All Sylabuss of HNDE(Electrical & Electronic Engineering )

7/25/2019 All Sylabuss of HNDE(Electrical & Electronic Engineering )

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D e m o c ra t i c S o c i a l i s t R e p u b l i c o f S r i L a n kaM i n i s t r y o f H i g h e r E d u ca t i o n

S r i L a n ka I n s t i t u t e o f A d va n ce d T e ch n o l o g i ca l E d u ca t i o n(S L I A T E )

ENHANCEMENT AND UPGRADING OF TECHNICAL EDUCATION

AT MATTAKULIYA ADVANCED TECHNOLOGICAL INSTITUTE

AND

LABUDUWA ADVANCED TECHNOLOGICAL INSTITUTE

FINALREPORT

PHASE 2-SYLLABUS

SEMESTER SYSTEM

ELECTRICAL AND ELECTRONIC

ENGINEERING

MARCH 2010

BY


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1. Key to the Subject Code

MA Mathematics

EN - English

IT - Information Technology

CE - Civil EngineeringEE - Electrical, Electronics and Telecommunication Engineering

ME - Mechanical Engineering

2. Guide to the Four Digit Code

First Digit - Academic Year (1or 2 or3 for the three respective years)

Second Digit - Semester (1 or 2)

Third and Fourth Digit - Number for a Module for a respective Division the

module is offered. It starts with 01 and increases.

Example.

CE2113 Offered by the Civil Engineering Department (Code is CE)Second Year (First Digit = 2)

First Semester (Second Digit = 1)

13th

Module out of the Total number of Modules offered by the CivilEngineering Department during total of 06 Semesters (03 Academic

Years) [Third & Fourth Digit = 13]

3. Guide to the Remarks Column

C,E,M Common Module for all three Disciplines (i.e. Civil, Electrical, Mechanical)

C, E Common to Civil and Electrical

C, M Common to Civil and Mechanical

E, M Common to Electrical and MechanicalC Civil only

E Electrical only

M Mechanical only

4. Other Abbreviations

Pro Production

R & A Refrigeration and Air Conditioning

Auto Automobile

MR Marine

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Curriculum

ELECTRICALandELECTRO

NIC

ENGINEERING

F

irstYear

SemesterI

Item

Code

Title

Remarks

LT

P

1

MA1101

EngineeringMathematics

C,E,M

30

2

2

3

2

EN1101

English

C,E,M

60

2

2

4

6

3

IT1101

InformationTechnologyI

C,E,M

75

2

3

3

9

4

ME1101

WorkshopEngin

eeringI

C,E,M

60

1

3

2

12

5

ME1102

EngineeringDra

wing

C,E,M

60

1

3

2

20

6

CE1102

FluidMechanics

C,M

90

2

1

3

3

23

7

EE1107

ElectricalPrinciplesA

E

90

2

1

3

3

27

8

ME1103

EngineeringMechanics

C,E,M

90

2

1

3

3

31

555

14

320

18

4

37

22

F

irstYear

SemesterII

Item

Code

Title

Remarks

LT

P

1

MA1202

AppliedEnginee

ringMathematics

C,E,M

30

2

2

36

2

EN1202

WorkshopEngin

eeringII

C,E,M

60

1

3

2

39

3

ME1205

EngineeringGra

phicsandAutoCAD

C,E,M

60

1

3

3

43

4

EE1208

ElectricalPrinciplesB

C,E,M

60

2

2

3

46

5

EE1209

ElectronicCircuitsandSystemsI

E

90

4

2

4

50

6

EE1210

Microelectronic

SystemsI

E

75

2

3

3

54

7

EE1211

TelecommunicationPrinciples

E

90

2

1

3

3

59

8

EE1212

IntroductiontoC

omputerSystems

E

60

2

2

2

63

9

EN1202

EnglishforProfessionals

C,E,M

60

2

2

3

66

585

18

120

22

3

39

25

SriLankaInstituteofAdvan

cedTechnologicalEducation

MinistryofHigherE

ducation,

SriLanka

HigherNationalDiplomainEngineering(HNDE)

CreditsperSemester

Total

Hours

Weekly

Distribution

TotalHrsperWeek

Weekly

Distribution

TotalHrsperWeek

CreditsperSemester

Page

Number

None

GPA

Credits

GPA

Credits

Total

Hours

GPA

Credits

None

GPA

Credits

Page

Number

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1

Sri Lanka Institute of Advanced Technological Education

Ministry of Higher Education, Sri LankaHigher National Diploma in Engineering

ELECTRICAL and ELECTRONIC ENGINEERING

Learning Outcomes

Knowledge on the use matrix algebra techniques in practical engineeringapplications.

Student will be knowledgeable in the area of infinite series and their convergenceso that he/ she will be familiar with limitations of using infinite seriesapproximations for solutions arising in mathematical modeling

Familiar with the functions of several variables which is needed in many branches

of engineering

Possession of the concepts of improper integrals, Gamma, Beta and Error

functions which are needed in engineering applications Acquaint with the mathematical tools needed in evaluating multiple integrals and

their usage

Syllabus

1. Matrices

Characteristic equation Eigen values and Eigenvectors of a real matrix Properties ofEigen values and eigenvectors Cayley-Hamilton Theorem Diagonalization of

matrices Reduction of a quadratic form to canonical form by orthogonal transformation

Nature of quadratic forms.

Module Number MA1101 Title Engineering Mathematics

Year First Year Semester 01

Number of Hours 30 Credit

Hours

02

Hours Per Week:

Theory 02 Tutorial Practical Filed

Visits(Other)

Day /Time/Hall

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2. Infinite Series

Sequences Convergence of series General properties Series of positive terms

Tests of convergence (Comparison test, Integral test, Comparison of ratios andDAlemberts ratio test) Alternating series Series of positive and negative terms

Absolute and conditional convergence Power Series Convergence of exponential,logarithmic and Binomial Series.

3. Functions of Several VariablesIndeterminate forms and L Hospitals rule, successive differentiation of one variable andLeibnitz theorem,

Limit and Continuity Partial derivatives Homogeneous functions and Eulers

theorem Total derivative Differentiation of implicit functions Change of

variables Jacobians Partial differentiation of implicit functions Taylors seriesfor functions of two variables Errors and approximations Maxima and minima of

functions of two variables Lagranges method of undetermined multipliers.

4. Improper Integrals

Improper integrals of the first and second kind and their convergence Evaluation of

integrals involving a parameter by Leibnitz rule Beta and Gamma functions

Properties Evaluation of integrals using Beta and Gamma functions Errorfunctions.

5. Multiple Integrals

Double integrals Change of order of integration Double integrals in polar

coordinates Area enclosed by plane curves Triple integrals Volume of Solids Change of variables in double and triple integrals Area of a curved surface. Mass

center of gravity and moment of inertia of two and three-dimensional bodies.

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Recommended Textbooks

1. Grewal B.S., Higher Engineering Mathematics (40th

Edition), Khanna Publishers,Delhi (2007).

2. Ramana B.V., Higher Engineering Mathematics, Tata McGraw Hill Co. Ltd.,

New Delhi (2007).

3.

Jain R.K. and Iyengar S.R.K., Advanced Engineering Mathematics (3

rd

Edition),Narosa Publications, Delhi (2007).

4. Bali N., Goyal M. and Watkins C., Advanced Engineering Mathematics (7th

Edition), Firewall Media, New Delhi (2007).5. Greenberg M.D., Advanced Engineering Mathematics (2

nd Edition), Pearson

Education, New Delhi (1998).

Schedule of Lectures (to be prepared by the Lecture and approved by the module

coordinator to be distributed to the students on the day of commencement of the module):

Week Topic Hours Lecturer Resource

Person/

Remarks

01

02

0304

05

06

07

08

09

10

11

12

13

1415

16

17

18 End Semester Exam

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Learning Outcomes To enable learners of English as an additional language to increase phonological

accuracy by developing an awareness of the features of English pronunciation, bycomparing learner language with the target language using real world and digital

media.

To extend and apply English language learning strategies to improve listening and

speaking skills in a range of task-focused situations.

Syllabus

1. Further Development of Grammar from the Intensive Program

Review of tenses, conditional statements, question tags, use of time expressions, time

expressions- past of present perfect.

2. Focus on Pronunciation

- Strategies for improving accuracy in pronunciation

- Articulation of sounds- Phonological patterning

- Pitch and intonation patterns

- Features of connected speech

3. Spoken English in Practice

- Strategies for autonomous language learning

- Vocabulary acquisition strategies- Word formation principles

- Listening to and reading transcriptions of spoken material in a range of contexts

- Strategies and skills related to practical speaking tasks- Social and cultural contacts withspeakers of English on campus and in the community

Module Number EN 1101 Title English


GPA None GPANumber of Hours 60 Credit

Hours

04

Hours Per Week:

Theory 04 Tutorial Practical FiledVisits(Other)

Day /Time/Hall

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4. Writing sentences

Sentence level accuracy, types of sentences and clauses; sentence structure issues, useof appropriate vocabulary, narration/description, note making, formal and informal

letter writing, editing a passage

5. Language Laboratory activities

Introduction to the Sounds of English- Vowels, Diphthongs & Consonants,

Introduction to Stress and Intonation, Situational Dialogues / Role Play, OralPresentations- Prepared and Extempore, 'Just A Minute' Sessions (JAM), Describing

Objects / Situations / People, Information Transfer, Debate, Telephoning Skills,

Giving Directions.

Recommended Software:

1. Cambridge Advanced Learners' English Dictionary with CD.2. The Rosetta Stone English Library

3. Clarity Pronunciation Power

4. Mastering English in Vocabulary, Grammar, Spellings, Composition5. Dorling Kindersley series of Grammar, Punctuation, Composition etc.

6. Language in Use, Foundation Books Pvt Ltd with CD.

7. Learning to Speak English - 4 CDs8. Microsoft Encarta with CD

9. Murphy's English Grammar, Cambridge with CD

Books to be procured for English Language Lab Library (to be located within the lab

in addition to the CDs of the text book which are loaded on the systems):

1. Spoken English (CIEFL) in 3 volumes with 6 cassettes, OUP.

2. English Pronouncing Dictionary Daniel Jones Current Edition with CD.

3. Spoken English- R. K. Bansal and J. B. Harrison, Orient Longman 2006 Edn.4. A Practical course in English Pronunciation, (with two Audio cassettes) by J.

Sethi, Kamlesh Sadanand & D.V. Jindal, Prentice-Hall of India Pvt. Ltd., New Delhi.

5. A text book of English Phonetics for Indian Students byT.Balasubramanian (Macmillan)

6. English Skills for Technical Students, WBSCTE with British Council, OL

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Week Topic Hours Lecturer ResourcePerson/ Remarks

01

02

03

04

05

06

07

08

09

1011

12

13

14

15

16

17


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Learning OutcomesOn completion of this module the students will be able to acquire a fundamental

knowledge of computer systems and database handling, create professional quality

spreadsheets and technical drawings.

Syllabus

1. Introduction to Computers 2hrs

Types of computers , Main Components of a Computer, Central Processing Unit, Main

Memory, Input and Output Devices, Ergonomics

of computer construction

2. Data Representation in the Computer 4hrs

Numerical Data Representation, Character Representation, Memory Capacity, Information

storage in the main memory.

3. Secondary Storage Devices 3hrs

Use of secondary storage devices., Hard Disks, Floppy Disks, Optical Disks and Magnetic

Tapes

4. Categories of Software 3hrs

Hardware, Software and Firmware, System Software and Application Software., Types of

system software, Packaged Software and Custom-Written Software

5. Database Systems 6hrs

Database Management Systems, Hierarchical Database, Network Database, Relational

Database, Object-Oriented Database

6. System Software 4hrs

The Operating System, CPU Management, File Management, Task Management, Operating

Systems: Linux, DOS, Windows and its applications and Network Operating Systems

Module Number IT1101 Title Information Technology I



Hours

03

Hours Per Week:

Theory 02 Tutorial Practical 03 FiledVisits(Other)

Day /Time/Hall

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7. Spreadsheet Applications 4 hrs

Work sheet, work book, row number, column letter, cell and an active cell, reference area.,

Numbers, Label and Formulae, Copying data, moving data, inserting, deleting, moving

columns and rows, formatting cells, Functions., Macros., Multiple work sheets., Charts.

8. The World Wide Web 4 hrs

The Web and how it works, Browser, Web Portals, Multimedia on the Web, FTP, Telnet,

Newsgroup,

Recommended Textbooks/Reading

1. Computer and Information Processing, D D Spencer.

2.

Using the World Wide Web D A Wall3. Microsoft Office 97 Professional Edition, M L Swanson

4. Information Technology; A practical course Harriet.Hraper

Practical List1. Operation of Computers and devices

2. Word Processing

3. Spread Sheets

4.

Data Bases

5. Internet

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Person/

Remarks

01

02

03

04

05

06

07

08

0910

11

12

13

14

15

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Ministry of Higher Education, Sri Lanka

Higher National Diploma in Engineering


Learning Outcomes

Knowledge on Workshop safety, operations, procedures, tools

Knowledge and skills on handling of machine tools and accessories

Knowledge and skills on Material processing for product design and manufacture

Syllabus

1. Introduction to workshop processes, tools and safety

a. The need for studying workshop technology, illustrations of different types of

workshops (i.e. mechanical, electrical, electronics, etc.) types of workshop processes,overview of the tools/machinery/equipment, accepted operational procedures in different

workshops.

b. workmans trade; craftsmanship, the working of materials, economics of production

c. Standards; purpose, creation of standards, advantages, SI units, ISO

d. Machine Tools; general, lathe, mill, shaper, bench and column drills, hand drills,

electric hand drills, saws, welding equipment.

e. Safety and accident prevention; causes of accidents, behavior, hygiene, housekeeping,

clothing, proper protective gear, harmful substances, start-stop controls, precautions,

lifting appliances, storage, electrical safety, lubrication and coolants,

f. Fire Fighting; Legal provisions, the fire fighting triangle, inflammable substance,

oxygen, heat(ignition temperatures), preventive fire protection, structural fire protection,

Module Number ME 1101 Title Workshop Engineering IYear First Year Semester 01

GPA None GPANumber of Hours 60 Credit Hours 02

Hours Per Week:

Theory 01 Tutorial Practical 03 Filed Visits(Other)

Day /Time/Hall

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preventive measures, conduct in case of fire, portable and other fire extinguishers,

testing, operational status and maintenance of protocols.

g. supply and handling of material.

2. Measuring

Methods of Measuring; direct measuring instruments, indirect measuring instrumentsAccuracy of MeasuringTypes of Instrument

oRule; types of rule; metric, precision steel rule, folding rule

oStraight edgeoCalipers

oVernier caliper gauge; external measuring, internal and depth measurements

oGraduation of the vernier scale; reading the vernier scaleoVernier depth gauge

o

Vernier protractoroExternal micrometer caliper; reading the micrometer scaleo

Dial gauge

FitsTerminologyoMating surfaces

oSizes; design size, tolerance, deviation, limits, actual size, clearance fit, interference

fit, transition fitoFree dimensions

oTolerance gradesoLimit gauges; Go- not go gap gauge, Go-not go plug gauge, taper gauges, Feeler

gauges, Radius gauges

Marking out Tools

Scriber, center punch, surface plates and tables, surface gauge, scribing block, try square,

protector, dividers, vernier height gauge, rule stand, box square, center finder, odd-leg

calipers, trammels, Parallel marking gauge, bubble level, templates.

3. Engineering Materials

a. Classification (different types);

Metals Ferrous & Non-Ferrous

Plastics Thermoplastics, Thermo sets, Elastromers

Ceramics & Other,

Composites

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Structure of Materials; atomic bonds, crystalline structure, deformation and strength of

single crystals, grains and grain boundaries, plastic deformation of PolycrystallineMetals,

Steels;

Production of Iron and Steel, Casting of Ingots, Continuous Casting, Alloy Steels,Stainless Steels, Tool and Die Steel.

Nonferrous Metals and Alloys;

Aluminum and Aluminum Alloys, Magnesium and Magnesium Alloys, Copper and

Copper Alloys, Nickel and Nickel Alloys, Super alloys, Titanium and Titanium Alloys,Refractory Metals and Alloys, Beryllium, Zirconium, Low-melting Alloys, Precious

Metals, Shape-Memory Metals, Amorphous Alloys.

Plastics;

Structure of Plastics, Thermoplastics, Thermo sets, Additives, General Properties andApplications of Thermoplastics, General Properties and Applications of Thermosetting

Plastics, Elastomers (Rubbers)

Composite Materials;

Structure of Reinforces Plastics, Properties of Reinforced Plastics, Applications, Metal-Matrix and Ceramic-Matrix Composites, Honeycomb Structures.

b. Mechanical Behavior, Manufacturing Properties, Failure;Tension, Compression, Torsion, Bending, Hardness, Fatigue, Creep,

c. Physical Properties;

Density, Melting Point, Specific Heat, Thermal Conductivity, Thermal Expansion,

Electrical and Magnetic Properties, Corrosion Resistance

d. Metal Alloys;

Structure, Phase Diagrams, Iron-Carbon Diagrams, Iron-Iron Carbide Phase Diagram and

Development of Microstructures in Steels, Cast Irons, Heat Treatment of Ferrous Alloys,Harden ability of Ferrous Alloys, Heat Treatment of Nonferrous Alloys and Stainless

Steels, Case Hardening, Annealing, Heat-Treating Furnaces and Equipment.

4. Basic Workshop Operations and Tools

Common clamping devicesParallel-jaw vice, Blacksmiths vice, Toolmakers clamp, Machine vice, Hand vice, Pipe

vice, Other clamping devices, vice attachments, safe use of clamping devices.

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Hammering;Hammers; riveting, hand, sledge Tinsmmiths and other special purpose hammersHammer-like tools; flatter, fuller, convex set hammer, Smiths chisel

Hammer construction and use of hammersPurpose of hammeringo

Materials which are easily shapedoMaterials which are difficult to shape

Hammer handlesAccidents with the hammer

StraighteningChanges in dimension

Methods of straightening

oStraightening by hand; main tools usedoStraightening with a straightening machine

o

Straightening by the application of heat

BendingChanges in structure, effect of cross sectionThe bending radius; factors affecting the bending radiusMaterials with good bending propertiesMarking tools

Bending methods

SawingDefinitionHandsaws for metal

o

Hacksaw; hacksaw blades, tension file

oCoping sawoMechanics saw

oSheet sawThe saw bladeo

Material with design featuresoTooth spacing

Working with a saw

oSecuring the bladeoApplication

Power saws; jig saw, horizontal blade saw, circular saw, power hacksaw

Safety

ChiselingThe purpose of chiseling

Chisel manufacture

Common chisels; flat chisel, cross-cut chisel, drift punch, punching chisel, grooving

chisel, hole punch

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ChiselingChisel sharpening (Grinding)Accident Prevention

FilingThe file;o

ClassificationoType of cut; single-cut file, double-cut file, Rasp-file

oType of width of cut; single-cut (mill saw file, Double-cut file, Raspo

File classification by gradeStandard file nomenclature

oType of file

oFile cross sectionoSecuring the work-piece for file

Filing work

oBody positionoMovement of the file

o

ApplicationSecuring the file handleCare of the file

ScrapingPurposeScraper blade

Types of scraperScraping flat surfacesCoating with marking paste

Grinding

Grinding Methods

oFlat surface grindingoCylindrical grinding (internal and external)

oHand grindingTool Grinding; Grinding wheels, cup and dish wheels, different shapes of grinding

wheelWheel Construction

oGrinding wheels

types of bonding material; vitrified bonding, synthetic resin bonding, rubberbonding

Types of abrasive; natural abrasive, artificial abrasive, fused alumina

Particle size; abrasive particles, size classification, wheel structureWheel hardness; grading

Factors in wheel selection; guide to wheel selection, material to be ground, type of

grinding, bonding agent, abrasive and colour

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RivetingDefinition, purpose, examples of rivet types & shapes of rivet heads

types of joint; lap-joint and butt-jointriveting classification; structural, machine and pressure vessel

Rivet materials; steel, brass, plastic, copper and aluminumRivet form, rivet proportion, rivet holes, marginRiveting methods; cold forming, hot formingLoad capacity of a riveted joint; joint in single shear and joint in double shearRiveting faults, safety precautions.

ShearingHand shears; curved shears, slitters, bench (hand operated) shears

Selection of shearsBench shearsSafety precautions

DrillingTypes of drill; flat, twistDrill construction; types of steel, point and clearance angles, helix angles; standard

helix drill, slow helix drill, quick helix drillSecuring the drillTaper-shank drills; securing taper-shank drills, grades of taper

Deep-hole drillsSecuring the work-pieceFactors affecting the drilling operation

Cutting speed

Feed rate; drill grinding drill grinding jig and grinding faultsCutting fluids; soluble oil; straight cutting oils; mineral and fatty-oil mixtures

sulphurized oilsSafety and accident prevention

Countersinking and Counter-Boring

Countersink, cutting angle, counter-bore, spot-face cutter, center drill, three and four

groove (flute) twist drills

Reaming

Parallel reamers, hand reamers, adjustable reamers, taper reamers, shell reamers, material

allowance, reaming speed, lubricants, and safety precaution

ThreadsTypes of screw thread; V-thread, acme thread, round thread, buttress thread, square

thread

Screw thread termsThread types; ISO metric formsTaps; types of tap wrench, tap set, bottoming taps, nut tap, Cutting external threads

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DiesPipe stocksRatchet die stock

Table of ISO metric threadsLubricants

Nuts, Bolts and AccessoriesTypes of fasteningsScrew and bots as fastenerso types of screw bolt; Machine screws and bolts, special purpose bolts, wood screws,

nuts examples of uses

oMarking; example of ISO markingsScrew Locking; locking devices, compression devices, mechanical devices, examples

of mechanical devices, permanent and semi-permanent devices, examples of

permanent and semi-permanent lockingPoint design

Tightening; screwdrivers, spanners, examples of common types of spanner and theirapplication, proper use

Pins and dowelsoPin fastening; dowel pins, securing pins, shear pins

oTypes of pins and dowels; parallel dowels, fitting a parallel dowel, taper pin or

dowelsoFitting tapered dowels

oSlotted dowels

oFitted bolts.

SolderingSoldering process,

Soft solder abbreviations, composition and melting pointForms of soft solder; flux materials, flux material containing acid, acid-free flux

materials

Soldering irons; types, gals blowlampSoldering procedure; preparation, procedure, causes of defective soldered joints on

printed circuit boardsSafety

Hardening

Safety rules for hardening, heat treatment, the laws of structural change of unalloyed

steel, steel, hardening, tempering, annealing of steel, heat treatment of light metals,devices for annealing and hardening, fault in heat treatment, hard metals (sintered

carbides), temperature measurement in hardening, hardness tests

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1. Workshop Technology Part I, Part II and Part III; W A Chapman

2. Production Technology, Processes Materials and Planning; W Bolton

Practical List

Lecture(s) has the choice of selecting workshop practical provided form the list provided

separately for different disciplines (i.e. Civil, Mechanical, Electrical) depending on themachines, tools, raw material available and the depth of practice needed. However, it is

advised to conduct separate hands on session during the semester break of first two years

with at least for Mechanical Engineering students.




Person/

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01

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0304

05

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10

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Learning Outcomes

Familiarization with the signs, conventions, abbreviations symbols and other

relevant tools of the universal language of Engineering Drawing that is used to

convey the engineering or manufacturing details/specifications of physical

objects with precision that no other existing universal language either written

or spoken with or without the assistance of photographs or pictorial sketches

can convey.

Ability to originate own design drawings and to read the design drawings

made by others.

Syllabus

1. Introduction

Basic Concepts, writing and reading, lines and lettering, method of expression,

methods of shape, description of Orthographic and Pictorial views, Units Sections,

Intersections, Developments

2.

Description and use of Instruments

Selection and Use, Scales and use of scales, Preparation of Drawings, Lettering

3. The Alphabet of Lines

Types of lines, Line gauges, Geometry of Straight Lines, Parallels, Perpendiculars,

Tangents, Tangent Points, Circles, Curves, Bisections, Trisections, Divisions,

Angles,

4. Orthographic Projections and Sketching

Methods of Projection-Classification, Definition and views, Six Principal views,

Combination of views, Three Space Dimensions, Representation of Lines,Freehand Sketching, Reading of Drawings.

Module Number ME 1102 Title Engineering Drawing



Hours

02

Hours Per Week:

Theory 01 Tutorial Practical

(Drawing)

03 Filed

Visits(Other)

Day /Time/Hall

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5. Auxiliary Views

Basic Concepts, Classification of Surfaces, Skew Surfaces.

6. Sectional Views

Definition, Classification,Auxiliary Sections, Sections Showing Arms, Ribs, Lugs,Crosshatching, Aligned Sections, Conventional Breaks and Symbols.

7. Pictorial Drawing and Sketching

Comparison with orthographic drawings, Isometrics, Perspective Drawings,

Oblique Projection, Sketching the Axes.

8. Dimensions, Notes, Limits and Precision

Lines and Symbols, Selection of Distances, Placement of Dimensions, Standard

Features, Precision and Tolerances, Production Methods.

Drawing Practice

Nine, 03 Hour Drawing Sessions to give students the adequate practice to grasp

each of the above 08 topics

Recommended Textbooks/Software

1. Siddheshwar, Machine Drawing, Tata-McGraw Hill.

2.

K. L. Narayana and P. Kannaiah, Machine Drawing,New Age International

Ltd

3. Textbook On Engineering Drawing Engineering Graphics, (Paperback -2005),

Narayana KI, Kannaiah P

4. Engineering Drawing, (Paperback 2008), Shah PJ.

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coordinator to be distributed to the students on the day of commencement of the

module):


Person/

Remarks

01

02

03

04

05

06

07

08

09

10

11

12

13

14

15

16

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Learning Outcomes

understand the basic principles governing the dynamics of non-viscous fluids

be able to derive and deduce the consequences of the equation of conservation of

mass

be able solve kinematics problems such as finding particle paths and streamlines

be able to apply Bernoulli's theorem and the momentum integral to simple

problems including river flows

calculate velocity fields and forces on bodies for simple steady and unsteadyflows derived from potentials

Syllabus

1. Static fluid systems

Immersed surfaces: rectangular and circular surfaces (eg retaining walls, tank sides,

sluice gates, inspection covers, valve flanges)

Centre of pressure: use of parallel axis theorem for immersed rectangular and circular

immersed surfaces

Devices: hydraulic presses; hydraulic jacks; hydraulic accumulators; braking systems;

determine outputs for given inputs

Module Number CE1102 Title Fluid Mechanics



Hours

03

Hours Per Week:

Theory 02 Tutorial 01 Practical 03 Filed

Visits(Other)

Day /Time/Hall

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2. Viscosity

Viscosity: shear stress; shear rate; dynamic viscosity; kinematic viscosity

Viscosity measurement: operating principles and limitations of viscosity measuring

devices (e.g. falling sphere, capillary tube, rotational and orifice viscometers)

Real fluids: Newtonian fluids; non-Newtonian fluids including pseudoplastic,

Bingham plastic, Casson plastic and dilatent fluids

3. Flow of real fluids

Head losses: head loss in pipes by Darcys formula; Moody diagram; head loss due tosudden enlargement and contraction of pipe diameter; head loss at entrance to a pipe;

head loss in valves; flow between reservoirs due to gravity; hydraulic gradient;siphons; hammer blow in pipes

Reynolds number: inertia and viscous resistance forces; laminar and turbulent flow;

critical velocities

Viscous drag: dynamic pressure; form drag; skin friction drag; drag coefficient

Dimensional analysis: checking validity of equations such as those for pressure atdepth; thrust on immersed surfaces and impact of a jet; forecasting the form of

possible equations such as those for Darcys formula and critical velocity in pipes

4. Fluid Dynamics

Introduction to Navier-Stokes Equation, Euler equation of motion along a stream line,

ernoullis equation, application of Bernoullis equation to Pitot tube, Venturi meter, Orifices,

Orifice meter, Triangular Notch & Rectangular Notch .(Without considering Velocity of

Approach)

5. Hydraulic machines

Impact of a jet: power of a jet; normal thrust on a moving flat vane; thrust on a

moving hemispherical cup; velocity diagrams to determine thrust on moving curvedvanes; fluid friction losses; system efficiency

Operating principles: operating principles, applications and typical system

efficiencies of common turbomachines including the Pelton wheel, Francis turbineand Kaplan turbine

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Operating principles of pumps: operating principles and applications of reciprocating

and centrifugal pumps; head losses; pumping power; power transmitted; systemefficiency


1. Frank M.White, Fluid Mechanics, McGraw Hill Publication.

2. James A. Fay., Introduction to Fluid Mechanics

3. Cengel & Cimbla Fluid Mechanics, TATA McGraw-Hill

4. Kumar K. L., Engineering Fluid Mechanics, S.Chand & Company Ltd, Eurasia

Publishing House

5. R.K. Rajput Fluid Mechanics & Hydraulic Machines, S.Chand & Company Ltd.

Practical List

1. Study of Pressure Measuring devices.

2. Determination of viscosity of liquids and its variation with temperature.

3. Stability of floating bodies and optimum loading capacity

4. Drawing Flow Net by using Electrical Analogy method.

5. Verification of modified Bernoullis equation.

6. Calibration of Venturimeter / Orifice meter.

7. Determination of hydraulic coefficients of orifice.

8. Calibration of notch (Triangular / Rectangular).9. Laminar and Turbulent flows by Reynoldss apparatus.

10. Flow around immersed bodies, point of stagnation, formation of wake etc by Haleshaw

apparatus.

11. Determination of Friction Factor for Laminar and Turbulent flow through pipes of

different materials.

12. Determination of minor losses due

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ScheduleofLectures(tobepreparedbytheLectureandapprovedbythemodulecoordinatorto

bedistributedtothestudentsonthedayofcommencementofthemodule):

Week

Topic

Hours

LecturerResource

Person/

Remarks

01

02

03

04

05

06

07

08

09

10

11

12

13

14

15

16

17

18

EndSemesterExam

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1



Electrical and Electronic Engineering

Module Number EE1107 Title Electrical Principles A



Hours

Hours Per Week:


Visits(Other)

Day /Time/Hall

Learning Outcomes:

On the completion of this module the student will be able to acquire the fundamental

knowledge of Basic Electricity, form a basis for advanced studies in Electrical

Engineering to be undertaken in the future

Syllabus

1. Kirchhoffs law 2 hrs

Kirchhoffs First Law, Kirchhoffs Second Law, Calculation of Mixed

Resistance Circuits by means of Ohms and Kirchhoffs Laws.

2. Work, Power and Efficiency 2 hrs

Mechanical Work (W), Mechanical Power (P), Electric Power (P),

Electrical Energy (WH), Efficiency ()

3.

The effect of Electric Current 2 hrs

Thermal Effect, Light Emission-Indirect light emission-Direct light

emission.

Magnetic effect, Chemical Effect, Physiological effects

4. Electrical Heating 1 hr

Joules law, Specific heat, Thermal efficiency

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5. Electro chemistry 1 hr

Fundamentals-Dissociation of an Electrolyte, Electrolysis and its

application, Faradays law, Further examples of Electrolysis

Metalloplastic Plating, Eloxal Process (Anodizing), Production of Pure

Metals

Electrochemical Voltage Sources, - Primary Cells, Electrolytic

polarization

Carbon Zinc Cell(Manganese Dioxide or Lecianche Cell)-Secondary

Cells, Accumulators General Description, Lead Acid Accumulators,

Capacity of Accumulators, Efficiency of accumulators, Types of charge

Steel accumulators. Acid Prevention

6.

Network theorems 2 hrsActive and passive networks, superposition theorem, Thevenins theorem

Nortons theorem

7. Electric Fields 1 hrStatic electricity, parallel plate capacitor, types of capacitors, Dielectric Strength

Charge Vs applied voltage, parallel & series connected capacitors, Electric force

and Electric flux density, potential gradient, composite dielectric capacitors

8. Electron Ballistics 1 hrForce on an isolated charge in an electric field, Movement of a free electron in

an electric field

9. Charging and Discharging Phenomena 1 hrCharging & discharging current for series CR circuit. Time Constants, Stored

energy in a capacitor, Force between oppositely charged plates

10.Magnetic Fields 2 hrsMagnetic poles, field strength, Magnetic Potential gradient, lines of magnetic

flux, magnetic Induction and magnetic screening

11.

Electromagnetism 1 hrRight hand grip rule or cork screw rule, Solenoid, toroid and force on a

conductor carrying current in a magnetic field, Flemings left hand rule, Lenzs

law

12.Magnetic Circuits 1 hrMmf, magnetizing force, Magnetic flux, Permeability of free space &r magnetic

Materials, Relative permeability, absolute permeability, Reluctance of a

magnetic circuits, magnetic leakage and fringing, Kirchhoffs laws for the

magnetic circuits, B-H curve, Hysterisis.

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13.Inductance in DC Circuits 1 hrInductive and non inductive circuits, inductance of a coil, inductance of a long

straight solenoid and a toroid coil, Step response for LR circuit (Charging &

decaying), energy stored in an inductive circuit, time constant of an inductive

circuit

14.Mutual Inductance 1 hrMutual inductance, Self inductance, coupling coefficient

15.Alternating Voltages and Currents 1 hrSine wave, Phase angle (lead/lag), frequency, speed and no. of pole pairs

Amplitude Alternating emf (single phase), Average, Peak and rms values of an

alternating current, rotating vector, Manipulations with AC quantities, vector

diagrams using rms values

16.

Single Phase Circuits 1 hrAnalysis of ac circuits with R, L, C, RLC in series & RLC in parallel, Phasor

diagrams, Power in ac circuits

17.Effect of Frequency in AC Circuits 1 hrSeries resonance, parallel resonance, active power and reactive power, power

factor using phase diagrams

18.Three Phase CircuitsThree phase generation, star and delta connection, line and phase voltage and

currents in a star connected system & delta connected system, power in three

phase system with balanced load

Recommended Text Books:

1 ElectricalCircuit Theory and Bird J

2 ElectricCircuits Nilsson J

3 BasicCircuit Analysis Johnson D

4 PowerSystem Analyses and Design Glover J and Sarma M

List of Practices

1. Verification of Kirchhoffs laws

2. Verification of Norton's and Thevenins Theorem .

3. RLC network in AC.

4. Q - meter/ Transformer O/C and S/C test

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Learning Outcomes

Understand the fundamentals of statics and dynamics.

Be proficient in using Statics and Dynamics to obtain solutions to engineering

problems.

Relate the fundamentals of Statics and Dynamics to practical applications.

Develop documentation skills and correct professional technique

Syllabus

1. Kinematics of a Particle

Units and Dimensions, Motion of Bodies, Rectilinear Motion of a Particle, Velocity of aParticle in Rectilinear Motion; Velocity, Distance Traveled, Acceleration, 3-D motion of

a particle, Basic Properties of Vectors, Vectorial representation of forces and moments ,

Vector operations.Velocity, acceleration in Plane motion, Centripetal Acceleration, Acceleration in 3-D

motion, Space, Time and Frames of Reference.

2. Fundamental Laws of Dynamics

Motion and interaction of Bodies, Force, Measuring Constant Forces, Coplanar Forces,

Resolution and Composition of forces, Equilibrium of a particle, Forces in space,

Equilibrium of a particle in space, Equivalent systems of forces , Principle oftransmissibility, single equivalent force, Newtons Second Law, Mass, Newtons Third

Module Number ME1104 Title Engineering Mechanics



Hours

03

Hours Per Week:


Visits(Other)

Day /Time/Hall

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Law, Forces and Newtons Second and Third Laws, Motion of a Body under the action of

given forces, Constrained motion under a body, Law of Conservation of Momentum,Transfer of Momentum from one body to another, Impulse of a Force, Motion of a Body

with Variable Mass.

3. Work and Energy

The Concept of Energy, Work and Energy, Work of a Force, Potential Energy of Strain,

Kinetic Energy of a Body, Perfectly Plastic Impact of Tow Bodies, Elastic Impact,

Impact of Non-elastic Bodies, Potential Energy, Change of Energy of a Body in theGravitational Filed, Low of Conservation of Energy

4. Relative Motion

Inertial Reference Frames, Motion of a Body in a Non-inertial System of Reference,

Inertia Forces, Inertia Forces Acting on a Body in a Rotating Frame of Reference,

Weightelessness, The Relationship Between the Vectors of Angular and Linear Velocityof a Paritcle, Inertia Forces Acting on a Body Moving in a Rotating Frame of Reference,

The Influence of the Earth Rotation on the Motion of Bodies

3. Motion of Rigid Bodies

Translational and Rotational Motions of a Rigid Body, Equilibrium Conditions of a Rigid

Body with a Fixed Axis of Rotation, Law of Dynamics for a Body Rotating About a

Fixed Axis, Angular Momentum, Kinetic Energy of a Rotating Body, Center of Gravity

and Centre of Mass of a Rigid Body, The Law of Motion of the Center of Mass of Body,Plane Motion of a Body, DAlemberts Principle, Rolling Motion of a Cylinder on a

Plane. Maxwellw Pendulum, Moments of Inertia of Bodies, Huygens-Steiner Parallel

Axes Theorem,

Kinetic Energy of a Body for Simultaneous Translatory and Rotational Motions, Free

Axis of Rotation, Kinematics of a Rigid Body, Moment of a Force about a Point andAngular Momentum of a Rigid Body, Angular Momentum of a Rigid Body and Moment

of Inertia, The Fundamental Law of Dynamics of a Rigid Body, Gyroscopes, Motion of

the Axis of Gyroscope, Motion of a Free Gyroscope, Gyroscopic Effect, Rotation of the

Axis of a Constrained Gyroscope, Motion of a Free Gyroscope

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4. Friction

Frictional Force, Laws of Coloumb friction, coefficient of static and kinetic friction

Simple Contact friction, Rolling and slipping,, Belt Friction. Introduction, dry friction,

fluid friction, semi lubricated friction, Screw friction, Simple clutches, Bearings,

5. Gravitational Attraction of Bodies

Law of Universal Gravitation, Inertial Mass and Gravitational Mass, Potential Energy ofGravitation, Basic, Laws of Celestial Mechanics, Motion of Earths Satellites and

Spaceships

Recommended Text Books :

1. Engineering Mechanics Dynamics; R S Hibbler

2. Engineering Mechanics Statics; J L Meriam and L G Kraige

3. Applied Mechanics; H Hannah, M J Hillier

4. Applied Mechanics and Strength of Materials; R S Khurmi

List of Practicals

1. Rotating Beams Apparatus

2. Inclined Plane

3. Compound Pendulum

4. Worm and Wheel Drive

5. Belt and Rope Friction

6. Screw Jack

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Schedule of Lectures (to be prepared by the Lecture and approved by the modulecoordinator to be distributed to the students on the day of commencement of the module):


Person/

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02

03

04

05

06

0708

09

10

11

12

13

14

15

16

17


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Curriculum

ELECTRICALandELECTRO

NIC

ENGINEERING

F

irstYear

SemesterI

Item

Code

Title

Remarks

LT

P

1

MA1101

EngineeringMathematics

C,E,M

30

2

2

3

2

EN1101

English

C,E,M

60

2

2

4

6

3

IT1101

InformationTechnologyI

C,E,M

75

2

3

3

9

4

ME1101

WorkshopEngin

eeringI

C,E,M

60

1

3

2

12

5

ME1102

EngineeringDra

wing

C,E,M

60

1

3

2

20

6

CE1102

FluidMechanics

C,M

90

2

1

3

3

23

7

EE1107

ElectricalPrinciplesA

E

90

2

1

3

3

27

8

ME1103

EngineeringMechanics

C,E,M

90

2

1

3

3

31

555

14

320

18

4

37

22

F

irstYear

SemesterII

Item

Code

Title

Remarks

LT

P

1

MA1202

AppliedEnginee

ringMathematics

C,E,M

30

2

2

36

2

EN1202

WorkshopEngin

eeringII

C,E,M

60

1

3

2

39

3

ME1205

EngineeringGra

phicsandAutoCAD

C,E,M

60

1

3

3

43

4

EE1208

ElectricalPrinciplesB

C,E,M

60

2

2

3

46

5

EE1209

ElectronicCircuitsandSystemsI

E

90

4

2

4

50

6

EE1210

Microelectronic

SystemsI

E

75

2

3

3

54

7

EE1211

TelecommunicationPrinciples

E

90

2

1

3

3

59

8

EE1212

IntroductiontoC

omputerSystems

E

60

2

2

2

63

9

EN1202

EnglishforProfessionals

C,E,M

60

2

2

3

66

585

18

120

22

3

39

25

Weekly

Distribution

TotalHrsperWeek

CreditsperSemester

Page

Number

None

GPA

Credits

GPA

Credits

Total

Hours

GPA

Credits

None

GPA

Credits

Page

Number

SriLankaInstituteofAdvan

cedTechnologicalEducation

MinistryofHigherE

ducation,

SriLanka

HigherNationalDiplomainEngineering(HNDE)

CreditsperSemester

Total

Hours

Weekly

Distribution

TotalHrsperWeek

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Learning Outcomes

acquaint with the concepts of vector calculus, needed for problems in all engineeringdisciplines

sound knowledge of techniques in solving ordinary differential equations that model

engineering problems

grasp the concepts of complex variables and relevance of complex functions inengineering problem analysis

understanding of the standard techniques of numerical solutions to engineering

problems.

knowledge of basic probability theory and will extend this into the real world ofapplied statistics.

Syllabus

1. Vector Calculus

Vector notations,Scalar and vector products,Triple products,Differentiation of vectors,Level surfaces, Directional derivatives, gradient, divergence and curl and their physical

meaning, vector operators and expansion formulae, Line, surface and volume integrations,

Theorems of Green, Stokes and Gauss, Application of vector calculus in engineering

problems, orthogonal curvilinear coordinates, expression of gradient, divergence

Module Number MA 1202 Title Applied EngineeringMathematics



Hours Per Week:

Theory 02 Tutorial Practical Filed Visits(Other)

Day /Time/Hall

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2. Differential Equations

Differential equations of first order and higher degree, Higher order differential equations

with constant coefficient, Rules for finding C.F. and P.I., Method of variation of

parameter, Cauchy and Legendres linear equations.

Simultaneous linear equations with constant coefficients: Linear dependence of solution,Removal of the first derivative-normal form, change of independent variable, single

integral differential equation. Various applications of higher order differential equations

in solution of engineering problem simple harmonic motion, free forced and dampedoscillations of springs and electrical circuits.

3. Analysis of Complex Variables

Limit continuity and differentiability of function of complex variables. Analytic functions.

Cauchy-Reimanns and Cauchys integral theorem, Moreras theorem , Cauchys Integralformula, Expansion of function of complex variables in Taylors and Laurents series,

singularities and poles. Residues theorem, contour integration, conformal mappings andits application, bilinear transformation.

4. Numerical Methods

Solution of equations in one variable, Successive substitution method, Method of false

position, Simple iterative method, Newton-Raphson method, Solution of simultaneous

linear equations; Jacobi method, Gauss Seidal method, Finite differences andinterpolation, Numerical differentiation, Numerical integration: Trapezoidal and

Simpsons rules, Runga-Kutta Method

5. Fundamentals of Probability & Statistics

Elementary probability theory, Conditional probability and Bayers theorem,

classification, tabulation and presentation of data, Measures of location and dispersion,Discrete and continuous probability distributions: Binomial, Poisons and Normal with

simple applications.

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1. Grewal B.S., Higher Engineering Mathematics (40th

Edition), Khanna Publishers,Delhi (2007).

2. Ramana B.V., Higher Engineering Mathematics, Tata McGraw Hill Co. Ltd.,

New Delhi (2007).

3.

Greenberg M.D., Advanced Engineering Mathematics (2

nd

Edition), PearsonEducation, New Delhi (1998).

4. Ronald. E. Walpole, & Raymond. H. Myers. Macmillan, Probability and Statistics

for Engineers and Scientists (6th

Edition). ISBN 0-02-424210-1.




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Learning Outcomes

Knowledge on Workshop safety, operations, procedures, tools

Knowledge and skills on handling of machine tools and accessories

Knowledge and skills on Material processing for product design and

manufacture

Syllabus

1. Sheet Metal work

Flat sheets, sheet metal used for covering, material characteristics (steel, Aluminium,

Duralumin, Copper, Zinc, Brass, Lead, Tin, Corrosion and corrosion protection;coating with oil and grease, painting and varnishing, enamel, plastic covering, metal

covering, dipping, electro-plating, spraying, chemically produced coatings, browning,

bonderising or Parkerizing, anodizing).

Marking with tools, templates, material usage

Cutting out (had shears, hand lever shear, machine shear, cutting with a chisel)

Making holes; punching machines.

Drilling of sheet metal, sawing and filling.

Module Number ME 1204 Title Workshop Engineering II



Hours Per Week:

Theory 01 Tutorial Practical 03 Filed Visits(Other)

Day /Time/Hall

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2

ShapingoStraightening of sheets

oBending by hand; turning edges (folding), bending

oBending and folding with machines; using folding machine, bending formula

(general), press brakes, tolling and bending machine

2. Turning

General; tidiness and the guidelines for tidiness and orderliness in order to prevent

accidents, safety on the lathe, turning, turning operation

Construction of the lathe; base, lathe bed, headstock (main spindle noses, external

screw and internal taper, steep Morse taper with slotted nut, cam lock design and

bayonet mounting with taper), tool carriage (principal components, the apron, lathewith reversing shaft, bathe with drag cable 10), tail stock, steadies (fixed steady,

traveling steady)

Devices for clamping the work pieces; purpose of the clamping devices, different

methodsoLocating between centers; different types of centre drilling as per DIN 332, center

drilling R48.5 DIN 332, centre drilling A48.5 DIN 332, centre drilling

B48.5 DIN 332.oTailstock centre; dead centre, live centre, revolving live centre, work piece driven

by lathe carrier, work piece driven with faceplate.oClamping in a chuck; three-jaw chucks, four-jaw chuck

o

Clamping on mandrels; simple mandrels.

The turning tooloTool angles; tool in the middle of the work piece, tool below the centerline,

greater clearance angle, smaller rake angle, tool above centerline

Turning tools; right-hand square nose tool; right cranked side tool, sintered carbides,

tool holder (multi-tool holders, quick release holder, clamping the tool, setting tool

height.

Tool materials

Cutting speeds

Knurling

Thread cutting

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3. Milling

General housekeeping principals, care of tools and equipment, prevention of accidents,

Classification and design of milling machines, types of drives used in milling machines,

mounting work pieces, mounting milling attachments, Milling techniques, operatingprocedures, operating parameters, cutting tools used for milling.

4. Gas Welding

Fusion welding, production of gases, safety precautions for gas welding and torch

cutting, physics of handling gas cylinders, classification of touches according to

construction, flames, accident prevention in gas welding, soldering brazing, torchcutting, simple testing methods, welding symbols, measuring welds, measures applied to

reduce deformation in gas-fusion welding,

5. Electric Welding

Safety regulations for arc welding, electric welding, welding electrodes, setting the

welding current, striking the arc, welding positions, are welding, common welds, welding

defects, weld testing methods

6.

Introduction to Metal Casting.

Solidification of Metals, Flow of Molten Metal in Molds, Furnaces and Melting

Practices, Casting Defects.


1. Workshop Technology Part I, Part II and Part III; W A Chapman2. Production Technology, Processes Materials and Planning; W Bolton

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Practical List

Lecture(s) has the choice of selecting workshop practical provided form the list providedseparately for different disciplines (i.e. civil, Mechanical, Electrical) depending on the

machines, tools, raw material available and the depth of practice needed. However, it is

advised to conduct separate hands on session during the semester break of first two years

with at least for Mechanical Engineering students.




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Ministry of Higher Education, Sri LankaHigher National Diploma in Engineering (Mechanical)


Learning Outcomes

Visualize 3-D shapes, there developments and intersection of 1-D, 2-D, and 3-D

objects with plane(s) or 3-D space.

Use of AutoCAD to produce engineering drawings with respective application inCivil, Mechanical and Electrical.

Syllabus

Part I Graphics

1. Graphic Geometry

Geometric Shapes, The Ellipse, Noncircular Curves, Parabola, Hyperbola, Cycloids,

Involutes, Spirals, Helices, Tangents to Curves, Development of Plane-faced Surface,

Cone Locus of Points, Lines and Planes (projections)

2. Surface Intersections

Intersections of Lines and Planes, Prisms, Pyramids, Curved Surfaces, Cylinders and

Cones with Lines and Planes, Intersection of Cylinders and Cones.

Module Number ME 1205 Title Engineering Graphics andAutoCAD



Hours Per Week:

Theory 01 Tutorial Practical

(Drawing)

03 Filed Visits(Other)

Day /Time/Hall

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3. Developed Views

Development of Prisms, Pyramids, Triangulation, Development of Connectors and

Transition Pieces, Development of Spheres, Joints, Connectors

Drawing Practice

Five, 03 Hour Drawing Sessions to give students the adequate practice to grasp each

of the above 03 topics.

Part II AutoCAD

Conduct of the 15 Lessons (under the Help menu) provided by the software during

the remaining 33 hours.

Through these 15 lessons it is envisaged to repeat the concepts covered in all the 08

topics of the Module ME 1102 Engineering Drawing conducted in the First Semester.

The advanced 3-D modeling will have to be covered under ME2111 AssemblyDrawingand Solid Modeling to be conducted in the Third Semester of second year.

(not relevant to Electrical Students)

Recommended Textbooks/Software

1. David I. Cook and Robert N. McDonnal, Engineering Graphics and Design withComputer Applications, Holt-Sounders International Editors.

2. Textbook On Engineering Drawing Engineering Graphics, (Paperback -2005),

Narayana KI, Kannaiah P3. Textbook on Engineering Drawing with CAD, (Paperback 2008), Shah, B.M.

4. AutoCAD (latest or available version)

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Learning Outcomes:

On the completion of this module the student will be able to acquire further knowledge of

Basic Electricity, form a basis for advanced studies in Electrical Engineering to be

undertaken in the future

Syllabus

1. Circuit analysis 5 hrsCircuit topology: circuit graph; tree; co-tree; Eulers equations and relationship to

mesh/nodal analysis (e.g. Meshes =B-N+1 and Nodal = N-1, non-planar circuits, etc)

Mesh and nodal analysis: methodical application of circuit laws (e.g. direct formulation

in matrix form, formulation as a set of simultaneous equations, Maxwells cyclic loop

currents, etc)

2.

Filters 3 hrsPassive low and high pass filters: filter design (e.g. normalized filter, de-normalized

filter,

Prototypes, Butterworth, Chebyshev) Second order active filters: e.g. Sallen and Key, bi-

quad, voltage control voltage source (VCVS), etc

Frequency response test: use of test equipment (e.g. transfer function analyzer, signal

generator, oscilloscope); frequency response of a filter (e.g. cut-off frequency, pass band

gain, stop band roll-off) l; use of computer simulation methods (e.g. frequency sweep,

Bode plots, etc)

Module Number EE 1208 Title Electrical Principles B



Hours

Hours Per Week:

Theory 02 Tutorial Practical 02 Filed

Visits(Other)

Day /Time/Hall

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3. Transmission lines 5 hrsSecondary transmission line parameters: evaluation of characteristic impedance and

propagation coefficient from the primary constants (e.g. loss free line, propagation

velocity, wavelength, phase delay, phase shift coefficient, attenuation coefficient)

Terminated lines: infinite line; correctly terminated line (e.g. voltage and currentDistribution, distortion)

Reflections on transmission lines: mismatched load (e.g. open circuit and short circuit

terminated lines, incident and reflected waves, reflection coefficient, standing waves)

Quarter wavelength matching stubs: impedance of loss free quarter wavelength stubs

(e.g. capacitive and inductive equivalence, open and short circuit stubs, use as basic

matching devices)

4.

Transients 3 hrs

transients are associated with changes of stored energy in inductors and

capacitors, response in an RLC at; under damped, over damped, criticallydamped, response obtained in an RLC circuit when step and sinusoidal voltage

function is applied, energy stored in the circuit, currents and voltages at t=o.

5.

Power system transients 3 hrsSurges: origin (e.g. lightning and switching operations); propagation and effects of

surges

(E.g. surge impedance, surge velocity, basic impulse level (BIL)); voltage and current

surges; reflection coefficient; propagation and reflection of surges at junctions of lines

and cables.

Bewley lattice diagram; circuit breaker transients. Control methods: components (e.g.

surge diverter, rod gap, expulsion tube)

6. Electrostatic and electromagnetic fields 4 hrselectric and magnetic properties of materials (e.g. dielectric strength, permittivity,

permeability, electric and magnetic flux density); application of the laws of Gauss,

Coulomb and Ampere to symmetrical systems of conductors to determine capacitance

and inductance (e.g. coaxial cylinders, parallel cylinders, etc) concepts associated with

analogous electrostatic field plotting techniques. Electric flux and equipotentials

7.

Energy Transfer 3 hrs

The principles of energy transfer with particular reference to electromechanical

conversion. Energy balance equation or are electrical system, power balance

equation, load conditions vs. losses and efficiency

8. Wave Propagation in Free Space 2 hrs

Understanding of how waves are propagated in free space. Maxwell's equation,

intrinsic impedance. Electromagnetic wave propagation in free space. Pointing

vector and the electric and magnetic field strengths for a plane wave, how a dipolecan propagate electromagnetic energy in free space.

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9. Fiber Optics 2 hrs

The principles involved in optical fiber communication. Light source and as a

light detector, bandwidth of optical fiber transmission systems.

Recommended Text Books:

1 ElectricalCircuit Theory and Bird J

2 ElectricCircuits Nilsson J

3 BasicCircuit Analysis Johnson D

4 Power System Analysis and Design Glover J and Sarma M

List of Practicles

1. Efficiency of Energy Conversion

2. Determination of RC Time Constants

3. Study of Simple AC Circuits

4. Study of MCBs & Fuses

5. Study of 2-wire DC line Model

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Learning Outcomes:


knowledge of Basic Electronics, form a basis for advanced studies in Electrical &

Electronics to be undertaken in the future

Syllabus

1. Semiconductor Materials 5 hrs

The structure of semiconductor crystals, The silicon atom, Intrinsic conductivity,

Doping of semiconductors, The construction of an N-type semiconductor, N-

silicon, The construction of a P-type semiconductor, P-silicon, PN-junction,Reverse biased, Forward biased

2. Semiconductor Diodes 5 hrs

Characteristic curve of a semiconductor diode, Testing semiconductor diodes,

Nominal values, limiting values and characteristic values for diodes, Examples

of limiting values for diodes, Examples of characteristics

Module Number EE1209 Title Electronics Circuits andSystems I



Hours

Hours Per Week:


Visits(Other)

Day /Time/Hall

50/206


52/207

2

3. Special Diodes 5 hrs

Zener diodes, General, Characteristic curve and circuit symbols for a Zener diode,The Zener effect, The avalanche effect, Application of Zener diodes, Capacitance

diodes or varactor diode

4. Power Supplies & Rectifiers 6 hrs

Half wave & full wave rectifiers, Accumulators Charging, discharging,

Ampere-hour capacity

5. Smoothing Circuits 4 hrs

C filter, LC Filter Section

6. Transistor Basics 5 hrs

Layer sequence, connecting electrodes, diode connections and circuit symbols, forNPN and PNP-transistors, The principle of operation of a PNP-transistor, Reverse

bias (base-collector diode), Increasing the voltage between emitter and base

7. Transistor Circuits 5 hrs

Basic transistor circuits, Common emitter circuits (connections), Common

collector circuits (connections), Common base circuits (connections),

Characteristic curve of transistors in a common emitter circuit, Measurementcircuits, Control characteristics, Input Output & Four-quadrant characteristics,

Transistor with collector load resistance, Transistor power loss (Ptot) , BJTSymbols & codes to identify BJTs, Transistor parameters, Leakage currents in

BJTs

8. Transistor Biasing 5 hrs

Biasing arrangement in C-B and C-E circuits of BJT, Load line equation for

transistor circuits, Q-point analysis

9. The Transistor As A Switch And Amplifier 4 hrs

The transistor as a switch, Calculation for a transistor switching stage, Direct

current amplification with a transistor, Power of the base dropping resistance,

Overriding control of a transistor switch, Darlington switching, The transistor asan amplifier

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10.Special Transistors 4 hrs

The field effect transistor (FET), The construction of a junction (barrier layer)field effect transistor (JFET), Operating principles of a junction field effect

transistor (N-channel type) space, charge (barrier layer), The MOS field effect

transistor (MOSFET) or insulated-gate FET (IGFET), The construction and

method of Operation of the MOS field effect transistor, The depletion type ornormally-on device, The enhancement type or normally-off device, Review of

the MOS-FET, Precautions when using MOSFETS, The uni- junction transistor

Construction, The Operation of a UJT, DC load line and analysis, AC load line inFET circuits

11.Combinational Logic 6 hrs

Number systems & codes, Basic logic gates and Boolean algebra, Combination

logic circuits & Minimization techniques, k-maps, Introduction to TTL & MOS,

Transistorized Monostables, Bistable & Astable devises

12.Sequential Logic 6 hrs

Sequential logic circuits, Optimization techniques

Recommended Texts:

1. Electronics Engineering; Schaum Series

2. Electronic Engineering; Schelling & Belove

3. Electronic Principles; Gray & Searle, Wily International

4. Electronic Circuits; Milman & Haukias

5. Principles of Electronics; J E Holding & M R Garvin

6. Digital Systems; R J Tocci,

7. Pulse & Digital circuits Milman & Taub, Mcgraw Hill

List of Practicles

1.

Synchronous counter circuit and asynchronous

2. 4-bit shift register design

3.

D/A Converter analysis

4. Design of decoder, encoder

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Week Topic Hours Lecturer ResourcePerson/ Remarks

01

02

03

04

05

06

07

08

09

1011

12

13

14

15

16

17


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1




Learning Outcomes:

Students are expected to gain the basic knowledge in Microprocessors and how instructionsexecute in Microprocessors. Also the knowledge of Bus Mechanisms and basic low level

programming.

Syllabus

1.

States and carrier distribution 1 hr

Density of states, Fermi-Direct distribution and Fermi-Level

2.

Equilibrant carrier concentrations 1 hr

Approximate solutions, Effective density of states, Alternative expression, Special cases,Example

3.

Carrier action 1 hr

Drift, Diffusion, Recombination-generation, Equations of state, Thermodynamicequilibrium versus steady state, Drift velocity versus electric field in Si, Hole andElectron drift current density

4. Diffusion and band bending 1 hr

Diffusion, Band bending, Hot-point probe measurement, Diffusion current, Particlediffusion, Total currents, Band bending and electrostatic variables,

5.

Relating diffusion coefficients and mobility 1 hrConstancy of Fermi-Level, Einstein relationship, Recombination and generation process

Module Number GC EE1210 Title Microelectronic Systems I


Number of Hours 75 Credit Hours

Hours Per Week:


Visits(Other)

Day /Time/Hall

54/206


56/207

2

6. Recombination and generation statistics 1 hr

Photo generation, Band gaps of common semiconductors, indirect thermalrecombination-generation, R-G statistics, Photoconductivity decay measurement

7.

Continuity equitation 1 hr

1-D Case, Minority carrier diffusion equations, Minority carrier diffusion length

8. PN-Junction electrostatics 1 hr

PN-junction fabrication, Examples, Quantative electrostatic relationships, Quantativeanalysis, Electrostatic potential

9.

Carrier injection under forward bias 1 hr

Equations explained, Deviations from the ideal

10.

Small-signal admittance 1 hr

Reverse bias junction or depletion layer capacitance, Forward bias diffusion or chargestorage capacity, forward and reverse bias conductance

11.Transient response 1 hr

Turn-off transient, ideal switching circuit, Diode current and voltage-time transients,Storage delay time, Transient response measurement

12.

BJT-Deviations from the ideal 1 hrBase-with modulation, Punch-trough, Avalanche multiplicator and break down

13.

BJT-transient response 1 hr

Transient response, Base current, idealized switching circuits, Analysis, Methods tospeed-up turn-off transients

14.

Schottky contact 1 hr

General, Ideal MS contacts, Energy band diagrams (MS), Schottky diode,Schottky diode I-V characteristics

15.MOS Basics 1 hr

General, MOSFET, MOSFET operation, Ideal MOS capacitor, Energy band diagram anddensity

16.MOS electrostatic: Quantitative analysis 1 hr

General, Electrostatic potential, Electrostatic parameters, Delta-depletion solution, Gate-voltage relationship

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3

17.MOS C-V characteristics 1 hr

General, p- and n-type Si, n-type Si, MOS-capacitor under accumulation, MOS-capacitorunder depletion, MOS-capacitor under inversion, Deep depletion

18.MOSFET 1 hr

General, NMOS, Threshold voltage for NMOS and PMOS, Shockley Model, Example,MOSFET small-signal equivalent circuit, MOSFET ac response, Characteristics MOS-C versus MOSFET

19.Non-ideal MOS 1 hr

General, Polysilicon gate MOS, Enhancement and depletion mode MOSFET`s

20.

CCD-DRAM hr

Charge coupled devices, Semiconductor memories, Concept of CCD-Imager, One

transistor DRAM cell

21.

Fabrication hr

General, Photographic process, Doping, Defects line break, Industrial issues

22.Microprocessor System Fundamentals. 1 hr

Block diagram of a typical microprocessor system, capability of controlling aprocess, temporary and permanent information in a microcomputer, the operatorand the operand of an instruction,

Basic purposes of ; Instruction Register , Program Counter (PC), Store AddressRegister, Accumulator, Arithmetic and Logic Unit (ALU), Status register,Control and Timing Devices

Fetch & Execution of instruction.

23.Microprocessor Instructions and Programming 2 hrs

Instruction execution, Fetch and execute cycle, Addressing modes and

Instruction types, Machine and timing cycles, Brief description of Z 80,8088,6800,6502 processors 80486 processor / PI, PII, PIII, PIV, Algorithms and flowcharts for simple problems

24.

Programming in Machine Code 2 hrs

Structure of an Instruction Set, Data Transfer Group, Arithmetic and LogicGroup, Conditional jumps and branch instructions, simple programs using 1 and2 byte instructions, entering the programs into the SDK85 kit, checking andexecution the programs. Verification of the contents of relevant registers.

Flaw chart and resting demonstration program, Identification of moos; Implied,Immediate, Direct, Indexed/indirect, Relative

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4

25.

Program creation at machine code level 1 hr

Flow chart to solve a problem, successful programming through algorithms,

Need of some software to load and execute a simple program, the trace table..

26.Instruction sets 1 hr

The main types. Data Transfer Group, Arithmetic and Logic Group, Test andBranch Group, the type of addressing, more complicated programs make use ofother forms of addressing.

27.

Programs with loops 2 hrs

A loop as a body of program which is repeated a number of times, a program

containing a loop, loop controls, operand, jump instruction,

28.CPU and store. 1 hr

Operation & storage characteristics of a store , Chip Select /Enable, Read/ WriteControl, Data and Address Lines, storing of data or instruction or garbage.

29.Bus Mechanisms. 1 hr

Data address and control bus. Bidirectional data flow, actively' connectedinformation at any one time, a tri-state device, usage a truth table, providing

signals from a control device and control actions; read, write, store or input/outputrouts.

Rec. Readings1. Computer System Architecture M. Morris Mano

2. Microprocessor Architecture, Programming and Applications Ramesh S. Goanker

3.

Modern Operating Systems Andrew S. Tanenbaum4. Hardware Bible Winn L. Rosch

5. The design & Analysis of Computer Algorithms Aho/Hopcroft/Ullman

6. Systems Programming John J. Donovan

List of Practicals

1. Input/Output and Data Transfer2. Micro Computer Hardware Configuration

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Week Topic Hours Lecturer ResourcePerson/

Remarks

01

02

03

04

05

06

07

08

0910

11

12

13

14

15

16

17


58/206


60/207

1




Learning Outcomes:


knowledge of Telecommunications, form a basis for advanced studies in Electrical &Electronics to be undertaken in the future

Syllabus

1. Communication systems 7 hrs

Elements of analogue and digital communication systems: the transmitter

(information source), the channel and the receiver (eg wired and wirelesssystems; simplex, duplex and half-duplex methods)

Characteristics of electro-magnetic waves: frequency (f), wavelength () and

velocity (v) and their interrelationship; the electro-magnetic spectrum andfrequency/wavelength allocations

Signal spectra: time and frequency domains; fundamental and harmonic

frequencies; complex waveforms; digital signals (eg unipolar, bipolar, return-to-zero (RTZ), non-return to-zero (NRZ))

Module Number GC EE1211 Title Telecommunications

Principles


Number of Hours 90 CreditHours

Hours Per Week:


Visits(Other)

Day /Time/Hall

59/206


61/207

2

Logarithmic relationships: the need for logarithmic representation; the Decibel

and its common derivatives (eg dBm, dBW and dBR) and typical applicationsincluding link budgets

2.

Communication channels and t

Documents

All Sylabuss of HNDE(Electrical & Electronic Engineering )