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CENTURION UNIVERSITY OF TECHNOLOGY & MANAGEMENT
DOMAIN BASED RE-ORIENTATION OF COURSES
DEPARTMENT OF CIVIL ENGINEERING
7th
& 8th
Semesters
Subject Code Course Title Course Nature Credits
PCCE 4101 Estimating, Costing & Quantity Surveying Theory + Practice 4
PCCE 4103 Steel Structures Design, Drawing & Detailing Theory + Practice 7
PCCE 4201 Construction Planning & Project Management Theory 3
DMHS0001 Life Skills Development Practice 2
Credits thro’ Core & Common Courses 16
Domain List
(A student has to select any one domain for a minimum of 32 Credits)
Domain I: Construction Planning and Management Domain II: Surveying
Domain III: Planning, Design & Drawing
32
TOTAL(16+ 32) = 48 TOTAL 48
MECHANICAL ENGINEERING
7th
& 8th
Semesters
Subject Code Course title Course Nature Credits
PCME 4101 Heat Transfer Theory 4
PCME 4102 Optimization Techniques Theory 4
PCME 4201 Product design and product tooling Theory 4
PLME 4111 Heat Transfer & Refrigeration and Air-conditioning Lab Practice 2
DMHS 0001 Life Skills Development Practice 2
Credits through Core & Common courses 16
Domain List
(A student has to select any one domain for a minimum of …36…. credits)
Domain 1: AUTOMOTIVE DESIGN
Domain 2: WELDING Domain 3: MANUFACTURING
36
TOTAL (16+36) =52 TOTAL 52
COMPUTER SCIENCE & ENGINEERING
7th
& 8th
Semesters
Subject Code Course Title Course Nature Credits
PCCS4102 Database Design & Implementation Theory + Practice + Project 8
PCCS4103 Project in Java / .net Project 4
DMHS0001 Life Skills Development Practice 2
Credits thro’ Core & Common Courses 14
Domain List
(A student has to select any one domain for a minimum of 30 Credits) 1. Web Technology
2. Data Analytics
3. Internet Security
30
TOTAL (14 + 30) = 44 TOTAL 44
ELECTRONICS & COMMUNICATIONS ENGINEERING
Subject Code Course Title Course Nature Credits
PCEC4101 Microwave and Radar Engineering Theory 4
PCEC4201 Satellite and Optical Communication Theory 4
PLEC4111 Microwave and Antenna Lab Practice 2
DMHS0001 Life Skills Development Practice 2
Credits thro’ Core & Common Courses 12
(A student has to select any one domain for a minimum of 32 Credits)
Domain I: Embedded System
Domain II: VLSI Design and Verification
32
TOTAL (12 + 32) = 44 TOTAL 44
ELECTRICAL ENGINEERING
Subject Code Course Title Course Nature Credits
PCEL 4101 Power System Operation & Control Theory 4
PCEL 4201 Power System Protection Theory 4
PLEL4105 Power System Analysis Lab (Common with EEE) Practice 2
DMHS0001 Life Skills Development Practice 2
Credits thro’ Core & Common Courses 12
Domain List
(A student has to select any one domain for a minimum of 34 Credits)
Domain I: Embedded System
Domain II: Industrial Automation
34
TOTAL (12 + 34) = 46 TOTAL 46
ELECTRICAL & ELECTRONICS ENGINEERING
7th
& 8th
Semesters
Subject Code Course Title Course Nature Credits
PCEE4101 Electrical Drives Theory 4
PCEE4102 Power System Analysis Theory 4
PLEL4105 Power System Analysis Lab (Common with EE) Practice 2
PLEE4106 Electrical Drives Lab Practice 2 DMHS0001 Life Skills Development Practice 2
Credits thro’ Core & Common Courses 14 Domain List
(A student has to select any one domain for a minimum of 36 Credits)
Domain I: Embedded System Domain II: Industrial Automation
36
TOTAL (14 + 36) = 50 TOTAL 50
CIVIL ENGINEERING
PCCE 4101 ESTIMATING, COSTING& QUANTITY SURVEYING (CREDITS:4)
COURSE OBJECTIVES:
1. To provide knowledge about the different parts of buildings, bridges and culvert.
2. To make understand detailed estimate of roads.
3. To make familiar with calculation of quantities.
4. To provide knowledge about the current rates of different materials and labours used in different items of
construction works.
5. To make student familiar with drawing(plans, elevations, sections,etc)for finding out the dimensions.
COURSE OUTCOMES:
1. Gain knowledge about how to estimate different construction works.
2. Analyse and calculate dry material in different construction works.
Module I (20hr)
INTRODUCTION Estimation- Definition of Estimate-Purpose- Necessity of Estimates- Types of Estimates-
A derailed Estimate-A preliminary-Quantity-Revised-Supplementary-Revised-Complete Estimate-Annual
Maintenance Estimation,
How to prepare a detailed Estimate-Measurement form-Abstract of Estimate form. Data required for preparing
detailed estimates.
Estimation of materials in single storeyed flat roof building with shallow foundation and RCC roof slab, two
storied building with all items of work
BRIDGES AND CULVERTS-Definition-common terms-Process of calculation of earth work for Abutment,
Wing and Curtain walls. Estimation of materials in Slab Culverts
simple inclined roof building with gabled / hipped roof and A.C. sheet / G.C.I. sheet proofing
Module II (15hr)
Principles of general and detailed specification for various types building works.
Analysis of rates, description, Prime cost, Schedule rates, Analysis of rates for various types of works.
Module – III (10hr)
Works- Classification of work-original, major, petty, repair work, annual repair, special repair
Contract Management:
Legal aspects, contract laws related to land acquisition, labour safety and welfare. Different types of contracts,
their relative advantages and disadvantages. Elements of tender operation. Evaluation of tenders, Award of
work,
Measurement book use & maintenance, procedure of marking entries of measurement of work and supply of
materials, labour employed, standard measurement books and common irregularity
Exercises for Sessional Work:
Text Books:
1. Estimating and Costing in Civil Engineering Theory & Practice, B.N. Dutta, UBS Publishers
Reference Books:
1. Estimating, Costing, Specification & Valuation in Civil engineering, M. Chakraborti
2. Civil engineering contracts and estimates by B.S. Patil, University Press.
3. Latest Orissa PWD and CPWD Schedule of Rates & Analysis of rates.
Module I
S.
No.
Topic Pedagogy Details Instructional Hrs
Theory Practice video Project
1
Introduction to Estimation
Definition of Estimate
Types of Estimates
Ref: T.B.:1B.N.DUTTA,pp-448,449, 452,453,454
CRT
Presentat
ion Mode
2
2
Preparation of detailed Estimate
Details of Measurement form
Abstract of Estimate form
Data required for preparing detailed estimates.
Units of Different items of works
Ref:T.B.:1 B.N.DUTTA,pp-4,5,14
CRT 1
3
Estimation of materials in single storeyed flat roof building
Methods of building estimates
Long Wall and Short Wall Method
Centre Line Method
Ref:T.B.:1 B.N.DUTTA,pp-29
CRT 1
4
Problem solving by using Long Wall and Short Wall
Method(Single Room, Double Room)
Ref:T.B.:1 B.N.DUTTA,pp- 31, 35
CRT+PRA
CTICE
Using
Estimator
2 Software
1 2
5
Problem solving by using Long Wall and Short Wall
Method(Residential Building,Double Storied Building )
Ref:T.B.:1 B.N.DUTTA,pp- 38
CRT+PRA
CTICE 1 4
6
Estimate of an office building, one of the room having Semi-
Circular Front
Problem solving by using Centre Line Method
Ref:T.B.:1 B.N.DUTTA,pp-46, 135
CRT+PRA
CTICE 1 2
7
BRIDGES AND CULVERTS
Process of calculation of earth work for Abutment,
Wing and Curtain walls. Estimation of materials in
Slab Culverts
Ref:T.B.:1 B.N.DUTTA,pp-375
CRT+PRA
CTICE Practice
through
Problem
Solving
1 2
8
Simple inclined roof building with gabled / hipped roof and
A.C. sheet / G.C.I. sheet proofing
Ref:T.B.:1 B.N.DUTTA,pp-189
CRT+PRA
CTICE 1 1
Subtotal 9 11 0 0
Module II
S.
No.
Topic Pedagogy Details Instructional Hrs
Theory Practice video Project
9 Specification
Various types of specifications
Principles of general specification for various types
building works. Ref:T.B.:1 B.N.DUTTA,pp-563
CRT Presentation Mode
1
10 Principles of detailed specification for various types
building works
Ref:T.B.:1 B.N.DUTTA,pp-565
CRT Presentatio
n Mode 2
11 Analysis of rates
Description
Difference between General Overhead and Job
Overhead
Task Or Out-Turn Work
Prime Cost
Schedule of rates
Building Cost Index
Bill of Quantities Ref:T.B.:1 B.N.DUTTA,pp-472, 458,459,460
CRT Presentatio
n Mode
1
12 Analysis of rates for various types of works.
Ref:T.B.:1 B.N.DUTTA,pp-481
CRT 2
13 Problems for Analysis of rates
Ref:T.B.:1 B.N.DUTTA,pp-482, 485, 486, 487
Practice
Using
Estimator 2 Software
3
14 Problems for Analysis of rates (Brick Work)
Ref:T.B.:1 B.N.DUTTA,pp-492
CRT +
Practice
1 2
15 Problems for Analysis of rates (Plastering)
Ref:T.B.:1 B.N.DUTTA,pp-499 1 2
16 Problems for Analysis of rates (Cement Concrete Floor)
Ref:T.B.:1 B.N.DUTTA,pp-503 1 2
Sub Total 9 9 0 0
Module III
S.
No.
Topic Pedago
gy
Details Instructional Hrs
Theory Practice video Project
17 Works
Classification of work according to their nature
original work
repair work
Classification of work according to their nature
petty work
major work
minor work
Ref:T.B.:1 B.N.DUTTA,pp-686
CRT Presentation
Mode
1
18 Different types of repairs work
annual repair
special repair Ref:T.B.:1 B.N.DUTTA,pp-687
CRT Presentatio
n Mode 1
19 Contract Management:
Legal aspects
contract laws related to land acquisition
Ref:T.B.:1 B.N.DUTTA,pp-687
CRT Presentatio
n Mode 1
20 Different types of contracts their relative advantages and
disadvantages
Ref:T.B.:1M.CHAKRABORTI,pp-656
CRT Presentatio
n Mode 1
21 Different types of contracts their relative advantages and
disadvantages(Continued)
Ref:T.B.: 1M.CHAKRABORTI,pp-656
CRT Presentatio
n Mode 1
22 Tender and Bill
Power of accepting tender
Ref:T.B.:1 B.N.DUTTA,pp-687,688
CRT+P
RACTI
CE
Presentatio
n Mode+
Practice
using
estimator 2 Software
1 2
23 Tender notice
Ref:T.B.:1 B.N.DUTTA,pp-687,688
CRT 2
24 Measurement book
use & maintenance
procedure of marking entries of measurement of work
and supply of materials
Ref:T.B.:1 B.N.DUTTA,pp-698
CRT Presentatio
n Mode
1
25 standard measurement books
Ref:T.B.:1 B.N.DUTTA,pp-700
CRT Presentatio
n Mode 1
Sub Total 10 2 0 0
PCCE4103 STEEL STRUCTURES Design, Drawing & Detailing (3-1-0) CREDITS: 7
Note: only IS-800-2007 and Steel table will be allowed in the examination hall
Course Objectives:
1. To introduce the basic concepts and steps steel structures design mainly in accordance limit state of method.
2. To help the student develop an intuitive feeling about structural and material wise behavior and design of steel structures
with different modes of fasteners like bolted connection and welded connection.
3. To make the students capable of identify and apply the applicable industry design codes relevant to the design of steel
structures.
4. To become familiar with professional and contemporary issues in the design and fabrication of steel structures.
Course Outcomes:
At the end of this course the students will be able to:
1. Understand general mechanical behaviour of steel with different sectional behaviour.
2. Understand the analysis & design of bolted and welded connection.
3. Understand the analysis & design of steel compression members.
4. Understand the analysis & design of steel tension members.
5. Analyse the laterally supported and unsupported beam..
6. Understand the analysis & design of types of base slabs and gusseted slab.
7. Get knowledge about design of purlin of roof truss and wind pressures on roof.
Module-I (30 Hrs): STEEL STRUCTURES
(A) Fundamental Concepts of limit state design of structures.
(B) Different types of rolled steel sections available to be used in steel structures.
(C) Bolted connection: Types of bolts, Advantages and disadvantages of bolted connections, types of bolted
connection, Failure of bolted joint, Design strength of bolts, Analysis and design of bolted joints subjected to
axial load, Analysis and design of bearing bolts subjected to eccentric load .Analysis of high strength friction grip
bolts
(D) Welded Connections: Advantages of welding, Types and properties of welds, Types of joints,
specifications Design of welded joints subjected to axial load, Eccentric welded connections.
Module-II (40 Hrs):
(A) Tension members. Types of tension members, modes of failure, factors affecting strength of tension
members, angles under tension, design of tension members.(Topics related to design and detaling of beam
through class room teaching mode and practice mode )
(B) Compression members: Possible failure modes, classification of crosssection, behavior of
compression members, Effective length, and radius of gyration and slenderness of compression
members, Allowable stresses in compression, Design of axially loaded compression members, built up
compression members, Laced and Battened columns. Design of column base, slab base, and gustted base:
Design and detailing of one way and two way slabs, doglegged and cantilever staircase and circular slab,
Introduction to flat slab concept (no design). (Most of the topics will be through class room teaching mode
and practice mode and project mode)
MODULE-III (20 Hrs):
(A)Beams: Beam types, section classifications, lateral stability of beams, Allowable stress in bending, Shear
and Bearing stresses, Effective length of compression flange, Laterally supported and unsupported beams,
Design of built up beams and plate girders (Most of the topics will be through class room mode and practice
mode and project mode)
(B) Roof trusses : Types of trusses, Economical spacing of roof trusses, loads on roof trusses, Estimation of
wind load on roof trusses as per IS : 875. Design of members of roof truss and joints, Design of angle and I
purlins
(Most of the topics will be through class room mode and practice mode and project mode)
Text Books:
1. Design of steel structures by limit state Method as per IS: 800-2007 –S.S. Bhavikatti ,IK International Publishing
House, Bangalore –560 001
2. Design of Steel structures –N. Subramanian, Oxford University Press
3. Design of steel structures in limit state method by S.K. Duggal
S.
No.
Topic Pedagogy Details Instructional Hrs
Module I Theory Practice video Project
a) Basic Principles: Characteristic strength, characteristic
loads, design values, partial safety factors.
CRT 2 0 0
0
b) Different types of rolled steel sections available
to be used in steel structures.
CRT 4 0
0 0
c) Bolted connections: Types of bolts, Advantages and
disadvantages of bolted connections, types of bolted
connection, Failure of bolted joint, Design strength of bolts,
Analysis and design of bolted joints subjected to axial load,
Analysis and design of bearing bolts subjected to eccentric
load
CRT AND
PRA
8 6 0 0
d) Welded Connections: Advantages of welding, Types and
properties of welds, Types of joints, specifications Design
of welded joints subjected to axial load, Eccentric welded
connections.
CRT AND
PRA
4 6 0
Module II Sub total (30 hours ) 18 12 0 0
d) Tension members: Types of tension members, modes of
failure, factors affecting strength of tension members,
angles under tension, design of tension members.
CRT AND
PRA,
Video,
Project
Vedio (Block
shear
failure, slot
weld, plug
weld)
Project(Lace
d column, batten
colum,
beam–
column joint
with Staad-
Pro and
AUTO-CAD)
8 6 1
0
e)
Compression members: Possible failure modes,
classification of cross-
section, behavior of compression members, Effective
length, and radius of gyration and slenderness of
compression members, Allowable stresses in compression,
Design of axially loaded compression members, built up compression members, Laced and Battened columns.
Columns: Short columns under axial load with lateral ties
and helical reinforcement, short column under uniaxial
bending, slender columns. Detailing of axial and
eccentrically loaded columns
CRT AND
PRA, Project
8 6 6
0
f) Design of column base, slab base, and gusseted base CRT AND
PRA
Manually
proto type
modelling
6 5 2
Module III Sub total (40 hours ) 24 17 9 40
g) Beams: Beam types, section classifications, lateral stability of
beams, Allowable stress in bending, Shear and Bearing
stresses, Effective length of compression flange, Laterally
supported and unsupported beams, Design of built up beams
and plate girders.
CRT , PRA 3 2 0
0
h) Roof trusses : Types of trusses, Economical spacing of roof
trusses, loads on roof trusses, Estimation of wind load on roof
trusses as per IS : 875. Design of members of roof truss and
joints, Design of angle and I purlins CRT ,PRA
Design of
purlin by
using
Staad-Pro
Manually
proto-type of
steel roof
truss
3 1 0 0
Sub total (20 hours ) 6 3 0 9
PECE 4201 CONSTRUCTION PLANNING & PROJECT MANAGEMENT (3-0-0) CREDITS: 3
Course Objectives:
1. To introduce the basic concepts project management techniques related to civil engineering works.
2. To bring awareness of work break down structure of different civil engineering works and enable the student to
develop a CPM / PERT network.
3. To make the student understand the concept of critical path and its significance in construction project management.
4. To make the student understand the functional aspects of different construction equipment, their selection and
maintenance aspects of the same.
5. To apprise the student on the costs involved in running of various construction equipment and the economic life of
the equipment.
6. To educate the student on the process of tender preparation and the process involved in bidding. 7. To make the student aware of the various types of contracts and the contract conditions to be fulfilled by the
contractor.
8. To introduce the aspects related to settlement of disputes in contract execution.
Course Objectives: At the end of the course the students will be
1. able to develop a CPM / PERT network and evaluate the critical path for execution of the project and arrive at the
time of completion of the project.
2. able to select equipment for specific project,
3. able to decide between owning and hiring of equipment in a project
4. able to prepare a tender notice, and also follow the contract conditions and the consequences of deviation from the contract agreement.
MODULE-I: Project Management Technique (15 4Hrs)
(A) Introduction to PERT and CPM: Origin of PERT and CPM, Planning, Scheduling and Controlling - Bar Charts, Milestone Charts, Weaknesses in Bar Charts.
(B) PERT and CPM Networks Comparison, Event,Activity, Rules for drawing networks, numbering events - Fulkerson’s law - Dummy
activities, Time Estimates - Expected time, Earliest allowable occurrence time, Latest allowable occurrence time. Slack, Project duration Probability of completion, Start and Finish time estimates, Floats, Project Scheduling,
Critical and sub-critical path.
MODULE-II : Planning and Selection of Construction Equipment (12Hrs)
(C) Planning and Selection of Equipment Construction Equipment, Classification, Standard and Special Equipment, Selection of equipment. Cost of owning and operation, Economic life.
(D) Different Categories of Equipment Description, operation and maintenance of the following categories of equipment:
(i) Hauling equipment,
(ii) Earth moving equipment,
(iii) Hoisting equipment,
(iv) Pumping & dewatering equipment,
(v) Pile driving equipment and
(vi) Tar & bitumen equipment
MODULE - III : Contracts & Tendering process (12Hrs)
(E) Contracts Element of contract, Types of contract- Lumpsum contract, Lumpsum and scheduled contract, Item rate contract,
Sub-contracts, Joint ventures, Offer acceptance and consideration, valid contract, department execution, Muster
roll, Form 21, Piece work agreement form, work order, Contract system with tenders. Some Important definitions – Contract, Contractor, Quotation, Earnest Money, Security money.
(F) Tendering Process Definition, Tender notice, Tender form, Bidding procedure, irregularities in bidding, Award of work, Disputes
and claim settlement. Arbitration, Text Books: 1) PERT & CPM – L.S. Srinath
2) Construction Planning – P. Deodhar
3) Construction Planning – U.K. Srivastava
Module I
S.
No.
Topic Pedagogy Details Instructional Hrs
Module - I Project Management Technique (15Hrs) Theory Practice Project
Introduction to PERT and CPM
a) Origin of PERT and CPM, Planning, Scheduling and Controlling - Bar Charts, Milestone Charts, Weaknesses in Bar Charts.
CRT & Practice
2 +1
(Brain
Storming)
2 0
PERT and CPM Networks
b)
Comparison, Event, Activity, Rules for drawing networks,
numbering events - Fulkerson’s law - Dummy activities, Time
Estimates - Expected time, Earliest allowable occurrence time,
Latest allowable occurrence time. Slack, Project duration
Probability of completion, Start and Finish time estimates,
Floats, Project Scheduling, Critical and sub-critical path.
CRT &
Project 4 2 4
Module - II Planning and Selection of Construction Equipment (12 Hrs) Sub-
total 6 +1 4 4
Planning and Selection of equipment
c)
Construction Equipment, Classification, Standard and Special
Equipment, Selection of equipment. Cost of owning and
operation, Economic life.
CRT &
Practice 3 2 0
Different categories of equipment 5 (Student Presentati
ons)
d) Description, operation and maintenance of the following
categories of equipment CRT &
Presentation 2 0
Module - III Contracts & Tendering process (12 Hrs) Sub-total 5 7 0
Contracts
e)
Element of contract, Types of contract- Lumpsum contract,
Lumpsum and scheduled contract, Item rate contract, Sub-
contracts, Joint ventures, Offer acceptance and consideration,
valid contract, department execution, Muster roll, Form 21, Piece work agreement form, work order, Contract system with
tenders. Some Important definitions - Contract, Contractor,
Quotation, Earnest Money, Security money.
CRT 4 0 0
Tenders
f)
Definition, Tender notice, Tender form, Bidding procedure,
irregularities in bidding, Award of work, Disputes and claim
settlement. Arbitration.
CRT &
Project 4 0 4
Sub-total 8 0 4
Total 19 + 1 11 8
Evaluation: Through Tests, Assignments, Presentations and projects.
1. Module - I will be assessed through the projects on bar charts and networking process both manually and through
the usage of MS Project in addition to online test.
2. Module - II will be assessed through the presentations made by the students both in a group and individually.
3. Module - III will be assessed through 2 Projects and one conventional test.
4. Attendance and Assignments will also add to the evaluation.
5. The students will be divided in to two major groups one representing the owner and the other representing the
contractor for the purpose of assigning project. The projects will be so given that all the students represent both
the owner and the contractor.
MECHANICAL ENGINEERING
PCME4101 HEAT TRANSFER (Credits: 4)
Course Objectives:
1. To understand the fundamentals of heat transfer mechanisms in fluids and solids and their applications
in various heat transfer equipment in process industries
Course outcome :
On successful completion of this course, students will be able to:
1.Ability to understand and solve conduction, convection and radiation problems
2.Ability to design and analyse the performance of heat exchangers and evaporators
3. Ability to design and analyse reactor heating and cooling systems problems.
Module: I (20 Hours)
Introduction to conduction heat transfer, Fourier’s law of conduction, thermal conduction equation – derivation
in Cartesian, Cylindrical and Spherical coordinates. One dimensional steady state conduction in plane wall and
composite wall. Thermal contact resistance variable conductivity, thermal resistance, electrical analogy, radial
systems – cylinder, sphere. Overall heat transfer coefficients, critical thickness of insulation. Heat generation in
plane wall, cylinder and sphere. The heat diffusion equation. One dimensional steady state conduction with and
without heat generation. The plane wall – Radial system. Heat Transfer from extended surfaces – effectiveness –
efficiency. Insulation – critical thickness. Transient conduction – the lumped capacitance method – semi-infinite
solid. Steady state conduction in two dimensions, conduction shape factor, numerical method of analysis.
Unsteady state conduction – lumped heat capacity systems, significance of Biot and Fourier numbers, transient
heat flow in a semi-infinite solid, use of Heisler and Grober charts.
Module: II (15 Hours) Energy equation – thermal boundary layer. Forced convection – Practical correlations –
flow over surfaces internal flow. Natural convection, combined forced and free convection – combined
convection and radiation in flows. Review of hydrodynamics and thermal boundary layer, significance of non-
dimensional numbers in connection. Dimensional analysis for free and forced convection. Forced Convection –
heat transfer over a flat plate, flow through pipes, use of empirical relations. Free Convection – heat transfer from
vertical, horizontal and inclined surfaces.
Module: III (15 Hours)
Radiative heat exchange between surfaces – radiation shape factor – reradiating surfaces. Radiation in gases.
Boiling – Pool and flow boiling, correlations. Condensation – modes and mechanisms – Correlations and
problems
Condensation and Boiling processes. Radiation – nature of thermal radiation, black body concepts, gray body,
radiation shape factor, relation between shape factors, radiation heat transfer between two surfaces. Electrical
analogy, Re-radiating surface, radiation shields.
Types of heat exchangers, overall heat transfer coefficients, LMTD and NTU methods, fouling factor. Design
factors – problems in heat exchangers, effectiveness.
Text Books:
1. Holman J.P., ‘Heat andMass Transfer’, Tata McGraw Hill, 8th Ed., 1989.
2. Sachdeva, ‘Heat and Mass Transfer’, Wiley Eastern, 1986.
References
1. Heat and Mass Transfer – R.K. Rajput – S.Chand & Company Ltd
2. Heat and Mass Transfer – D.S.Kumar / S.K.Kataria& Sons
3. Heat and Mass Transfer-Kondandaraman
Module I
S.
No.
Topic Pedagogy Details Instructional Hrs
Conduction: Theory Practice video Project
1 Introduction to conduction heat transfer, Fourier’s law of
conduction, general heat conduction equation – derivation
in Cartesian, Cylindrical and Spherical coordinates.
CRT
2 1 0 0
2 One dimensional steady state conduction in plane wall and
composite wall. Thermal contact resistance variable
conductivity, thermal resistance, electrical analogy, radial
systems – cylinder, sphere.
CRT, PRA
& ANSYS
Simulation
2 3 0 0
3 Overall heat transfer coefficients, critical thickness of
insulation. Heat generation in plane wall, cylinder and
sphere.
CRT
2 0 0 0
4 The heat diffusion equation. One dimensional steady state
conduction with and without heat generation.
CRT 2 0 0 0
5 The plane wall – Radial system. Heat Transfer from
extended surfaces – effectiveness – efficiency. Insulation –
critical thickness.
CRT
2 0 0 0
6 Transient conduction – the lumped capacitance method –
semi-infinite solid. Steady state conduction in two
dimensions, conduction shape factor, numerical method of
analysis.
CRT
3 0 0 0
7 Unsteady state conduction – lumped heat capacity systems,
significance of Biot and Fourier numbers, transient heat
flow in a semi-infinite solid, use of Heisler and Grober
charts
CRT
3 0 0 0
Sub total 20 16 4 0 0
Module II
S.
No.
Topic Pedagogy Details Instructional Hrs
Convection: Theory Practice video Project
1 Energy equation – thermal boundary layer. Forced
convection – Practical correlations – flow over surfaces
internal flow
CRT
2 0 0 0
2 Natural convection, combined forced and free convection –
combined convection and radiation in flows
CRT, PRA
& ANSYS Simulation
2 3 0 0
3 Review of hydrodynamics and thermal boundary layer,
significance of non-dimensional numbers in connection,
Dimensional analysis for free and forced convection
CRT
3 0 0 0
4 Forced Convection – heat transfer over a flat plate, flow
through pipes, use of empirical relations. Free Convection –
heat transfer from vertical, horizontal and inclined surfaces.
CRT, PRA
& ANSYS
Simulation
2 3 0 0
Sub total 15 9 6 0 0
Module III
S.
No. Topic Pedagogy Details Instructional Hrs
Radiation: Theory Practice video Project
1 Radiative heat exchange between surfaces – radiation shape
factor – reradiating surfaces CRT &
PRA
0 2 0 0
2 Radiation in gases. Boiling – Pool and flow boiling,
correlations CRT
&PRA
0 2 0 0
3 Condensation – modes and mechanisms – Correlations and
problems
CRT 2 0 0 0
4 Condensation and Boiling processes. Radiation – nature of
thermal radiation, black body concepts
CRT 2 0 0 0
Gray body, radiation shape factor, relation between shape
factors, radiation heat transfer between two surfaces.
Electrical analogy, Re-radiating surface, radiation shields.
CRT
3 0 0 0
1 Types of heat exchangers, overall heat transfer coefficients,
LMTD and NTU methods, fouling factor.
CRT &
PPT
2 1 0
0
2 Design factors – problems in heat exchangers, effectiveness. CRT 1 0 0 0
Sub Total 15 10 5 0 0
PCME4102 OPTIMIZATION TECHNIQUES (Credits: 4)
Course Objectives:
1. To introduce the fundamental concepts of Optimization Techniques
2. To understand the theory of optimization methods and algorithms developed for solving various types of optimization problems.
3. Introduce methods of optimization to engineering students, including linear programming, network flow algorithms,
integer programming, interior point methods, quadratic programming, and nonlinear programming methods
4. To provide the concepts of various classical and modern methods for constrained problems in both single and
multivariable.
Course outcome:
students are able to understand about
1) Basic theoretical principles in optimization;
(2) Formulation of optimization models;
(3) To solve various constrained and unconstrained problems in single variable as well as multivariable
Module I: Introduction to Optimization (15 Hrs)
(A) Introduction: Need and scope of optimization. Historical development, statement of optimization problem
- Objective function and its surface, Design variables, constraints and constraint surface. Classification of
optimization problems various functions, Continuous, discontinuous and discrete functions, Monotonic, Non-
monotonic and unimodal functional behavior.
(B) Classical optimization techniques: Differential calculus method, multivariable optimization by method of
constrained variation and Lagrangean multipliers (generalized problem), Khun - Tucker conditions for
optimality.
Module II: Linear Programming (15 Hrs)
(C) Linear Programming - Graphical Method: Definition, Characteristics of linear and Steps
involved, Redundant constraints - Application of L.P. to engineering problems.
(D) Linear Programming - Simplex method: Definition, Basics of Simplex Method, Slack, Surplus, Decision
and Artificial variables - Significance of these variables and their application in Simplex method. Two Phase
method, Big M method. Duality in linear progrmming.
(E) Transportation Problem & Assignment Problems: Transportation Problem -Definition, Basic feasible
solution, steps involved in solution of transport problem. Assignment Problem - Basic differences between
transportation and Assignment problems - Balanced and unbalanced Assignment Problems.
Module III: (15 Hrs)
(F) Non-linear Programming: Definition, Unconstrained minimization – Fibonacci, Golden section, Quadratic
and Cubic interpolation methods for one-dimensional minimization and univariate method, Powel’s, Newton’s
and Davidson, Fletchar and Powel’s method for multivariable optimization. Conditions for a function to be
convex and concave. Constrained minimization - Cutting plane method.
(G) Dynamic Programming: Meaning, Basic Principles of Dynamic programming, Simple examples of
dynamic programming.
Text books:
1) Optimizaion theory and Applications - Rao, S.S. - Wiely Eastern Ltd., New Delhi
2) Optimmum structural Design, theory and applications - Edited by R.H. Gallegher and O.C. Zienkiwiez. John Wiley and
Sons Newyork
Module I
S.
No.
Topic Pedagogy Details Instructional Hrs
Introduction to Optimization Theory Practice video Project
1 Introduction: Need and scope of optimization. Historical
development
CRT & PPT 1 0 0 0
2 Statement of optimization problem - Objective function
and its surface, Design variables, constraints and
constraint surface
CRT & PPT
&P RA
2 1 0 0
3 Classification of optimization problems various functions,
Continuous, discontinuous and discrete functions,
Monotonic, Non-monotonic and unimodal functional
behavior.
CRT &
PPT&PRA
3 1 0 0
4 Classical optimization techniques: Differential calculus
method,
CRT & PPT 2 0 0 0
5 Multivariable optimization by method of constrained
variation and Lagrangean multipliers (generalized
problem), Khun - Tucker conditions for optimality
CRT & PPT
& PRA
4 1 0 0
Module II Sub total 15 12 3 0 0
1 Graphical Method: Definition, Characteristics of linear
and Steps involved, Redundant constraints - Application of
L.P. to engineering problems.
CRT & PRA
1 1 0 0
2 Simplex method: Definition, Basics of Simplex Method,
Slack, Surplus, Decision and Artificial variables -
Significance of these variables and their application in
Simplex method.
CRT & PRA
2 1 0 0
3 Two Phase method, Big M method. Duality in linear
progrmming
CRT, PRA
& ANSYS
Simulation
1 3 0 0
4 Transportation Problem: Definition, Basic feasible
solution, steps involved in solution of transport problem
CRT 3 0 0 0
5 Assignment Problem: Basic differences between
transportation and Assignment problems - Balanced and
unbalanced Assignment Problems.
CRT
3 0 0 0
Sub total 15 10 5 0 0
Module III
S.
No.
Topic Pedago
gy
Detail
s
Instructional Hrs
Theory Practice video Project
1 Non-linear Programming: Definition, Unconstrained minimization –
Fibonacci, Golden section, Quadratic and Cubic interpolation
methods for one-dimensional minimization and univariate method
CRT
3 1 0 0
2 Powel’s, Newton’s and Davidson, Fletchar and Powel’s method for
multivariable optimization
CRT 3 1 0 0
3 Conditions for a function to be convex and concave. Constrained
minimization - Cutting plane method.
CRT 3 0 0 0
4 Dynamic Programming: Meaning, Basic Principles of Dynamic
programming, Simple examples of dynamic programming
CRT 3 1 0 0
Sub total 15 12 3 0 0
PCME4201 PRODUCT DESIGN AND PRODUCT TOOLING (Credits: 4)
Course Objectives: To introduce the objectives of product design and the requirements of a good product design. To expose the students to
different design principles like designing for function, production, installation and handling, maintenance, packaging etc.
Course outcome :
The student will be able to
1.Apply the principles of product design to modify existing engineering systems or to develop new artifacts.
2.Design a system taking into consideration the concepts of ease of production, maintenance, handling, installation etc.
Module - I (16 Hrs)
Product design considerations, product planning, product development, value analysis, product specification,
Role of computer in product design.
Product design for sand casting: design of gating system, objectives of gating design, and risering, gating ratio,
choke area.
Module - II (16 Hrs)
Forging design: allowances die design for drop forging, design of flash and gutter, upset forging die design, drop
forging die design.
Sheet metal working: Design consideration for shearing, blanking, punching, deep drawing operation, Die design
for sheet metal operations, progressive and compound die, strippers, stops, strip layout.
Module - III (18 hours)
Design of jigs and fixtures, principle of location and clamping, clamping methods, locating methods, Drill Jig
bushing, Indexing type drilling Jig. Design of single point cutting tool, broach and form tool, Design of limit
gauges, Process planning– selection of processes, machines and tools. Design of sequence of operations, Time &
cost estimation, Tooling design for turret lathe and automats.
Text Books: 1. Fundamentals of Tool Engineering design, S.K. Basu, S.N. Mukherjee, R. Mishra, Oxford & IBH Publishing co.
2. Manufacturing Technology, P.N. Rao, Tata McGraw Hill
3. A Textbook of Production Engineering, P.C. Sharma, S. Chand & Co
Reference Books: 1. Product Design & Manufacturing, A K Chitale, R C Gupta, Eastern Economy Edition, PHI. 2. Product Design & Development, Karl T Ulrich, Steven D Eppinger, Anita Goyal, McGraw Hill
3. Technology of Machine Tools, Krar, Gill, Smid, Tata Mc Graw Hill
4. Jigs & Fixture Design, Edward G Hoffman, Cengae Learning.
Module I
S.
No.
Topic Pedagogy Details Instructional Hrs
Theory Practice video Project
1 Product design considerations, product planning,
product development
CRT & Video
presentation
4 1 0 0
2 Value analysis, product specification, Role of
computer in product design.
CRT, PRA 4 1 0 0
3 Product design for sand casting: design of gating
system, objectives of gating design, and risering,
gating ratio, choke area.
CRT
4 2 0 0
Module II Sub total 16 12 4 0 0
1 Forging design: allowances die design for drop
forging, design of flash and gutter
CRT 3 0 0 0
2 Upset forging die design, drop forging die design. CRT & video 3 0 1 0
3 Sheet metal working: Design consideration for
shearing, blanking, punching, deep drawing
operation
CRT & video
3 0 1 0
4 Die design for sheet metal operations, progressive
and compound die, strippers, stops, strip layout
CRT & video 4 0 1 0
Sub total 16 13 0 3 0
1 Design of jigs and fixtures, principle of location and
clamping, clamping methods, locating methods CRT & PRA 3 1 0 0
2 Drill Jig bushing, Indexing type drilling Jig. CRT &PRA 3 1 0 0
3 Design of single point cutting tool, broach and form
tool
CRT & PRA 2 1 0 0
4 Design of limit gauges CRT 1 0 0 0
5 Process planning– selection of processes, machines
and tools
CRT &
PPT&ViDEO
2 1 0
0
6 Design of sequence of operations, time & cost
estimation
CRT 1 0 0 0
7 Tooling design for turret lathe and automats CRT & PRA 1 1 0 0
Sub Total 18 13 5 0 0
PLME4111 HEAT TRANSFER & REFRIGERATION AND AIR CONDITIONING
LABORATORY (Credits: 2)
Heat Transfer: 1. Determination of Thermal conductivity of composite slab
2. Determination of heat transfer coefficient in natural convention 3. Determination of surface emissivity
4. Performance test on parallel flow and counter flow heat exchanger
5. Efficiency and effectiveness of Pin fins
6. Verification of Stefan Boltzman’s law. 7. Determination of heat transfer coefficient in forced convention
8. Determination of Critical heat flux during boiling heat transfer
Refrigeration and Air Conditioning: 1. Determination of C.O. P on vapour compression system
2. Determination of C.O. P on vapour absorption system 3. Performance test on Air conditioning test rig (Window type)
4. Performance test on Air conditioning test rig (Duct type)
5. Determination of C.O.P of ice plant
6. Performance analysis in an experimental cooling tower
COMPUTERSCIENCE & ENGINEERING
PCCS4102 DATABASE DESIGN & IMPLEMENTATION
Course Nature: Theory + Practice + Project Credit: 8
Course Objectives:
1. Understand the role of a database management system in an organization.
2. Understand the role of the database administrator
3. Understand basic database concepts, including the structure and operation of the relational data model.
4. Construct simple and moderately advanced database queries using Structured Query Language (SQL)
5. Understand and successfully apply logical database design principles, including E-R diagrams and database normalization
Course Outcomes:
On successful completion of this course, students will be able to:
1. Master the basic concepts and appreciate the applications of database systems.
2. Master the basics of SQL and construct queries using SQL)
3. Be familiar with a commercial relational database system (Oracle, my sql ,sql server)by writing SQL using the
system
4. Mater of logical design of databases using the E‐R method and normalization approach.
5. Student will be master in creating a database project including database connectivity.
Module-I (08 Hrs): Data base concepts and uses.
(A) Data modelling using the E_R Model:
E-R model : Entity types, Entity sets, Weak entity types Attributes, Keys
Relationship: Relationship type, cardinality ratio, partial participation, total participation
Mapping: Mapping E-R model into relational model
(B) Constraints: Varieties of constraints and their applications. . (All the topics will be through PPT,Case
studies )
Module-II (09 Hrs) : Database programming
(C) Basic sql queries: Creation of Database, Creation of tables, Imposing keys, Imposing constraints,DDL
commands.DML commands . (Topics related sql basic queries will be taught through practice mode)
(D) Join: Variety of joins (inner join, Outer join with full concept. . (All the topics will be through PPT as
well as practices )
(E) Implementing aggregate functions like max, mean, count and various clauses like group by, having etc
etc…
(All the topics will be through practices )
MODULE-III (12 Hrs): Additional database programming:
(F) Stored procedures: Writing stored procedures , Executing sub queries, Using functions, Creating views,
Implementing triggers (All the topics will be through practices )
(G) Databse administration (Giving authorisation),Database connectivity programming(JDBC,ODBC)
(H) Introduction to PL/SQL :Use of loops ,arrays, strings
Text Books:
1. Fundamentals of Database Systems by Ramez Elmasri, S B Navathe pearson publications
2. Databse systems by Thomas Connolly and Carolyn Begg
Module I
S.
No.
Topic Pedagogy Details Instructional Hrs
Theory Practice video Project
Data modelling using the E_R Model
1 E-R model : Entity types, Entity sets, Weak
entity types Attributes, Keys
presentation 2
2 Relationship: Relationship type,
cardinality ratio, partial participation,
total participation
Presentation
and practice
1 1
3 Mapping: Mapping E-R model into
relational model
Presentation
and practice
1 1
4 Constraints: Varieties of constraints and their applications
Presentation 2
Module II Sub Total 6 2
5 Creation of Database, Creation of tables,
Imposing keys,
practice 2
6 Imposing constraints practice 1
7 DDL commands.DML commands practice 1
8 Inner join &Outer join, Normalisation Presntaion with
practice
2 1
9 Aggregate functions practice 2
Module III Sub Total 2 7
10 Writing stored procedures Practice 2
11 Executing sub queries Practice 1
12 Using functions Practice 2
13 Creating views, Implementing triggers Practice 2
14 Database connectivity
programming(JDBC,ODBC), Databse
administration (Giving authorisation
practice
3
15 Introduction to PL/SQL :Use of
loops ,arrays, strings
2
Sub Total 12
Note: The student has to do a database project, based on any topic, which should be including all the concept covered in
the said syllabus.
This project work carries 6 credits. The instructor has to review the project work in all the stages and has to maintain the
progress report.
The project work has to go simultaneously along with the class work or beyond the class hours and the weekly work
progress report should be close to the concepts covered during the class hours.(40 ) hours minimum.
ELECTRONICS & COMMUNICATION ENGINEERING
PCEC4101 MICROWAVE AND RADAR ENGINEERING
Credits: 04 Hours: [54] Course Objectives:
The objectives of this subject are
1. To introduce the student to the basics of Microwave and Radar.
2. To focus on the fundamentals of microwave theory and techniques and its selected applications
Course Outcomes:
Upon successful completion of this subject, students should be able to:
1. Distinguish Electromagnetic wave propagation through reflections from voltage and current transmission.
2. Analyze performance of microwave components from field point of view.
3. Maintain microwave components and Set up of microwave bench for optimum operation.
4. Maintain microwave semiconductor devices used to realized amplifiers and oscillators.
5. Maintain RADAR system as microwave application.
MODULE - I (24Hours)
Transmission lines: The Lumped-Element Circuit model for a Transmission line. Wave propagation,
FieldAnalysis of two wire & Co-ax Transmission Lines.Terminated transmission line. Reflection coefficient,
scattering matrix, Transmission line problems ,Single Stub and Double Stub matching,problems using Smith
Chart.
Rectangular and Cylindrical waveguide: Design & analysis to support various modes. Field solution for TE
and TM modes, Field patterns of power flow through waveguide. Attenuation due to conductor and dielectric
losses
MODULE - II (14Hours)
Power Dividers and Couplers: Basic Properties, T -Junction Power Divider, Wilkinson Power divider,
Waveguide Directional Couplers, Ferrite Isolator. Rectangular Cavities Resonator, Resonant frequencies of
Cavity Supporting dominant mode only, Dielectric resonator. Strip line and micro strip. Klystron and Reflex
Klystron: klystron: construction and operation only Reflex klystron: Principle of Operation, Velocity
Modulation, Output Power and Efficiency
Multicavity Magnetron: Principle of Operation, Rotating Field,Π-Mode of Operation, Frequency of Oscillation,
Output Power and Efficiency. TWT - Principle of Operation as an amplifier
MODULE - III (16Hours)
Microwave Transistors: Physical structure, principles operation, applications of microwave bipolar transistor
and HBT.Operation and characteristic of Tunnel diode.Gunn Oscillator Principle and performance.Microwave
hazards.
Introduction to Radar: Basic radar, radar block diagram, radar frequencies & applications, Radar Indicators.
RADAR Equation: Detection of signal in noise, receiver noise and SNR, probability of detection and
false alarm, integration of radar pulses, radar cross section of targets, PRF, system losses.
MTI RADAR: Introduction, delay line cancellers, Doppler filter banks, limitation of MTI, Staggered
PRF, Pulse Doppler radar, Tacking by radar
Text Books:
1. Microwave Engineering by D. M. Pozor, 2nd Edition, John Willy & Sons.
2. Microwave Device and Circuit, 3rd Edition, Sammuel Y, Liao, Perason 72
3. Introduction to RADAR systems by Merrill I. Skolnik, 3rd edition, Tata McGraw Hill.
Reference Book:
1. Principles of Microwave Engineering, Reich, Oudong and Others.
2. Elements of Engineering Electromagnetics, 6th Edition, N. N. Rao, Pearson Education,
3. Electromagnetic Waves and Radiating Systems, 2nd Edition, E.C. Jordan and K.G. Balman, Pearson Education,
New Delhi.
4. Engineering Electromagnetic, 7th Edition, William H. Hayt, Tata McGraw Hill Publishing Company Ltd., New Delhi
5. RADAR Principles, Technology, Application by Byron Edde, 1st edition, Pearson, 2004.
6. Understanding RADAR system by Simon Kingsley, Shaun Quegan, Standard publication
PEDAGOGY
S.
No.
Topic Pedagogy Deta
ils
Instructional Hours
MODULE-I (24 Hours) Theory Practice video Project
1 Introduction, history and application of
Microwave engineering. Review of Plane wave
propagation. Lumped element circuit model for a
transmission line.
CRT 1 0 1 0
2 Wave propagation in a transmission line and
Lossless transmission line. Reflection and
transmission coefficient. Standing wave ratio. Line
impedance and admittance. Characteristic
impedance.
CRT 2 0 1 0
3 Field analysis of co-axial transmission lines.
Development of Telegraphic equation.
Propagation constant, Impedance, and power flow
for lossless co-axial line.
CRT 2 0 0 0
4 R, L, C and G parameters of co-ax and two wire
transmission lines
CRT 2 0 0 0
5 Terminated loss less transmission line.
Transmission line as circuit element. Microwave
co-axial connectors.
CRT 2 0 0 0
6 Introduction to graphical solution of transmission
line problem. Principle of Smith Chart
construction.
CRT &
Project
2 0 0 0
7 Solution of transmission line problems using Smith
Chart.
CRT 1 0 0 0
8 Single Stub and Double Stub matching. Low loss
transmission line.
CRT 1 0 0 0
9 Introduction to wave guide. Rectangular wave
guide.
CRT 1 0 0 0
10 Field solution for TE modes. CRT 1 0 0 0
11 Field solution for TM modes. CRT 1 0 0 0
12 Field solution for TE and TM modes. CRT 1 0 0 0
13 Field patterns and power flow through wave
guide.
CRT 1 0 0 0
14 Attenuation due to conductor and dielectric losses
in wave guide.
CRT 1 0 0 0
15 Design of Rectangular waveguide to support
Dominant TE10
CRT 1 0 0 0
16 TEM mode in coax line. Cylindrical wave guide
(Dominant mode).
CRT 1 0 0 0
17 Design of Cylindrical waveguide to support
dominant TE11 mode
CRT &
Project
1 0 0 0
18 Rectangular Waveguide Cavities. Resonant
frequencies and of cavity supporting. (Dominant
mode only)
CRT 1 0 0 0
19 Excitation of waveguide and Resonators(principle
only)
CRT 1 0 0 0
Sub Total 24 0 0 0
S.
No. Topic Pedago
gy
Deta
ils
Instructional Hours
MODULE-II (14 Hours) Theory Practice video Project
20 Basic properties of Power dividers and Directional
couplers. CRT 1 0 0 0
21 The T-junction power Divider. CRT 1 0 0 0
22 Waveguide Directional Couplers (Calculation of S
matrix of Directional couplers). CRT 1 0 0 0
23 Fixed and Precision Variable Attenuator. Ferrite
Isolator (Principle of Operation). CRT 2 0 0 0
24 Rectangular Cavities Resonator, Resonant frequencies
of Cavity Supporting dominant mode only,
CRT &
Project 2 0 0 0
25 Dielectric resonator. Strip line and micro strip. CRT 1 0 0 0
26 Reflex Klystron: Velocity Modulation, Electronic
Admittance CRT 1 0 0 0
27 Power Output and Frequency vs. Reflector Voltage.
Square wave modulation CRT 1 0 0 0
28 Multicavity Magnetron: Principle of Operation,
Rotating Field CRT 1 0 0 0
29 ∏-mode of Operation, Frequency of Oscillation. CRT 1 0 0 0
30 TWT - Principle of Operation as an amplifier CRT 2 0 0 0
MODULE-III (16 Hours) Sub Total 14 0 0 0
31 Microwave Transistors: Physical structure, principles
operation, applications of microwave bipolar transistor
and
CRT
2 0 0
0
32 HBTOperation and characteristic of Tunnel diode. CRT 1 0 0 0
33 Gunn Oscillator Principle and performance. 1
34 Microwave hazards CRT 1 0 0 0
35 Radar Block diagram& radar Equation CRT 2 0 0 0
36 Radar Frequencies& Information available from Radar
Echo, Prediction, Minimum detectable signal, Receiver
Noise, SNR
CRT
2 0 0
0
37 Probabilities of detection & False Alarms CRT 1 0 0 0
38 Radar cross section of Targets &Transmitted
power,Pulse repetition frequency &Antenna parameters
CRT 2 0 0
0
39 System losses & Propagation effect CRT 2 0 0 0
40 MTI radar CRT 1 0 0 0
41 Pulse Doppler radar CRT 1 0 0 0
Sub Total 16 0 0 0
PCEC4201 SATELLITE AND OPTICAL COMMUNICATION
Credits: 04 Hours [50]
Course Objective:
The objectives of this subject are to:
The recent development and trends in optical fibers
The satellite link design and multiple access
Optical fiber construction techniques and losses of it.
Course Outcome:
Upon successful completion of this subject, students should be able to:
Apply their knowledge to the analysis and design of satellite communication systems and the design of certain
components for the system. Understand of the theory of modern optical communication systems.
Apply their knowledge to the design of optical communications systems at a conceptual level
Understand different optical sources available.
MODULE-I (17Hours)
Orbital Mechanics: Determination of Orbital Parameters, look angle of a geostationary Satellite from
Earth. Launches and Launch Vehicle. Placing Satellite into Geo-stationary Orbit.
Satellite Subsystems: A brief Description of AOCS, TTC & M and Power System. Description of
Communication System –Transponders. Satellite Antennas: Basic Antennas Types and Relationship; Global
Beam Antenna, Satellite Antennas in Practice. Equipment Reliability & Space qualification. Redundancy.
Multiple Access: Comprehensive study on FDMA, TDMA and CDMA.
Satellite Link Design: Basic Transmission Theory, System Noise Temperature and G/T Ratio; G/T Ratio for
Earth Station. Design of Down Link. Up link Design. Satellite Communication Link Design Procedure. System
Design Example –Ku Band
Propagation Effects and Their Impact on Satellite: Earth Links: Attenuation, Depolarization,
Ionospheric&Tropospheric effects. Prediction of Rain Attenuation.
MODULE-II (17 Hours)
Optical Communication System: Major Elements of an optical fiber communication link. Optical fiber
attenuation as a function of wavelength.
Optical fiber: Refractive index profile of step Index and Graded Index Fibers. Light ray propagation
thorough Optical fiber. Total Internal Reflection. Numerical Aperture, Modal Concept. V number.
Electromagnetic Theory of wave Propagation thorough step index fiber Mode Theory for Circular
waveguide.Wave Equator Step Index fiber. Modes in step index fiber. Power flow in step index fiber.Graded
index fiber structure. Mono mode fiber
Fiber Materials: Fiber Fabrication : Double –Crucible Method. Cabling of Optical Fibers.Signal Degradation in
Optical Fiber:
Attenuation: Factors contributing to losses. Signal Distortion –Inter-and Intra Modal, CHoursomatic, Wave
guide and Polarization Dispersions. Pulse Broadening in SI &GI fibers.Km -Bandwidth Concept.
MODULE –III (16Hours)
Optical Sources : LED, Typical GaAlAs p-n junction double hetero-structure, Typical Spectral pattern,
Modulation of an LED. Laser diodes: Principle of Operation. Typical Constructional features Radiation Pattern.
Modulation of Laser diode , Typical Manufactures’ specifications of LED & LASER. Power
Lunching&Coupling: Source to fiber power launching, Coupling Power Calculation. Lensing Scheme for
improvement of coupling.Fiber-to-fiber Connectors Connector loss. Techniques of splicing .Splicing loss. Photo
Detectors : p-n , PIN and APD Photo detectors, Responsively and Bandwidth of diodes. Noise in PDs.
Equivalent Circuits, SNR.
Optical Receiver : Receiver Configuration Sensitivity and Bandwidth of Receiver Bit Error Rate.Trans
Impendence Preamplifier.Design of Fiber Optic link : Time Budget and Power Budget . Optical Amplifier, WDM
: Principle & Practice.
TEXT BOOKS:
1)Satellite Communication by T. Pratt, C. Bostian and J. Allnutt. 2nd Edition ,Joihn Wiley Co.
Selected Portion from Chapters 2,3,4,6,8,9 and 11.
2) Digital Communication with Satellite and Fiberoptic Application, HarlodKolimbins, PHI
3) Optical Fiber Communications by G. Keiser. 3rd Edition McGraw Hill Book Co.
4) Fiber Optic Communications Technology by D. K. Mynbaev& Lowell L. Scheiner –Pearson Education.
Reference Books:
1. Optical fibers and Fiber Optic communication systems by Subir Kumar Sarkar , Publication : S. Chand & Co.
2. Fiber Optic communications By Joseph C. Palais 4th Edition, Pearson Publication Asia.
3. Satellite Communication by Robert M. Gagliardi, CBS Publishers
4. Advanced Electric Communication System by Wayne Tomani, 6th Edition , Pearson Education
MODULE I [17 HOURS]
S.
No.
Topic Pedago
gy Details
Instructional Hours
Theory Practice video Project
01
Introduction to Subject: Orbital Mechanics: Determination of Orbital Parameters, look angle
of a geostationary Satellite from Earth. Launches
and Launch Vehicle. Placing Satellite into Geo-
stationary Orbit. Reference: T.PRATT:
CRT
Chalk
& Talk
and
PPT
4 0 0 0
02
Satellite Subsystems: A brief Description of
AOCS, TTC & M and Power System description
of Communication System –Transponders. Satellite
Antennas: Basic Antennas Types and
Relationship; Global Beam Antenna, Satellite
Antennas in Practice. Equipment Reliability &
Space qualification.Redundancy.MultipleAccess:
Comprehensive study on FDMA, TDMA and CDMA. Reference:T.PRATT, HarlodKolimbins, Robert M.
Gagliardi
CRT
Chalk
& Talk
, PPT
4 0 0 0
03
Satellite Link Design: Basic Transmission Theory,
System Noise Temperature and G/T Ratio; G/T Ratio
for Earth Station. Design of Down Link. Up link
Design. Satellite Communication Link Design
Procedure. System Design Example –Ku Band,
Propagation Effects and Their Impact on Satellite:
Earth Links: Attenuation, Depolarization,
Ionospheric&Tropospheric effects. Prediction of
Rain Attenuation. Reference: T.PRATT
CRT
Chalk
& Talk
, PPT
9 0 0 0
MODULE II [17 HOURS] Sub Total: 17 0 0 0 0
04
Key Topics: Optical Communication System:
Major Elements of an optical fiber communication
link.Optical fiber attenuation as a function of wavelength. Optical fiber: Refractive index profile
of step Index and Graded Index Fibers. Light ray
propagationthrough Optical fiber. Total Internal
Reflection. Numerical Aperture, Modal Concept. V
number. Reference: Keiser, Joseph C.Palais
CRT
Chalk
& Talk
, PPT
5 0 0 0
05
Key Topic
Electromagnetic Theory of wave Propagation
through step index fiber Mode Theory for Circular
waveguide. Wave Equator Step Index fiber. Modes in
step index fiber. Power flow in step index fiber.
Graded index fiber structure. Mono mode fiber
Reference: Keiser, Joseph C.Palais
CRT
&
BCRT
(Beyon
d CRT)
Chalk
& Talk
, PPT,
Industr
y visit
5 0 0 0
06
Fiber Materials: Fiber Fabrication:Double–Crucible Method. Cabling of Optical Fibers.Signal
Degradation in Optical Fiber:
Attenuation: Factors contributing to losses. Signal
Distortion –Inter-and Intra Modal, CHoursomatic,
Wave guide and Polarization Dispersions. Pulse
Broadening in SI & GI fibers. Km -Bandwidth
Concept.Reference: Keiser, Joseph C.Palais
CRT
Chalk
& Talk
, PPT
7 0 0 0
17 0 0 0
MODULEIII [16 Hours]
S.
No. Topic Pedago
gy
Details Instructional Hours
Theory Practice video Project
07
Optical Sources : LED, Typical GaAlAs p-n
junction double heterostructure, Typical Spectral
pattern, Modulation of an LED. Laser diodes:
Principle of Operation. Typical Constructional
features Radiation Pattern. Modulation of Laser
diode , Typical Manufactures’ specifications of
LED
Reference: Keiser, Joseph C.Palais
CRT
Chalk
& Talk
, PPT
5 0 0 0
08
LASER. Power Lunching Coupling: Source to fiber
power launching, Coupling Power Calculation.
Lensing Scheme for improvement of coupling.
Fiber-to-fiber Connectors Connector loss.
Techniques of Splicing .Splicing loss. Photo
Detectors : p-n , PIN and APD Photo detectors,
Responsively and Bandwidth of diodes. Noise in
PDs. Equivalent Circuits.SNR
Reference : Keiser, Joseph C.Palais
CRT
Chalk
& Talk
, PPT
5 0 0 0
09
Optical Receiver: Receiver Configuration Sensitivity
and Bandwidth of Receiver Bit Error Rate.Trans-
Impendence Preamplifier. Design of Fiber Optic
link: Time Budget and Power Budget. Optical
Amplifier, WDM: Principle & Practice.
Reference: Keiser, Joseph C.Palais
CRT
Chalk
& Talk
, PPT
6 0 0 0
Sub Total 16 0 0 0
PLEC4111 MICROWAVE AND ANTENNA LAB
Credits: 02 Hours: [42]
Course Objective:
The objectives of this laboratory are to
Introduce students to microwave systems, components and devices and develop an understanding of the microwave
circuit analysis technique,
Expose students to circuit design tools/ Software used in microwave engineering and introduce students to
microwave measurement techniques and instrumentation
Course Outcome:
Upon successful completion of laboratory, students should be able to:
1. Describe, analyse and design simple microwave circuits and devices e g matching circuits, couplers, antennas and
amplifiers.
2. Describe and coarsely design common systems such as radar and microwave transmission links.
3. Be able to apply analysis methods to determine circuit properties of passive/active microwave devices.
4. Know how to model and determine the performance characteristics of a microwave circuit or system using
computer aided design methods.
LIST OF EXPERIMENTS:
1. Introduction to microwave bench and components, Observe different signals output of the microwave
bench with GUNN oscillator and measure the frequency with frequency meter.
2. Study of the characteristics of a Reflex Klystron oscillator.
3. Plotting of Standing Wave Pattern along a transmission line when the line is open-circuited short-
circuited and terminated by a resistive load at the load end.
4. Experimental/Simulation Study of filter (LPF, HPF, BPF) response using HFSS.
5. Simulation study of Smith chart using HFSS.
6. Simulation study of Smith chart - Single and double stub matching using HFSS.
7. Input Impedance of a terminated coaxial line using shift in minima technique using HFSS.
8. Radiation Pattern of dipole antenna using HFSS
9. Radiation Pattern of folded dipole antenna using HFSS
10. Radiation Pattern of 3-element Yagi-Uda Antenna using HFSS
11. Beam width, gain and radiation pattern of a 3-element, 5-element and 7-element. Yagi-Uda antenna
Comparative- study using HFSS.
12. To simulate using HFSS :-
Dipole antenna by plotting its radiation pattern, measuring -3dB beam width, gain and return
loss.
Yagi antenna by plotting its radiation pattern, measuring -3dB beam width, gain and return loss.
Parabolic reflector antenna by plotting its radiation pattern, measuring -3dB beam width, gain
and return loss.
13. Radiation pattern, polarization, wavelength and frequency measurement of horn antenna by microwave
bench.
14. Measurement of wavelength, VSWR, reflection coefficient and transmission coefficient using a slotted
co-axial transmission line and a microwave generator
15. Study the characteristics of scattering parameters of circulator ,isolator, attenuator & directional coupler
16. Power division and coupling measurement analysis using HFSS
a. H-plane
b. E-plane
c. Magic tee junctions
ELECTRICAL ENGINEERING
PCEL 4101 Power System Operation & Control Credits: 04 Total Hrs: [50]
Course Objectives:
1. To introduce the concepts of optimization techniques used in power systems. 2. To introduce the basic governing systems for automatic generation and control.
3. To provide a solid foundation in mathematical and engineering fundamentals required to control the governing
system in turbine models.
4. To provide the knowledge of power system stability.
5. To provide the knowledge of reactive power flow control.
Course Outcomes:
On successful completion of this course, students will be able to:
1. Make Economic operation of power system and importance of LFC.
2. Solve problems (numerical problems at present) by using different problem models related to Economic load
despatch, reactive power control.
3. Discuss about thermal and hydro power plant operation in meeting the load demand optimally.
4. Discuss about single area load frequency control and two area load frequency control. 5. Apply their knowledge in PSOC for competitive exams like GATE,IES and PSUs etc.
MODULE-I (15 Hours)
Load Flow Studies: Network model formulation, Y bus formation(MATLAB) and singular matrix transformation,
Load flow problem, Gauss Seidel (GS) method, Newton-Raphson method (NR) (Polar, Rectangular form),
Decoupled, Fast Decoupled load flow and comparison(Chalk duster class room teaching). Concept of DC loads
flow.(Topics on Gauss Seidel (GS) method, Newton-Raphson method (NR) and Y bus formation will be
through classroom teaching and MATLAB & Power world simulator)
MODULE-II(20 Hours)
Economic System Operation: Generator operating cost:- input-output, Heat rate and IFC curve, Constraints in
operation, Coordinate equation, Exact coordinate equation, Bmn coefficients, transmission loss formula(Chalk
duster class room teaching), Economic operation with limited fuel supply and shared generators, Economic
exchange of power between the areas(media presentation). Optimal unit commitment (MATLAB)and reliability
considerations(Chalk duster class room teaching)
Automatic Generation and control: Load frequency control problem, Thermal Governing system and transfer
function(media presentation),Steam Turbine and Power system transfer function, Isolated power system:- static
and dynamic response , PI control and implementation. (Simulink)
Two area load frequency control, static and dynamic response, Frequency biased Tie line Bias control-
implementation and effect, Implementation of AGC(media presentation), AGC in restructured power
system(media presentation), under frequency load shedding, GRC, Dead band and its effect. (Most of the topics
will be through video presentation)
MODULE-III(15 Hours)
Power System Stability: Types of Stability Study, Dynamics of synchronous machine(media presentation),
Power angle equation, Node elimination technique(Chalk duster class room teaching), Simple Systems, Steady
state stability(media presentation), Transient stability(media presentation), Equal area criteria and its
applications, Numerical solution of swing equation, Modified Euler’s method. (Most of the topics will be through
video presentation and MATLAB programming)
Text Books: 1. Kothari. D. P, Nagrath. I. J., Modern Power System Analysis, TMH Publication, Third Edition, 2008
2. Kothari. D. P, Nagrath. I. J., Power System Engineering, TMH Publication, Second Edition, 2008
3. George Kausic. Computer Aided Power System Analysis, Prentice Hall Publication.2008
4. Chakrabarti .A, Halder. S, Power System Analysis- Operation and Control, PHI, Second Edition 2008.
5. Allen. J. Wood., Bruce. F. Wollenberg., Power Generation operation and Control, Wiley India, Second Edition,
2007.
6. PrabhaKundur , Power System Stability and Control , TMH Publication,2008.
Reference Books: 1. Soman. S. A, Kharphade. S. A, and SubhaPandit Computer Methods for Large Power System Analysis, an Object
Oriented Approach, Kluwer Academic Publisher New York 2001
2. Anderson P.M, Fouad A.A, Power System Control and Stability, Wiley Inter-Science, 2008 Edition
3. Kimbark E W, Power System Stability, Volume I, and III, Wiley Publication.
4. Jr W.D. Stevenson., G. J. Grainger. Elements of Power System. Mc-Graw-Hill Publication
5. HadiSaadat, Power System Analysis, TMH Publication ,Second Edition, 2002
Module 1
Sl.
No
Topic Pedagogy Details Instructional Hrs
Theory+T
utorial
Practice Video Project
1 Load Flow Studies
2 Network model
formulation
CRT
Chalk duster class
room teaching
2 0 0 0
3 Y bus formation and
singular matrix
transformation
CRT+PRA Chalk duster class
room
teaching+MATLAB
2 2 0 0
4 Load flow problem,
Gauss Seidel (GS)
method
CRT+PRA Chalk duster class
room
teaching+MATLAB
2 2 0 0
5 Newton-Raphson
method (NR) (Polar,
Rectangular form)
CRT+PRA Chalk duster class
room
teaching+MATLAB
2 1 0 0
6 Decoupled, Fast Decoupled load flow
and comparison.
Concept of DC loads
flow.
CRT Chalk duster class room
teaching+PPT
2 0 0 0
Sub Total 10 5 0 0
Module 2
Sl.
No
Topic Pedago
gy
Details Instructional Hrs
Theory Practice Video Project
1 Economic System Operation-
2 Generator operating cost:- input-output, Heat
rate and IFC curve
CRT
CRT
2 0 0 0
3 Constraints in operation, Coordinate equation, Exact coordinate equation,
CRT 1 0 0 0
4 Bmn coefficients, transmission loss formula CRT 1 0 0 0
5 Economic operation with limited fuel supply
and shared generators, Economic exchange of
power between the areas.
CRT CRT +
PPT +
Videos
2 0 0 0
6 Optimal unit commitment and reliability
considerations
CRT CRT + e-
content
2 0 0 0
7 Automatic Generation and control: PPT PPT +
Videos
1 0 0 0
8 Load frequency control problem
PPT PPT + e-
content
1 0 0 0
9 Thermal Governing system and transfer
function
CRT+
Media
Present
ation
e-content
+ CRT
1 0 0 0
Sl.
No
Pedago
gy
Details Instructional Hrs
Theory Practice Video Project
10 Steam Turbine and Power system transfer
function, Isolated power system:- static and
dynamic response , PI control and
implementation.
CRT+
Media
Present
ation
CRT
3 0 0 0
11 Two area load frequency control, static and
dynamic response,
2 0 0 0
12 Frequency biased Tie line Bias control-
implementation and effect, Implementation of
AGC
CRT CRT 2 0 0 0
13 AGC in restructured power system, under
frequency load shedding,
CRT+
Media
Present
ation
PPT 1 0 0 0
14 GRC, Dead band and its effect. CRT CRT 1 0 0 0
Module 3 Sub Total 20 0 0 0
Power System Stability:
2
1 Types of Stability Study, Dynamics of
synchronous machine
CRT+
Media Present
ation
PPT+
Videos
2 0 1 0
2 Power angle equation, CRT e-content 2 0 0 0
3 Node elimination technique CRT CRT 2 0 0 0
4 Simple Systems, Steady state stability,
Transient stability,
CRT e-content
+ PPT
2 0 0 0
5 Equal area criteria and its applications, CRT 2 0 0 0
6 Numerical solution of swing equation CRT CRT 1 0 0 0
7 Modified Euler’s method CRT 1 0 0 0
Sub Total 14 0 1 0
PCEL4201 Power System Protection
Credits: 04 Total Hrs: [50]
Course Objective
To make students conversant with Power plant and Power system protection practice, as per Indian Electricity Act,
Electricity rule.
Course outcomes:
Students will learn fundamentals of protection in a system i.e. for reasons of safety the protection will work
when control fails.
How the different protection schemes work. The logic of a protection scheme.
Details of different protective equipments & instrument transformer
how power plants (hydro-thermal-solar-wind) works in integration with power grid,
what are the risk in system/machines & how to mitigate risk
Modern Protection schemes
Module-I (16 Hours)
Introduction: Need for protective scheme, nature and cause of faults, types of faults, effect of faults, zones of
protection, primary and back-up protection, classification of protective relays, classification of protective
schemes, CT & PT for protection, basic relays terminologyOperating principles and relay construction:
Technique to produce time delays, Thermal relays Comparators and signal mixing-introduction, replica
impedance, mixing transformer or circuits, phase and amplitude comparators-classification, general equation for
comparator
Module-II (16 Hours)
Over current Relays-introduction, instantaneous over current relays, time current relays, application of different
types of time-current characteristics, basic principles of time over current relays, practical circuit for time over
current relays
Differential relays-introduction, operating characteristics, restraining characteristics, types of differential relays,
Analysis of electromagnetic and static differential relays, static relay scheme
Directional relays-introduction, phase comparator directional units, amplitude comparator directional units,
inputs to static directional relays for maximum output. Distance relays-introduction, types of distance relays
Module-III (16 Hours)
Microprocessor Based Protective Relays (Numerical Relays): Introduction, Circuit interface and programme
algorithm of over current relays, Impedance, Mho relay relays
Circuit Breaker: Arc voltage, arc interruption, restriking and recovery voltage, current chopping, interruption of
capacitive current, classification of circuit breaker-oil CB, Air blast CB, SF6 CB, Vacuum CB, DC Circuit
Breakers.
Text Book: 1. Power System Protection and Switchgear by Badri Ram& D. N. Vishwakarma, Tata-McGraw-Hill Power System
2. Protection: Static Relays with microprocessor application by T. S. MadhavaRao, Tata-McGraw-Hill
Reference Books:
1. Power System Protection and Switchgear–B Ravindranath& M Chander–New Age International Publishers.
2. Fundamentals of Power system Protection–Y G Paithankar& S R Bhide, PHI Publishers.
Module I
S.
No.
Topic Pedagogy Details Instructional Hrs
Theory Practice video Project
1 Introduction: Need for protective scheme, nature
and cause of faults, types of faults, effect of faults,
zones of protection, primary and back-up
protection, classification of protective relays,
classification of protective schemes, CT & PT for
protection, basic relays terminology
CRT & Video
presentation
www.ge.com/r
elays/facult-
clearing#
3 1 1
0
2 Operating principles and relay construction:
Technique to produce time delays, Thermal relays
www.simens
.com/relay-
details
3 1 1 0
3 Comparators and signal mixing-introduction,
replica impedance, mixing transformer or circuits,
phase and amplitude comparators-classification,
general equation for comparator
CRT www.electroni
cs for
you.in/phase
comparisons
4 0 2 0
Sub total 10 2 4 0
Module II
S.
No.
Topic Pedagogy Details Instructional Hrs
Theory Practice video Project
1 Over current Relays-introduction, instantaneous
over current relays, time current relays,
application of different types of time-current
characteristics, basic principles of time over
current relays, practical circuit for time over
current relays CRT &
Video
presentation
www.ge.com/rel
ays/facult-
clearing# 3 1
1
0
2 Differential relays-introduction, operating
characteristics, restraining characteristics, types
of differential relays, Analysis of electromagnetic
and static differential relays, static relay scheme
www.simens
.com/relay-
details 3 1 1 0
3 Directional relays-introduction, phase
comparator directional units, amplitude
comparator directional units, inputs to static
directional relays for maximum output
CRT www.electronics
for you.in/phase
comparisons 3 0 0 0
4 Distance relays-introduction, types of distance
relays
www.nptel.com/
distanceprotecti
on
3
Sub total 12 2 2 0
Module III
S.
No.
Topic Pedagogy Details Instructional Hrs
Theory Practice video Project
1 Microprocessor Based Protective Relays
(Numerical Relays): Introduction, Circuit
interface and programme algorithm of Over
current relays, Impedance, Mho relay relays CRT & Video
presentation
www.ge.com/n
umerical-
relay 5 1 0
6
2 Circuit Breaker: Arc voltage, arc interruption,
restriking and recovery voltage, current chopping,
interruption of capacitive current, classification of
circuit breaker-oil CB, Air blast CB, SF6 CB,
Vacuum CB, DC CB
Telkltd.com
4 2 0 0
Sub total 9 3 0 6
PLEL4105 POWER SYSTEM ANALYSIS LAB
(Common with EEE)
Credits: 02 Total Hrs: [36]
Course Objectives:
-To introduce the concepts of power flow techniques.
--To provide the knowledge of reactive power flow control.
Course Outcomes:
On successful completion of this course, students will be able to:
-Make different power flow solutions for different techniques.
-Understand the different fault conditions under different short circuit studies.
List of Experiments: 1. Fault Analysis of 3-phase Alternator 2. Determination of Xd and Xq of 3-phase salient pole Synchronous motor
3. IDMT (Inverse Definite Minimum Time) relay characteristics
4. Determination of breakdown strength of oil by variable distance electrodes.
5. Determination of transmission line parameters. 6. Fault analysis (LL, LG, and LLL) of transmission lines.
Simulation Based (Using Matlab Or Any Other Software):
1. To obtain steady-state, transient and sub-transient short-circuit currents in an alternator. 2. To formulate the Y-Bus matrix and perform load flow analysis.
3. To compute voltage, current, power factor, regulation and efficiency at the receiving end of a three
phase Transmission line when the voltage and power at the sending end are given. Use П model. 4. To perform symmetrical fault analysis in a power system.
5. To perform unsymmetrical fault analysis in a power system.
6. Conduct a power flow study on a given power system.
EXPT.
No
Topic Pedagogy Details Instructional Hrs
Theory Practice Video Project
1 Fault Analysis of 3-phase Alternator PRAC
Hardware
0 3 0
2 Determination of Xd and Xq of 3-phase
salient pole Synchronous motor
PRAC 0
3 0
3 IDMT (Inverse Definite Minimum Time)
relay characteristics
PRAC 0
3 0
4 Determination of breakdown strength of
oil by variable distance electrodes
PRAC 0
3 0
5 Determination of transmission line
parameters
PRAC 0
3 0
6 Fault analysis (LL, LG, and LLL) of
transmission lines
PRAC 0
3 0
7 To obtain steady-state, transient and sub-
transient short-circuit currents in an
alternator
PRAC
Hardware
&
simulation
Practice
using
Simulink
0
3 0
8 To formulate the Y-Bus matrix and
perform load flow analysis
PRAC 0
3 0
9 To compute voltage, current, power
factor, regulation and efficiency at the
receiving end of a three phase
Transmission line when the voltage and power at the sending end are given. Use
П model
PRAC
0
3
0
10 To perform symmetrical fault analysis in
a power system
PRAC 0
3 0
11 To perform unsymmetrical fault analysis
in a power system
PRAC 0
3 0
12 Conduct a power flow study on a given
power system
PRAC simulation
Practice
using
Simulink
0
3 0
ELECTRICAL & ELECTRONICS ENGINEERING
PCEE4101 ELECTRICAL DRIVES
Credits: 04 Total Hours: [50]
Course Objectives:
-To provide students with a solid foundation in industrial application of drives so that they can analyze, design, solve
problems and participate successfully in the development activities of the industry. -To enhance their comprehending power in tackling complex situations in operation and control and be able to work
in multi-disciplinary projects.
-To make the students understand the basic concept and working of VFD used in industry.
-To train the students on the application of power electronics.
Course Outcomes:
On successful completion of this course, students will be able to:
-Demonstrate an ability to analyze in problems associated with electrical drives. .
-Can participate and succeed in competitive examinations like GATE, GRE.
-Will demonstrate knowledge of electrical drives.
-Able to perform the different speed control technique as per the requirement of industry.
Module-I (16 Hours)
1. Study of Motor Drives: Electrical Drives, Advantages of Electrical Drives, Electrical Motors, Power
Modulators, Choice of electrical Drives, Fundamentals of Torque Equations, Speed Torque Conventions
and Multi-quadrant Operation, Equivalent Values of Drive Parameters, Components of Load Torques,
Nature and Classification of Load Torques, Calculation of Time and Energy Loss in Transient Operations,
Steady State Stability, Load Equalization, Thermal Model of Motor for Heating and Cooling, Classes of
Motor Duty, Determination of Motor Rating.
Module-II (18 Hours)
2. Steady State Performance of DC/AC Drives: DC Motors and their Performances, Starting, Braking,
Speed Control, Methods of Armature Voltage Control, Transformer and Uncontrolled Rectifier Control,
Controlled Rectifier Fed DC Drives, Chopper Controlled DC Drives.
3. Induction Motor Drives: Speed Control, Pole Changing, Pole Amplitude Modulation, Stator Voltage
Control, Variable Frequency Control from Voltage Source, Voltage Source Inverter Control, Variable
Frequency Control from Current Source, Current Source Inverter Control, Current Regulated Voltage
Source Inverter Control, Rotor Resistance Control, Slip Power Recovery
Module-III (16 Hours)
4. Traction Drives: Nature of Traction Load, Calculation of Traction Drive Ratings and Energy
Consumption, Tractive Effort and Drive Ratings, Specific Energy Consumption, Maximum Allowable
Tractive Effort, Conventional DC and AC Traction Drives, 25 kV AC Traction using Semiconductor
Converter Controlled DC Motors, DC Traction employing Polyphase AC Motors, AC Traction
employing Polyphase AC Motors.
Text Books:
1. “Fundamentals of Electrical Drives”-By G.K.Dubey, Alpha Science International Limited, Pangbourne, UK,
Second Edition, 2001.
2. “Electric Drives-Concepts and Applications”- By VedamSubramanyam, Second Edition, Tata McGraw Hill
Publication, 2010-11.
Reference Book:
1. Modern Power Electronics and AC drives- by B.K.Bose, Pearson Education.
Module I
S.
No.
Topic Pedagogy Details Instructional Hrs
Study of Motor Drives: Theory Practice video Project
1 Advantages of Electrical Drives,
Electrical Motors, Power
Modulators, Choice of electrical
Drives, Fundamentals of Torque
Equations, Speed Torque
Conventions and Multi-quadrant
Operation,
CRT
presentation
With
animations for
the better
understanding 6+0 0 0 0
2 Equivalent Values of Drive
Parameters, Components of Load
Torques, Nature and Classification of
Load Torques, Calculation of Time and Energy Loss in Transient
Operations, Steady State Stability,
Load Equalization, Thermal Model
of Motor for Heating and Cooling,
Classes of Motor Duty,
Determination of Motor Rating.
CRT
presentation
6+4 0 0 0
Module II Total 16
Steady State Performance of DC/AC
Drives:
Motors and their Performances,
Starting, Braking
CRT
Presentation
practice Matlab
Simulink 3+1
Methods of Armature Voltage
Control, Transformer and
Uncontrolled Rectifier Control,
Controlled Rectifier Fed DC Drives,
Chopper Controlled DC Drives.
CRT
Presentation
practice
Matlab
Simulink and
hardware
4+2
Speed Control, Pole Changing, Pole
Amplitude Modulation, Stator
Voltage Control, Variable Frequency
Control from Voltage Source, Voltage
Source Inverter Control, Variable
Frequency Control from Current Source, Current Source Inverter
Control, Current Regulated Voltage
Source Inverter Control, Rotor
Resistance Control, Slip Power
Recovery Traction Drives:
CRT
Presentation
practice
Matlab Simulink
6+2
Module III Total 18
6
Nature of Traction Load, Calculation of Traction Drive Ratings and
Energy Consumption, Tractive Effort
and Drive Ratings, Specific Energy
Consumption, Maximum Allowable
Tractive Effort
CRT
Presentation 5+4
7
Maximum Allowable Tractive Effort,
Conventional DC and AC Traction
Drives, 25 kV AC Traction using
Semiconductor Converter Controlled
DC Motors, DC Traction employing
Polyphase AC Motors, AC Traction
employing Polyphase AC Motors.
CRT
Presentation 7
Total 16
PCEE4102 POWER SYSTEM ANALYSIS
Credits: 04 Total Hours: [50]
Course Objectives:
-To introduce the concepts of power flow techniques.
-To provide the knowledge of power system stability.
-To provide the knowledge of reactive power flow control.
Course Outcomes:
On successful completion of this course, students will be able to:
-Make different power flow solutions for different techniques.
-Understand the different fault conditions under different short circuit studies.
-Apply their knowledge in PSA for competitive exams like GATE, IES and PSUs etc.
MODULE-1 (16 Hours)
Power System Network Matrices
Graph Theory: Definitions, Bus Incidence Matrix, Ybus formation by Direct and Singular Transformation
Methods, Numerical Problems.Formation of ZBus: Partial network, Algorithm for the Modification of ZBus
Matrix for addition element for the following cases: Addition of element from a new bus to reference, Addition
of element from a new bus to an old bus, Addition of element between an old bus to reference and Addition of
element between two old Busses (Derivations and Numerical Problems).- Modification of ZBus for the changes
in network
MODULE-2 (20 Hours)
Power flow studies
Necessity of Power Flow Studies – Data for Power Flow Studies – Derivation of Static load flow equations –
Load flow solutions using Gauss Seidel Method: Acceleration Factor, Load flow solution with and without P-V
buses, Algorithm and Flowchart. Numerical Load flow Solution for Simple Power Systems (Max. 3-Buses):
Determination of Bus Voltages, Injected Active and Reactive Powers (Sample One Iteration only) and finding
Line Flows/Losses for the given Bus Voltages. Newton Raphson Method in Rectangular and Polar Co-Ordinates
Form: Load Flow Solution with or without PV Busses- Derivation of Jacobian Elements, Algorithm and
Flowchart. Decoupled and Fast Decoupled Methods. - Comparison of Different Methods – DC load Flow
MODULE-3 (18 Hours)
Short Circuit Studies
Per-Unit System of Representation, Per-Unit equivalent reactance network of a three phase Power System,
Numerical Problems. Symmetrical fault Analysis: Short Circuit Current and MVA Calculations, Fault levels,
Application of Series Reactors, Numerical Problems. Symmetrical Component Theory: Symmetrical Component
Transformation, Positive, Negative and Zero sequence components: Voltages, Currents and Impedances.
Sequence Networks: Positive, Negative and Zero sequence Networks, Numerical Problems. Unsymmetrical Fault
Analysis: LG, LL, LLG faults with and without fault impedance, Numerical Problems, Elementary concepts of
Steady State, Dynamic and Transient Stabilities, Description of: Steady State Stability Power Limit, Transfer
Reactance, Synchronizing Power Coefficient, Power Angle Curve and Determination of Steady State Stability
and Methods to improve steady state stability. Derivation of Swing Equation, Determination of Transient Stability
by Equal Area Criterion, Application of Equal Area Criterion, Critical Clearing Angle Calculation.- Solution of
Swing Equation: Point-by-Point Method. Methods to improve Stability - Application of Auto Reclosing and Fast
Operating Circuit Breakers.
TEXT BOOKS: 1. Computer Techniques in Power System Analysis by M.A.Pai, TMH Publications.
2. Modern Power system Analysis – by I.J.Nagrath & D.P.Kothari: Tata McGraw-Hill Publishing company, 2nd edition.
REFERENCE BOOKS: 1. Power System Analysis by Grainger and Stevenson, Tata McGraw Hill.
2. Power System Analysis – by A.R.Bergen, Prentice Hall, Inc. 3. Power System Analysis by Hadi Saadat – TMH Edition
Module I
S.
No.
Topic Pedagogy Details Instructional Hrs Theory Practice video Project
Graph Theory
1
Definitions, Bus Incidence
Matrix
CRT & e-
material
https://www.youtube.
com/watch?v=iP359
o1zYPs
1 0 0 0
2 Ybus formation by direct method CRT & e-
material
With E-Content &
NPTEL Video 2 0 0 0
3 Ybus formation by Singular
transformation method
CRT, e-
material &
Practice
With E-Content,
NPTEL Video&
Software- MATLAB
2 1 0 0
4
Formulation of ZBUS:Partial
Network
CRT, e-
material &
Practice
With E-Content,
NPTEL Video&
Software- MATLAB
1 1 0 0
5
Algorithm for the Modification
of ZBus Matrix for addition
element
CRT & e-
material
With E-Content &
NPTEL Video 1 0 0 0
6 Addition of element from a new
bus to reference
CRT & e-
material
With E-Content &
NPTEL Video 2 0 0 0
7 Addition of element from a new
bus to an old bus
CRT & e-
material
With E-Content &
NPTEL Video 1 0 0 0
8 Addition of element between an
old bus to reference bus
CRT & e-
material
With E-Content &
NPTEL Video 2 0 0 0
9
Addition of element between
two old Busses, Modification
of ZBus for the changes in
network.
CRT & e-
material
With E-Content &
NPTEL Video 2 0 0 0
Sub total 14 02 0 0
Module II
S.
No.
Topic Pedagogy Details Instructional Hrs
Power flow studies Theory Practice video Project
1 Necessity of Power Flow Studies CRT & e-
material
With E-Content &
NPTEL Video
1 0 0 0
2 Data for Power Flow Studies CRT & e-
material 1 0 0 0
3 Derivation of Static load flow equations CRT & e-
material 1 0 0 0
4 Load flow solutions using Gauss Seedel
Method: Acceleration Factor
CRT, e-
material &
Practice
2 1 0 0
5 Load flow solution with and without P-
V buses, Algorithm and Flowchart
CRT, e-
material &
Practice
1 1 0 0
6 Numerical Load flow Solution for
Simple Power Systems
CRT & e-
material 1 0 0 0
7 Determination of Bus Voltages CRT & e-
material 1 0 0 0
8
Injected Active and Reactive Powers (Sample One Iteration only) and finding
Line Flows/Losses for the given Bus
Voltages.
CRT & e-
material 1 0 0 0
9
Newton Raphson Method in
Rectangular and Polar Co-Ordinates
Form
CRT, e-
material &
Practice
With E-Content,
NPTEL Video&
Software-
MATLAB
2 1 0 0
10
Load Flow Solution with or without PV
Busses- Derivation of Jacobian
Elements
CRT & e-
material
With E-Content &
NPTEL Video 1 0 0 0
11 Algorithm and Flowchart
CRT, e-
material &
Practice
With E-Content,
NPTEL Video&
Software-
MATLAB
2 1 0 0
12 Decoupled and Fast Decoupled Methods
CRT & e-material
With E-Content & NPTEL Video
1 0 0 0
13 Compcomparison of Different Methods – DC
load Flow
CRT & e-
material
With E-Content &
NPTEL Video 1 0 0 0
Sub total 16 4 0 0
Module III
S. No. Topic Pedagogy Details Instructional Hrs
Theory
+Tutorial Practice video
Project
1
Per-Unit System of Representation, Per-Unit
equivalent reactance network
of a three phase Power System
CRT & e-
material
With E-Content
& NPTEL Video 2 0 0 0
2
Symmetrical fault Analysis,
Short Circuit Current and
MVA Calculations
CRT & e-
material
With E-Content
& NPTEL Video 1 0 0 0
3 Application of Series
Reactors
CRT & e-
material
With E-Content
& NPTEL Video 1 0 0 0
4 Symmetrical Component
Transformation
CRT, e-
material &
Practice
With E-Content,
NPTEL Video&
Software-
MATLAB
1 1 1 0
5
Positive, Negative and Zero
sequence components,
Voltages, Currents and
Impedances.
CRT, e-
material &
Practice
With E-Content,
NPTEL Video&
Software-
MATLAB
2 1 0 1
6 Positive, Negative and Zero sequence Networks
CRT & e-material
With E-Content & NPTEL Video
1 0 0 0
7
LG, LL, LLG faults with and
without fault impedance,
Numerical Problems.
CRT, e-
material &
Practice
With E-Content,
NPTEL Video&
Software-
MATLAB
1 1 0 0
8
Elementary concepts of
Steady State, Dynamic and
Transient Stabilities
CRT & e-
material
With E-Content
& NPTEL Video 1 0 0 0
9
Steady State Stability Power
Limit, Transfer Reactance,
Synchronizing Power
Coefficient
CRT & e-
material
With E-Content
& NPTEL Video 1 0 0 0
10
Power Angle Curve and
Determination of Steady State
Stability and Methods to improve steady state stability.
CRT & e-
material
With E-Content
& NPTEL Video 1 0 0 0
11
Derivation of Swing
Equation, Point-by-Point
Method. Methods to improve
Stability.
CRT, e-
material & Practice
With E-Content,
NPTEL Video&
Software- MATLAB
2 1 0 0
Subtotal 14 4 0 0
PLEL4105 POWER SYSTEM ANALYSIS LAB
(Common with EE)
Credits: 02 Total Hours: [36]
Course Objectives:
-To introduce the concepts of power flow techniques.
--To provide the knowledge of reactive power flow control.
Course Outcomes:
On successful completion of this course, students will be able to:
-Make different power flow solutions for different techniques.
-Understand the different fault conditions under different short circuit studies.
List of Experiments:
7. Fault Analysis of 3-phase Alternator
8. Determination of Xd and Xq of 3-phase salient pole Synchronous motor
9. IDMT (Inverse Definite Minimum Time) relay characteristics
10. Determination of breakdown strength of oil by variable distance electrodes.
11. Determination of transmission line parameters.
12. Fault analysis (LL, LG, and LLL) of transmission lines.
Simulation Based (Using Matlab Or Any Other Software):
7. To obtain steady-state, transient and sub-transient short-circuit currents in an alternator.
8. To formulate the Y-Bus matrix and perform load flow analysis.
9. To compute voltage, current, power factor, regulation and efficiency at the receiving end of a three phase
Transmission line when the voltage and power at the sending end are given. Use П model.
10. To perform symmetrical fault analysis in a power system.
11. To perform unsymmetrical fault analysis in a power system.
12. Conduct a power flow study on a given power system.
EXPT
. No
Topic Pedagogy Details Instructional Hrs
Theory Practice Video Project
1 Fault Analysis of 3-phase Alternator PRAC Hardware 0 3 0
2 Determination of Xd and Xq of 3-phase
salient pole Synchronous motor PRAC Hardware 0 3 0
3 IDMT (Inverse Definite Minimum Time)
relay characteristics PRAC Hardware 0 3 0
4 Determination of breakdown strength of
oil by variable distance electrodes PRAC Hardware 0 3 0
5 Determination of transmission line
parameters PRAC Hardware 0 3 0
6 Fault analysis (LL, LG, and LLL) of
transmission lines PRAC Hardware 0 3 0
7
To obtain steady-state, transient and
sub-transient short-circuit currents in
an alternator
PRAC
Hardware &
simulation
Practice
using
Simulink
0 3 0
8 To formulate the Y-Bus matrix and
perform load flow analysis PRAC 0 3 0
9
To compute voltage, current, power
factor, regulation and efficiency at the
receiving end of a three phase
Transmission line when the voltage and
power at the sending end are given. Use
П model
PRAC 0 3 0
10 To perform symmetrical fault analysis
in a power system PRAC 0 3 0
11 To perform unsymmetrical fault
analysis in a power system PRAC 0 3 0
12 Conduct a power flow study on a given
power system PRAC 0 3 0
PLEE4106 ELECTRICAL DRIVES LAB
Credits: 02 Total Hours: [36]
Course Objectives:
-To provide students with a solid foundation in industrial application of drives so that they can analyze, design, solve
problems and participate successfully in the development activities of the industry.
-To enhance their comprehending power in tackling complex situations in operation and control and be able to work
in multi-disciplinary projects.
-To make the students understand the basic concept and working of VFD used in industry.
Course Outcomes:
On successful completion of this course, students will be able to:
-Demonstrate an ability to analyze in problems associated with electrical drives. .
-Will demonstrate knowledge of electrical drives.
-Able to perform the different speed control technique as per the requirement of industry.
1. Study of torque-speed characteristics of separately excited DC motor from single phase full converter.
2. Study of torque-speed characteristics of armature voltage controlled of separately excited DC motor from
single phase full converter
3. Study of torque-speed characteristics of separately excited DC motor from three phase full converter
4. Study of torque-speed characteristics of DC series motor using chopper.
5. Three phase induction motor speed control using slip power recovery scheme.
6. V/F Control of induction motor.
7. open loop speed control of separately excited DC motor using chopper at high frequency.
8. Three phase induction motor speed control using rotor resistance control
9. Simulation of chopper fed DC drive using MATLAB/SIMULINK.
10. Simulation of variable frequency induction motor drive using MATLAB/SIMULINK
11. Simulation of three phase converter fed separately excited DC motor control using
MATLAB/SIMULINK.
12. Simulation of t single phase converter fed separately excited DC motor control using
MATLAB/SIMULINK.
Expt.
no
Topic Pedagogy Details Instructional Hrs
Theory Practice Video Project
1
Study of torque-speed characteristics of
separately excited DC motor from
single phase full converter
PRAC
Hardware &
simulation
Practice
using
Simulink
0 3 0
2
Study of torque-speed characteristics of
armature voltage controlled of
separately excited DC motor from
single phase full converter
PRAC 0 3 0
3
Study of torque-speed characteristics of
separately excited DC motor from three
phase full converter
PRAC 0 3 0
4 Study of torque-speed characteristics of
DC series motor using chopper PRAC 0 3 0
5
Three phase induction motor speed
control using slip power recovery
scheme
PRAC 0 3 0
6 V/F Control of induction motor PRAC 0 3 0
7
open loop speed control of separately
excited DC motor using chopper at high
frequency
PRAC 0 3 0
8 Three phase induction motor speed control using rotor resistance control
PRAC 0 3 0
9 Simulation of chopper fed DC drive
using MATLAB/SIMULINK PRAC 0 3 0
10
Simulation of variable frequency
induction motor drive using
MATLAB/SIMULINK
PRAC 0 3 0
11
Simulation of three phase converter fed
separately excited DC motor control
using MATLAB/SIMULINK
PRAC 0 3 0
12
Simulation of t single phase converter
fed separately excited DC motor control
using MATLAB/SIMULINK
PRAC
simulation
Practice
using
Simulink
0 3 0