1
13 The Equation of Continuity for Time Varying Fields, Inconsistency of Ampere’s Law 214 Maxwell’s Equations, Conditions at a Boundary Surface. 2
Unit-III15 Electromagnetic Waves : Continuity equations, Displacement current 116 Maxwell’s equation, Boundary conditions 217 Plane wave equation and its solution in conducting and non-conducting media. 218 Phasor notation, Phase velocity, Group velocity 119 Depth of penetration, Conductors and dielectrics 120 Impedance of conducting medium Polarization 121 Reflection and refraction of plane waves at plane boundaries 122 Poynting vectors and Poynting theorem 1
Unit-IV23 Transmission line equations 124 Characteristic impendence, Distortion-less lines
(Unit – IV to be continued in III – Term)1
S E C O N D M I N O R E X A MTHIRD TERM25 Unit – IV (continued ………)
Input impendence of a loss less line, computation of primary and secondary constants1
26 Open and Short circuited lines, 127 Standing wave and reflection losses 128 Impedance matching, Loading of lines, Input impedance of transmission lines, 129 RF lines, Relation between reflection coefficient and voltage standing wave ratio (VSWR) 130 Lines of different lengths – λ/2, λ/4, λ/8 lines 131 Losses in transmission lines, Smith chart and applications,.. 132 Impedance matching Single stub and Double stub 1
PROPOSED ACADEMIC PLAN FOR IV SEMESTER (JAN-2015 JUN-2015)
SUBJECT: COMMUNICATION SYSTEM BRANCH: ICE (4th Sem) SUBJECT CODE: ETIC-212 CREDITS: 4
TOTAL LECTURE CLASSES: 44
Sl. No. CONTENTS Total No. of
Lectures
FIRST TERM Lecture
Unit-1
1 Overview of Communication system, Communication channels,
1
2 Mathematical Models for Communication Channels Definition of
random variables, PDF, CDF and its properties CDF 2
3 Marginalized PDF, CDF, , 2
4 WSS wide stationery strict sense stationery 1
5 Non stationery signals, UDF, GDF, RDF, 2
6 Binomial distribution, White process 1
7 Poisson process, Wiener process. 2
Unit-2
Amplitude modulation
8 Need for Modulation, Amplitude Modulation theory 1
9 . DSB-SC, SSB, VSB. Modulators and Demodulators 2
10 Angle Modulation ,Relation between FM and PM Wave 1
11 Generation of FM wave- Direct and Indirect Methods. Bandwidth of
FM (NBFM, WBFM)) 2
12 Pulse Analog Modulation: Sampling-Natural and Flat top.
reconstruction, , Generation and Recovery. 1
SECOND TERM
13 .TDM-Pulse Amplitude Modulation (TDM-PAM), Pulse Width
Modulation (PWM), Pulse Position Modulation(PPM), Generation and
Recovery
1
14 Pulse Digital Modulation: Pulse Code Modulation (PCM) 1
15 Differential Pulse Code Modulation (DPCM) 1
16 Delta Modulation (DM), ADPCM) 1
Unit-3
17 Advantages of digital communication. Modulation schemes: ASK,
PSK, FSK. Spectral Analysis. Comparison. 3
18 Digital Signaling Formats-Line coding 1
19 Information and Coding Theory: Entropy, Information 3
21 . Channel Capacity 1
22 Source Coding Theorem ,Shannon Fano Coding, Huffman Coding 3
Unit-4
23 Advanced Communication Systems: Introduction to cellular radio
telephones. Introduction to satellite Communication3 3
THIRD TERM
24 Fiber Optical System: Basic Optical Communication System. Optical
fibers versus metallic cables, 2
25 Light propagation through optical fibers. Acceptance angle and
acceptance cone,. 2
26 ..
Fiber configurations, Losses in optical fibers
2
27 .Introduction to Lasers and light detectors. Applications: Military,
Civil and Industrial applications 2
Total No. of Lectures 44
Text Books:-
George Kennedy,”Electronics Communication System,” TMH,1993
B.P.Lathi, ”Analog &Digital Communication, ”Oxford University Press 1999
Reference Books: -
K.Sam Shanmugam,” Digital and Analog Communication System”,John Wiley,2000
Simon haykins,”Introduction to Analog and Digital Communication System ”,John Wiley,1998
Tannenbaum,”Computer Networks”,Pearson,5th Edition
PROPOSED ACADEMIC PLAN FOR IV SEMESTER (JAN 2015- MAY2015)
Subject Code: ETEE-212 Branch: ICE (4th Sem)
Subject: Control System Credit: 4
Total Lecture Classes: 42
SI.
No.
Topics to be covered Total No.
of
Lectures FIRST TERM
UNIT 1- Control Systems – Basic and Components
1. Introduction of basic terms, classifications and types of Control Systems 1
2. Block diagram simplification , Signal Flow Graph
2
3. Transfer Function, Determination of transfer function using block diagram
reduction techniques
2
4. Mason’s Gain formula. 1
5. Control system components: Electrical, Mechanical, Electronic
1
6. A.C., D.C. types , Servo Motors, 2
7. Stepper Motors, Tacho Generators, 2
8. Synchros, Magnetic Amplifiers, Servo Amplifiers. 2
UNIT-2 Time Domain Analysis
9. Time Domain Performance Criteria 1
10. Transient response of first, second & higher order system 3
11. Steady State Errors in unity feedback control systems 1 SECOND TERM
12. Static Error Constants in unity feedback control system 1
13. Response with P,PI controllers , Response of PID Controllers , Limitations of
time domain analysis
2
UNIT-3 Frequency Domain Analysis
15. Polar and Inverse Polar Plots 2
16. Frequency Domain Specifications, performance of LTI System 2
17. Logarithmic plots (Bode Plots), Gain and Phase Margins;
1
18. Relative Stability, 1
19. Correlation with Time Domain performance close
loop frequency responses from open loop response
2
20 Limitations of frequency domain analysis, minimum/non minimum
phase systems.
1
UNIT-4 Stability and Compensation Techniques
20. Concept , absolute , Asymptotic stability and conditional stability and
marginal stability
1
21. Routh – Hurwitz criterion; 1
22. Nyquist stability criterion; Close loop frequency responses from open loop
response.
2
23. Root Locus plots and their applications. 2 THIRD TERM
24. Concept of compensation, Lag, Lead and Lag-Lead networks; 2
25. series/parallel/ series-parallel/feedback compensation 2
26 Design of closed loop systems using compensation techniques; 1
27. Feedback Compensation using P, PI, PID Controllers. 1
Text Books:
[T1] B. C. Kuo, “Automatic Control System”, Prentice Hall of India, 7th edition 2001.
[T2] Nagraath Gopal “Control Systems Engineering -Principles and Design” New AgePublishers
Reference Books:
[R1] Norman S. Nise, “Control systems engineering” John Wiley & Sons (Asia) Singapore.
[R2] Raymond T. Stefani, Design of Feedback Control System, Oxford University Press.
[R3] K. Ogata, “Modern control engineering”, Pearson 2002.
[R4] S. P. Eugene Xavier, “Modern control systems”, S. Chand & Company.
[R5] M. Gopal “Control Systems-Principles and Design” TMH 4th Edition 2012
PROPOSED ACADEMIC PLAN FOR IV SEMESTER (JAN 2015- MAY 2015)
SUBJECT: ELECTRICAL MACHINE BRANCH: ICE (4th Sem)
SUBJECT CODE: ETIC-210 CREDITS: 4
TOTAL LECTURE CLASSES: 42
TOPICS TO BE COVERED
TOTAL NO.
OF
LECTURE
Basic Concept of Rotating Machines
1. General working principle and constructional
features
2. Type of windings.
3 Generation of voltage & Production of torque
1
1
1
4.Constructional features of generators and motors
5 Commutator action armature reaction, E.M.F.
Equation
6. Classification of D.C. Generator and motors
1
1
1
7. Classification of different D.C Generators
8. Characteristics and applications
9. Methods of speed control
1
1
1
10 Starting of D.C.Motors
Transformer& Poly phase Motors
11 Basic principle and construction of transformer.
12. Ideal and practical Transformer
1
1
1
13 Equivalent circuit & phasor diagram
14. OCC and SCC tests
15. Efficiency and voltage regulation
1
1
1
16. Three phase transformer
17. Three winding transformer
18. Introduction to polyphase induction machines.
1st TERMINAL EXAMINATION
1
1
1
19. Production of rotating magnetic flux vecto
20. Importance of air gap, comparison with
transformer, types of rotor
1
1
21.Development of an equivalent circuit,
22. Estimation of parameters,
23. Principle of operation
1
1
1
24. Equivalent circuit and phasor diagram
25. Torque Equation
26. Maximum torque slip characteristics
1
1
1
27. No load and block rotor tests for 3 phase I.M
28. Equivalent circuit determination of 3 phase I.M
29. Method of starting of 3 phase I.M
Single phase induction motor
1
1
1
30. Double field revolving theory
31. Starting methods of single phase induction motors
32.Universal motor and introduction to switched
reluctance motor.
Synchronous Machine
1
1
1
33. Construction
34. Pitch factor and distribution factor
1
1
35. Induced emf equation
36. Equivalent circuits and phasor diagrams
2nd TERMINAL EXAMINATION
1
1
37. Power relations
38. OCC and SCC characteristics for voltage regulation
of alternator
39. Salient pole and cylindrical rotor machines and
phasors
1
1
1
40. Effect of excitation and V curves
41.Power factor correction
42. Parallel operation of synchronous generator.
3rd TERMINAL EXAMINATION
1
1
1
Text books:
[T1] I.J Nagrath and D.P.Kothari, “Electrical Machines”, Tata Mc Graw Hill, 2010,
Fourth Edition
[T2] Bhag S. Guru, Huseyin R. Hiziroglu, “Electric Machinery and Transformers”,
Oxford Pub., 3rd Ed.
Reference Books
[R1] M. V. Deshpande, “Electrical Machines” PHI
[R2] PC Sen, “Principles of Electric Machinery and Power Electronics”, Wiley and Sons,
Third Edition.
[R3] Ashfaq Hussain, “Electrical Machines”, Dhanpat Rai
[R4] Fitzgeral, A.E. , C.Kingslay & Umans, “Electrical Machines”, Mc Graw Hill.
[R5] Ghosh, “ Electrical Machines”, Pearson
PROPROSED ACADEMIC PLAN FOR IV SEMESTER ( Jan 2015 – May 2015)
Subject: Measurement and Instrumentation Branch : ICE (4th Sem)
Subject Code: ETIC 204 Credits: 3
Total Lecture Classes: 44
Sr.
No.
Topics to be covered No. of lectures
UNIT I
1.
A. C. Potentiometer:
Theory and operation of coordinate AC Potentiometer
Theory and operation of polar types A. C. Potentiometer
Errors and Applications.
2
1
2
2. A. C. Bridges:
Configurations, Errors and accuracies, different types of bridges and
their applications.
De SautyBridge, Schering Bridge, Anderson Bridge
Maxwell Bridge, Wein Bridge
Use of Shielding in Bridges,Wagner Earth Connection, Grounding
and Guarding.
2
1
1
1
UNIT II
3.
Instrument Transformers:
Construction, operation, ratio and phase errors in potential
transformers
Compensation techniques for errors in potential transformers,
testing of potential transformers.
Construction and operation of current transformers
Ratio and Phase errors in current transformers,
END OF 1st TERM
2
2
2
2
4. Current transformers:
Compensation techniques for errors in current transformers, testing
of current transformers, absolute and comparison methods.
2
UNIT III
5.
AC instruments and Meters:
Induction type instruments:
Theory and operation of single phase energy meter
Adjustments and calibration of single phase energy meter,
Polyphase energy meter, Ampere Hour Meters,
Measurement of Volt-ampere and reactive volt amperes.
2
1
2
1
6. Power Factor Meters, Frequency Meters, Synchroscopes
Phase sequence Indicators, maximum demand meters.
2
1
Regulated Power Supplies, Function Generator: Sine, Cosine,
Square and triangular wave,
Instrumentation amplifier and their applications.
2
1
UNIT IV
7. Electronic Measuring Instruments:
General purpose Cathode Ray Oscilloscope: Construction &
working principles
Various controls, applications in measurement.
END OF 2nd TERM
2
2
8. Digital Instruments:-
Voltmeter, Multimeter,
Multi-parameter indicator, Signal conditioning,
Introduction to active filters and their applications.
Digital storage Oscilloscope (DSO).
2
2
2
2
Text Books:
[T1] P.Purkait,B.Biswas,Sanatanu Das,C. Koley, “Electrical and Electronic Measurements
and Instrumentation”, McGraw Hill Edu.
[T2] Albert D.Helfrick,William D.Cooper, “Modern Electronic Instrumentation and
Measurement Techniques”, PHI India
Reference Books:
[R1] E.W. Golding & Widdis, “Electrical Measurements & Measuring Instruments”, Wheeler
Publication.
[R2] H. S. Kalsi, “Electronic Instrumentation”, 3rd Edition, McGraw Hill Edu.
[R3] Kishore-Electronic Instrumentation and Measurement”, Pearson
PROPOSED ACADEMIC PLAN FOR IV SEMESTER (Jan 2015- May 2015)
Subject: Power Electronics Branch: ICE (4th Sem)
Subject Code: ETIC 206 Credits: 4
Total Lecture Classes: 44
Sl.
No.
Topics to be covered Total No. of
Lecture
FIRST TERM
1 UNIT- I INTROUDUCTION 1
Characteristics and switching behaviour of Power Diode, SCR, UJT,
TRIAC
2 Characteristics and switching behaviour of DIAC, GTO, MOSFET,
IGBT 2
3 MCT and power BJT, two-transistor analogy of SCR, firing circuits of
SCR and TRIAC 2
4 SCR gate characteristics, SCR ratings. Protection of SCR against over
current, over voltage 2
5 High dV/dt, high dI/dt, thermal protection, Snubber circuit
2 6 Methods of commutation, series and parallel operation of SCR, Driver
circuits for BJT/MOSFET 2
7 UNIT- II A.C. TO D.C. CONVERTER 1
Classification of rectifiers, phase controlled rectifiers,
8 Fully controlled and half controlled rectifiers and their performance
parameters 3
9 Three phase half wave, full wave and half controlled rectifiers and
their performance parameters
3
SECOND TERM
10 Effect of source impedance on the performance of single phase and
three phase controlled rectifiers
2
11 Single-phase and three phase dual converter
2
12 UNIT- III D.C. TO D.C. CONVERTER 3
Classification of choppers as type A, B, C, D and E, principle of
operation
13 Switching mode regulators: Buck, Boost, Buck-Boost, Cuk regulators
3
14 A.C. TO A.C. CONVERTER 3
AC voltage Controllers, Cyclo-converters : single phase to single
phase, three phase to single phase
15 Three phase to three phase Cyclo-converter circuit and their operation,
Matrix converter 2
16 UNIT – IV D.C. TO A.C. CONVERTER
3 Single phase single pulse inverter: Square wave, quasi square. Three
phase single pulse inverters (120̊ and 180 ̊ conduction)
Text Books:
[T1] M.H. Rashid, “Power Electronics: Circuits, Devices and Applications” Pearson
Publications.
[T2] Daniel W. Hart, “Power Electronics “Tata McGraw-Hill
[T3] H.C. Rai, “Power Electronics Devices, Circuits, Systems and Application”, Galgotia
Publications, 3rd Edition
References Books: [R1] Singh, Kanchandani, “Power Electronics”, Tata McGraw-Hill.
[R2] Ned Mohan, Tore M. Undeland and Robbins, “Power Electronics: Converters,
Applications and Design” Wiley India Publication
[R3] V R Moorthi, “Power Electronics: Devices, Circuits and Industrial Applications”,
Oxford Publication.
[R4] Kassakian, Schlecht, Verghese, “Principles of Power Electronics”, Pearson
Publications
[R5] P. S. Bimbhra “Power Electronics”, Khanna Publishing.
THIRD TERM
17 Modulation Techniques and reduction of harmonics, PWM
techniques,
2
18 SPWM techniques, SVM, Carrier less modulation
2
19 SPWM techniques, SVM, Carrier less modulation
2
20 Current source inverter, Multi level Inverter: cascaded and NPC
Inverters. 2
PROPOSED ACADEMIC PLAN FOR IV SEMESTER (Jan - May 2015)
Subject: Theory and Application of Integrated Circuits Branch: ICE (4th Sem)
Subject Code: ETIC-208 Credits: 4
TOTAL LECTURE CLASSES: 44
S. No. TOPICS TO BE COVERED Total No. of
Lecture
FIRST TERM
UNIT- I: Fundamentals of IC Fabrication and Circuit Configurations for Linear IC
1 IC classification, fundamental of monolithic IC technology 1
2 epitaxial growth, masking and etching, diffusion of impurities. Realization of
monolithic ICs and packaging.
2
3 Differential Amplifier, Differential Amplifier Configurations, Bipolar
differential Amplifier, AC and DC characteristics.
3
4 Current mirror and BJT Current Source. Current source as Active load. Voltage
Sources, voltage reference. 3
5 Operational Amplifiers IC 741, DC and AC performance characteristics 1
6 Open and closed loop configurations. 1
UNIT- II: Applications of Operational Amplifiers
7 Inverting and non inverting Amplifier 1
8 Scale Changer, Phase Shift Circuits, Voltage Follower 1
9 V-to-I and I-to-V converters, adder, subtractor, 1
10 Instrumentation amplifier 1
11 Integrator, Differentiator 1
12 Logarithmic amplifier, Antilogarithmic amplifier 1
13 Comparators, Schmitt trigger 1
SECOND TERM
14 Precision rectifier, peak detector, clipper and clamper 1
15 Low-pass, high-pass and band-pass Butterworth filters 3
UNIT- III: Analog Multiplier, PLL, A/D and D/A Convertor
16 Analog Multiplier using Emitter Coupled Transistor Pair – Gilbert Multiplier
cell – Variable transconductance technique
3
17 analog multiplier ICs and their applications 1
18 Operation of the basic PLL, Closed loop analysis, Voltage controlled oscillator 2
19 Analog and Digital Data Conversions–weighted resistor type, R-2R Ladder type 2
20 A/D Converters – Flash type – Successive Approximation type – Single Slope
type – Dual Slope type – A/D Converter using Voltage-to-Time Conversion
3
UNIT- IV : Waveform Generators and Special Function ICs
21 Sine-wave generators 3
THIRD TERM
22 Multivibrators and Triangular wave generator, Saw-tooth wave generator,
ICL8038 function generator, Timer IC 555
4
23 IC Voltage regulators – Three terminal fixed and adjustable voltage regulators –
IC 723 general purpose regulator – Monolithic switching regulator
2
24 Switched capacitor filter IC MF10, Frequency to Voltage and Voltage to
Frequency converters
1
25 Audio Power amplifier, Video Amplifier, Opto-couplers. 1
Text Books:
T1. Sergio Franco, Design with operational amplifiers and analog integrated circuits, 3rd Edition, TMH, 2007.
T2. D. Roy Choudhry, Shail Jain, Linear Integrated Circuits, New Age International Pvt. Ltd., 2000
Reference Books:
R1. Ramakant A. Gayakwad, OP-AMP and Linear ICs, Prentice Hall/Pearson Education, 4th Edition, 2001.
R2. K Lal Kishore, Operational Amplifier and Linear Integrated Circuits, Pearson Education, 2006.
R3. S.Salivahanan & V.S. Kanchana Bhaskaran, Linear Integrated Circuits, TMH, 2008.
R4. J.Michael Jacob, Applications and Design with Analog Integrated Circuits, Prentice Hall of India, 1996.
IT
LECTURE PLAN
Subject: Control Systems
Subject Code: ETEE-212
Total No. of lectures: 42
S.NO. TOPIC TO BE COVERED No. of Lecturers
Allotted
FIRST TERM
UNIT-I
1. Introduction to basic terms, examples, classifications & types of Control Systems
with their advantages, disadvantages and comparison
1
2. Concept of mathematical modeling with examples of Mechanical translational
systems and electrical systems, Transfer function with simple examples 2
3. Block diagram Algebra-its use in reduction and feed forward compensation 2
4. Signal flow graph, Mason gain formula 2
5. Control system components: AC/DC Servomotors, Stepper motors 2
6. Tachogenerator, synchros 1
7. Magnetic amplifier and servo amplifiers 1
UNIT-II
8. Time domain performance specifications 2
9. Transient response of first & second order systems 3
10. Steady state errors and static error constants in unity feedback control systems 2
11. Basic control Actions: Proportional, integral and Derivative controllers 2
12. Limitations of time domain analysis. 1
SECOND TERM
UNIT-III
13. Frequency domain specifications and performance of LTI systems 2
14. Polar and inverse polar plots, 2
15. Logarithmic plots (Bode plots), gain and phase margins, relative stability 3
16. Correlation with time domain performance, closed loop frequency responses from
open loop response 2
17. Limitations of frequency domain analysis, minimum/non minimum
phase systems 1
UNIT-IV
18. Concepts: absolute, asymptotic, conditional and marginal stability 1
19. Routh Hurwitz stability criterion 1
20. Nyquist stability criterion 2
21. Root locus technique-Determination of gain and stability from root locus 2
THIRD TERM
22. Introduction to compensators: series/parallel/ series-parallel/feedback compensation, 2
23. Lag/Lead/Lag-Lead networks for compensation 2
24. Compensation using P, PI, PID controllers 1
Deepali Sharma (GTBIT) M.NO. 9212365617
Text Books:
[T1] B. C. Kuo, “Automatic control system”, Prentice Hall of India, 7th edition 2001.
[T2] Nagraath Gopal “Control Systems Engineering -Principles and Design” New Age Publishers
Reference Books:
[R1] Norman S. Nise, “Control systems engineering” John Wiley & Sons (Asia) Singapore.
[R2] Raymond T. Stefani, Design of Feedback Control System, Oxford University Press.
[R3] K. Ogata, “Modern control engineering”, Pearson 2002.
[R4] S. P.Eugene Xavier, “Modern control systems”, S. Chand & Company.
[R5] M. Gopal “Control Systems-Principles and Design” TMH 4th Edition 2012
Lecture Plan for Computer Organization Architecture
Subject Code: ETCS-204 Credits:4
S.No Contents No. of
Lectures
1. Introduction to Computer Architecture (
Difference between Computer Architecture,
Computer Hardware & Computer
Organization )
1
2. Understanding Register Transfer Language
( RTL).
1
3. Common Bus & Memory transfer
( Hardware Implementation )
2
4. Arithmetic micro operation : Binary Adder,
Binary Adder Subtractor , Arithmetic
Circuit. ( Hardware Implementation )
1
5. Logical shift micro operation ( Hardware
Implementation )
1
6. Instruction Code : Stored Program
Organization, Indirect Addresses.
2
7. Computer registers, Instruction, timing &
control
2
8. Basic computer design 2
9. Accumulator Design 1
10. Control memory 1
11. 8085 instruction set architecture 1
12. CPU – introduction and organization, stack
organization
1
13. Assembly language instructions 2
14. Instruction Codes, Computer Registers 2
15 Computer Instructions 1
16 Timing & Control, Instruction Cycle 1
18 Memory Reference Instructions, Input-Output
and Interrupts
2
19. Instruction sequencing & interpretation,
Hardwired & Micro Programmed (Control
Unit)
3
20. Micrprogrammed computers, , Microcoded CPU 2
21. Design & implementation of simple CPU 1
22. CPU – introduction and organization, stack
organization
1
23. Instruction Formats-3,2,1,0 1
24. Addressing modes explanation and
numerical example solving
1
25 Internal architecture of 8085
microprocessor.
2
26 Memory hierarchy, main memory, auxiliary
memory ( RAM , ROM Chips, Magnetic
Disks, Magnetic Tapes )
1
27. Virtual Memory, Asynchronous Data
Transfers
1
28. Direct memory Access 1
29. Characteristics of multiprocessor,
interconnection structure
1
30. Serial Communication & UARTs, RS-232-
C & RS-422 standard
1
Lesson Plan for Database Management Systems (MAE)
Course Name: B.Tech. Semester: 4th SUB CODE: ETCS-208
S.No Topic Details No of
Hours
Reference/text book
1.
Unit-I:
Introductory Concepts of
DBMS: Introduction and
application of DBMS
Data Independence,
Database System
Architecture – levels,
Mapping, Database users
and DBA
Entity – Relationship
model, constraints, keys,
Design issues, E-R Diagram
Extended E-R features-
Generalization,
Specialization,Aggregation,
Translating E-R model into
Relational model.
2
3
2
3
T1, T2
2.
UNIT-II : Relational
Model: The relational
Model, The catalog, Types,
Keys
Relational Algebra,
Fundamental operations,
Additional Operations.
SQL fundamentals,
DDL,DML,DCL PL/SQL
Concepts, Cursors, Stored
Procedures, Stored
Functions, Database
Integrity – Triggers.
2
3
5
T2,R3
3.
UNIT-III: Functional
Dependencies, Non-loss
Decomposition
First, Second, Third Normal
Forms, Dependency
Preservation, Boyce/Codd
Normal Form
Multi-valued Dependencies
and Fourth Normal Form,
Join Dependencies and
Fifth Normal Form.
2
4
4
T2, R1, R3
4.
UNIT-IV: Transaction
Management: ACID
properties, serializability of
Transaction, Testing for
Serializability
Concurrency control, Lock
based concurrency control
(2PL, Deadlocks), Time
stamping methods
Database recovery
management.
Implementation
Techniques: Overview of
Physical Storage Media,
File Organization, Indexing
and Hashing, B+ tree Index
Files
Query Processing
Overview, Catalog
Information for Cost
Estimation, Selection
Operation, Sorting, Join
Operation, Materialized
views, Database Tuning.
.
3
3
2
2
2
T1, T2, R2
Text Books:
[T1] Abraham Silberschatz, Henry F. Korth, S. Sudharshan, “Database System
Concepts”, 5th Edition, Tata McGraw Hill, 2006
[T2] Elmsari and Navathe, “Fundamentals of Database Systems”, 6th Ed., Pearson,
2013
References Books: [R1] C.J.Date, A.Kannan, S.Swamynathan, “An Introduction to Database Systems”, 8th
Edition, Pearson Education, 2006.
[R2] J. D. Ullman, “Principles of Database Systems”, 2nd Ed., Galgotia Publications,
1999.
[R3] Vipin C. Desai, “An Introduction to Database Systems”, West Publishing Co.,
Lesson Plan for Applied Mathematics-IV
Course Name: B.Tech. Semester: 4th SUB CODE: ETCS-202
S.No Topic Details No of
Hours
Reference/text book
1.
UNIT – I
Partial Differential
Equation: linear partial
differential equations with
constant coefficient,
homogeneous linear
equations
non homogeneous linear
equations
Method of separation of
variables.
Laplace equation
wave equation
heat flow equation in
Cartesian coordinates only
with initial and boundary
value.
2
2
2
2
1
2
T1
2.
UNIT II
Probability Theory:
Definition, addition law of
probability, multiplication
law of probability,
conditional probability
Baye’s theorem,
Random variable: discrete
probability distribution,
Continuous probability
distribution
2
1
2
T1,T2
Expectation, moments,
moment generating function
Skewness, kurtosis
Binomial distribution,
Poisson distribution, normal
distribution.
2
2
3
3.
UNIT-III
Curve Fitting: Principle of
least square Method of least
square and curve fitting for
linear and parabolic curve
Correlation Coefficient,
Rank correlation, line of
regressions and properties
of regression coefficients.
Sampling distribution:
Testing of hypothesis, level
of significance,
sampling distribution of
mean and variance, Chi-
square distribution,
Student’s T- distribution, F-
distribution, Fisher’s Z-
distribution.
3
3
2
4
T1,T2
4.
UNIT IV
Linear Programming:
Introduction,
formulation of problem
Graphical method,
Canonical and Standard
form of LPP
Simplex method
Duality concept,
Dual simplex method
2
2
1
2
T1
Transportation and
Assignment problem.
3
Text Books:
[T1] B. S. Grewal,”Higher Engineering Mathematics” Khanna Publications.
[T2]. N.M. Kapoor, “Fundamentals of Mathematical Statistics”, Pitambar Publications
References Books:
[R1] E. kresyzig,” Advance Engineering Mathematics”, Wiley publications
[R2] Miller and Freund, “ Probability and statistics for Engineers” , PHI
[R3] Gupta and Kapoor, “ Fundamentals of Mathematical Statistics” Sultan Chand and
Sons
[R4] G. Hadley, “Linear Programming”, Narosa.
[R5] Schaum’s Outline on Probability and Statistics” Tata McGraw-Hill
[R6] Gupta and Manmohan, “ Problems in Operations Research”, Sultan Chand and
Sons.
[R7] R.K. Jain and S.R.K. Iyengar,”Advanced Engineering Mathematics “Narosa
Publications.
Lecture Topics
L1 Programming Paradigms
L2-L3 Introduction to OOPs
L4 Object Oriented Languages
L5-L6 Basic Terms and Ideas
L7-L8 Review of C
L9 Memory allocation
L10 Data types, control statements,
indentifiers
L11 Arrays, Operator
L12-L13 Classes and Objects
L14-L15 Constructors and Destructors
L16-L17 Object's Instantiation
Introducing Object Oriented Approach related to other
paradigms (Functional, Data decomposition).
Understanding Objects
Lecture PlanOBJECT ORIENTED PROGRAMMING (ETCS-210)
Guru Tegh Bahadur Institute Of Technology
Sub - Topic
Objective of Constructors
Types of Constructors
Constructor overloading
Destructors
Instantiation of objects
Default Parameter Value Object types
In-Line functions
Monolythic programming,
Procedural Programming,
Structured Programming,
Object Based Programming
Characteristics and Features of Object Oriented
Languages
Abstraction
Encapsulation
Information Hiding
Interhitence
Polymorphism
Differences between C and C++
Differences between cin, cout and printf and scanf
Simple Data Types
Literals
Variables
Type conversion and casting
Control Statements:
if-else,
while,
do-while,
for,
switch-case
One-D array
Multidimensional arrays
Operators:
Review of C operators
Scope resolution operator (::)
endl operator
member to pointer operator
De-referencing operator
Abstract Data Type
State Identity and Behaviour of Object
Defining a Class
Creating Objects
Difference in memory allocation in c and C++
new and delete operators
Lecture Topics
Lecture PlanOBJECT ORIENTED PROGRAMMING (ETCS-210)
Sub - Topic
Monolythic programming,
Procedural Programming,
Structured Programming,
Object Based Programming
L18 Static and Constant Keyword
L19-L20 Dynamic Memory Allocation
L21 Garbage Collection
L22 Abstract keyword
L23-L24 Inheritance
L25 Access Specifiers
L26 Aggregation and Containership
L27-L28 Polymorphism
L29-L30 Operator Overloading
L31-L32 Run-time Polymorphism
L33-L34 Templates
L35- L37 File Handling
L38-L39 Namespaces
L40-L41 Exception Handling
Features of Inheritance
Types of Inheritance
Single/multiple/multilevel/Hierarchical
Class Hierarcy
Types of Derivations
Public Derivations, Private Derivations and Protected
Derivations
Static Data Members
Static Member Functions
Constant Data, Constant Member Function
Constant Objects
Dynamic Memory Allocation using New Operator
Dynamic Memory Deallocation using Delete Operator
Differences between new & delete and Malloc & Free
C++ Garbage Collection
Abstract methods and abstract classes
Persistant Objects
Stream and files
Opening and closing a file
Reading from and writing in file
Performing operations on files:
Insertion, Deletion, Updation and Extraction of specific
records
seekg() and tellg(), seekp() and tellp()
Error handling in files
Aggregation
Composition
Classification
Differences between the three
Errors
Types of Errors:
Run-time and Compile Time
Keywords used for Exception handling:
try, catch and throw
Rethrowing an Exception
Types of Polymorphism
Compile time, Run-time polymorphism
Method Polymorphism
Polymorphism by parameters
Overloading of operators
Operators which cannot be overloaded
Multiple Inheritance
Overriding inheritance method
Generic Function
Keyword Template
Generic Classes
Features of Namespaces
Namespace Keyword
Creating and using own namespaces
Lecture Topics
Lecture PlanOBJECT ORIENTED PROGRAMMING (ETCS-210)
Sub - Topic
Monolythic programming,
Procedural Programming,
Structured Programming,
Object Based Programming
L42 Standard Template Library
L43-L44 Other STL elements
Over-view of standard template library organization
Containers and Function objects
Algorithms, Iterators and allocators
strings, streams
manipulators, user defined manipulators
vectors, valarray, slice, generalized numeric algorithm
Lesson Plan for Theory of Computation
Course Name: B.Tech. Semester: 4th SUB CODE: ETCS-206
S.No Topic Details No of
Hours
Reference/text book
1.
UNIT- I
Overview: Alphabets,
Strings & Languages,
Chomsky Classification of
Languages
Finite Automata,
Deterministic finite
Automata (DFA) &
Nondeterministic finite
Automata (NDFA),
Equivalence of NDFA and
DFA, Minimization of
Finite Automata
Moore and Mealy machine
and their equivalence.
Regular expression and
Kleen’s Theorem(with
proof), Closure properties
of Regular Languages,
Pumping Lemma for
regular Languages(with
proof).
1
5
2
3
T1, T2
2.
UNIT- II
Context free grammar,
Derivation trees, Ambiguity
in grammar and its removal
Simplification of Context
Free grammar, Normal
forms for CFGs: Chomsky
Normal Form & Greibach
Normal Form
2
2
T1,T2
Pumping Lemma for
Context Free languages,
Closure properties of
CFL(proof required)
Push Down Automata
(PDA), Deterministic PDA,
Non Deterministic PDA
,Equivalence of PDA and
CFL
Overview of LEX and
YACC
3
3
1
3.
UNIT- III
Turing machines, Turing
Church’s Thesis, Variants
and equivalence of Turing
Machine
Recursive and recursively
enumerable languages
Halting problem,
Undecidability, Examples
of Undecidable problem.
6
3
2
T1,T2
4.
UNIT- IV
Introduction to Complexity
classes, Computability and
Intractability, time
complexity,
P, NP, Co-NP, Proof of
Cook’s Theorem
Space Complexity, SPACE,
PSPACE, Proof of
Savitch’s Theorem, L ,NL
,Co-NL complexity
3
3
5
T1, T2
Text Books:
[T1] Hopcroft, John E.; Motwani, Rajeev; Ullman, Jeffrey D “Introduction to
Automata Theory,
Languages, and Computation”, Third Edition, Pearson.
[T2] Sipser, Michael, ”Introduction to the theory of Computation”, Third Edition,
Cengage.
References Books:
[R1] Martin J. C., “Introduction to Languages and Theory of Computations”, Third
Edition, TMH.
[R2] Papadimitrou, C. and Lewis, C.L., “Elements of the Theory of Computation”,
PHI.
[R3] Daniel I.A. Cohen, ”Introduction to Computer Theory”,Second Edition, John
Wiley.
MAE
ACADAMIC LECTURE PLAN FOR MAE 4th SEMESTER(Batch 2013
onwards)
Subject: Measurements And Instrumentation Paper Code: ETME-208
Total Teaching weeks in Semester: 15 weeks L T C 3 0 3 Total Lecture Classes available : 45
S.NO TOPIC DETAIL NO. OF
LECTURES
FIRST TERM
UNIT-1
1. Introduction To measurement: Block Diagram and components of measuring
instrumentation system, classifications of instruments 1
2. Static Characteristics of instruments 1
3. Dynamic Characteristics of instruments 2
4. Errors in Measurements: Gross error, systematic errors 1
5. Calibration of Instruments: Process of calibration, Standard of calibration and
classification of standard. 2
6. Different Sensors: Introduction sensing element used in temperature, pressure, force,
torque and flow measurement. 2
UNIT-II
7. Transducers: Introduction and classification. 1
8. Transducers: Constructional features, working principle and applications of resistive,
Inductive 2
9. Constructional features, working principle and applications of
Photoelectric & Capacitive Transducers 2
10. Constructional features, working principle and applications of magneto-strictive,
Ionization 2
11. Constructional features, working principle and applications of piezoelectric, hall effect 2
SECOND TERM
12. Constructional features, working principle and applications of Thermoelectric and digital
transducers. 2
UNIT-III
13. Measurement of Pressure: Classification of pressure measuring devices 1
14. High pressure Measurement , 1
15. Low pressure measurement, Vacuum pressure measurement 2
16. Measurement of Flow: Method of flow measurement. 1
17. Obstruction meters, electromagnetic flow meters 2
18. Hot wire anemometer, ultrasonic flow meter. 1
UNIT-IV
18. Measurement of Temperature: Thermometer, thermocouples, Thermistors 2
19. Resistance thermometers and pyrometers. 2
20. Strain Gauges and Related Measurement: Electric resistance strain gauge 2
21. semiconductor strain gauge, temperature problems and compensation 2
THIRD TERM
22. Applications of strain gauges in measurement 3
23. Measurement of Force, Displacement, Rotating speed 3
24. Measurement of Torque, Level , Humidity and Moisture 3
S.No Topics to be covered
UNIT I: Lectures
1 Introduction: Introduction and classification of fluid machineries,
2Introduction to hydrodynamic thrust of jet on a fixed and moving surface (flat & curve), jet
propulsion
3 Hydraulic Turbines: Classification of turbines
4Impulse turbines, Constructional details, Velocity triangles, Power and efficiency calculations,
Governing of Pelton wheel
5 Reaction Turbines: Francis and Kaplan turbines Constructional details, Velocity triangles,
6 Power and efficiency calculations, Degree of reaction, Draft tube,
7 Cavitations in turbines, Performance characteristics,
8Principles of similarity, Unit and specific speed, selection of turbines hydroelectric plants
UNIT II :
9 Centrifugal Pumps: Classifications and utility of various type pumps
10 introduction to centrifugal Pumps Vector diagram, Work done by impellor
11 Efficiencies of centrifugal pumps, Specific speed, Model testing
12 Cavitations & separation and their control, Performance characteristics
13Hydraulic Power and its Transmission: Transmission of hydraulic power through pipe lines;
14 water hammer, precautions against water hammer in turbine and pump installations
15Power Hydraulics: Introduction to Positive pumps (gear, vane, screw, variable delivery
pumps),
16Different types of Valves (flow control, pressure control, direction control, solenoid operated
valve)
UNIT IV
17 Hydraulic systems: Function, construction and operation of Hydraulic accumulator
18hydraulic intensifier, hydraulic crane, hydraulic lift and hydraulic press, Fluid coupling and
torque converter, Hydraulic ram
19 Hydraulic and Pneumatic Circuits: Basic principles,
20 comparison of pneumatic and hydraulic Systems,
21 hydraulic circuits, (meter-in, meter-out, bleed-off).
Text Books:
[T1]Dr. R.K. Bansal, “Fluid Mechanics & Hydraulic Machines”, Laxmi Publications (P) Ltd., 2002.
[T2] Jagadish Lal, “Fluid machines Including Fluid mechanics”, Metropolitan Book Co., New Delhi, 1995
Reference Books:
[R1] Dr. D.S. Kumar, “Fluid Mechanics & Fluid Power Engineering”, S.K. Kataria & Sons,2001
[R2] Kumar, K.L, “Engineering Fluid Mechanics”, Eurasia Publishing House, New Delhi, 1995.
[R3] P.N Modi and S.M Seth, “Hydraulics and Fluid Mechanics”, Standard Book House
UNIT IV
L-9
TERM-1
UNIT III :
TERM-III
L-8
UNIT II:
TERM-2
L-8
L-7
ACADEMIC PLAN FOR IV SEMESTER(Batch 2013 onwards)Fluid System Paper Code: ETAT-204
L T C
3 1 4
Total Lecture Classes available : 45 Total Tutorial Classes available : 15
Total No. of
L-10
L-3
Totorials
UNIT IV
T-3
TERM-1
UNIT III :
TERM-III
T-3
UNIT II:
TERM-2
T-2
T-2
ACADEMIC PLAN FOR IV SEMESTER(Batch 2013 onwards)Fluid System Paper Code: ETAT-204
L T C
3 1 4
Total Lecture Classes available : 45 Total Tutorial Classes available : 15
Total No. of
T-3
T-2
ACADAMIC LECTURE PLAN FOR MAE 4th SEMESTER (Batch 2013
onwards)
Subject: Switching Theory and Logic Design Paper Code: ETEC-202
Total Teaching weeks in Semester: 15 weeks L T C 3 0 3 Total Lecture Classes available : 45
S.NO TOPIC DETAIL NO. OF
LECTURES
FIRST TERM
UNIT-1
1. Number Systems and Codes: Decimal, Binary, Octal and Hexadecimal Number
systems, Codes- BCD 1
2. Gray Code, Excess-3 Code, ASCII, EBCDIC, Conversion between various Codes. 2
3. Switching Theory: - Boolean Algebra- Postulates and Theorems, De’ Morgan’s Theorem 2
4. Switching Functions-Canonical Forms- Simplification of Switching Functions- Karnaugh
Map and Quine Mc-Clusky Methods. 2
5. Combinational Logic Circuits:- Review of basic gates- Universal gates, Adder,
Subtractor ,Serial Adder, Parallel Adder- Carry Propagate Adder, Carry Look-ahead
Adder, Carry Save Adder.
2
6. Comparators, Parity
Generators, Decoder and Encoder, Multiplexer and De-multiplexer, ALU, PLA and PAL 2
UNIT-II
7. Integrated circuits: - TTL and CMOS logic families and their characteristics. Brief
introduction to RAM and ROM. 2
8. Brief introduction to RAM and ROM. 1
9. Sequential Logic Circuits: - Latches and Flip Flops- SR, , D, T and MS-JK Flip Flops,
Asynchronous Inputs. 1
10. Counters and Shift Registers:- Design of Synchronous and Asynchronous Counters:
Binary, BCD, Decade and Up/Down Counters , 2
11. Shift Registers, Types of Shift Registers, Counters using Shift Registers- Ring
Counter and Johnson Counter 1
SECOND TERM
UNIT-III
12. Synchronous Sequential Circuits:- State Tables State Equations and State Diagrams 2
13. State Reduction and State Assignment,. 2
14. Design of Clocked Sequential Circuits using State Equations 3
15. Finite state machine-capabilities and limitations, Mealy and Moore models-minimization
of completely specified and incompletely specified sequential machines 4
16. Partition techniques and merger chart methods concept of minimal cover table. 2
UNIT-IV
17. Algorithmic State Machine: Representation of sequential circuits using ASM charts
synthesis of output and next state functions 3
18. Data path control path partition-based design. 2
THIRD TERM
19. Fault Detection and Location: Fault models for combinational and sequential circuits,
Fault detection in
combinational circuits;
5
20. Homing experiments, distinguishing experiments 2
21. Machine identification and fault detection experiments in sequential circuits. 2
ACADEMIC PLAN FOR IV SEMESTER MAE (Batch 2013 onwards)
SUB: Theory of Machines Sub. Code: ETAT-202
Total Teaching weeks in Semester: 15 weeks L T C
3 1 4 Total Lecture Classes available : 45 Total Tutorial Classes available : 15
S.No TOPICS TO BE COVERED Total no. of
Teaching 6 Weeks TERM-I Lectures Tutorial
Simple mechanism
9
2
Introduction to subject, Introduction and application of simple mechanism,
Types of kinematic links, Different types of kinematics pairs
Kinematics Chains, Grashofs criterion for mobility determination,
Grubler’s rule for DOF in plane mechanism, Inversions of 4R,3R-1P and 2R-2P, chains,
Kinematic analysis of planer mechanism:-Relative velocity method, acceleration in planer
mechanism , Coriollis acceleration component
Dynamic Analysis
Velocity and acceleration of the reciprocating parts:- Analytical method;
Graphical method- Klein’s construction,
Analysis of various forces acting on single slider-crank mechanism,
3
2
Flywheel
Introduction to Flywheel, 3 1
Turning moment diagram for 4-s stroke internal engine
Governors:
Introduction to Governors; Hartnell governors 3 1
Porter governors – construction and working
Teaching 6 Weeks TERM-II
CAM and Followers
Classification of Cams and followers, Nomenclatures for Cam profile
5
2 Types of Motion of followers,
Cam Profile Construction for uniform velocity,
Uniform acceleration and retardation,SHM, Cycloidal motion, Oscillating Followers
Gears:- Toothed Gear
9
2
Introduction and classification of gears,
Nomenclatures for Gear teeth, Law of gearing,
Construction and utility of different teeth profiles, Interference and methods to avoid
interference,
Introduction to helical, spiral and worm gears,
Gear Train
Simple, Compound gear trains
Epicyclic gear trains (Simple and Compound) – Analysis by tabular and relative velocity method,
fixing torque.
Balancing
Static and Dynamic balancing, Balancing of revolving masses,
4
2 Balancing of reciprocating masses, Single and multi-cylinder engines
Teaching 2 Weeks TERM-III
Gyroscopes
Gyroscopic law, effect of gyroscopic couple on automobiles, ships, aircrafts 5 2
Vibrations
Vibration analysis of single degree of freedom, natural, damped forced vibrations, based-excited
vibrations, and transmissibility ratio. 4 1
Text Books:
1. S.S. Rattan, “Theory of Machines”, Tata McGraw Hill, 2. Ghosh A & Malik A K “ Theory of Mechanisms and Machines” Affiliated
East West Press 3.R.K. Bansal, “Theory of Machines”,, Laxmi Publication, New Delhi, 4.Shigley J E “Theory of Machines”, Pearson
ACADEMIC PLAN FOR IV SEMESTER MAE(Batch 2013 onwards)
Sub: Manufacturing Machines Subject Code: ETME 206
Total Teaching weeks in Semester: 15 weeks L T C
3 1 4
Total Lecture Classes available : 45 Total Tutorial Classes available : 15
S.No TOPICS TO BE COVERED TOTAL NO. OF
Total Teaching Weeks: 6 Lecture Tutorial
FIRST TERM
Introduction of Machines Tool
1 Classification of Machine Tools (Based on application purpose, process & production rate) 2
2 Elements of Tool Geometry (Tool signature as per ASA).Cutting tool Materials & Applications 1
3 Various types of lathe (Centre Lathe, Facing Lathe, Gap-bed Lathe, Capstan Lathe, Turret Lathe, NC,
CNC and DNC lathe), major difference between CNC and Conventional Lathe
3
4 Major sub-assemblies of lathe (Bed, Head stock, Tail stock, Carriage consisting Saddle, Cross-slide,
Compound slide, Tool post and Apron
2
5 Work holding devices (Self centering three jaw chuck, Independent four jaw chuck,, Collets, Face
plates, Dog carriers, Centers, Mandrels and Rest (steady and moving)).
2
6 Driving mechanism (Apron mechanism, Thread Cutting mechanism & Machining Time calculation
(Num. problems)
2 2
7 Features of half-nut engagement-disengagement, indexing dial mechanism (indexing-logical problem) 2 1
8 Operations on Lathe (Thread Cutting, Facing, Under Cutting, Drilling, Reaming, Boring, Parting-Off,
Knurling, Chamfering, Taper Turning & calculation)
1 2
9 Reciprocating Type Machine Tools (Shaper, Planer and Slotter: Constructional Features, Basics
machines and Kinematics and related Calculation)
3 1
SECOND TERM
Total Teaching Weeks: 6
Drilling Machines
10 Constructional features and Feed Mechanism of – Bench Drilling Machine, Radial Drilling Machine,
Multi-Spindle Drilling Machines
2
11 Work holding devices & Tool holding devices 1
12 Drilling Operations (Drilling, Reaming, Counter boring & Counter sinking etc.) 2
13 Machine Time calculation for drilling 1 2
Milling Machines
14 Types of Milling Machines: Horizontal, Vertical & Universal and their Principal Parts 1
15 Types of Milling Cutters and their applications 2
16 Milling Operations 1
17 Work holding devices (vice, clamps, chucks, dividing head & uses) 1
18 Indexing (simple, compound & differential) 2
19 Indexing calculations & Machining Time calculations 1 4
20 Classification of Machining Centers based on machining axes 1
Grinding Machines
21 Construction, Features & Mechanisms, Specifications of Cylindrical, Surface and Center less
Grinding machines
3
THIRD TERM
22 Grinding Operations (Honing, Lapping & Super Finishing processes) 3 3
Gear Manufacturing Machines
23 Gear Forming, Gear Generation 3
24 Gear Shaping & Gear Hobbing 3
Text Books:
[T1] B.S. Raghuwanshi, “Workshop Technology”, Vol.2, Dhanpat Rai & Sons, 2003.
[T2] S.F. Krar Stevan F. and Check A.F., “Technology of M/C Tools”, McGraw Hill Book Co., 1986
[T3] O.P.Khanna., “Production Technology”, Vol.2, Dhanpat Rai Publications, 2013.
S.No Topics to be covered
UNIT 1: Probability Theory Lectures Totorials
1 conditional probability, Baye’s theorem,
2 Random variable: discrete probability distribution,
continuous probability distribution, expectation,
Moments, moment generating function
3 Skewness, kurtosis
4 binomial distribution, Poisson distribution, normal distribution
5 Curve Fitting: Principle of least square Method of least square
6 curve fitting for linear and parabolic curve
7 Correlation Coefficient, Rank correlation
8 line of regressions and properties of regression coefficients ,ANOVA
9Sampling distribution: Testing of hypothesis, level of significance, sampling distribution of
mean and variance
10 Chi-square distribution, Student’s T- distribution,
11 F- distribution, Fisher’s Z- distribution
12Solution of algebraic and transcendental equations using bisection method, Regula-Falsi
method and Newton Raphson Method
13Solution of linear simultaneous equations using Gauss-Jacobi’s Iteration method and Gauss
Seidal Iteration Method
14 Finite differences: Forward differences, backward differeces and Central Differences
15Interpolation: Newton’s interpolation for equi-spaced values. Stirling’s central difference
interpolation formula
16Divided differences and interpolation formula in terms of divided differences, Lagrange’s
interpolation formula for unequi-spaced values
17 maxima and minima of a tabulated function
18Newton-Cote’s quadrature formula, Trapezoidal rule, Simpson’s one-third rule and Simpson’s
three-eighth rule
19Numerical solution of ordinary differential equations: Picard’s method, Taylor’s
method,Euler’s method, modified Euler’smethod, Runge-Kutta method of fourth order.
Text Books:
[T1] R.K. Jain and S.R.K. Iyengar,” Numerical methods for Scientific and Engineering Computation”, New
Age.
[T2] N.M. Kapoor, “Fundamentals of Mathematical Statistics”, Pitambar Publications
Reference Books:
[R1] E. kresyzig,” Advance Engineering Mathematics”, Wiley publications
[R4] Michael Greenberg, “Advance Engineering mathematics”, Pearson.
[R6] B.S. Grewal., “Numerical Methods in Engg. And Science”, Khanna Publications
Total No. of
ACADEMIC PLAN FOR IV SEMESTER(Batch 2013 onwards) Numerical Analysis & Statistical Techniques Paper Code: ETMA-202
L T C
3 1 4
Total Lecture Classes available : 45 Total Tutorial Classes available : 15
UNIT IV :Numerical Differentiation and Integration
L-9 T-3
TERM-1
L-7 T-2
UNIT III :Numerical Methods
L-11 T-4
TERM-III
L-12 T-4
UNIT II: Correlation & Regression
L-6 T-2
TERM-2
ME
ACADEMIC PLAN FOR IV SEMESTER ME (2014-15)
SUB: Kinematics of Machines Sub. Code: ETME-202
Total Teaching weeks in Semester: 14 weeks L T C
3 1 4
Total Lecture Classes available : 42 Total Tutorial Classes available : 14
S.No TOPICS TO BE COVERED Total no. of
Teaching 6 Weeks TERM-I Lectures Tutorial
General concepts, Velocity and Acceleration Analysis 1
3
1 Introduction of Simple mechanism, Different types of Kinematics pair, Grublers rule for
degree of freedom, Grashof’s Criterion for mobility
2 Inversions of four bar chain, slider crank chain and double slider crank chain 1
3 Velocity of point in mechanism, relative velocity method, Velocities in four bar mechanism, slider crank mechanism and quick return motion mechanism
2
4 Instantaneous center method, Types & location of instantaneous centers, Kennedy’s
theorem, Velocities in four bar mechanism & slider crank mechanism 1
5 Acceleration of a point on a link, Acceleration diagram 2
6 Coriolis component of acceleration, Crank and slotted lever mechanism, Klein’s
construction for Slider Crank mechanism and Four Bar mechanism 2
7 Analytical method for slider crank mechanism 1
Cams:
8 Classification, Cams with uniform acceleration and retardation 2
2 9 SHM, Cylcloidal motion 2
10 oscillating followers 1
Mechanism with lower pairs:
11 Description of Straight line mechanisms like Peaucellier’s mechanism and Hart
mechanism 2
1 12 Engine indicator mechanism, 1
Teaching 6 Weeks TERM-II
Mechanism with lower pairs:
13 Steering mechanism of vehicles ,Hook’s joints 2
Friction:
1
2
2
2
2
1
2
2
14 Concepts of frictions and wear related to bearing and clutches
15 Belt and pulley drive, Length of open and cross belt drive
16 Ratio of driving tensions for flat belt drive, centrifugal tension
17 Condition for maximum power transmission, V belt drive
Brakes & Dynamometers
18 Shoe brake, Band brake, Band and Block brake
19 Absorption and transmission type dynamometers
Gears:
20 Geometry of tooth profiles, Law of gearing, involute profile 1 2
1
2 21 Path of contact. Arc of contact, Contact ratio
22 Interference in involute gears. Methods of avoiding interference, Back lash
23 Comparison of involute and cycloidal teeth., Profile Modification., helical, spiral and
worm gears 2
Teaching 2 Weeks TERM-III
24 Simple gear train, Compound gear train, Reverted gear train, 2
2 25 Trains – Analysis by tabular and relative velocity method, fixing torque 2
26 Sun and planet gear 2
Text Books
[T1] Theory and Machines: S.S. Rattan, Tata McGraw Hill.
[T2] Theory of Machines and Mechanisms: Joseph Edward Shigley and John Joseph Uicker, Jr. Second Edition,
MGH, New York
Reference Books
[R1] Thomas Beven, “The Theory of Machines”, CBS Publishers,
[R2] V.P. Singh, “Theory of Machines”, Dhanpat Rai & Co.(P)Ltd
[R3] Malhotra & Gupta, “The Theory of Machine”, Satya Prakashan,.
[R4] Ghosh A & Malik A K “ Theory of Mechanisms and Machines” Affiliated East West Press
ACADEMIC PLAN FOR IV SEMESTER ME (2014-15)
SUB: STRENGTH OF MATERIAL -II Sub. Code: ETME-204
Total Teaching weeks in Semester: 14 weeks L T C 3 1 4 Total Lecture Classes available : 39 Total Tutorial Classes available : 14
S.No TOPICS TO BE COVERED TOTAL NO. OF
Teaching 6 Weeks TERM-I Lectures Tutorial
3 D Stresses
1 Three dimensional stress and strain, Stress tensor, 2 2
2 Strain Tensor, Equilibrium Equations, St. Vernants principle, 2
3 Stress invariants, generalized hooks law, 2
4 Theories of elastic failure. 2
Strain Energy
5 Strain Energy Due to Axial Force, Shear Stress, Bending
1 2
6 Maxwell’s reciprocal theorem, Castigliano’s theorem for statistically determinate structures
2
Shear Stresses in Beams
7 Shear stress at a section,shear stress distribution for different sections: square, rectangular, Triangular,
2 1
8 Circular section, I-section, T-section. 2
Teaching 6 Weeks TERM-II
Thick Cylinders 9 Stresses in thick cylinders, Sphere subjected to internal pressure, Lame’s equations, ,
2 2
10 Compound cylinders, spherical vessels 1
11 Hub shrunk on solid shafts. 1 Columns
12 Combined direct and bending stresses in columns 1 2 13 Euler’s and Rankine Gordon equations 2
14 Applications of Johnson's empirical formula for axially loaded columns 2
Curved Beams
15 Bending of beams with large initial curvature. 1 2 16 Position of neutral axis for rectangular, trapezoidal and circular cross sections 2
17 Stress in crane hooks 2
Rotating Disc and Cylinders
18 Rotational stresses in discs and rims of uniform thickness 2 1 19 Discs of uniform Strength, long cylinder 2
Teaching 2 Weeks TERM-III Unsymmetrical Bending and Shear Centre:
22 Properties of beam cross-section, Principal Axes 2 2 23 Determination of Principal Axes, stress and deflection in unsymmetrical bending 3
24 Shear centre 1 Text Books:
Sadhu Singh, “Strength of Materials”, Khanna Publishers, New Delhi, 2000
Hibbler R.C., “Mechanics of Materials”, Prentice Hall, New Delhi, 1994.
R.K. Bansal, Strength of Materials”, Laxmi Publication, New Delhi, 2001
Ryder G.H., “Strength of Materials”, Macmillan, Delhi, 2003
ACADEMIC PLAN FOR 4TH
SEMESTER 2015
SUBJECT: FLUID MECHANICS SUBJECT CODE: ETME-212
CREDITS: 4
TOPICS TO BE COVERED TOTAL NO. OF
LECTURE TUTORIAL
1ST
TERM
Unit 1
1. Introduction of subject, Fundamental definitions, Fluid properties
2. Classification of fluids, Flow characteristics, Foundations of flow analysis
3. Incompressible and compressible fluids, one, two and three dimensional flows
4. Pascal’s law, pressure variation in a fluid at rest
5. Classification of different manometers
6. Fluid pressure, Forces on solid surfaces
7. Buoyant forces, Metacentre and Metacentric height. Stability of floating bodies
Unit 2
1. Types of fluid flow, streamline, path line and streak line
2. Continuity equation, Equations for acceleration, Irrotational and rotational flow
3. Velocity potential and stream function
4. Vortex flow
1
1
1
1
2
2
3
1
2
1
1
1
1
1
2ND
TERM
Unit 2
1. Control volume analysis, Eulers equation of motion
2. Bernoulli’s equation, Bernoulli’s theorems from steady flow energy equation
3. Venturi meter; Pitot tube, Momentum equation
4. Reynold’s experiment, Critical velocity, Steady laminar flow through a circular tube
5. Measurement of viscosity
Unit 3
1. Shear stress in turbulent flow. Hydro dynamically smooth & rough boundaries
2. Velocity distribution for turbulent flow in smooth and rough pipes
3. Boundary Layer Theory and Applications
4. Boundary Layer thickness, displacement, momentum and energy thickness
5. Flow separation, Drag and lift on immersed bodies
6. Darcy-Weisbach equation, Moody diagram
7. Energy losses in pipelines, concept of equivalent length
8. Flow between two reservoirs multiple pipe systems. Siphon
1
1
2
1
1
1
2
1
1
2
1
1
2
1
1
1
1
3RD
TERM
Unit 4
1. Buckingham’s Theorem and its applications, Geometric, Kinematics and Dynamic
similarity
2. Dimensionless numbers-Reynolds, Froude, Euler, Mach, Weber Number and their
significance
3. Measurement of flow using, orifice meter, nozzle
4. Measurement of flow in open channels – rectangular, triangular
5. Trapezoidal weir, Cipoeletti weir. Hot-wire anemometer
3
2
2
2
2
1
1
Text Books:
1. R.K. Bansal, “Fluid Mechanics & Hydraulic Machines”, Laxmi Publications (P) Ltd.,2002.
2. D.S. Kumar, “Fluid Mechanics and Fluid Power Engineering”, S.K. Kataria & Sons, 2000.
Reference Books:
1. I.H. Shames, “Mechanics of Fluids”, Tata McGraw Hill
2. V.L. Streeter and E.B. Wylie, “Fluid Mechanics”, Tata McGraw Hill
3. Modi, P.N., and Seth, S.H., “Hydrualics and Fluid Machines”, Standard Book House,
4. Vijay Gupta and S.K.Gupta, “Fluid Mechanics and its Applications”, Wiley Eastern Ltd,
5. Som, S.K. & Biswas G. : Introduction of fluid mechanics & Fluid Machines, TMH, 2000,
ACADEMIC PLAN FOR IV SEMESTER ME (2014-15)
IC Engines and Gas Turbines ETME 210
Total Teaching weeks in Semester: 14 weeks L T C Total lecture classes available : 40 3 1 4 Total tutorial classes available : 14
S.No TOPICS TO BE COVERED TOTAL NO. OF
Teaching 6 Weeks TERM-I Lectures Tutorial
Introduction
1 Basic Engine components and Nomenclature, Classification of Engines 2 2
2 The working principle of Engines, Comparison of 2-Stroke and 4-Stroke Engines; CI,
and SI Engines
2
3 Ideal and Actual Working Cycles and their analysis, Valve timing Diagram 2
Fuels
4 Fossil fuels, Chemical structure of Petroleum 1 1
5 Properties of SI and CI Engine Fuels, Fuel Ratings; Octane Number, Cetane Number. 2 Carburetors and Fuel Injection 6 Air Fuel Mixture Requirements, Construction and Working of Simple Carburetor 1 2
7 Calculation of Air-Fuel Ratio, Parts of Carburetor. 1
8 Requirement of Injection Systems, Classification of Injection Systems, Fuel Feed
pump, Injection Pumps 2
9 Working principles of Governors, Nozzles and Fuel Injector, Injection in SI and CI
Engines 2
Combustion and Ignition Systems in SI and CI Engines
10 Normal and Abnormal Combustion in SI and CI Engines, 1 1
11 Stages of Combustion, Detonation and Knocking 2 Teaching 6 Weeks TERM-II
Performance Parameters for IC Engines
12 Engine Power, Engine Efficiencies 1 2 13 Performance Characteristics, Variables Effecting Performance Characteristics 3
14 Methods of Improving Engine Performance, Heat Balance 2
Modern Automotive Engines 15 Changes in Fuel injection Methods in S.I and C.I engines. 2
2 16 Common Rail Direct Injection System, Gasoline Direct Injection 2
17 Variable Valve Technology, A brief review of Design changes to achieve high
efficiency
2
Gas Turbines 18 Introduction to Gas Turbines, Development, Classification and Application of Gas
Turbines
2 2
19 Ideal and Actual Cycles; Effect of Intercooling, Reheating, Regeneration, Combined
cycle and Cogeneration
3
Teaching 2 Weeks TERM-III Gas Turbine Cycles for Aircraft Propulsion 20 Criteria of performance, Intake and propelling nozzle efficiencies 1 2 21 Simple Turbojet Cycle, The turboprop engine, Thrust augmentation 2
22 Gas turbine combustion systems, Combustion chamber designs, Gas Turbine Emissions 2 Text Books:
Ganesan V., “Internal Combustion Engines”, Tata Mcgraw-Hill
HIH Saravanamutto, H. Cohen, GFC Rogers “Gas Turbine Theory”, Pearson.
John B Heywood, “Internal Combustion Engine Fundamentals”, Tata McGraw-Hill.
K..K. Ramalingam, “ Internal Combustion Engines” 2nd ed, SCITECH Publications.
E.T. Vincent “Theory & Design of Gas Turbine and Jet Engine” Tata McGraw Hill.
Gas Turbine Principles and Practice, Cox Newnes.
ACADEMIC PLAN FOR IV SEMESTER ME
Sub: Manufacturing Machines Subject Code: ETME 206
Total Teaching weeks in Semester: 14 weeks L T C
3 1 4
Total Lecture Classes available : 42 Total Tutorial Classes available : 14
S.No TOPICS TO BE COVERED TOTAL NO. OF
Total Teaching Weeks: 6 Lecture Tutorial
FIRST TERM
Introduction of Machines Tool
1 Classification of Machine Tools (Based on application, purpose, process & production rate) 2
2 Elements of Tool Geometry (Tool signature as per ASA).Cutting tool Materials & Applications 1
3 Various types of lathe (Centre Lathe, Facing Lathe, Gap-bed Lathe, Capstan Lathe, Turret Lathe, NC,
CNC and DNC lathe), major difference between CNC and Conventional Lathe
2
4 Major sub-assemblies of lathe (Bed, Head stock, Tail stock, Carriage consisting Saddle, Cross-slide,
Compound slide, Tool post and Apron
2
5 Work holding devices (Self centering three jaw chuck, Independent four jaw chuck,, Collets, Face
plates, Dog carriers, Centers, Mandrels and Rest (steady and moving)).
2
6 Driving mechanism (Apron mechanism, Thread Cutting mechanism & Machining Time calculation
(Num. problems)
2 2
Numerical Problems on
7 Features of half-nut engagement-disengagement, indexing dial mechanism (indexing-logical problem) 2 1
8 Operations on Lathe (Thread Cutting, Facing, Under Cutting, Drilling, Reaming, Boring, Parting-Off,
Knurling, Chamfering, Taper Turning & calculation)
2 2
9 Reciprocating Type Machine Tools (Shaper, Planer and Slotter: Constructional Features, Basics
machines and Kinematics and related Calculation)
3 1
SECOND TERM
Total Teaching Weeks: 6
Drilling Machines
10 Constructional features and Feed Mechanism of – Bench Drilling Machine, Radial Drilling Machine,
Multi-Spindle Drilling Machines
2
11 Work holding devices & Tool holding devices 1
12 Drilling Operations (Drilling, Reaming, Counter boring & Counter sinking etc.) 2
13 Machine Time calculation for drilling 1 2
Milling Machines
14 Types of Milling Machines: Horizontal, Vertical & Universal and their Principal Parts 1
15 Types of Milling Cutters and their applications 2
16 Milling Operations 1
17 Work holding devices (vice, clamps, chucks, dividing head & uses) 1
18 Indexing (simple, compound & differential) 2
19 Indexing calculations & Machining Time calculations 1 4
20 Classification of Machining Centers based on machining axes 1
Grinding Machines
21 Construction, Features & Mechanisms, Specifications of Cylindrical, Surface and Center less
Grinding machines
3
THIRD TERM
22 Grinding Operations (Honing, Lapping & Super Finishing processes) 2 2
Gear Manufacturing Machines
23 Gear Forming, Gear Generation 2
24 Gear Shaping & Gear Hobbing 2
Text Books:
[T1] B.S. Raghuwanshi, “Workshop Technology”, Vol.2, Dhanpat Rai & Sons, 2003.
[T2] S.F. Krar Stevan F. and Check A.F., “Technology of M/C Tools”, McGraw Hill Book Co., 1986
[T3] O.P.Khanna., “Production Technology”, Vol.2, Dhanpat Rai Publications, 2013.
LECTURE PLAN SIGNALS AND SYSTEMS
Paper Code: ETMT-206 L T C Paper: Signals and Systems 3 1 4
Objective: This is the first course for representation of various types of electronic signals and LTI systems. Applications of Fourier series, understanding of Fourier transforms and sampling of various signals. Analysis of various systems using the Z transforms, Laplace transforms.
S. No. Topic No. of
Hours
FIRST TERM 1 UNIT- I 2
Continuous And Discrete Time Signals: Definition of signal, Classification of Signals:
Periodic and Aperiodic, Even and Odd, Energy and Power signals, Deterministic and
Random signals.
2 Singular Functions: Unit impulse, unit step, unit ramp, complex and exponential, parabolic, 2 Signum, Sinc etc. Properties of unit impulse in continuous and discrete domain, properties
of basic functions w.r.t. orthogonality.
3 Transformation in independent variable of signals: Time scaling, Time shifting, 1 Amplitude scaling. Representation of signals in terms of singular function and orthogonal
functions.
4 Systems: Definition of system, types of systems: Linear and nonlinear, static and dynamic, 3 causal and non-causal, time variant and invariant, invertible and non-invertible, stable and
non-stable. System described by differential equation and difference equation.
5 LTI System: Properties of LTI System, impulse response, convolution and its properties in 4 continuous and discrete domain with proof. Linear convolution in continuous and discrete
domain using graphical method, using general formula and matrix method.
6 UNIT- II 1 Fourier series: Need and application of Fourier series.
7 Fourier series representation of continuous time and discrete time signals using exponential 4 method and trigonometric method. Magnitude and Phase spectrum of signals.
SECOND TERM
8
Fourier Transform: Introduction, Properties of the Continuous time and discrete time 3 Fourier Transform.
9 Magnitude and Phase representations of frequency response of LTI systems Analysis and 3 characterization of LTI systems using Differential Equations and Difference equation.
10 UNIT- III 4 Magnitude- Phase Representation of Frequency Response of LTI System: Linear phase,
concept of phase delay and group delay. All pass system.
11 Laplace Transform: Properties of Laplace transform, concept of ROC and its properties. 4 Computation of impulse response & transfer function using Laplace transform.
12 Inverse-Laplace transforms. Computation of impulse response, total response (zero state and 3 zero input response) & transfer function using Laplace transform.
THIRD TERM
13 UNIT- IV 2 Sampling: Sampling of low pass signals, ideal sampling, Aliasing effect, Nyquist rate,
reconstruction of signal. Sampling of discrete time signals.
14
Z Transform: Region of convergence – properties of ROC, Properties of Z-transform. 3
15 Inverse Z-transform using contour integration - Residue theorem, Power series expansion 2 and partial fraction expansion.
16 Relationship between Z-transform, Fourier transform and Laplace transform. Computation 3 of impulse response, total response (Zero state and Zero input response) & Transfer function
using Z-Transform. Stability of discrete-time LTI System
Text Books:
[T1] AlanV.Oppenheim, Alan S.Willsky, S.Hamid Nawab, “Signals & Systems”, 2nd edition, Pearson Education, 1997.
[T2] Simon Haykin and Barry Van Veen, “Signals and Systems”, John Wiley, 1999.
Reference Books: [R1] M.J.Roberts, “Signals and Systems Analysis using Transform Method and MATLAB”, TMH 2003. [R2] Tarun kumar rawat “signals and systems “, Oxford University Press, Incorporated, 2010
[R3] A. Anand kumar, “signals and systems” 3rd
edition , PHI [R4] Ramesh Babu and R.Anandanatrajan ,”Signals and system”, 4
th edition Sci Tech ,2013 [R5]
Moman .H. Hays, “Digital Signal Processing”, Schaum’s outlines, Tata McGraw-Hill2004. [R6] John G.Proakis and Dimitris G.Manolakis, “Digital Signal Processing, Principles, Algorithms and
Applications”, 3rd
edition. PHI, 2000. Scheme and Syllabi for B. Tech-ECE, 1
st year (Common to all branches) w.e.f batch 2014-15 and (2
nd, 3
rd & 4
th years) w.e.f batch 2013-14
approved in the 22nd
BOS of USET on 30th
June, 2014 and approved in the 37th
AC Sub Committee Meeting held on 10th
July, 2014.
Lesson Plan for HYDRAULICS AND PNEUMATICS
For B Tech(Mechatronics) at DITE Campus II
Paper Code: ETMT-212 L T/P C
Paper: Hydraulics and Pneumatics 3 1 4
Objective: The objective of the paper is to facilitate the students with the working and applications of a
large class of pneumatic and hydraulic instruments used in various plants and industries.
UNIT I Hydraulic system No. of Hrs. 12
Day1 Introduction to fluid power system, Advantage and
Disadvantage of Fluid power, Hydraulic fluids- functions,
fluid characteristics
2hrs
Day2 Construction, operation, characteristics and graphical symbols
of hydraulic components
2hrs
Day3 Sources of hydraulic power, pump classification. Fluid power
actuator, Fluid motors.
2hrs
Day4 Pneumatic Systems
Introduction, comparison of pneumatic/ hydraulic and electrical
systems,
2hrs
Day5 characteristics & symbols of pneumatic components 2hrs
Day6 Air Compression system, Air preparation – principles and
components
2hrs
..
UNIT II Hydraulic Components & Hydraulic Circuits No. of Hrs. 11
Day7 Introduction, function of control elements 2hrs
Day8 , direction control valve, check valve, pressure control valve, 2hrs
Day9 pressure reducing valve, flow control valves 2hrs
Day10 , sequence valve, electrical control solenoid valves 2hrs
Day11 Accumulators – types of accumulators, applications and
accumulator circuits
1hrs
Day 12 , intensifier – application and circuits. 2hrs
, UNIT III Pneumatic Components & Pneumatic Circuits No. of Hrs. 11
Day 13 Pneumatic Components- Filter, regulators, lubricators 2hrs
Day14
pneumatic actuators, quick exhaust valve, pressure
sequence valve
2hrs
Day15 time delay valve, solenoid valve, electrical limit switch 2hrs
Day16 proximity switch, speed control circuits 2hrs
Day17 cascade method- sequential circuit design 1hrs
Day18 synchronizing circuits, time delay circuits 2hrs
UNIT IV Application, failure and trouble shooting No. of Hrs. 10
Day20 Development of hydraulic / pneumatic circuits applied to
machine tools
2hrs
Day21 presses, material handling systems, automotive systems,
packaging industries, manufacturing automation,
2hrs
Day22 Maintenance of fluid power systems – preventive and
breakdown. Maintenance procedures
2hrs
Day23 Trouble shooting of fluid power systems – fault finding process 2hrs
Day24 equipments/ tools used, causes and remedies. Safety aspects
involved.
2hrs
Class Schedule: 4hrs/week, total duration: 3months approx
ACADEMIC LESSON PLAN FOR ORGANIZATIONAL BEHAVIOUR/ ETMT-202/ 4TH. SEM.
MECHATRONICS(B. TECH.)
DELHI INSTITUTE OF TOOL ENGINEERING, OKHLA
TOPICS TO BE COVERED TOTAL NO. OF
LECTURE TUTORIAL
1 ST. TERM
UNIT-I 1. Introduction: Concept and nature of Organizational Behaviour 1 2. Contributing disciplines to the field of O. B. 1 3. O. B. Models 1 4. Need to understand human behaviour 2 5. Challenges and Opportunities 1 6. Management functions 2 7. Tasks and responsibilities of a professional manager 1 8. Managerial skills 1
UNIT-II 9. Individual and Interpersonal Behaviour 2 10. Biographical Characteristics 1 11. Ability, Values 1 12. Attitudes- Formation, Theories 1 13. Organization related attitudes 1 14. Relation between attitude and behaviour 1 15. Personality- determinants and traits 1 16. Emotions; Learning-Theories and reinforcement schedules 2 17. Perception- process and errors 2
1 ST. TERMINAL TEST
2 ND. TERM
UNIT-III 18. Organization structure and process: Organizational climate 1 19. Organizational culture 1 20. Organizational structure and Design 1 21. Managerial Communication 1 22. Motivation, stress and its management 2 23. Decision Making 1 24. Organizational context of Decisions 1 25. Decision Making Models; Problem solving 2
UNIT-IV 26. Interactive aspects of Organizational Behaviour: Interpersonal Behaviour: Johari window
3
2 ND. TERMINAL TEST
3 RD. TERM
UNIT-IV 27. Transactional Analysis- ego states, types of transactions 2 28. Life positions, Applications of T. A. 2 29. Group Dynamics 2 30. Management of Organizational conflicts, Leadership styles 3
ACADEMIC LESSON PLAN FOR ORGANIZATIONAL BEHAVIOUR/ ETMT-202/ 4TH. SEM.
MECHATRONICS(B. TECH.)
DELHI INSTITUTE OF TOOL ENGINEERING, OKHLA
TOPICS TO BE COVERED TOTAL NO. OF
LECTURE TUTORIAL
1 ST. TERM
UNIT-I 1. Introduction: Concept and nature of Organizational Behaviour 1 2. Contributing disciplines to the field of O. B. 1 3. O. B. Models 1 4. Need to understand human behaviour 2 5. Challenges and Opportunities 1 6. Management functions 2 7. Tasks and responsibilities of a professional manager 1 8. Managerial skills 1
UNIT-II 9. Individual and Interpersonal Behaviour 2 10. Biographical Characteristics 1 11. Ability, Values 1 12. Attitudes- Formation, Theories 1 13. Organization related attitudes 1 14. Relation between attitude and behaviour 1 15. Personality- determinants and traits 1 16. Emotions; Learning-Theories and reinforcement schedules 2 17. Perception- process and errors 2
1 ST. TERMINAL TEST
2 ND. TERM
UNIT-III 18. Organization structure and process: Organizational climate 1 19. Organizational culture 1 20. Organizational structure and Design 1 21. Managerial Communication 1 22. Motivation, stress and its management 2 23. Decision Making 1 24. Organizational context of Decisions 1 25. Decision Making Models; Problem solving 2
UNIT-IV 26. Interactive aspects of Organizational Behaviour: Interpersonal Behaviour: Johari window
3
2 ND. TERMINAL TEST
3 RD. TERM
UNIT-IV 27. Transactional Analysis- ego states, types of transactions 2 28. Life positions, Applications of T. A. 2 29. Group Dynamics 2 30. Management of Organizational conflicts, Leadership styles 3
LECTURE PLAN SIGNALS AND SYSTEMS
Paper Code: ETMT-206 L T C Paper: Signals and Systems 3 1 4
Objective: This is the first course for representation of various types of electronic signals and LTI systems. Applications of Fourier series, understanding of Fourier transforms and sampling of various signals. Analysis of various systems using the Z transforms, Laplace transforms.
S. No. Topic No. of
Hours
FIRST TERM 1 UNIT- I 2
Continuous And Discrete Time Signals: Definition of signal, Classification of Signals:
Periodic and Aperiodic, Even and Odd, Energy and Power signals, Deterministic and
Random signals.
2 Singular Functions: Unit impulse, unit step, unit ramp, complex and exponential, parabolic, 2 Signum, Sinc etc. Properties of unit impulse in continuous and discrete domain, properties
of basic functions w.r.t. orthogonality.
3 Transformation in independent variable of signals: Time scaling, Time shifting, 1 Amplitude scaling. Representation of signals in terms of singular function and orthogonal
functions.
4 Systems: Definition of system, types of systems: Linear and nonlinear, static and dynamic, 3 causal and non-causal, time variant and invariant, invertible and non-invertible, stable and
non-stable. System described by differential equation and difference equation.
5 LTI System: Properties of LTI System, impulse response, convolution and its properties in 4 continuous and discrete domain with proof. Linear convolution in continuous and discrete
domain using graphical method, using general formula and matrix method.
6 UNIT- II 1 Fourier series: Need and application of Fourier series.
7 Fourier series representation of continuous time and discrete time signals using exponential 4 method and trigonometric method. Magnitude and Phase spectrum of signals.
SECOND TERM
8
Fourier Transform: Introduction, Properties of the Continuous time and discrete time 3 Fourier Transform.
9 Magnitude and Phase representations of frequency response of LTI systems Analysis and 3 characterization of LTI systems using Differential Equations and Difference equation.
10 UNIT- III 4 Magnitude- Phase Representation of Frequency Response of LTI System: Linear phase,
concept of phase delay and group delay. All pass system.
11 Laplace Transform: Properties of Laplace transform, concept of ROC and its properties. 4 Computation of impulse response & transfer function using Laplace transform.
12 Inverse-Laplace transforms. Computation of impulse response, total response (zero state and 3 zero input response) & transfer function using Laplace transform.
THIRD TERM
13 UNIT- IV 2 Sampling: Sampling of low pass signals, ideal sampling, Aliasing effect, Nyquist rate,
reconstruction of signal. Sampling of discrete time signals.
14
Z Transform: Region of convergence – properties of ROC, Properties of Z-transform. 3
15 Inverse Z-transform using contour integration - Residue theorem, Power series expansion 2 and partial fraction expansion.
16 Relationship between Z-transform, Fourier transform and Laplace transform. Computation 3 of impulse response, total response (Zero state and Zero input response) & Transfer function
using Z-Transform. Stability of discrete-time LTI System
Text Books:
[T1] AlanV.Oppenheim, Alan S.Willsky, S.Hamid Nawab, “Signals & Systems”, 2nd edition, Pearson Education, 1997.
[T2] Simon Haykin and Barry Van Veen, “Signals and Systems”, John Wiley, 1999.
Reference Books: [R1] M.J.Roberts, “Signals and Systems Analysis using Transform Method and MATLAB”, TMH 2003. [R2] Tarun kumar rawat “signals and systems “, Oxford University Press, Incorporated, 2010
[R3] A. Anand kumar, “signals and systems” 3rd
edition , PHI [R4] Ramesh Babu and R.Anandanatrajan ,”Signals and system”, 4
th edition Sci Tech ,2013 [R5]
Moman .H. Hays, “Digital Signal Processing”, Schaum’s outlines, Tata McGraw-Hill2004. [R6] John G.Proakis and Dimitris G.Manolakis, “Digital Signal Processing, Principles, Algorithms and
Applications”, 3rd
edition. PHI, 2000. Scheme and Syllabi for B. Tech-ECE, 1
st year (Common to all branches) w.e.f batch 2014-15 and (2
nd, 3
rd & 4
th years) w.e.f batch 2013-14
approved in the 22nd
BOS of USET on 30th
June, 2014 and approved in the 37th
AC Sub Committee Meeting held on 10th
July, 2014.
Lesson Plan for HYDRAULICS AND PNEUMATICS
For B Tech(Mechatronics) at DITE Campus II
Paper Code: ETMT-212 L T/P C
Paper: Hydraulics and Pneumatics 3 1 4
Objective: The objective of the paper is to facilitate the students with the working and applications of a
large class of pneumatic and hydraulic instruments used in various plants and industries.
UNIT I Hydraulic system No. of Hrs. 12
Day1 Introduction to fluid power system, Advantage and
Disadvantage of Fluid power, Hydraulic fluids- functions,
fluid characteristics
2hrs
Day2 Construction, operation, characteristics and graphical symbols
of hydraulic components
2hrs
Day3 Sources of hydraulic power, pump classification. Fluid power
actuator, Fluid motors.
2hrs
Day4 Pneumatic Systems
Introduction, comparison of pneumatic/ hydraulic and electrical
systems,
2hrs
Day5 characteristics & symbols of pneumatic components 2hrs
Day6 Air Compression system, Air preparation – principles and
components
2hrs
..
UNIT II Hydraulic Components & Hydraulic Circuits No. of Hrs. 11
Day7 Introduction, function of control elements 2hrs
Day8 , direction control valve, check valve, pressure control valve, 2hrs
Day9 pressure reducing valve, flow control valves 2hrs
Day10 , sequence valve, electrical control solenoid valves 2hrs
Day11 Accumulators – types of accumulators, applications and
accumulator circuits
1hrs
Day 12 , intensifier – application and circuits. 2hrs
, UNIT III Pneumatic Components & Pneumatic Circuits No. of Hrs. 11
Day 13 Pneumatic Components- Filter, regulators, lubricators 2hrs
Day14
pneumatic actuators, quick exhaust valve, pressure
sequence valve
2hrs
Day15 time delay valve, solenoid valve, electrical limit switch 2hrs
Day16 proximity switch, speed control circuits 2hrs
Day17 cascade method- sequential circuit design 1hrs
Day18 synchronizing circuits, time delay circuits 2hrs
UNIT IV Application, failure and trouble shooting No. of Hrs. 10
Day20 Development of hydraulic / pneumatic circuits applied to
machine tools
2hrs
Day21 presses, material handling systems, automotive systems,
packaging industries, manufacturing automation,
2hrs
Day22 Maintenance of fluid power systems – preventive and
breakdown. Maintenance procedures
2hrs
Day23 Trouble shooting of fluid power systems – fault finding process 2hrs
Day24 equipments/ tools used, causes and remedies. Safety aspects
involved.
2hrs
Class Schedule: 4hrs/week, total duration: 3months approx