department of electrical & electronics …m).pdf · specialization involving complex...

CBCS CURRICULUM (2016 -17) (Regulation – C)

Program Name: BE-Electrical and Electronics Engineering

Controlled Copy Rev 00/01.10.2012

DEPARTMENT OF ELECTRICAL & ELECTRONICS ENGINEERING

(For the Batches Admitted From 2017-2018)

OUTCOME BASED

EDUCATION SYSTEM




VISION

MISSION

To sustain our identity as a leader in

maritime education through progressive

innovation in training, research and

development that will render a brilliant

future for our student and transformative

impact on the global society.

To deliver technical knowledge and ethical

values with uncompromising strides of

excellence that will make our students

employable, our faculty advance their

knowledge, our staff achieves excellence

and our alumni become global leaders.

DEPARTMENT VISION AND MISSION

VISION

MISSION

To become a model department for higher

learning and research of international

eminence through development of

highly competent and dynamic Marine

Electrical and Electronics Engineers

while remaining sensitive to ethical,

societal and environmental issues.

To impart quality education of

international standards and to produce

highly innovative Marine Electrical

and Electronics Engineers

To transform the Department into

Centre of Excellence by promoting




research and development,

consultancy work and industry-

institute interaction activities.

Mapping of University Vision and Mission to Department Vision and Mission

Pre-eminence among the world‘s Maritime Universities by

University Vision and Mission Department Vision and

Mission

High Quality education through delivery

of technical knowledge and ethical

values to the students

Students would excel which will make

them employability and emerge as a

global leaders

Faculty shall advance knowledge

through Research and development




PROGRAM EDUCATIONAL OBJECTIVES (PEOs)

AND

PROGRAM OUTCOMES (POs)




PROGRAM EDUCATIONAL OBJECTIVES (PEOs)

Our graduates will,

• PEO1: Become competent by applying their technical and managerial skills.

• PEO2: Adapt to any environment and succeed in higher positions in marine electrical

engineering field .

• PEO3: Update the breadth of knowledge and engage themselves in the life-long learning

process to meet all challenges.




Program Outcomes POs Description

PO1 Apply knowledge of mathematics, science and engineering in their

specialization involving complex engineering problems.

PO2 Analyze a problem, identify, formulate and solve engineering problems

using basic fundamental principles of mathematics and science.

PO3 Design a system component or process to meet the desired needs and

standards within realistic constraints such as public health and safety,

social and environmental considerations.

PO4 Design and conduct experiments, as well as do research, analyze and

interpret data and give clear solutions.

PO5 Use and learn the limitations involved in recent techniques, skills and

modern engineering tools necessary for engineering practice.

PO6 Assess the local and global impact of engineering solutions on

individuals, organization and society and the consequent

responsibilities relevant to their professional engineering practice.

PO7 Understand the impact of the professional engineering solutions in

societal and environmental contexts and demonstrate the knowledge of,

and need for sustainable development.

PO8 Understand the professional and ethical responsibilities and norms of

engineering practice.

PO9 Work with multi-disciplinary teams, involve in team activities and

accomplish a common goal.

PO10 Communicate effectively with engineering community for presentation,

documentation of reports adopting the design standards.

PO11 Understand engineering and management principles and apply these to

one‘s own work, as a member and leader in a team, to manage projects

and in multi-disciplinary environments.

PO12 Meet contemporary issues and create advance technologies and will be

engaged to lifelong learning in the broadest scale.




Program Specific Outcomes

PSOs Description

PSO1 Attain proficiency in mathematics, physical science and also excel in

problem solving by operating as a team to find solutions of various issues in

the core area of Marine Electrical and Electronics Engineering.

PSO2 Operate effectively in a professional environment by executing quality

Marine Electrical works in on board ships and applying modern tools and

techniques. PSO3 Achieve excellence in outstanding leadership in Marine Electrical

Engineering position and passion for lifelong learning and research in

advanced fields




Mapping of PEO’s with PO’s

S. No Program Educational Objectives

PO

1

PO

2

PO

3

PO

4

PO

5

PO

6

PO

7

PO

8

PO

9

PO

10

PO

11

PO

12

PS

O1

PS

O2

PS

O3

1. Become competent by applying their

technical and managerial skills.

2. Adapt to any environment and succeed in

higher positions in marine electrical

engineering field.

3. Update the breadth of knowledge and

engage them in the life-long learning

process to meet all challenges.




List of Courses for the Program (Semester wise)

SEMESTER : I

S.

No

Course Code Course Title Cate-

gory

Contact

Hours

L T P C M

THEORY

1. UCLEC01 Technical English-I HS 2

2 0 0 2 100

2. UBMTC01 Engineering Mathematics-I BS 4 3 1 0 4 100

3. UCPHC01 Engineering Physics-I BS 3 3 0 0 3 100

4. UBCHC01 Engineering Chemistry BS 3 3 0 0 3 100

5. UCIT101

Fundamentals of Computer

Programming

ES 3 3 0 0 3

100

PRACTICAL

6. UBMCCPA Engineering Graphics ES 4 0 2 2 3 100

7. UCPHCPA Engineering Physics

Laboratory

BS 2

0 0 2 1 100

8. UBCHCPA Engineering Chemistry

Laboratory

BS 2

0 0 2 1 100

9. UCIT1PA

Computer Programming in C

Lab

ES 2 0 0 2 1

100

10. UCLECPB Spoken English - I EEC 4 0 0 4 2 100

TOTAL 29 14 3 12 23

TOTAL: 29 Periods / Week + 1 Hour Seminar

LEGEND:

L Lecture

T Tutorial

P Practical / Laboratory

C Credit

M Marks

CATEGORY:

HS Humanities course

BS Basic Science

ES Engineering Science




PC Professional Core

PE Professional Elective

EEC Employment Enhancement Course

S.

No


gory

Contact

Hours

L T P C M

THEORY

1. UCLEC02 Technical English-II HS 2 2 0 0 2 100

2. UBMTC02 Engineering Mathematics-

II

BS 4 3 1 0 4

100

3. UCPHC02 Engineering Physics-II BS 3 3 0 0 3 100

4 UBEEC01 Basics of Electrical &

Electronics Engineering

PC 3 3 0 0 3

100

5 UBBTC01 Environment Studies HS 2 2 0 0 2 100

6 UBMCC03 Engineering Mechanics ES 4 3 1 0 4 100

7 UCEE201 Digital Logic Circuits PC 3 3 0 0 3 100

PRACTICALS




SEMESTER : II

LEGEND:

L Lecture

T Tutorial


C Credit

M Marks

CATEGORY:


BS Basic Science





SEMESTER : III S.

No

Course

Code

Course Title Cate-

gory

Contact

Hours

L T P C M

THEORY

1. UBMTC03 Engineering Mathematics -

III

BS 4

3 1 0 4 100

2. UBEE302 DC and AC Machines PC 3 3 0 0 3 100

8

UBEECPA

Basics of Electrical &


Laboratory

PC

2 0 0 2 1

100

9 UBWSCPA Engineering Practices

Laboratory

BS 4

0 0 4 2 100

10 UCLECPC Spoken English – II EEC 3 0 0 3 2 100

TOTAL 30 19 2 9 26

TOTAL: 30 Periods / Week




3. UCIT301 Object Oriented

Programming

ES 3

3 0 0 3 100

4. UBMCC11 Thermodynamics ES 4 4 0 0 4 100

5. UBMCC04 Fluid Mechanics ES 3 3 0 0 3 100

6. UBEE309 Electric Circuits And

Electronic Devices

PC 3

3 0 0 3 100

PRACTICALS

7. UBEE3PA DC and AC Machines

Laboratory

PC 2 0 0 2 1

100

8. UBMCCPC Fluid Mechanics Laboratory ES 2 0 0 2 1 100

9. UCIT3PA Object Oriented

Programming Laboratory

ES 2 0 0 2 1

100

10. UCLECPD Spoken English - III EEC 2 0 0 2 1 100

TOTAL 28 19 1 8 24

TOTAL: 28 Periods + 2 hours Seminar

LEGEND:

L Lecture

T Tutorial


C Credit

M Marks

CATEGORY:


BS Basic Science








SEMESTER : IV S.

No

Course

Code

Course Title Cate-

gory

Contact

Hours

L T P C M

THEORY

1. UBMT403 Numerical Methods BS 4 4 0 0 4 100

2. UCEE405 Sensors and Transducers PC 3 3 0 0 3 100

3. UBEE404 Linear Integrated Circuits PC 3 3 0 0 3 100

4. UCEE401 Control Systems PC 4 3 1 0 4 100

5. UBEE402 Electromagnetic Theory PC 4 3 1 0 4 100

6. UBMCC05

Pneumatics, Hydraulics &

Electrical Control Systems

ES 3 3 0 0 3

100

PRACTICALS

7. UBEE4PA Integrated Circuits

Laboratory

PC 2

0 0 2 1 100

8.

UBMCCPB


Electrical Control System

Laboratory

ES

2 0 0 2 1

100

9. UBEE4PB Transducers Laboratory PC 2 0 0 2 1 100

10. UCLECPE Spoken English- IV EEC 2 0 0 2 1 100

TOTAL 29 19 2 8 25

TOTAL: 29 Periods + 1 hour Seminar

LEGEND:

L Lecture

T Tutorial


C Credit

M Marks

CATEGORY:


BS Basic Science








SEMESTER : V S.

No

Course

Code

Course Title Cate-

gory

Contact

Hours

L T P C M

THEORY

1. UBEE505 Power Electronics PC 4 3 1 0 4 100

2. UBEE508 Marine Electrical

Technology

PC 4 3 1 0 4 100

3. UCEE503 Microprocessor and

Microcontroller

PC 4 3 1 0 4 100

4. UBMEC01 Marine Engineering – I ES 3 3 0 0 3 100

5. Core Elective Course-I PE 3 3 0 0 3 100

6. Open Elective Course-I OE 2 2 0 0 2 100

PRACTICALS

7. UCEE5PA Microprocessor &

Microcontroller Laboratory

PC 2

0 0 2 1 100

8. UBEE5PB Power Electronics

Laboratory

PC 2

0 0 2 1 100

9. UBEE5PC Marine Electrical

Technology Laboratory

PC 2

0 0 2 1 100

10. UBLECPF Personality Development

Programme-I

EEC 2

0 0 2 1 100

TOTAL 28 17 3 8 24

Professional Elective Courses-I:

1 UCEE511 Communication Engineering PE 3 3 0 0 3 100

2

UBEE513 Maintenance of Marine

Electrical Equipment PE 3

3 0 0 3

100

Open Elective Courses-I:

1

UBEE514 Distributed Computer

Control System

OE 2

2 0 0 2

100

2

UBEE515 Electrical Estimation and

Wiring

OE 2

2 0 0 2

100

TOTAL: 28 Periods / Week + 2 Seminar




LEGEND:

L Lecture

T Tutorial


C Credit

M Marks

CATEGORY:


BS Basic Science








SEMESTER : VI

S.

No

Course

Code

Course Title Cate-

gory

Contact

Hours

L T P C M

THEORY

1. UCEE604 Process Control and

Marine Automation

PC 4

3 1 0 4 100

2. UBEE602 Digital Signal Processing PC 4 4 0 0 4 100

3. UBEE601 Design of Electrical

Machines

PC 4

3 1 0 4 100

4. Core Elective Course - II PE 4 4 0 0 4 100

5. Open Elective Course - II OE 4 4 0 0 4 100

6. UBMEC02 Marine Engineering – II ES 4 4 0 0 4 100

PRACTICALS

7.

UBEE6PA

Process Control and

Marine Automation

Laboratory

PC

2 0 0 2 1

100

8. UCEE6PB Digital Signal Processing

Laboratory

PC 2 0 0 2 1 100

9. *UBEE6PB Safety and instrumented

System EEC 2* 0 0 0 1* 100

10. UBIVCPZ Industrial Visit EEC 0 0 0 1 100

TOTAL 28 22 2 4 27

Professional Elective Course – II

1 UBEE608 Transmission &

Distribution

PE 4 4 0 0 4

100

2 UBEE611 Electrical Power Plant

Engineering

PE 4 4 0 0 4

100

Open Elective Course – II

1 UBEE609 Electrical Hybrid Vehicles OE 3 3 0 0 3 100

2

UBEE610

Electrical Energy

Generation, Utilization &

Conservation

OE

3 3 0 0 3

100

TOTAL: 28 Periods / Week + 2 Hrs Seminar

*Additional one credit course (Optional)




LEGEND:

L Lecture

T Tutorial


C Credit

M Marks

CATEGORY:


BS Basic Science








SEMESTER : VII S.

No

Course

Code

Course Title Cate-

gory

Contact

Hours

L T P C M

THEORY

1 UBEE706 Solid State Drives PC 4 3 1 0 4 100

2 UBEE702 High Voltage on Merchant

Ships

PC 4 3 1 0 4 100

3 UBEEC02 Marine Control Engineering

& Automation

PC 3 3 0 0 3 100

4 Core Elective Courses - III PE 3 3 0 0 3 100

5 UCEE705 Marine Electrical System

Design & Layout

PC 3

3 0 0 3 100

6 Core Elective Courses - III PE 3 3 0 0 3 100

PRACTICALS

7 UBEE7PA High Voltage and Switch

Gear Laboratory

PC 2 0 0 2 1 100

8 UCEE7PB Marine Automation

Laboratory

PC 2 0 0 2 1 100

9 UBISCPX Internship EEC 0 0 0 2 100

10 UBMPCPY Minor Project EEC 4 0 0 4 2 100

TOTAL 28 18 2 8 26

Professional Elective Course – III

1 UBEE712 Special Electrical Machines PE 3 3 0 0 3 100

2 UBEE711 Embedded System Design PE 3 3 0 0 3 100

3 UBEE704 Marine Electrical Protection

and Switch Gears

PE 3 3 0 0 3 100

TOTAL: 28 Periods / Week + 2 Seminar

LEGEND:

L Lecture

T Tutorial


C Credit

M Marks

CATEGORY:





BS Basic Science





SEMESTER : VIII S.

No

Course

Code

Course Title Cate-

gory

Contact

Hours

L T P C M

THEORY

1 UBEE801 Mobile Communication PC 3 3 0 0 3 100

2 UBEE802 Flexible AC Transmission

Systems

PC 3 3 0 0 3 100

3 UBBSC01 Total Quality Management PC 3 3 0 0 3 100

PRACTICAL

4 UBEE8PA Project Work EEC 12 0 0 12 6 100

TOTAL 21 9 0 12 15

TOTAL: 21 Periods / Week

LEGEND:

L Lecture

T Tutorial


C Credit

M Marks

CATEGORY:


BS Basic Science








List of Courses for the Program (Category wise)

Humanities Courses

S.

No

Course

Code

Course Title Cate-

gory

Contact

Hours

L T P C

1 UCLEC01 Technical English-I HS 2 2 0 0 2

2 UCLEC02 Technical English-II HS 2 2 0 0 2

3 UBBTC01 Environment Science HS 2 2 0 0 2

Basic Sciences S.

No


gory

Contact

Hours

L T P C

1 UBMTC01 Engineering Mathematics-I BS 4 3 1 0 4

2 UCPHC01 Engineering Physics-I BS 3 3 0 0 3

3 UBCHC01 Engineering Chemistry BS 3 3 0 0 3

4 UCPHCPA Engineering Physics

Laboratory

BS 2

0 0 2 1

5 UBCHCPA Engineering Chemistry

Laboratory

BS 2

0 0 2 1

6 UBMTC02 Engineering Mathematics-II BS 4 3 1 0 4

7 UCPHC02 Engineering Physics-II BS 3 3 0 0 3

8 UBWSCPA Engineering Practices

Laboratory

BS 4

0 0 4 2

9 UBMTC03 Engineering Mathematics - III BS 4 3 1 0 4

10 UBMT403 Numerical Methods BS 4 4 0 0 4




Engineering Science S.

No

Course

Code

Course Title Cate-

gory

Contact

Hours

L T P C

1 UCIT101


Programming

ES 3 3 0 0 3

2 UBMCCPA Engineering Graphics ES 4 0 2 2 3

UCIT1PA

Computer Programming in C

Lab

ES

2 0 0 2 1

3 UBMCC03 Engineering Mechanics ES 4 3 1 0 4

4 UBMCC11 Thermodynamics ES 4 4 0 0 4

5 UCIT301 Object Oriented

Programming

ES 3

3 0 0 3

6 UBMCC04 Fluid Mechanics ES 3 3 0 0 3

7 UBMCCPC Fluid Mechanics Laboratory ES 2 0 0 2 1

8 UCIT3PA Object Oriented

Programming Laboratory

ES 2 0 0 2 1

9 UBMCC05



ES 3 3 0 0 3

10

UBMCCPB


Electrical Control System

Laboratory

ES

2 0 0 2 1

11 UBMEC01 Marine Engineering – I ES 3 3 0 0 3

12 UBMEC02 Marine Engineering – II ES 4 4 0 0 4




Professional Core

S.

No

Course

Code

Course Title Cate-

gory

Contact

Hours

L T P C

1 UBEEC01 Basics of Electrical &


PC 3 3 0 0 3

2

UBEECPA

Basics of Electrical &


Laboratory

PC

2 0 0 2 1

3 UCEE201 Digital Logic Circuits PC 3 3 0 0 3

4 UBEE302 DC and AC Machines PC 3 3 0 0 3

5 UBEE309 Electric Circuits And

Electronic Devices

PC 3

3 0 0 3

6 UBEE3PA DC and AC Machines

Laboratory

PC 2 0 0 2 1

7 UCEE405 Sensors and Transducers PC 3 3 0 0 3

8 UBEE404 Linear Integrated Circuits PC 3 3 0 0 3

9 UCEE401 Control Systems PC 4 3 1 0 4

10 UBEE402 Electromagnetic Theory PC 4 3 1 0 4

11 UBEE4PA Integrated Circuits

Laboratory

PC 2

0 0 2 1

12 UBEE4PB Transducers Laboratory PC 2 0 0 2 1

13 UBEE505 Power Electronics PC 4 3 1 0 4

14 UBEE508 Marine Electrical

Technology

PC 4 3 1 0 4

15 UCEE503 Microprocessor and

Microcontroller

PC 4 3 1 0 4

16 UBEE5PA Microprocessor &

Microcontroller Laboratory

PC 2

0 0 2 1

17 UBEE5PB Power Electronics

Laboratory

PC 2

0 0 2 1

18 UBEE5PC Marine Electrical

Technology Laboratory

PC 2

0 0 2 1

19 UCEE604 Process Control and Marine

Automation

PC 4

3 1 0 4

20 UBEE602 Digital Signal Processing PC 4 4 0 0 4




Professional Elective

S.

No

Course

Code

Course Title Cate-

gory

Contact

Hours

L T P C

1 UCEE511 Communication Engineering PE 3 3 0 0 3

2 UBEE513 Maintenance of Marine

Electrical Equipment PE 3

3 0 0 3

3 UBEE608 Transmission & Distribution PE 4 4 0 0 4

4 UBEE611 Electrical Power Plant

Engineering

PE 4 4 0 0 4

5 UBEE704 Marine Electrical Protection

and Switch Gears

PE 3 3 0 0 3

21 UBEE601 Design of Electrical

Machines

PC 4

3 1 0 4

22 UBEE6PA

Process Control and Marine

Automation Laboratory

PC 2 0 0 2 1

S.

No

Course

Code

Course Title Cate-

gory

Contact

Hours

L T P C

23 UCEE6PB Digital Signal Processing

Laboratory

PC 2 0 0 2 1

24 UBEE706 Solid State Drives PC 4 3 1 0 4

25 UBEE702 High Voltage on Merchant

Ships

PC 4 3 1 0 4

26 UBEEC02 Marine Control Engineering

& Automation

PC 3 3 0 0 3

27 UCEE705 Marine Electrical System

Design & Layout

PC 3

3 0 0 3

28 UBEE7PA High Voltage and Switch

Gear Laboratory

PC 2 0 0 2 1

29 UCEE7PB Marine Automation

Laboratory

PC 2 0 0 2 1

30 UBEE801 Mobile Communication PC 3 3 0 0 3

31 UBEE802 Flexible AC Transmission

Systems

PC 3 3 0 0 3

32 UBBSC01 Total Quality Management PC 3 3 0 0 3




6 UBEE712 Special Electrical Machines PE 3 3 0 0 3

7 UBEE711 Embedded System Design PE 3 3 0 0 3

Open Elective S.

No

Course

Code

Course Title Cate-

gory

Contact

Hours

L T P C

1 UBEE514 Distributed Computer

Control System

OE 2

2 0 0 2

2 UBEE515 Electrical Estimation and

Wiring

OE 2

2 0 0 2

3 UBEE609 Electrical Hybrid Vehicles OE 3 3 0 0 4

4 UBEE610

Electrical Energy

Generation, Utilization &

Conservation

OE

3 3 0 0 4

Employment Enhancement Courses S.

No


gory

Contact

Hours

L T P C

1 UCLECPB Spoken English-I EEC 4 0 0 4 2

2 UCLECPC Spoken English-II EEC 3 0 0 3 2

3 UCLECPD Spoken English -III EEC 2 0 0 2 1

4 UCLECPE Spoken English - IV EEC 2 0 0 2 1

5 UBLECPF Personality Development

Programme-I

EEC 2

0 0 2 1

6 *UBEE6PB Safety and instrumented

System EEC 2* 0 0 0 1*

7 UBIVCPZ Industrial Visit EEC - 0 0 0 1

8 UBISCPX Internship EEC - 0 0 0 2

9 UBMPCPY Minor Project EEC 4 0 0 4 2

10 UBEE8PA Project Work EEC 12 0 0 12 6

*Additional one credit course (Option




Summary of Credits

S.

No

Course Area Credit per Semester Total

credit I II III IV V VI VII VIII

1 Humanities

Courses 2 4 6

2 General / Basic

Science 12 9 4 4 29

3 Engineering

Science 7 4 12 4 3 4 34

4 Professional

Core 7 7 16 15 14 16 9 84

5 Professional

Electives 3 4 6 13

6

Employment

Enhancement

Courses

2 2 1 1 1 1 4 6 18

7 Open Electives 2 3 5

TOTAL 23 26 24 25 24 26 26 15 189

8

Non-Credit

Courses/

Additional one

credit course

(Optional)

1*

GRAND TOTAL 23 26 24 25 24 26 26 15 189




Mapping PO’s and CO’s S

e

m

Course

Code Courses

PO

1

PO

2

PO

3

PO

4

PO

5

PO

6

PO

7

PO

8

PO

9

PO

10

PO

11

PO

12

PS

O1

PS

O2

PS

O3

Sem

este

r 1

UCLEC01 Technical

English-I

UBMTC01 Engineering

Mathematics-I

UCPHC01 Engineering

Physics-I

UBCHC01 Engineering

Chemistry

UCIT101

Fundamentals of

Computer

Programming

UBMCCPA Engineering

Graphics

UCPHCPA Engineering

Physics

Laboratory

UBCHCPA Engineering

Chemistry

Laboratory

UCIT1PA

Computer

Programming

in C Lab

UCLECPB Spoken English-

I

Sem

este

r 1I

UCLEC02 Technical

English-II

UBMTC02 Engineering

Mathematics-II

UCPHC02 Engineering

Physics-II

UBEEC01 Basics of

Electrical &

Electronics

Engineering




UBBTC01 Environment

Studies

UBMCC03 Engineering

Mechanics

Course

Code

Courses

PO

1

PO

2

PO

3

PO

4

PO

5

PO

6

PO

7

PO

8

PO

9

PO

10

PO

11

PO

12

PS

O1

PS

O2

PS

O3

UCEE201 Digital Logic

Circuits

UBEECPA

Basics of

Electrical &

Electronics

Engineering

Laboratory

UBWSCP

A

Engineering

Practices

Laboratory

UCLECPC Spoken English-

II

Sem

este

r II

I

UBMTC03 Engineering

Mathematics -

III

UBMCC11 Thermodynamic

s

UBEE302 DC and AC

Machines

UBIT301 Object Oriented

Programming

UBMCC04 Fluid Mechanics

UBEE309 Electric Circuits

And Electronic

Devices

UBEE3PA DC and AC

Machines

Laboratory

UBMCCPC Fluid Mechanics

Laboratory




UCIT3PA Object Oriented

Programming

Laboratory

UCLECPD Spoken English

–III

S

emes

ter

IV

UBMT403 Numerical

Methods

UCEE405 Sensors and

Transducers

UBEE404 Linear

Integrated

Circuits

UCEE401 Control Systems

Course

Code

Courses

PO

1

PO

2

PO

3

PO

4

PO

5

PO

6

PO

7

PO

8

PO

9

PO

10

PO

11

PO

12

PS

O1

PS

O2

PS

O3

UBEE402 Electromagnetic

Theory

UBMCC05

Pneumatics,

Hydraulics &

Electrical

Control Systems

UBEE4PA Integrated

Circuits

Laboratory

UBMCCPB

Pneumatics,

Hydraulics &

Electrical

Control System

Laboratory

UBEE4PB Transducers

Laboratory

UCLECPE Spoken English

- IV

Sem

este

r V

UBEE505 Power

Electronics

UBEE508 Marine

Electrical

Technology




UCEE503 Microprocessor

and

Microcontroller

UBMEC01 Marine

Engineering – I

UCEE511 Communication

Engineering

UBEE513 Maintenance of

Marine

Electrical

Equipment

UBEE514 Distributed

Computer

Control System

UBEE515 Electrical

Estimation and

Wiring

Course

Code

Courses

PO

1

PO

2

PO

3

PO

4

PO

5

PO

6

PO

7

PO

8

PO

9

PO

10

PO

11

PO

12

PS

O1

PS

O2

PS

O3

UCEE5PA Microprocessor

&

Microcontroller

Laboratory

UBEE5PB Power

Electronics

Laboratory

UBEE5PC Marine

Electrical

Technology

Laboratory

UBLECPF Personality

Development

Programme-I

Sem

este

r

VI

UCEE604 Process Control

and Marine

Automation

UBEE602 Digital Signal

Processing




UBEE601 Design of

Electrical

Machines

UBMEC02 Marine

Engineering – II

UBEE608 Transmission

& Distribution

UBEE611 Electrical Power

Plant

Engineering

UBEE609 Electrical

Hybrid Vehicles

UBEE610

Electrical

Energy

Generation,

Utilization &

Conservation

UBEE6PA

Process Control

and Marine

Automation

Laboratory

UCEE6PB Digital Signal

Processing

Laboratory

Course

Code

Courses

PO

1

PO

2

PO

3

PO

4

PO

5

PO

6

PO

7

PO

8

PO

9

PO

10

PO

11

PO

12

PS

O1

PS

O2

PS

O3

UBIVCPZ Industrial Visit

Sem

este

r V

II

UBEE706 Solid State

Drives

UBEE702 High Voltage on

Merchant Ships

UBEEC02 Marine Control

Engineering &

Automation

UBEE704 Marine

Electrical

Protection and

Switch Gears




UBEE712 Special

Electrical

Machines

UBEE711 Embedded

System Design

UCEE705 Marine

Electrical

System Design

& Layout

UBEE7PA High Voltage

and Switch Gear

Laboratory

x

UBISCPX Internship

UBMPCPY Minor Project

Sem

este

r V

III

UBEE801 Mobile

Communication

UBEE802 Flexible AC

Transmission

Systems

UBBSC01 Total Quality

Management

UBEE8PA Project Work

Course Assessment DIRECT INDIRECT

Continuous Assessment Test (CAT1) Course end Survey

Continuous Assessment Test (CAT2) Alumni feedback

Model examination Industry feedback

Assignment

Attendance

End Semester Examination




PROGRAM BE-Electrical and Electronics Engineering

Course Code UCLEC01

Course Name : Technical English-I

L T P C

2 0 0 2

(Common to BE – Mechanical Marine, BE – EEE, BE –PE, BE – HE, BE - NA&OE)

Year and Semester

I Year (I Semester ) Contact hours per week

( 2 Hrs )

Prerequisite

course

NIL

Course

Objective

1. To make the students learn to speak grammatically correct English. Guiding and

supporting their skill development –Listening, speaking, reading and writing in

English.

2. Making them realise the importance of English as Global language and its importance

in today‗s scenario. Course Outcome The Students will be able to

1. Understand the importance of technical English.

2. Express technical and general vocabulary.

3. Distinguish different tenses and to distinguish common error.

4. improve and write formal and informal letters and report

5. Develop and acquire good listening and speaking skills

6. Build and learn to speak and write English grammatically




UNIT 1: COMMUNICATION SKILL & READING SKILL 6 Hrs

Importance of Technical Communication-Topic sentence and its Role-Reading and Interpretations-Critical

Reading -Creative and Critical Thinking-Note Making -Transfer of Information-Visual Aids-Graphics-Lab.

UNIT II: FOCUS ON LANGUAGE – VOCABULARY 6 Hrs

General Vocabulary-Dictionary-Word Formation: Prefix and Suffix-Synonyms and antonyms- Idioms and

Phrases-Homophones-Technical Vocabulary-Words commonly misspell –Lab-Test.

UNIT III: ENGLISH GRAMMAR 6 Hrs

Parts of Speech-Subject Verb Agreement-Tenses, Articles, Prepositions-Common errors in English-Lab-Test.

UNIT IV: WRITING SKILL 6 Hrs

Descriptive Writing –Paragraph-Technical descriptions-Essays-Letter Writing – Formal and Informal-Business

Letters-Job Application Letter-Types of reports-Instructions and Checklists- Lab-Test.




UNIT V: LISTENING AND SPEAKING 6 Hrs

Types of Listening -Listening and note taking-Pronunciations-Stress and Intonation- Conversation technique-

Dialogue Writing -Professional Communication-Interview-Group Discussion –Power point Presentation Lab.

TOTAL:30 Hours

TEXT BOOKS:

1. Department of English, Anna University. Mindscapes: English for Technologists and Engineers. Orient

Blackswan, Chennai. 2012

2. Dhanavel, S.P. English and Communication Skills for Students of Science and Engineering. Orient

Blackswan, Chennai. 2011

REFERENCES:

1. Essential Grammar in use- Raymond Murphy ,Cambridge , 2007.

2. Raman, Meenakshi & Sangeetha Sharma. Technical Communication: Principles and Practice. Oxford

University Press, New Delhi. 2011.

3. Regional Institute of English. English for Engineers. Cambridge University Press, New Delhi. 2006.

4. Rizvi, Ashraf. M. Effective Technical Communication. Tata McGraw-Hill, New Delhi. 2005

5. Rutherford, Andrea. J Basic Communication Skills for Technology. Pearson, New Delhi. 2001.

6. Viswamohan, Aysha. English for Technical Communication. Tata McGraw-Hill, New Delhi. 2008.



Document Prepared in― Board of Studies‖ held on Document Approved in ― Academic Council‖ held on

Date : 21.04.2017 Date: 28.04.2017


PROGRAM BE – Electrical and Electronics Engineering

Course Code

UBMTC01

Course Name :

Engineering Mathematics-I

L T P C

3 1 0 4

Year and Semester I Year ( I Semester ) Contact hours per week ( 4 Hrs ) Prerequisite course NIL

Course Objective 1. To know the application of analytical geometry and understanding shapes of

three dimensions.

2. To understand the techniques of differentiating a function.

3. To acquaint the student with function of several variables.

4. To introduce the concepts and methods to solve the integrals.

5. To understand the application of integrals.

Course Outcome The Students will be able to

1. Understand the three dimensional analytical geometry.

2. Solve problems on differential calculus.

3. Categorize the function of several variables.

4. Apply integral calculus on engineering problems.

5. Use multiple integrals to solve problems.

6. Understand the basic concepts on fundamental of geometry integral for

engineering applications.

UNIT I: THREE DIMENSIONAL ANALYTICAL GEOMETRY 12 Hrs

Equation of a sphere – Plane section of a sphere – Tangent Plane – Equation of a cone – Right circular cone –

Equation of a cylinder – Right circular cylinder.

UNIT- II:- DIFFERENTIAL CALCULUS 12 Hrs

Differentiation of algebraic – circular - exponential and logarithmic functions of products and quotient –

Functions of a function and simple implicit functions – Successive differentiation- introduction and notation –

nth

order derivatives of standard functions – nth

order derivatives using trigonometric identities and standard

functions and partial fractions – Leibnitz theorem – Maclaurin‗s Theorem and standard expansions – Taylor‗s

theorem – Indeterminate forms and L‗Hospital‗s rule.

UNIT- III:- FUNCTIONS OF SEVERALVARIABLES 12 Hrs

Limits and continuity-Partial derivatives – definition-geometrical interpretation and rules of partial

differentiation – Higher order partial derivatives – Homogeneous functions – Euler‗s theorem for

homogenous functions – Total derivatives and chain rules – Differentiation of implicit functions and




Date : 21.04.2017 Date: 28.04.2017


composite functions – Maxima and Minima – Method of Lagrangian multipliers.

UNIT- IV:- INTEGRAL CALCULUS 12 Hrs

Integration by trigonometric substitution – The definite integral as the limit of a sum- Bernoulli's rule –

Reduction formulae – Properties of definite integrals – beta and gamma Functions and problems – Work done

by variable forces – mean values – Root mean square values of in sin x and Cos nx.

UNIT –V:- MULTIPLE INTEGRALS 12 Hrs

Double and triple integrals – Cartesian coordinates – Region of integration and change of order of

integration – Spherical polar and cylindrical coordinates Theorems of parallel and perpendicular

axes. Applications – Area – Volume - Mass of wire - lamina and solid - Centre of Gravity of wire – lamina

and solid – Moment of Inertia using multiple integrals.

TOTAL : 60 Hours

TEXT BOOKS:

1. Bali N. P and Manish Goyal, ―Text book of Engineering Mathematics, Third edition, Laxmi

Publications (p) Ltd.,2008.

2. Grewal. B.S, ―Higher Engineering Mathematics, 40th Edition, Khanna Publications, Delhi,

2007.

REFERENCES:

1. Dass, H.K., and Er. Rajnish Verma,‖ Higher Engineering Mathematics‖, S. Chand Private Ltd.,

2011.

2. Glyn James, ―Advanced Modern Engineering Mathematics‖, 3rd Edition, Pearson Education, 2012.

3. Peter V. O‘Neil,‖ Advanced Engineering Mathematics‖, 7th Edition, Cengage learning, 2012.

4. Ramana B.V, ―Higher Engineering Mathematics‖, Tata McGraw Hill Publishing Company, New

Delhi, 2008.

5. Sivarama Krishna Das P. and Rukmangadachari E., ―Engineering Mathematics‖, Volume I, Second

Edition, PEARSON Publishing, 2011.



Document Prepared in― Board of Studies‖ held on

Date : 28.06.2017

PROGRAM B. E. Electrical and Electronics Engineering

Course Code UCPHC01

Course Name : Engineering Physics I

L T P C

3 0 0 3

Year and Semester

I Year ( I Semester ) Contact hours per week

3 Hours

Prerequisite course

Fundamental concepts of Physics

Course Objective

1. Students should gain an understanding on basic mechanics of solids and fluids, their properties and applications.

Course Outcome Students will be able to

1 Apply the laws of basic mechanics of solids and fluids for solving engineering problems

2 Apply the concepts mechanics to design machines.

3 Demonstrate concepts of fluid at rest and motion.

4 Determine the elastic limit of different materials

5 Interpret the basic heat laws and behavior of light.

6 Explain the concepts of electromagnetic induction and their applications

UNIT I: MECHANICS 9 Hrs

Force-inertia – Newton`s laws of motion- impulse and impact – Friction – cause of friction – types of

friction – laws of friction – coefficient of friction – angle of friction. Motion-types of motion – simple

harmonic motion – simple pendulum – circular motion –centripetal and centrifugal force – conical

pendulum-working of a steam engine governor based on the principle of conical pendulum. Newton`s law of

universal gravitation – Satellite-principle of launching of satellite – orbital velocity – time period – escape

velocity. Planetary motion and Kepler‘s Laws – Deduction of Kepler`s third law – Law of gravitation from

Kepler`s third law.

UNIT II: HYDROSTATICS AND HYDRODYNAMICS 9 Hrs

Fluid-Pascal`s law – Archimedes principle – Laws of floatation – centre of buoyancy – stability of

equilibrium of a floating body – metacentre – metacentric height of a ship – experiment. Hydrostatic

pressure, differential manometer – Centre of pressure – Centre of pressure of a rectangular lamina immersed

in a homogenous liquid at rest – Centre of pressure of a triangular lamina with one side parallel to the

surface-Surface tension – angle of contact – capillarity – derivation of surface tension. Viscosity – Viscous

Document Approved in ― Academic Council‖ held on

Date: 03.10.2017



force-Stokes Law – coefficient of viscosity – experiment to find coefficient of viscosity. Bernoulli‘s

Theorem – Venturimeter – Plimsol lines.

UNIT III: PROPERTIES OF MATTER 9 Hrs

Elasticity- stress and strain – Hooke`s law – modulus of elasticity – different types – Poisson ratio Torsion –

torque per unit twist – work done in twisting – Torsion pendulum – theory and experiment – bending of

beams – bending moment – Cantilevers – depression of a cantilever – non uniform bending and uniform

bending – theory and experiment.

UNIT IV: HEAT AND LIGHT 9 Hrs

Laws of thermodynamics – Specific heat capacity – Specific heat capacity of gases – CP and CV – Relation

between them – Transmission of heat – conduction – coefficient of thermal conductivity – Lee,s disc

experiment – cylindrical flow of heat – convection – radiation – Black body radiation – distribution of

energy – Wien`s displacement law– Rayleigh Jeans law. Interference – Double slit experiment- Diffraction

due to single slit and circular aperture. Limit of resolution, Resolving power of optical instruments.

UNIT V: ELECTRICITY 9 Hrs

Heating effect of current – Joules law of heating – Applications – fuse – thermopile. Ampere`s Law, Biot

Savart law – Magnetic field at a point due to straight conductor carrying current – Kirchhoff‘s current and

voltage laws – Whetstone‘s network – Electromagnetic induction – Faraday‘s laws of Electromagnetic

induction – Lenz law – Self induction – Mutual induction . DC Generator – principle, construction and

working – AC Generator – principle, construction and working. Transformer – principle, construction and

working – Losses in transformer – methods to reduce the losses.

TOTAL: 45 Hours

TEXT BOOKS:

1. A Nelson, ―Engineering Mechanics‖ Tata McGRaw Hill, 2009

2. M. Narayanamurthi, M. Nagarathnam, ―Statics, Hydrostatics and Hydrodynamics‖, The National

Publishing Company, 8th Edition, 2008.


Date : 28.06.2017


Date: 03.10.2017



3. R. Murugeshan, Properties of matter and acoustics, S. Chand & Co, New Delhi 2012.

4. D.S. Mathur, Elements of properties of matter, S.Chand & Company Ltd., New Delhi 2010.

5. Brijlal, N. Subramanyam and P.S. Hemne ―Heat and thermodynamics”, S.Chand & Co,

New Delhi 2008.

6. N. Subramaniyam, Brijlal and M.N. Avadhanulu, A text book of Optics, S. Chand & Co, New

Delhi, 2012.

REFERENCES:

1. R Feynmann, R Leighton, M Sands, ―The Feynmann Lectures on Physics‖, Volume 1, Pearson

Education; 1st edition 2012.

2. D Halliday, R Resenic and J Walker ―Fundamentals of Physics‖, Wiley India, 6th edition, 2006.

3. Brijlal and Subramaniyam, ―Properties of matter‖, S. Chand & Co, New Delhi, Revised edition,

2008.

4. R W. Fox, A T. McDonald, P J. Pritchard John, ―Introduction to Fluid Mechanics‖, Wiley & Sons,

6th edition, 2008.

5. E M. Purcell and Morin, ―Electricity and Magnetism‖, 3rd Edition, Cambridge University Press,

2011

6. A Ghatak, ―Optics‖, McGraw-Hill Education; 1st Edition, 2009




Course Code UBCHC01

Course Name : Engineering Chemistry

L T P C

3 0 0 3

(Common for Mech, EEE(M), NA of 1st Semester & Common for ME, PE,HE of 2nd Semester)

Year and Semester


( 3Hrs )

Prerequisite

course

Nil

Course

Objective

1. To impart a sound knowledge with respect to Phase rule, Hazardous Chemicals, and

treatment of water for industrial purpose.

2. To understand principle involved in corrosion control, the concept of energy storage devices and the importance of fuels.

3. To develop polymer based materials and functional materials towards different

applications.

Course Outcome After successful completion of this course, the Students will be able to

1. Understand the fundamentals of phase rule and reduced phase rule.

2. Infer and gain the knowledge on boiler feed water requirements, related problems and

water treatment techniques.

2. Identify the types of fuels, manufacture of solid, liquid and gaseous fuels and

combustion.

3. Build and acquire the principles of electrochemical reactions, redox reactions in corrosion of materials.

4. Illustrate the knowledge on petroleum refining operations, ferrous and non-ferrous

alloys, fiber reinforced plastics and the manufacturing process of steel, cement.

5. Discuss the organic compounds will provide a strong platform to understand the

concepts on these subjects for further learning.

6. Develop knowledge on hazardous cargoes, water treatment techniques, fuels, high

energy materials and organic compounds.



UNIT- I PHASE RULE: 9 Hrs

Terminology-Phase rule – one component system, reduced phase rule – application of reduced phase rule to

binary alloy system-Hazard of Inorganic, Organic cargos carried on board vessels with respect to flammability,

toxicity, reactivity and solubility.

UNIT- II WATER & IT TREATMENTS: 9 Hrs

Sources of water - hard and soft water-determination of hardness - Softening of water - lime soda process

Ion exchange process - Boiler feed water - removal of oil - blow down operation - Caustic Embrittlement -

internal conditioning - Water for domestic purposes screening - aeration , sedimentation, Chlorination, break

point chlorination - Disinfection with ozone – desalination - Waste water treatment- marine sediments.

UNIT -III FUEL & COMBUSTION: 9 Hrs

Conventional & non conventional energy resources and energy conversion - classification and properties of

fuel - calorific value determination using bomb calorimeter - Solid fuels – Analysis - proximate and ultimate

analysis, hydrogenation & carbonization of coal - Liquid fuels - characterization of various constituents viz

petrol diesel with regard to their application in IC engine (knocking)Gaseous fuels- coal gas, producer gas,

biogas, water gas and flue gas analysis using Orsat apparatus - Toxic and other ill effects of cargos on human

and environment.

UNIT -IV ELECTROCHEMISTRY: 9 Hrs

Electrodes - Standard & single electrode potential - Nernst equation - Cell terminology - cell reaction -

Galvanic cells - fuel cells - Lead acid battery - Nickel cadmium battery - Electrochemical Reaction:

Electrolysis - Electroplating – galvanizing - Corrosion Control on Board Ship: Thermodynamics & Kinetics of

corrosion - various forms of corrosion - corrosion prevention methods.

Lubricants:

Classification and properties of lubricating oils (Viscosity, flash, fire point & cloud and pour points) Effects of

pressure on melting & boiling point - Relevance of gas laws to LPG carrier and reefer ships. Physical and

Chemical Properties of Fuels and Lubricants - Production of Oils from Crude Oil - Properties and

characteristics of fuels and lubricants - Shore side and shipboard sampling and testing - Interpretation of test

results - Contaminants including microbiological infection - Treatments of fuels and lubricants including

storage, centrifuging, blending, pretreatment and handling.



UNIT- V 9 Hrs

Production of steel - Bessemer converter process - Open hearth process - Chemical addition to steels

production of non-ferrous alloys, brass, bronze, aluminum alloys - Special reference to ship building (ship

propellers etc) – Cement - manufacturing of cement - setting & hardening of cement – concrete - reinforced

concretes - Basic Metallurgy - Metals and Processes - Properties and Uses - Non-Metallic Materials -

Characteristics and limitations of process used for fabrication and repair – Process - Heat Treatment of Carbon

Steel - Technology of Material - Metallurgy of Steel and Cast Iron - Properties and application of material used

in machinery on board ship.

Organic Compounds:

Hydrocarbon- petroleum & its fractionated products - extraction of aromatic compounds from Petroleum -

Aromatic compounds – Benzene - polycyclic hydrocarbons- Naphthalene, anthracene, Naphthacene - Fiber

and Reinforced plastics.

Total: 45 Hours

TEXT BOOK:

1. Jain P.C. and Monica Jain, ―Engineering Chemistry‖, Dhanpat Rai Publishing Company (P) Ltd., New

Delhi, 2010

2. Kannan P., Ravikrishnan A., ―Engineering Chemistry‖, Sri Krishna Hi-tech Publishing Company Pvt.

Ltd. Chennai, 2009

REFERENCES:

1. Dara S.S, Umare S.S, ―Engineering Chemistry‖, S. Chand & Company Ltd., New Delhi 2010

2. Sivasankar B., ―Engineering Chemistry‖, Tata McGraw-Hill Publishing Company, Ltd., New Delhi,

2008.

3. Gowariker V.R. , Viswanathan N.V. and JayadevSreedhar, ―Polymer Science‖, New Age International

P (Ltd.,), Chennai, 2006.

4. Ozin G. A. and Arsenault A. C., ―Nanochemistry: A Chemical Approach to Nanomaterials‖, RSC

Publishing, 2005.




Date : 11.07.2017 Date: 03.10.2017


PROGRAM BE –Electrical and Electronics Engineering

Course Code

UCIT101

Course Name :


Programming

L T P C

3 0 0 3

Year and Semester

I Year (I Semester )

Contact hours per week ( 3Hrs ) Prerequisite course

NIL

Course

Objective

1. To explain the problem solving concepts using a computer .

2. To develop problem solutions for the computer by using problem solving tools.

3. To describe the Programming structure of C language.

4. To convert an Algorithm, Pseudo code and Flowchart into a C program .

5. To find errors and execute a C program .

Course Outcome

The Students will be able to

1. Apply the problem solving tools such as flowchart, IPO chart and pseudo code

to design the problem solutions executable by the computer .

2. Summarize the programming structure of C Language.

3. Design an Algorithm, Pseudo code or a Flowchart for a given problem.

4. Write a c program for a given problem .

5. Debugging a C program .

6. Create simple project by using C programming.




Date : 11.07.2017 Date: 03.10.2017


UNIT I:INTRODUCTION 9 Hrs

Generations and Classification of Computers - Applications of Computers - Basic Organization of a Computer

- Number system - Binary, Decimal, Octal and Hexadecimal - Problems

UNIT- II:- INTRODUCTION TO PROBLEM SOLVING AND PROGRAMMING 9 Hrs

General Problem - Solving Concepts - Problem Solving Concepts for the Computer - An Introduction to

Programming Structure - Problem Solving with the Sequential Logic Structure - Problem Solving with

Decisions - Problem Solving with Loops

UNIT- III:- DATA STRUCTURES 9 Hrs

Primary Data Types - One-dimensional Arrays - Two-dimensional Arrays - Table Look-Up Technique -

Sequential Search, Binary Search - Sorting Techniques - Selection Sort, Bubble Sort, Shell Sort, Stacks, and

Queues - File Concepts

UNIT- IV:- PROGRAMMING STRUCTURE OF C LANGUAGE 9 Hrs

Importance of C - Basic Structure of a C Program – Constants, variables and data types- Operators and

Expressions - Input and Output Operations - Branching and Looping - Arrays and Strings - User-defined

Functions

UNIT –V:- PROGRAMMING IN C LANGUAGE 9 Hrs

Structures and Unions – Pointers - File Management in C - Development of C programs - Executing a C

Program - compilation and linking - Common Programming Errors - Program Testing - Program Debugging

Total : 45 Hours




Date : 11.07.2017 Date: 03.10.2017


TEXT BOOKS:

1. Maureen Sprankle & Jim Hubbard, ―Problem Solving & Programming Concepts‖, Sixth Edition,

Prentice Hall, 2012.

2. E. Balagurusamy, ―Programming in ANSI C‖, Seventh Edition, McGraw Hill India, 2016.

3. Kernighan,B.W and Ritchie,D.M, ―The C Programming language‖, Second Edition, Pearson

Education, 2006.

REFERENCES:

1. Ashok Kamthane, ―Programming in C‖, Third Edition, Pearson Education India, 2015.

2. Herbert Schildt, ―C: The Complete Reference‖, Fourth edition, McGraw Hill Education, 2000.

3. Byron S Gottfried, ―Programming with C‖, Schaum‘s Outlines, Second Edition, Tata McGrawHill,

2006.

4. Dromey R.G., ―How to Solve it by Computer‖, Pearson Education, Fourth Reprint, 2007.





Course Code

UBMCCPA

Course Name :

Engineering Graphics

L T P C

0 2 2 3


Year and Semester

1 Year (1 Semester ) Contact hours per week

( 4Hrs )

Prerequisite

course

NIL

Course Objective

1. Develop the ability of students to understand graphic skills for communication of concepts.

2. To analyze and design ideas of engineering products.

Course Outcome The Students will be able to 1. Identify the three Dimensional objects in two dimensional media.

2. Prepare the projection of points, straight lines and determination of true length and true inclination.

3. Sketch the simple solid on plain surface.

4. Sketch the projection of solids and development of surfaces.

5. Construct the isometric projection of simple solids and guide line to direction of

view. 6. Discover the different isometric views and projections.

UNIT-I PLANE CURVES AND ORTHOGRAPHIC VIEWS 12 Hrs

Introduction-Use of drafting instruments-Drawing conventions-size-Line types-Lettering and dimensioning

Curves used in engineering practices: Conics – Construction of ellipse, parabola and hyperbola by eccentricity

method – Construction of cycloid – construction of involutes of square and circle – Drawing of tangents and

normal to the above curves Visualization concepts: Representation of Three Dimensional objects in two

dimensional media-Visualization of objects from pictorial views to orthographic views

UNIT II PROJECTION OF POINTS, LINES AND PLANE SURFACES 12 Hrs

Orthographic projection: Principal views and principal planes of projection-First angle projection- Third angle

projection-projection of points. Projection of straight lines (only First angle projections) inclined to both the

principal planes -Determination of true lengths and true inclinations by rotating line method-Projection of

plane surfaces


Date : 06.03.2016


Date: 03.04.2017





Date: 03.04.2017

UNIT III PROJECTION OF SOLIDS 12 Hrs

Projection of simple solids placed in Different positions-perpendicular to HP or VP-parallel to either HP or VP

and inclined to the other-Inclined to both VP and HP

UNIT IV PROJECTION OF SECTIONED SOLIDS AND DEVELOPMENT OF SURFACES 12 Hrs

Sectioning of simple solids in simple vertical position when the cutting plane is inclined to the one of the

principal planes-Development of lateral surfaces of simple solids by Parallel line method and radial line

method

UNIT V ISOMETRIC PROJECTION AND ISOMETRIC VIEWS 12 Hrs

Principles of isometric projection-isometric projection of simple solids-Guide lines to read the isometric view

visualizing of plane surfaces inclined to the direction of view.

TOTAL : 60 Hours

TEXT BOOKS:

1. Bhatt N.D. and Panchal V.M., Engineering Drawing., Charotar Publishing House, 50th

Edition, 2010.

2. Gopalakrishna K.R., Engineering Drawing. (Vol. I & II combined), Subhas Stores, Bangalore, 2007.

3. Luzzader, Warren.J. and Duff,John M., Fundamentals of Engineering Drawing with an introduction to

Interactive Computer Graphics for Design and Production, Eastern Economy Edition, Prentice Hall of

India Pvt. Ltd, New Delhi, 2005

REFERENCES:

1. Shah M.B., and Rana B.C., ―Engineering Drawing‖, Pearson, 2nd Edition, 2009.

2. Venugopal K. and Prabhu Raja V., ―Engineering Graphics‖, New Age International (P) Limited, 2008.

3. Natrajan K.V., ―A text book of Engineering Graphics‖, Dhanalakshmi Publishers, Chennai, 2009.

4. Basant Agarwal and Agarwal C.M., ―Engineering Drawing‖, Tata McGraw Hill Publishing Company Limited,

New Delhi, 2008.


Date : 06.03.2016

Document Prepared in“ Board of Studies” held on

Date : 28.06.2017




Course Code UCPHCPA

Course Name : Engineering Physics Lab

L T P C

0 0 2 1

Year and Semester


2 Hours

Prerequisite course

Nil

Course Objective

Students should obtain the skill to design experiments to demonstrate various concepts of physics for determination of properties of materials

Course Outcome

Students will be able to

1 Apply the basic concept of physics to determine various properties of materials.

2 Interpret and validate the measured parameters

3 Justify the various error in experiments leading to deviation from standard values

4 Experiment with light and use it for measuring thickness of thin wires and radius of curvature of lens

5 Determine the surface tension and viscosity of a given liquid

6 Utilize measuring instruments such as screw gauge, vernier caliper and microscope

LIST OF EXPERIMENTS

1. Calibration of low range voltmeter - potentiometer 2. Torsion pendulum – Rigidity modulus of elasticity 3. Spectrometer- Grating - wavelength of mercury spectral lines 4. Newton`s rings – Radius of curvature of a convex lens

5. Air wedge – Thickness of a wire

6. Surface tension of water -Capillary rise method 7. Uniform bending – Young‘s modulus of elasticity of a bar

8. Coefficient of viscosity of water – graduated burette

9. Non uniform bending -Young‘s modulus of elasticity of a bar

10. Field along the axis of a coil

Total : 30 Hours

REFERENCE:

1. D Halliday, R Resenic and J Walker ―Fundamentals of Physics‖, Wiley India, 6th edition, 2006.


Document Approved in “ Academic Council” held

on

Date: 03.10.2017

CBCS CURRICULUM (2016 -17) (Regulation –C)




Date: 03.10.2017


Course Code

UBCHCPA

Course Name :

Engineering Chemistry Laboratory

L T P C

0 0 2 1

(Common to BE – Mechanical ,BE-Marine, BE –PE, BE – HE, BE - NA&OE, BE – FPT & BE-Mining)

Year and Semester I Year ( I Semester ) Contact hours per week ( 2 Hrs ) Prerequisite course NIL

Course Objective 1. To make the student to develop practical skills in the determination of water quality

parameters through volumetric analysis.

2. To enlighten the student on instrumental methods for estimation of pH, conductivity,

metal ion content, determination of molecular weight and degree of dissociation of a

polymer by viscometry.

Course Outcome The Students will be able to 1. Interpret hands-on knowledge in the quantitative chemical analysis of water

quality related parameters.

2. Explain pH metry.

3. Analyze conductivity of the material.

4. Demonstrate potentiometry operation

5. Illustrate viscometry.

6. Develop practical skills in the determination of water quality parameters through

volumetric analysis.

List of Experiments:

1. Estimation of Bicarbonate Alkalinity

2. Estimation of Hydroxide Alkalinity

3. Estimation of Total Hardness of Water

4. Estimation of Chloride Content of Water

5. Estimation of Temporary and Permanent Hardness

6. Estimation of COD & BOD of Water, TDS and TSS (Demo only) 7. Conduct metric Titration of a strong acid and base.

8.PH titration of a strong acid and strong base

9. Potentiometric titration of Ferrous Ion

10. Determination of Single Electrode potential (Galvanic Cell)

11. Determination of Calorific value of a solid fuel

12. Determination of Molecular weight of a polymer.

13. Determination of degree of dissociation of a polymer.

14. Proximate analysis of a solid fuel / Liquid fuel TOTAL : 30 Hours


Date : 28.01.2016




Date : 11.07.2017 Date: 03.10.2017



Course Code UCIT1PA

Course Name : Computer Programming in C Lab

L T P C

0 0 2 1

Year and Semester


( 2 Hrs )

Prerequisite course

NIL

Course

Objective

1. To write C programs to solve the problems

2. To compile and execute programs in C

3. To identify the syntax errors and semantic errors

4. To debug the program in C

5. To write C programs to solve the problems

Course Outcome The students will be able to

1. Solve mathematical and scientific calculation.

2. Understanding files concept(Read, Write)

3. Write C programs to solve the problems

4. Compile and execute programs in C

5. Identify the syntax errors and semantic errors

6. Debug the program in C




Date : 11.07.2017 Date: 03.10.2017


LIST OF EXPERIMENTS:

1. Program to write in ascending and descending order of a given ‗n‘ numbers using C

2. Program to find the odd, even, maximum, minimum, sum and average of given ‗n‘ numbers using C

3. Program to swap two numbers without using third variable using C

4. Program to solve quadratic equation using C

5. Program to find the Fibonacci sequence using C

6. Program to find the Addition of two matrixes using C

7. Program to identify the palindrome string

8. Program to use File operations – create, open, read, write, close and search

9. Program to apply sequential and binary search in C

10. Program to apply Selection Sort, Bubble Sort, Shell Sort algorithms

11. Write functions for Stack operations – create a stack, add & remove an item

12. Write functions for Queue operations – create a queue, add & remove an item

TOTAL :30 Hours





Course Code UCLECPB

Course Name : Spoken English-I

L T P C

0 0 4 2

(Common to BE – Mechanical Marine, BE – EEE, BE –PE, BE – HE, BE - NA&OE,BBA, FPT, NS)

Year and Semester

I Year (I Semester ) Contact hours per week

( 4 Hrs )

Prerequisite course

NIL

Course

Objective

1. To help learners develop their listening skills, which will, enable them listen to

lectures and comprehend them by asking questions, seek clarifications.

2. To help learners develop their speaking skills and speak fluently in real contexts. 3. Making them realise the importance of English as Global language and its

importance in today‗s scenario.

Course Outcome The Students will be able to 1. Participate effectively in informal conversation; comprehend their views without

making grammatical errors.

2. Define their perspective more operationally.

3. Acquire the delicacy of using the linguistics skills.

4. Versatility of the language will be enhanced

5. Aggrandize the assertive proficiency.

6. Nurtures the ability of self actualization which widens his vicinity.

UNIT 1: GRAMMAR AND FOUNDATON 18 Hrs

Training the students on basic grammar and foundation and laying the standard platform-A complete standard

syllabus of Cambridge is used-The main part of the 1st semester is to cover the major tenses (Present tense,

Present Continuous, Past Tense, Past Continuous, Present Perfect, and Present Perfect continuous).

UNIT II: FOCUS ON LANGUAGE – VOCABULARY 4 Hrs


Phrases- Diplomatic Phrases – Food Phrases- Vocabulary-Words commonly misspelt – Lab-Test.

UNIT III: INTERACTIVE ENGLISH 10 Hrs

The main objective is English for International communication-It course contains conversations, snapshots,

readings, activities, a greater variety and amount of listening materials and more visuals to introduce

vocabulary, more opportunities to build fluency, and up-to-date art and design- The course covers the fours

skills of listening, speaking, reading and writing, as well as improving pronunciation and building vocabulary.


Date : 11.07.2017


Date: 03.10.2017





Date : 11.07.2017


Date: 03.10.2017

UNIT IV: LISTENING AND SPEAKING 14 Hrs


Dialogue Writing -Professional Communication-Interview-Group Discussion –Power point Presentation-

Debate , Oratorical Lab

UNIT V: INTERVIEW SKILLS AND PERSONALITY DEVELOPMENT 14 Hrs

Out of box thinking -Lateral Thinking- Intrinsic and Extrinsic Motivators- Factors influencing Attitude-

Challenges and lessons from Attitude- Etiquette-Value of time- Diagnosing Time Management- Weekly Planner

To do list- Prioritizing work.

TOTAL: 60 Hours

TEXT BOOKS:

1. Essential Grammar in use- Raymond Murphy ,Cambridge , New Third Edition

REFERENCE BOOKS:

1. New Interchange ( English for International Communication ) Jack C. Richards




Date : 12.04.2017 Date: 03.10.2017



Course Code UCLEC02

Course Name : Technical English-II

L T P C

2 0 0 2

Year and Semester

I Year (II Semester ) Contact hours per week

( 2Hrs )

Prerequisite course

NIL

Course

Objective 1. To make the students learn to speak grammatically correct English. Guiding and

supporting their skill development –Listening, speaking, reading and writing in

English..

2. Making them realize the importance of English as Global language and its

importance intoday‗s scenario.


1. Identify the importance of technical English.

2. Understand the English grammar and vocabulary

3. Improve reading and summarizing skills.

4. Acquire knowledge on writing letters and descriptive writings.

5. Develop speaking and listening skills.

6. Apply the correct pause and pronunciation.

UNIT I: COMMUNICATION & FOCUS ON LANGUAGE 6 Hrs

Process of Communication -Language as a tool of Communication-Importance of Technical Communication.

UNIT II: VOCABULARY & ENGLISH GRAMMAR 6 Hrs


Phrases-Homophones -Parts of Speech-Subject Verb Agreement-Tenses, Articles, Prepositions-Common

errors in English General Vocabulary - Adverbs- Gerund and Infinitive – Word Formation: Prefix and Suffix -

Noun - Compound Noun- Adjective – Degrees of Comparison – Double Adjective - Voice -Tense – Verbs -

Homograph, Homophone – Commonly Confused Words - Collocation – Punctuation marks.

UNIT III: READING SKILL 6 Hrs

Intensive Reading-Skimming &Scanning - Extensive Reading –Meta cognitive reading - Topic sentence and

its Role-Reading and Interpretations- Critical Reading – Reading and summarizing.




Date : 12.04.2017 Date: 03.10.2017


UNIT IV: WRITING SKILL 6 Hrs

Descriptive Writing –Paragraph-Technical descriptions-Essays-Letter Writing – Formal and Informal-Business

Letters-Job Application Letter-Types of reports-Instructions and Checklists Paragraph Writing- Descriptive

Writing –Paragraph - Definition Writing – Extended Definition – Purpose Statement – Sequence words – E

mail writing – Flow chart – pie chart – note taking – Dialogue writing – Circular writing- Latter to the editor –

personal letter writing – circular writing

UNIT V: LISTENING AND SPEAKING 6 Hrs


Dialogue Writing -Professional Communication-Interview-Group Discussion –Power point Presentation-Lab

Listening and note taking – Role play – Group Discussion

TOTAL: 30 Hours

TEXT BOOK:

1. Department of English, Anna University. Mindscapes: English for Technologists and Engineers. Orient

Blackswan, Chennai. 2012.

2. English and communication skills—S.P.Dhanavel.Orient Blackswan (2010).

REFERENCE BOOKS:

1. Essential Grammar use – Raymond Murphy, Cambridge (2007).

2. Anderson, Paul V. Technical Communication: A Reader-Centered Approach. Cengage. New Delhi.

2008.

3. Muralikrishna, & Sunita Mishra. Communication Skills for Engineers. Pearson, New Delhi. 2011.

4. Smith-Worthington, Darlene & Sue Jefferson. Technical Writing for Success. Cengage, Mason USA.

2007.




Date : 21.04.2017 Date: 28.04.2017



Course Code

UBMTC02

Course Name :

Engineering Mathematics – II

L T P C

3 1 0 4

Year and Semester

I Year ( II Semester ) Contact hours per week ( 4Hrs )

Prerequisite course

Engineering Mathematics – I

Course

Objective

1. To provide the required skill to apply the concepts of ordinary differential equations.

2. To provide the required ideas to solve the problems on higher order ordinary differential

equations.

3. To acquaint the student with the concepts of vector calculus needed for problems in

engineering discipline.

4. To understand the standard techniques of complex variable problems.

5. To create a new domain to handle the problem in easier by using transform.


1. Gain knowledge on ordinary differential first order equations in the process field related

to engineering.

2. Illustrate the use of ordinary differential higher order equations in the process field

related to engineering.

3. Solve problems using vector calculus.

4. Construct and understand the properties of analytic functions.

5. Interpret the use of Laplace transforms in the engineering field.

6. Summarize the applications of ordinary differential equations, vector calculus and

Laplace transforms in the engineering field.




Date : 21.04.2017 Date: 28.04.2017


UNIT I ORDINARY DIFFERENTIAL EQUATIONS–FIRST ORDER AND APPLICATION 12Hrs

Definition - order and degree - formation of differential equation - Solution of first order - first degree

equations in variable separable form - homogeneous equations - other substitutions - Equations reducible to

homogeneous and exact differential equations - Equations reducible to exact Integration Factor - Linear

differential equation of first order first degree, reducible to linear - Applications to electrical circuits and

orthogonal trajectories.

UNIT II ORDINARY DIFFERENTIAL EQUATIONS–HIGHER ORDER AND APPLICATIONS

12 Hrs

Higher (nth) order linear differential equations - definition and complementary solution- Methods of obtaining

PI, Method of variation of parameters - Method of undetermined coefficients - Cauchy‗s Homogeneous LDE

and Legendre‗s equations - System of Ordinary Differential Equations Simultaneous equations in symmetrical

form.

UNIT III VECTOR CALCULUS 12 Hrs

Gradient Divergence and Curl – Directional derivative – irrotational and solenoidal vector fields –Vector

integration – Green‗s theorem in a plane, Gauss divergence theorem and stokes‗theorem (excluding proofs) –

Simple applications involving cubes and rectangular parallelepipeds.

UNIT IV ANALYTIC FUNCTIONS 12 Hrs

Functions of a complex variable – Analytic functions – Necessary conditions, Cauchy – Riemann equation and

Sufficient conditions (excluding proofs) – Harmonic and orthogonal properties of analytic function –

Harmonic conjugate – Construction of analytic functions – Conformal mapping - bilinear transformation.

UNIT V LAPLACE TRANSFORM 12 Hrs

Laplace transform – Conditions for existence – Transform of elementary functions – Basic properties–

Transform of derivatives and integrals – Transform of unit step function and impulse functions –Transform of

periodic functions. Definition of Inverse Laplace transforms as contour integral – Convolution theorem

(excluding proof) – Solution of linear ODE of second order with constant coefficients using Laplace

transformation techniques.

TOTAL: 60 Hours




Date : 21.04.2017 Date: 28.04.2017


TEXT BOOK:

1. Bali N. P and Manish Goyal, ―Text book of Engineering Mathematics, 3rd

Edition, Laxmi Publications

(p) Ltd., 2008.

2. Grewal. B.S, ―Higher Engineering Mathematics, 40thEdition, Khanna Publications, Delhi, 2007.

REFERENCE BOOKS:

1. Ramana B.V, ―Higher Engineering Mathematics, Tata McGraw Hill Publishing Company,

NewDelhi, 2007.

2. Glyn James, ―Advanced Engineering Mathematics, 3rdEdition, Pearson Education, 2007.

3. Erwin Kreyszig, ―Advanced Engineering Mathematics, 7thEdition, Wiley India, 2007.

4. Jain R.K and Iyengar S.R.K, ―Advanced Engineering Mathematics, 3rdEdition, Narosa Publishing House

Pvt., 2007.





Course Code

UCPH CO2 Course Name :

Engineering Physics II

L T P C

3 0 0 3

Year and Semester

I Year ( II Semester ) Contact hours per week

3 Hours

Prerequisite course

Engineering Physics-I

Course

Objective Students should understand about properties of light and sound waves and relate their significance for the development of technology


1 Demonstrate the applications of sound waves.

2 Describe the laser principle, their working and applications.

3 Determine crystal parameters.

4 Deduce the electrical conductivity in semiconductors and superconductors.

5 Explain the behavior of dielectric and magnetic materials.

6 Identify the principles of light and sound waves in various applications

UNIT – I: ACOUSTICS AND ULTRASONICS: 9 Hrs

Wave-types of waves-wave motion. Sound- classification of sound – characteristics of musical sound.

Loudness – Weber Fechner law – Decibel – Reverberation – Reverberation time – Sound absorption

coefficient- Sabine‘s formula for determining reverberation time (Rate of Growth and Rate of Decay) –

determination of sound absorption coefficient – Factors affecting acoustics of buildings (Optimum

reverberation time, loudness, focusing, eco, echelon effect, resonance and noise) and their remedies.

Ultrasonics- production- piezo-electric method – SONAR-Ultrasonic flaw detector as non-destructive

testing technique.

UNIT-II: LASER AND FIBRE OPTICS: 9 Hrs

Laser-principle-properties – Einstein coefficient (A and B)-Nd-YAG laser – CO2 laser- Applications of

laser – Holography-construction and reconstruction of a hologram – Principle and propagation of light

in an optical fibre-types of optical fibres – applications-fibre optic communication system (block

diagram) – fibre optic sensors.

UNIT-III: CRYSTAL PHYSICS: 9 Hrs

Lattice-unit cell – Bravais lattice – lattice planes – Miller indices – ‗d‘ spacing in cubic lattice –

calculation of number of atoms per unit cell – atomic radius-coordination number – packing factor for

SC, BCC, FCC and HCP structures – Diamond and graphite structures (qualitative treatment) – X-ray -


Date : 28.06.2017


Date: _03.10.2017




Document Approved in ― Academic Council‖ held

on Date: _03.10.2017

Powder diffraction method to identify crystal structure parameters.

UNIT-IV: SEMICONDUCTORS AND SUPERCONDUCTORS 9 Hrs

Semiconductors – intrinsic and extrinsic semiconductor. Fermi level –Variation of Fermi level with

temperature-electrical conductivity. Band gap determination-Hall effect – Determination of Hall

coefficient – Applications. Superconductivity: Properties – Type I and Type II superconductors – BCS

theory of superconductivity-High Tc superconductors-Applications of superconductors – SQUID,

cryotron, magnetic levitation.

UNIT-V: DIELECTRIC, MAGNETIC AND NEW ENGINEERING MATERIALS 9 Hrs

Electrical susceptibility – dielectric constant – electronic, ionic, orientational and space charge

polarizations-frequency and temperature dependence on polarization-internal field – Claussius-Mosotti

relation – uses of dielectric materials. Magnetic properties – diamagnetic – paramagnetic –

ferromagnetic materials – super paramagnetism – Transducers. Properties and applications of metallic

glasses – nano materials – shape memory alloys – bio materials.

TOTAL: 45 Hours

TEXT BOOKS

1. S. O Pillai ―Solid State Physics‖, New Age International Pvt Ltd; 7th

edition, 2015.

2. Ajoy Ghatak , ―Optics‖, McGraw-Hill Education; 1st edition 2009.

3. Ajoy Ghatak, ―Introduction to Fiber optics‖, Foundation Books, 2002.

REFERENCES BOOKS:

1. Charles Kittel,‖ Introduction to Solid state physics‖, Wiley; Eighth edition 2012.

2. Ghatak and Thyagarajan, ―Laser Fundamentals and Applications‖, Springer, 2011.

3. Richard Feynmann, Robert Leighton and Matthew Sands,‖The Feynmann Lectures on Physics‖,

Volume 1, Student Edition, Narosa Publishing house, 2003.

4. Richard Feynmann, Robert Leighton and Matthew Sands ―The Feynmann Lectures‖ on Physics,

Volume 2, Student Edition, Narosa Publishing house, 2003.


Date : 28.06.2017




Date : 19.08.2017 Date: 03.10.2017



Course Code: UBEEC01

Course Name :

Basics of Electrical & Electronics

Engineering

L T P C

3

0

0

3

Year and Semester


( 3Hrs )

Prerequisite course

NIL

Course

Objective

1. To familiarize the basic laws, DC and AC theorems and the methods of analyzing

electrical circuits.

2. To understand the characteristics and performance of Semiconductor devices, Moving

coil and moving iron instruments.


1. Know the Laws and analysis with different source in DC circuits.

2. Illustrate the operation of single phase AC Circuits.

3. Gain level on Three phase AC Circuits.

4. Understand the performance characteristics of Semiconductor Devices.

5. Understand the basic concept of Electrical instruments.

6. Obtain knowledge on basis of Electrical & Electronics Engineering.

UNIT I:DC CIRCUITS 9 Hrs

Importance of Electrical Engineering in day-to-day life - Electrical elements and their classifications - KCL

and KVL equations - Loop current and node voltage method - Steady state analysis with independent and

dependent sources - parallel and series circuits and star delta conversion.

UNIT II: ANALYSING SINGLE PHASE AC CIRCUITS 9 Hrs

Common Signals and their Wave Form: RMS Value, Average Value, Form Factor and Peak Factor - Single

Phase A.C Series Circuits: Types, Phasor Diagram, Power Factor, Impedance, Power Triangle - Single Phase

A.C Parallel Circuits: Types, Phasor Diagram, Power Factor, Power Triangle – A.C Network Theorem‘s:

Thevinin‘s and Norton‘s Theorem– Superposition Theorem – Maximum Power Transfer Theorem - Mesh

Current and Node Voltage Method with A.C sources.

UNIT III: ANALYSING THREE PHASE AC CIRCUITS 9 Hrs

Three Phase Balanced and Unbalanced Voltage Sources – Analysis of Three Phase 3-Wire and 4-Wire Circuits




Date : 19.08.2017 Date: 03.10.2017


with Star and Delta Connected Loads, Balanced & Unbalanced – Phasor Diagram of Voltages and Currents –

Power and Power Factor Measurements in Three Phase Circuits.

UNIT IV: SEMICONDUCTOR DEVICES 9 Hrs

Characteristics of PN Junction Diode-Zener effect-Zener Diode and its Characteristics- Voltage regulation-

Bipolar Junction Transistor-CB, CE ,CC Configurations and Characteristics- Basic Construction of ‗N‘

channel & ‗P‘ channel JFET-Half wave and Full wave rectifiers.

UNIT V: BASIC ELECTRICAL MEASUREMENTS 9 Hrs

Construction and Operating Principles of Moving Coil and Moving Iron Instruments (Ammeter and

Voltmeter), Dynamometer Type Wattmeter and Basic Torque Equations, Electrodynamic frequency meter,

Energy Meter and Megger – Measurement Errors.

TOTAL: 45 Hours

TEXT BOOKS:

1. Arumugam and Prem Kumar, Electric Circuit Theory, Khanna Publishers, 2002.

2. William H. Hayt Jr, Jack E. Kemmerly and Steven M. Durbin, ―Engineering Circuits Analysis‖, Tata

McGraw Hill publishers, 6 th edition, New Delhi, 2003

3. R.S.Sedha, A Textbook of Applied Electronics, 3rd revised edition Edition,2008.

4. A.K.Sawhney-A Course in Electrical and Electronics Measurements and Instrumentation, 19th Revised

Edition 2011.

REFERENCE BOOKS:

1. Joseph A. Edminister, Mahmood Nahri, ―Electric circuits‖, Schaum‘s series, Tata McGraw-Hill, New

Delhi, 2001.

2. Sudhakar A and Shyam Mohan SP, ―Circuits and Network Analysis and Synthesis‖, Tata McGraw

Hill, 2007.

3. Charles K. Alexander, Mathew N.O. Sadiku, ―Fundamentals of Electric Circuits‖, Second Edition,

McGraw Hill, 2003.





Course Code UBBTC01

Course Name : Environmental Studies

L T P C

2 0 0 2

Common for BE (ME, PE, HE, Mech, EEE, NA)& BBA Shipping

Year and Semester


( 2Hrs )

Prerequisite course

Nil

Course

Objective 1. To study the interrelationship between living organism and environment. 2. To study the integrated themes and biodiversity, natural resources, pollution control

and wastemanagement.

Course Outcome The Students will be able to 1. Implement scientific, technological, economic and political solutions to environmental

problems.

2. Identify the interrelationship between living organism and environment.

3. Understand the importance of environment by assessing its impact on the human

world.

4. Analyze the envision the surrounding environment, its functions and its value..

5. Discuss the development and improvement in std. of living

6. Classify the integrated themes such as biodiversity, natural resources, pollution control

and waste management.

UNIT I: NATURAL RESOURCES 6 Hrs

Environmental studies – terminologies – need for public awareness – Natural resources – Renewable and non –

renewable resources – Characteristics, uses and conservation of natural resources-Forest resources, Water

resources, Mineral resources, Food resources, Energy resources and Land resources – Role of an individual in

conservation of natural resources – equitable use of resources for sustainable lifestyles.

UNIT II: ECOSYSTEMS 6Hrs

Concept of an ecosystem – Structure and function of an ecosystem – Producers, consumers and decomposers –

Energy flow in the ecosystem – Ecological succession – Food chains, food webs and ecological pyramids –

Introduction, types, characteristic features, structure and function of the different ecosystems – Forest

ecosystem, Grassland ecosystem, Desert ecosystem, Aquatic ecosystems (ponds, streams, lakes, rivers,

oceans, estuaries)

UNIT III : BIODIVERSITY AND ITS CONSERVATION 6Hrs

Introduction – Definition : genetic, species and ecosystem diversity – Biogeographical classification of India –

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


Date : 19.08.2017


Date: 03.10.2017





Date: 03.10.2017

Biodiversity at global, National and local levels – Inida as a mega-diversity nation - Hot-sports of biodiversity

– Threats to biodiversity - Endangered and endemic species of India – Conservation of biodiversity : In-situ

and Ex-situ conservation of biodiversity.

UNIT IV: ENVIRONMENT AND SOCIAL ISSUES 6Hrs

Environmental Pollution – Cause, effects and control measures of different types of pollution-Solid waste

Management –Role of an individual in prevention of pollution – Disaster management. Social Issues and the

Environment – from Unsustainable to Sustainable development – Urban problems related to energy – Water

conservation – Resettlement and rehabilitation of people – its problems and concerns- Environmental ethics –

Climate change, global warming, nuclear hazards, ill-effects of fireworks – Wasteland reclamation – Laws and

acts in India for environment protection , Public awareness.

UNIT V: HUMAN POPULATION AND THE ENVIRONMENT 6 Hrs

Population growth-variation among nations-Population explosion – Family Welfare Programme –

Environment and human health – Human Rights – Value Education – HIV/AIDS – Women and Child Welfare

– Role of Information Technology in Environment and human health. Field work and Field Visit.

TOTAL :30 Hours

TEXT BOOKS :

1. Gilbert M.Masters, ‗Introduction to Environmental Engineering and Science‘, 2nd edition, Pearson

Education, 2004.

2. Benny Joseph, ‗Environmental Science and Engineering‘, Tata McGraw-Hill, New Delhi,2006.

REFERENCES:

1. Agarwal K.C. Environmental Biology, Nidi Publications Limited, Bikaner, India, 2001.

2. Erach Bharucha. Textbook of Environmental Studies for Undergraduate Courses. University Grants

Commission, New Delhi , 2013.

3. N. Arumugam and V Kumaresan, Environmental Studies (UGC Syllabus), Saras Publications,

Nagercoil, India, 2014.

4. D.K. Asthana and Meera Asthana, A Textbook of Environmental Studies. S. Chand Publishing, New

Delhi, 2010.

5. B.S. Chauhan, Environmental Studies. Laxmi Publications, New Delhi, 2015


Date : 19.08.2017




Date : 06.03.2017 Date: 03.04.2017



Course Code UBMCC03

Course Name : Engineering Mechanics

L T P C

3

1

0

4

Year and Semester


( 4Hrs )

Prerequisite course

Nil

Course

Objective

1. Develop the ability to understand, formulate and analyze any engineering problem in a

simple logical manner and to solve basic problems in Engineering Mechanics.

2. Further, he should understand the principle of work and energy


1. Explain the engineering principles dealing with force, displacement, velocity and

acceleration

2. Build the knowledge on the equilibrium of rigid bodies

3. Examine rigid body subjected to dynamic forces

4. Use the fundamental concepts of kinematics and kinetics of particles to solve

engineering problems

5. Determine Friction and its effects

6. Demonstrate the principles of work and energy

UNIT I BASICS & STATICS OF PARTICLES 12 Hrs

Introduction - Units and Dimensions – Forces – System of forces – Resultant forces – Parallelogram law of

forces – Triangular law of forces – Polygon law of forces – Resolution and composition of forces – Principles

of transmissibility. Single equivalent force - Equilibrium of particles – Moment and couple – Scalar

components of moment – Varigon‗s Theorem.

UNIT II EQUILIBRIUM OF RIGID BODIES 12 Hrs

Equilibrium of forces – Law of mechanics - Lami‗s theorem. - Free body diagram – Requirement of Stable

Equilibrium – Equilibrium of rigid bodies in 2D – Examples - Type of supports and their support reactions.

UNIT III FRICTION 12 Hrs

Static and Dynamic Friction – Laws of friction - Equilibrium of a body on a rough Horizontal plane, inclined

Plane and inclined plane subjected to a force acting along the inclined plane - Applications of friction - Simple




Date : 06.03.2017 Date: 03.04.2017


contact friction (Ladder friction) – Screw friction – weight lifted by screw jack - Belt friction – Rolling

Resistance.

UNIT IV PROPERTIES OF SURFACES AND SOLIDS 12 Hrs

Determination of Areas and Volumes-First moments of area and the Centroid of sections- Rectangle, circle,

triangle from integration-T section, I section, Angle section, Hollow section using standard formula- Second

and product moments of plane area- Rectangle, triangle, circle from integration-T section. I section, Angle

section, Hollow section by using standard formula parallel axis theorem and perpendicular axis theorem- Mass

moment of Inertia.

UNIT V DYNAMICS OF PARTICLES AND RIGID BODIES 12 Hrs

Dynamics of Particles - Displacement, velocity and acceleration, their relationship – Relative motion-

Curvilinear motion – Newton‗s law – work-energy equation of particles - Impulse and Momentum – Law of

conservation of momentum – D‗Alembert‗s Principle – Types of collision - Collision of Elastic Bodies –

Newton‗s law of collision of bodies - co-efficient of restitution. Dynamics of Rigid Bodies – General plane

motion – Velocity and Acceleration – Absolute and relative motion method – Equilibrium of Rigid bodies in

Plane motion.

TOTAL : 60 Hours

TEXT BOOKS:

1. K.V. Natarajan, ―Engineering Mechanics‖, Dhanalakshmi publications, Revised Edition, 2008.

2. R.S Khurmi, ―A Textbook of Engineering Mechanics, S. Chand Publishers, 20th

Revised Edition,

2014.

REFERENCE BOOKS:

1. S.S. Bhavikatti, ―Engineering Mechanics, New Age International Publishers, 4th

revised edition, 2012.

2. Palanichamy & Nagan, ―Engineering Mechanics Statics & Dynamics, Tata McGraw-Hill, Latest

Edition, 2001.

3. S. Rajasekaran, G. Sankara Subramania, ―Fundamentals of Engineering Mechanics‖, Vikas Publishing

House Pvt. Ltd., 2006.

4. Beer, F.P and Johnson Jr. E.R, ―Vector Mechanics for Engineers, Vol.1 Statics and Vol.2.

Dynamics, TataMcGraw-Hill International Edition, 2001.




Date : 19.08.2017 Date: _03.10.2017



Course Code UCEE201

Course Name : Digital Logic Circuits

L T P C

3 0 0 3

Year and Semester


( 3Hrs )

Prerequisite course

NIL

Course

Objective

1. To introduce the concept of digital and binary systems

2. Be able to design and analyze combinational logic circuits & sequential logic circuits.


1. Understand the basic fundamentals of number system and logic families

2. Develop and design a combinational circuit and analyze the logic

3. Design and analysing all digital circuits

4. Build p the knowledge on ASM and PLC

5. Recall VHDL code for combinational and sequential circuits

6. Design a sequential circuit using the design procedure

UNIT – I NUMBER SYSTEMS AND DIGITAL LOGIC FAMILIES 9 Hrs

Review of number systems - binary codes - error detection and correction codes (Parity and Hamming code)-

K-map representations- minimization using K maps and Tabulation method- Digital Logic Families and its

comparison. Characteristics of digital logic family.

UNIT – II COMBINATIONAL CIRCUITS 9 Hrs

Combinational logic - representation of logic functions - SOP and POS forms, – simplification and

implementation of combinational logic – Encoder and Decoder - multiplexers and demultiplexers -code

converters, adders, Subtractors.

UNIT- III SYNCHRONOUS SEQUENTIAL CIRCUITS 9 Hrs

Sequential logic- SR, JK, D and T flip flops - level triggering and edge triggering -counters - asynchronous and

synchronous type – Modulo counters - Shift registers - design of synchronous sequential circuits – Moore and

Melay models- state diagram, state reduction and state assignment.




Date : 19.08.2017 Date: _03.10.2017


UNIT – IV ASYNCHRONOUS SEQUENTIAL CIRCUITS AND PROGRAMMABLE LOGIC

DEVICES 9 Hrs

Asynchronous sequential logic circuits-Transition table, flow table-race conditions - hazards &errors in digital

circuits - analysis of asynchronous sequential logic circuits-introduction to Programmable Logic Devices:

PROM – PLA –PAL.

UNIT-V: VHDL 9 Hrs

RTL Design – combinational logic – Sequential circuit – Operators – Introduction to Packages – Subprograms

– Test bench. (Simulation /Tutorial Examples: adders, counters, flip-flops, FSM, Multiplexers

/Demultiplexers)

TOTAL : 45 Hours

TEXTBOOKS:

1. Raj Kamal, ‗ Digital systems-Principles and Design‗, Pearson Education 2nd edition, 2007.

2. M. Morris Mano, ‗Digital Design with an introduction to the VHDL‗, Pearson Education, 2013.

3. Comer ―Digital Logic & State Machine Design, Oxford, 2012.

REFERENCES:

1. Mandal Digital Electronics Principles & Application, McGraw Hill Edu,2013. 2. William Keitz, Digital Electronics-A Practical Approach with VHDL,Pearson,2013.

3. Floyd and Jain, Digital Fundamentals‗, 8th edition, Pearson Education, 2003.

4. Anand Kumar, Fundamentals of Digital Circuits,PHI,2013.

5. Charles H.Roth,Jr,Lizy Lizy Kurian John, Digital System Design using VHDL, Cengage, 2013.

6. John M.Yarbrough, Digital Logic, Application & Design‗, Thomson, 2002.

7. Gaganpreet Kaur, VHDL Basics to Programming, Pearson, 2013.

8. Botros, HDL Programming Fundamental, VHDL& Verilog, Cengage, 2013




Date : 19.08.2017


Date: 03.10.2017



Course Code

UBEECPA

Course Name :

Basics of Electrical & Electronics

Engineering Laboratory

L T P C

0

0

2

1


Year and Semester


( 2Hrs )

Prerequisite course

NIL

Course

Objective

1. To acquire knowledge with an adequate work experience in the measurement of

different quantities

2. Expertise in handling the instruments involved.

Course Outcome The Students will be able to 1. Obtain knowledge on electric instruments, such as ammeter, voltmeter, multimeter

and oscilloscope.

2. Draw vector diagram for different R,L and C characteristics

3. Identify AC power sources and service equipment.

4. Demonstrate operation of various Electronic devices.

5. Conduct experiment using resistors, capacitors, inductors, voltage sources. 6. Conduct experiment to study the characteristics of electronic devices


1. Measurement of 'Low and High' resistances by Voltmeter and Ammeter method.

2. To obtain the current and voltage distribution in A.C. 'R-L-C' series circuits and draw the vector diagrams.

3. To obtain the current and voltage distribution in AC 'R.L.C' parallel circuits and draw the vector diagrams.

4. To measure the power and power factor of a single-phase load by 3 voltmeter method & ammeter

method.

5. To measure the power input to 3-phase induction motor using two watt meters.

6. Characteristics of PN Junction Diode.

7. Characteristics of Zener Diode

8. Characteristics of JFET

9. Study of Half wave and Full wave Rectifiers

10. Study of CRO and LISSAJOUS pattern

TOTAL : 30 Hours



Document Prepared in― Board of Studies‖ held

on


on

Date: 03.04.2017 Date : 06.03.2017



Course Code

UBWSCPA

Course Name : Engineering Practices Laboratory

L T P C

0 0 4 2

Year and Semester


( 4Hrs )

Prerequisite course

Nil

Course

Objective

1. To provide exposure to the students with hands on experience on machining,

electric arc welding oxy – acetylene welding and fitting


1. Outline the operation of lathes and drilling machines.

2. Make use of welding equipments to join the structures.

3. Create simple components using lathe and drilling machine

4. Develop the Process of chipping, filling, hack sawing, drilling, tapping

5. Plan assembling and dismantling of components 6. Construct simple lap, butt and tee joints using arc welding equipments

MACHINING:

Introduction and familiarization of operation of laths, drilling machines, shaping, milling and grinding

machines - Safety- personal, tools, machines and environmental - Measuring tools and methods of

measurement, reading of sketches and drawing, cutting tools, tool geometry - setting of tools methods of

fixing of jobs on chucks, vices, jigs and fixtures - Speeds and feeds of machines - Operations of machines -

Practical exercises on machines to develop and improve hands on skills.

FITTING:

Introduction and familiarization of various hand tools- Measuring, marking, cutting, holding and assembly

tools, materials, parts, uses and safety of tools and personal safety - Process and procedures for measuring,

Understanding of sketches and drawing - Marking and job holding methods - Process of chipping, filling,

hack sawing, drilling, tapping, dieying, assembling and dismantling of components - Practical exercises to

develop and improve hands on skills.

ELECRIC ARC WELDING

Introduction, familiarization of different types of welding machines- welding Transformer, functions, tools,

and equipment and environmental - Basic procedures of striking the arc - different methods of joining

metals- different welding joints in different positions - welding defects - testing of welding joints - Practical

exercises of welding of different thickness of metals in different positions to develop and improve hands on

skills.




on


on

Date: 03.04.2017 Date : 06.03.2017


OXY – ACETELENE WELDING

Introduction – familiarization of tools and equipments - Gas cylinders, regulators, hoses and gas welding

and gas cutting blow pipes - DS Processors - Procedures for setting up the equipments - Checking for

leakage of gases, setting of jobs filler rods, flux, flame setting and controls of flame safety - personal safety

protection, safety of cylinders, tool equipments and environmental safety-Procedures for gas welding,

brazing and gas cutting - Different methods of joints in different positions and defects of joints, testing of

joints - Practical exercises to develop and improve hands on skill of gas welding, brazing and gas cutting.

TOTAL : 30 Hours




Date : 11.07.2017 Date: 03.10.2017



Course Code UCLECPC

Course Name : Spoken English-II

L T P C

0 0 4 2

Year and Semester


( 4 Hrs )

Prerequisite course

NIL

Course

Objective

1. To help learners develop their listening skills, which will, enable them listen to

lectures and comprehend them by asking questions, seek clarifications.

2. To help learners develop their speaking skills and speak fluently in real contexts.

3. Address the interview confidently

4. Making them realise the importance of English as Global language and its

importance in today‗s scenario. Course Outcome The Students will be able to

1. Understand the factors that influence use of grammar and vocabulary in speech and

writing.

2. Comprehend the Commitment towards Personality Improvement.

3. Assess their communication skills and apply strategies for improving their ability

to listen and speak effectively.

4. Develop verbal and Non-verbal communication and problem solving skills

5. Highlight the strength of interview skills.

6. Identify and introspect their extrovert skills




Date : 11.07.2017 Date: 03.10.2017



Training the students on second phase of grammar such as Articles, Prepositions, Pronouns, Modal Auxiliaries,

Parts of Speech, Adjectives and Adverbs .

UNIT II: INTRO TO PROFESSIONAL ETHICHS Hrs 8 hrs

Stepping the students to advanced learning resource and introducing them about International standards

How to conduct meetings, huddle, public speaking, free speech. Dress code.


The main objective is English for International communication. It course contains conversations, snapshots,

readings, activities, a greater variety and amount of listening materials and more visuals to introduce

vocabulary, more opportunities to build fluency, and up-to-date art and design.


Types of Listening –Introduction to International Standards of listening skills. Presentation skills: delivery

(emphasis and phrasing) / making it interesting / body language / referring to visual aids


Familiarize the students with types of Interviews such as mock interviews , campus Interview, skype

interview, telephonic Interview, Panel Interview,

TOTAL: 60 Hours

TEXT BOOKS:


REFERENCE BOOKS:






Course Code UBMTC03

Course Name : Engineering Mathematics – III

L T P C

3 1 0 4

Common for BE (MECH, EEE, NA, PE, HE, ME)

Year and Semester

II Year ( III Semester ) Contact hours per week

( 4Hrs )

Prerequisite

course

Engineering Mathematics – II

Course

Objective 1. To introduce Fourier series analysis this is central to many applications in engineering

apart from its use in solving boundary value problems. To acquaint the student with

Fourier transform techniques used in wide variety of situations.

2. To introduce the effective mathematical tools for the solutions of partial differential

equations that model several physical processes and to develop Z transform techniques for

discrete time systems.


1. Solve problems on Partial Differential Equations.

2. Demonstrate the use of Fourier Series in solving physical problems.

3. Illustrate the applications of Partial Differential Equations.

4. Apply Fourier Transform in physical systems.

5. Evaluate Z-transform of physical systems.

6. Understand the applications of partial Differential Equations, Fourier series, and all the

transforms.

UNIT I PARTIAL DIFFERENTIAL EQUATIONS PARTIAL DIFFERENTIAL EQUATIONS 12 Hrs

Formation of partial differential equation – Solution of PDE by direct Integration- Solution of equation

Pp Qq R- Nonlinear equations of First order – Four types – (p,q) 0, f (z, p,q) 0, f x, p f y,q and z

xp yq f (p,q)

UNIT II FOURIER SERIES 12 Hrs

Definition of Fourier‗s series – Fourier Coefficients – Expansion of functions in Fourier series – Even and odd

functions – Half range Fourier series for any interval -l, l – Harmonic analysis – Estimation of Fourier

coefficients given values of function in it domain.


Date : 21.04.2017


Date: 28.04.2017





on Date: 28.04.2017

UNIT III APPLICATIONS OF PARTIAL DIFFERENTIAL EQUATIONS 12 Hrs

Classification of PDE – Method of separation of variables - Solutions of one dimensional wave equation – One

dimensional equation of heat conduction – Steady state solution of two dimensional equation of heat

conduction (excluding insulated edges).

UNIT IV FOURIER TRANSFORMS 12 Hrs

Definition-Fourier Integral Theorem-Fourier Transform-Properties of Fourier transform (Without proof)-

Convolution-Relation between Fourier and Laplace transforms.

UNIT V Z - TRANSFORMS 12 Hrs

Definition- standard Z-transforms- Standard results- properties of Z- transform (Without proof)- Initial value

and Final value theorem- Inverse Z-transform –Convolution theorem-Convergence- Evaluation of Z-transform

TOTAL: 60 Hours

TEXT BOOKS:

1. Veerarajan. T., "Transforms and Partial Differential Equations", Tata McGraw Hill Education Pvt.Ltd.,

New Delhi, Second reprint, 2012.

2. Grewal. B.S., "Higher Engineering Mathematics", 42nd Edition, Khanna Publishers, Delhi, 2012..

REFERENCES:

1. Bali.N.P and Manish Goyal, "A Textbook of Engineering Mathematics", 7th Edition, Laxmi Publications

Pvt Ltd , 2007.

2. Ramana.B.V., "Higher Engineering Mathematics", Tata Mc-Graw Hill Publishing Company

Limited,NewDelhi, 2008.

3. Glyn James, "Advanced Modern Engineering Mathematics", 3rd Edition, Pearson Education, 2007.

4. Erwin Kreyszig, "Advanced Engineering Mathematics", 8th Edition, Wiley India, 2007.

5. Ray Wylie. C and Barrett.L.C, "Advanced Engineering Mathematics" Tata Mc Graw Hill Education Pvt

Ltd, Sixth Edition, New Delhi, 2012.

6. Datta.K.B., "Mathematical Methods of Science and Engineering", Cengage Learning India Pvt Ltd,Delhi,

2013.


Date : 21.04.2017


Date : 19.08.2017 Date: 03.10.2017


CBCS CURRICULUM (2016 -17) (Regulation – C) Program Name: BE-Electrical and Electronics Engineering


Course Code UBEE302

Course Name: DC and AC Machines

L T P C

3 0 0 3

Year and Semester II Year ( III Semester ) Contact hours per week

( 3Hrs ) Prerequisite course Electromagnetic theory, Circuit Analysis

Course Objective 1. To impart knowledge about construction and characteristics of DC and AC Machines

2. To estimate the various losses and performance.


1. Illustrate the construction details and characteristic of DC generators

2. Determine the performance characteristic of dc motor and starters

3. Outline the functions of single phase and three phase transformers.

4. Analyze the performance and characteristics of induction machines

5. Infer knowledge on the performance and characteristics of synchronous machines

6. Analyze the electrical apparatus and their application to power system

UNIT I : DC GENERATORS 9 Hrs

Constructional details – EMF equation – Methods of excitation – Self and separately excited generators –

Characteristics of series, shunt and compound generators – Armature reaction and commutation – parallel

operation of DC shunt and compound generators

UNIT II: DC MOTORS 9 Hrs

Principle of operation – Back emf and torque equation – Characteristics of series, shunt and compound motors

– starting of DC motors – Types of Starters – speed control of DC series and shunt motors.

UNIT III: TRANSFORMERS 9 Hrs

Constructional details of core and shell type transformers – Type of windings – Principle of operation – emf

equation – Transformation ratio – Transformer on no load- Parameters referred to HV/ LV winding –

Equivalent circuit – Transformer on load Regulation – Parallel operation of single phase transformers – Auto

transformer – Three phase transformers – vector group.

UNIT:IV INDUCTION MACHINES THEORY AND PERFORMANCE 9 Hrs

Construction – type – principle of operation of motor – emf, torque and power flow equations – torque and

speed curves – double cage motor and equivalent circuit induction motor testing, equivalent circuit and circle

diagram – losses and efficiency – performance characteristics – harmonics , cogging- starting methods – speed

control methods – braking – temperature rise and insulating –energy motors.


Date : 19.08.2017 Date: 03.10.2017



UNIT: V SYNCHRONOUS MACHINES: THEORY AND PERFORMANCE 9 Hrs

Construction – Types – generator and motor action – theory of cylindrical motor machines – armature reaction

and synchronous reactance – emf and power equation synchronization – synchronizing power and parallel

operation steady state operating characteristics – hunting – short circuit.

TOTAL :45 Hours

TEXT BOOKS:

1. Nagrath I. J and Kothari D. P. ‗Electric Machines‘, Fourth Edition, Tata McGraw Hill Publishing

Company Ltd, 2010.

2. P.S. Bimbhra, Electrical Machinery‗,Khanna Publishers, 2003.

3. Fitzgerald. A.E., Charles Kingsely Jr, Stephen D.Umans, ‗Electric Machinery‘, Sixth edition, Tata

McGraw Hill Books Company, 2003

REFERENCES:

1. Theraja, B.L. Electrical Technology Vol-II S. Chand Publication, New Delhi,23rd

edition, Reprint

2004.

2. Deshpande M. V., ―Electrical Machines‖ PHI Learning Pvt. Ltd., New Delhi, 2011

3. S.Sarma & K.Pathak ―Electric Machines‖, Cengage Learning India (P) Ltd., Delhi, 2011.


Date : 11.07.2017 Date: 03.10.2017




Course Code UCIT3PA

Course Name : Object Oriented Programming Lab

L T P C

0 0 2 1


Year and Semester

II Year (III Semester ) Contact hours per week

( 2Hrs )

Prerequisite course

Nil

Course

Objective

1. To state basic programming skills in C++ and Java

2. To illustrate object oriented concepts in Java and C++ including data abstraction,

data encapsulation, overloading and inheritance

Course Outcome 1. Understand basic programming skills in C++ and Java

2. Design and implement C++ programs

3. Design and implement Java programs

4. Apply good programming design methods for program development

5. Apply the OOP concepts for implementing solutions to practical problems

6. Understand Object oriented concepts

LIST OF EXPERIMENTS :

Implementation in the following Topics:

1. Problems for practicing basic programming structures in C++ and Java

2. Classes and Objects

3. Interfaces

4. API Collections

5. Friend Function & Friend Class

6. Inheritance

7. Polymorphism & Function Overloading


Date : 11.07.2017 Date: 03.10.2017



8. Virtual Functions

9. Overload Unary & Binary Operators Both as Member Function & Non Member Function

10. Class Templates & Function Templates

11. Exception Handling Mechanism

12. File Stream classes

Total : 30 Hours



Document Prepared in― Board of Studies‖ held on Document Approved in ― Academic Council‖ held

on

Date: 03.04.2017 Date : 06.03.2017_



Course Code UBMCC11

Course Name : Thermodynamics

L T P C

4 0 0 4

(Common to BE – Mechanical ,BE-Marine & BE - NA&OE)

Year and Semester


( 4Hrs )

Prerequisite course

NIL

Course

Objective

1. This course provides basic knowledge about thermodynamics and relation

2. Application of thermodynamics to various processes.


1. Understand thermodynamics laws and their applications

2. Explain concept of entropy and availability

3. Evalute the properties of steam and their uses of steam table and moulier chart

4.Apply thermodynamics relation

5. Describe psychometric chart

6. Summarize the concepts of thermodynamics and its applications.

UNIT I:- BASIC CONCEPTS AND FIRST LAW 12 Hrs

Basic concepts - concept of continuum, comparison of microscopic and macroscopic approach. Path and

point functions. - Intensive and extensive, total and specific quantities. System and their types -

Thermodynamic Equilibrium State - path and process Quasistatic, reversible and irreversible processes -

Heat and work transfer, definition and comparison - sign convention – Displacement work and other modes

of work – pv diagram - Zeroth law of thermodynamics – concept of temperature and thermal equilibrium –

relationship between temperature scales – new temperature scales - First law of thermodynamics –

application to closed and open systems – steady and unsteady flow processes.

UNIT- II:- SECOND LAW AND AVAILABILITY ANALYSIS 12 Hrs

Heat Reservoir, source and sink - Heat Engine, Refrigerator and Heat pump – Statements of second law and

its corollaries - Carnot cycle Reversed Carnot cycle, Performance - Clausius inequality. - Concept of –

entropy - t-s diagram - Tds Equations - entropy change for pure substance - ideal gases – different processes,

principle of increase in entropy - Applications of II Law - High and low grade energy - Available and non-

available energy of a source and finite body - Energy and irreversibility - Expressions for the energy of a

closed system and open systems - Energy balance and entropy generation - Irreversibility. I and II law

Efficiency.



Document Prepared in― Board of Studies‖ held on Document Approved in ― Academic Council‖ held

on

Date: 03.04.2017 Date : 06.03.2017_


UNIT- III:- PROPERTIES OF PURE SUBSTANCE AND STEAM POWER CYCLE 12 Hrs

Formation of steam and its thermodynamic properties – p-v, p-T, T-v, T-s, h-s diagrams - p-v-T surface -

Use of Steam Table and Mollier Chart - Determination of dryness fraction - Application of I and II law for

pure substances - Ideal and actual Rankine cycles - Cycle Improvement Methods - Reheat and Regenerative

cycles, Economizer, preheater, Binary and Combined cycles.

UNIT- IV:- IDEAL AND REAL GASES, THERMODYNAMIC RELATIONS 12 Hrs

Properties of Ideal gas- Ideal and real gas comparison- Equations of state for ideal and real gases - Reduced

properties-Compressibility factor - Principle of Corresponding states. Generalized Compressibility Chart and

its use - Maxwell relations - Tds Equations - Difference and ratio of heat capacities - Energy equation – Joule

- Thomson Coefficient – Clausius Clapeyron equation - Phase Change Processes - Simple Calculations.

UNIT –V:- GAS MIXTURES AND PSYCHROMETRY 12 Hrs

Mole and Mass fraction - Dalton‗s and Amagat‗s Law - Properties of gas mixture - Molar mass, gas constant,

density, change in internal energy, enthalpy, entropy and Gibbs function - Psychometric properties -

Psychometric charts - Property calculations of air vapour mixtures by using chart and expressions -

Psychometric process - adiabatic saturation, sensible heating and cooling, humidification, dehumidification,

evaporative cooling and adiabatic mixing - Simple Applications.

TOTAL : 60 Hours

TEXT BOOKS:

1 .Nag.P.K., ―Engineering Thermodynamics, 4thEdition, Tata McGraw-Hill, New Delhi,2008.

2. Cengel. Y and M.Boles, "Thermodynamics - An Engineering Approach", 7th Edition, Tata Mc Graw

Hill, 2010.

REFERENCES:

1. Natarajan E., "Engineering Thermodynamics: Fundamentals and Applications", Anuragam

Publications, 2012

2. Rathakrishnan. E., "Fundamentals of Engineering Thermodynamics", 2nd Edition, Prentice-Hall of

India Pvt. Ltd.,2005.

3. Chattopadhyay, P, "Engineering Thermodynamics", Oxford University Press, 2010

4. Arora C.P, ―Thermodynamics, Tata McGraw-Hill, New Delhi, 2003.




Date : _06.03.2017_ Date: 03.04.2017



Course Code UBMCC04

Course Name : Fluid Mechanics

L T P C

3 0 0 3

Common for BE (ME, MECH, NAVOE and EEE)

Year and Semester


( 3Hrs )

Prerequisite course

NIL

Course

Objective

1. To understand the properties and characteristics of fluids flow.

2. To understand the properties and characteristics of fluids and to analyze the

performance of pumps and turbines


1. Understand the various properties of fluids and governing equations for fluid flow.

2. Obtain knowledge on flow through circular conduits.

3. Infer knowledge on Buoyancy and floatation.

4. Demonstrate the operation of various pumps and their uses.

5. Illustrate the working principle of various types of turbines.

6. Apply knowledge on fluid mechanism in real world applications.

UNIT I: FLUID PROPERTIES AND FLOW CHARACTERISTICS 9 Hrs

Units and dimensions- Properties of fluids- mass density, specific weight, specific volume, specific gravity,

viscosity, compressibility, vapour pressure, surface tension and capillarity - Flow characteristics – concept of

control volume - application of continuity equation, energy equation - Equation of motion – Eulers‗ equation

of motion – Bernoulli‗s equation - Momentum equation

UNIT II: FLOW THROUGH CIRCULAR CONDUITS 9 Hrs

Hydraulic and energy gradient - Laminar flow through circular conduits and circular annuli- Boundary layer

concepts – types of boundary layer thickness – Darcy Weisbach equation – friction factor- Moody diagram-

commercial pipes- minor losses – Flow through pipes in series and parallel

UNIT III: BUOYANCY AND FLOATATION 9 Hrs

Buoyancy – centre of Buoyancy – Metacentre – Meta centric height – Analytical method for determining meta

centre – Condition for Equilibrium of a floating and sub-merged Bodies – experimental method of

determination of Meta centric height.




Date : _06.03.2017_ Date: 03.04.2017


UNIT IV: PUMPS 9 Hrs

Impact of jets - Euler‗s equation - Theory of roto-dynamic machines – various efficiencies– velocity

components at entry and exit of the rotor- velocity triangles - Centrifugal pumps– working principle - work

done by the impeller - performance curves - Reciprocating pump working principle – Rotary pumps –

classification.

UNIT V: TURBINES 9 Hrs

Classification of turbines – heads and efficiencies – velocity triangles. Axial, radial and mixed flow turbines.

Pelton wheel, Francis turbine and Kaplan turbines- working principles - work done by water on the runner –

draft tube. Specific speed - unit quantities – performance curves for turbines – governing of turbines.

TOTAL : 45 Hours

TEXT BOOKS:

1. Dr. R.K.Bansal ―A text book of Fluid Mechanics and Hydrulic Machines‖ , Laxmi Publications, 9th

edition, 2017.

2. Modi P.N. and Seth, S.M. "Hydraulics and Fluid Mechanics", Standard Book House, New Delhi 2004.

REFERENCES:

1. Kumar K. L., "Engineering Fluid Mechanics", Eurasia Publishing House(p) Ltd., New Delhi , 2004.

2. Robert W.Fox, Alan T. McDonald, Philip J.Pritchard, ―Fluid Mechanics and Machinery, 2011.




Date : 19.08.2017 Date: 03.10.2017



Course Code

UBEE309

Course Name :

Electric Circuits and Electronic

Devices

L T P C

3

0

0

3

Year and Semester


(3Hrs )

Prerequisite course

Basics of Electrical and Electronics Engineering

Course

Objective

1. Analyze various switching circuits

2. Apply knowledge, techniques, and skills to design electrical and electronic circuits.

Course Outcome The Students will be able to 1. Illustrate the transient response of series and parallel circuits and to solve problems

in time domain using Laplace Transform.

2. Analyze the concept of resonance in series & parallel circuits and coupled circuits.

3. Discuss the concept of Amplifiers.

4. Distinguish the feedback amplifiers and Oscillators.

5. Classify the basic concepts of pulse generation circuits, filters and power supply circuits.

6. Design and construct various electronics circuits.

UNIT I :TRANSIENT ANALYSIS OF FIRST & SECOND ORDER CIRCUITS 9 Hrs

Source free response of RL , RC and RLC series circuits – forced (step) response of RL, RC and RLC series

circuits, forced response of RL, RC and RLC series circuit to sinusoidal excitation – Initial and final value

theorems – driving point and transfer impedance.

UNIT II: RESONANCE AND COUPLED CIRCUITS 9 Hrs

Resonance in series and parallel circuits – Q factor, half-power frequencies and bandwidth of resonant circuits

– Coupled circuits – mutual inductance – coefficient of coupling – dot convention – analysis of simple

coupled circuits.

UNIT III: SMALL SIGNAL AND LARGE SIGNAL AMPLIFIERS 9 Hrs

Small signal analysis of CE, CC & Common base amplifiers – Cascade and Darlington connections – Push-

pull amplifiers – Differential amplifiers – Common mode and differential mode analysis – DC and AC analysis

– Characteristics of tuned amplifiers – Single & double tuned amplifier.

UNIT IV: FEEDBACK AMPLIFIER AND OSCILLATORS 9 Hrs

Characteristics of negative feedback amplifiers – Voltage / current, series/shunt feedback – Theory of

sinusoidal oscillators – Phase shift and Wien bridge oscillators – Colpitts, Hartley and crystal oscillators.




Date : 19.08.2017 Date: 03.10.2017


UNIT V: PULSE CIRCUITS ,FILTERS & POWER SUPPLY CIRCUITS 9 Hrs

RC wave shaping circuits – Diode clampers and clippers – Multivibrators – Schmitt triggers – UJT based saw

tooth oscillators. Inductor filter – Capacitor filter - Series voltage regulator, Switched mode power supply.

TOTAL : 45 Hours

TEXT BOOKS:

1. Arumugam and Prem Kumar, Electric Circuit Theory, Khanna Publishers, 2002.

2. Joseph A. Edminister, Mahmood Nahvi, Electric Circuits‗, Schaum‗s Series,Tata McGraw Hill

Publishing Co. Ltd., New Delhi 2001.

3. R.S.Sedha, A Textbook of Applied Electronics, Reprint, 2016.

4. David A.Bell ―Electronic Devices and Circuits‖, Oxford Higher Education Press, 5th Edition, 2010.

REFERENCES:

1. William H.HaytJr, Jack E.Kemmerly, and Steven M.Durbin, Engineering Circuit Analysis‗,

TataMcGraw Hill Publishing Co Ltd, New Delhi, 2002.

2. T.Nageswara Rao, Electric Circuit Analysis, A.R Publications, Sirkali, Tamil Nadu-2009.

3. Robert. L. Boylestad& Lo Nashelsky, Electronic Devices & Circuit Theory‗, Eighth edition, Pearson

Education, Third Indian Reprint, 2002.

4. Adel .S. Sedra, Kenneth C. Smith, ―Micro Electronic Circuits‖, 6th Edition, Oxford University Press,

2010.

5. Donald L.Schilling and Charles Belove, Electronic Circuits‗, 3rd Edition,Tata McGraw Hill,2003.





Date: 03.10.2017


Course Code UBEE3PA

Course Name: DC and AC Machines Laboratory

L T P C

0 0 2 1

Year and Semester


( 2 Hrs )

Prerequisite

course

Nil

Course Objective

1. To impart knowledge about various types of motors and their Load test

characteristics of Electrical Machines

2. To analyze the efficiency and performance of transformer ,induction and synchronous

motors by conducting various test


1. Illustrate the performance and characteristic of DC generators

2. Demonstrate the operation and characteristic of various DC motors.

3. Experiment with the load of single phase and three phase transformers.

4. Analyze the performance and characteristics of Induction Machines

5. Infer the performance and characteristics of Synchronous machines

6. Analyze the electrical apparatus and their application to power system

List of Experiments

1. Open circuit and load characteristics of D.C separately excited shunt generator

2. Open circuit and load characteristics of D.C self excited shunt generator

3. Load characteristics of D.C. compound generator with differential and cumulative connection

4. Load characteristics of D.C. shunt motor

5. Load characteristics of D.C series motor

6. Load characteristics of D.C compound motor

7. Swinburne‗s test and speed control of D.C shunt motor

8. Load test on single-phase transformer

9. Open circuit and short circuit tests on single phase transformer

10. No load and blocked rotor tests on Induction motor

11. Load test on induction motor.

12. V and Inverted V curves of Three Phase Synchronous Motor.

TOTAL :30 Hours


on

Date : 19.08.2017


Date : 06.03.2017 Date: 03.04.2017




Course Code UBMCCPC

Course Name : Fluid Mechanics Laboratory

L T P C

0 0 2 1

(Common to BE – Mechanical , Marine, BE – EEE)

Year and Semester


( 2Hrs )

Prerequisite course

NIL

Course

Objective 1. To understand the properties and characteristics of fluids.

2. Analyze the performance of pumps and turbines.


1. Illustrate the various properties of fluids and governing equations for fluid flow.

2. Analyze the flow and boundary layer concepts.

3. Find the coefficient of discharge of orifice and mouth piece

4. Illustrate the various types of pumps along with their applications

5. Determine the characteristics of Centrifugal Single stage pumps.

6. Demonstrate the performance characteristics of reaction Turbine

LIST OF EXPERIMENTS

1. To verify the Bernoulli‗s Theorem

2. To find the co-efficient of discharge in Orifice

3. To find the co-efficient of discharge in Mouth Piece

4. To find the co-efficient of discharge in Pitot Tube

5. To find the co-efficient of discharge in Pipe Friction apparatus

6. To determine the discharge in Triangular Notch

7. To determine the Met centric Height of the vessel

8. To determine the discharge of Jet Pump

9. To determine the discharge of Centrifugal Single stage Pump

10. To determine the discharge of Reciprocating Pump

11. Performance characteristics of Reaction Turbine

TOTAL :30 Hours


Date : 11.07.2017 Date: 03.10.2017



PROGRAM BE –Electrical and Electronics Engineering

Course Code UCIT301

Course Name : Object Oriented Programming

L T P C

3 0 0 3

Year and Semester II Year (III Semester ) Contact hours per week ( 03Hrs )

Prerequisite course Fundamentals of computer programming.

Course Objective

1. To summarize the fundamentals of object oriented concepts.

2. To compose a simple Constructor and destructor programs.

3. To contrast the various types of overloading and Inheritance.

4. To substitute interface for multiple inheritance in Java .

5. To compose Java packages and Thread programs in Java for real world problems.

Course Outcome

The Students will be able to

1. Apply the object oriented approach to programming and identify potential benefits of object-

oriented programming over other approaches.

2. Reuse the code and write the classes which work like built-in types.

3. Design applications which are easier to debug, maintain and extend.

4. Use object oriented concepts in real world applications.

5. Apply object-oriented concepts in Java and C++ including data abstraction, data encapsulation,

overloading and inheritance.

6. Differentiate Java and c++ programming through oops concepts.


Date : 11.07.2017 Date: 03.10.2017



UNIT I BASICS OF OOP 9 Hrs

Basic concepts of object oriented programming – Data Abstraction, Encapsulation, Inheritance and

Polymorphism - Benefits of OOP – Object-oriented languages – Applications of OOP - Structure of a C++

Program - Tokens – Keywords – Identifiers and constants – Data types – Symbolic constants – Declaration of

variables – Dynamic initialization of variables – Reference variables – Operators in C++ – Manipulators –

Type cast operator –Expressions and their types – Control structures - Function prototyping – Call by reference

– Return by reference – Inline functions –Function overloading

UNIT II CLASS AND OBJECT IN C++ 9 Hrs

Class – Defining member functions –Arrays within class – Memory allocation for objects – Static data

members – Static member functions – Arrays of objects – Objects as function arguments - Friendly function –

Constructors – Destructors

UNIT III OVER LOADING AND INHERITANCE IN C++ 9 Hrs

Operator overloading - Manipulation of strings using operators – Type Conversions - Defining derived classes

– Inheritance – Single, Multilevel inheritance – Abstract classes - Pointers to objects: This pointer – Pointers to

derived classes

UNIT IV JAVA WITH BASIC OOP FEATURES 9 Hrs

Java program structure – Java tokens – Java statements – Java virtual machine JVM – Command line

arguments - Constants – Variables – Data types – Operators in Java - Class and objects – Accessing class

members – Constructors – Method overloading – Static members – Inheritance – Overriding methods –

Abstract methods and classes - Arrays – Strings – Vectors

UNIT V JAVA WITH ADVANCED OOP FEATURES 9 Hrs

Interfaces - Java API packages – Using system packages – Adding a class to a package – Threads – Thread

exceptions – Thread priority – Life cycle of a thread – Using thread methods - Types of Exceptions –

Exception handling – Multiple Catch statements – Throwing our own exceptions – Using exceptions for

debugging

TOTAL: 45 Hours


Date : 11.07.2017 Date: 03.10.2017



TEXT BOOKS:

1. E.Balagurusamy, Object Oriented Programming with C++, Sixth edition, Tata McGraw Hill, 2013.

2. E.Balagurusamy, Programming with JAVA - A Primer, Fourth Edition, Tata McGraw Hill, 2010.

REFERENCES:

1. Herbert Schildt, ―C++ - The Complete Reference‖, Tata McGraw Hill, 1997.

2. Bjarne Stroustrup, ―The C++ Programming Language‖, Addison Wesley, 2000.

3. John R Hubbard, Schaums, ―Outline Programming with C++‖, Tata McGraw Hill, 2003.




Course Code UCLECPD

Course Name : Spoken English-III

L T P C

0 0 2 1


Year and Semester


( 2 Hrs )

Prerequisite course

NIL

Course

Objective

1. To make students to learn the advanced English

2. To raise up their confidence level

3. Making them aware of the coorporate world and the expectations

4. Prepare them for campus Interview


1. Conceptualize the nuances of the tenses in situational usage

2. Enhance verbal and collaborating other communicative activities

3. Coordinate and build fluency in the individuals lexical

4. Participate actively and Interactive participation of the self with other individuals

5. Participate and confidently step into and command situations with Clair.

6. Enhance the versatility of the students on all skills.


Training the students on basic grammar and foundation and laying the standard platform - A complete standard

syllabus of Cambridge is used - The main part of the 1st semester is to cover the major tenses (Present tense,

Present Continuous, Past Tense, Past Continuous, Present Perfect, and Present Perfect continuous.

UNIT II: BODY LANGUAGE AND LEXICAL RESOURCE WITH BASIC WRITTEN SKILS 6 Hrs

Posture, eye contact, gestures with hands and arms, speech, tone of the voice - One word substitutes - E-mail

communication, creating blogs, free writing on any given topic - writing definitions.


The main objective is English for International communication - It contains conversations, snapshots, readings,

activities, a greater variety and amount of listening materials and more visuals to introduce vocabulary, more

opportunities to build fluency, and up-to-date art and design - The course covers the fours skills of listening,

speaking, reading and writing as well as improving pronunciation and building vocabulary.


Date : 11.07.2017


Date: 03.10.2017




Date : 11.07.2017


Date: 03.10.2017



Dialogue Writing -Professional Communication-Interview-Group Discussion –Power point Presentation-Lab


Personality development – Self motivation, Self actualization, Stress management, Interview skills,

Negotiation skills, familiarization and strategies of telephonic , skype, one on one, panel, exit interviews.

TOTAL: 30 Hours

TEXT BOOKS:


2. Communication skills

REFERENCE BOOKS:



Date : 21.04.2017_ Date: 28.04.2017_




Course Code

UBMT403

Course Name :

Numerical Methods

L T P C

4 0 0 4

Common for BE( ME,PE,HE,NA,MECH, EEE) & BSC(NS) & BBA SHIPPING)

Year and Semester

II Year ( IV Semester ) Contact hours per week

( 4Hrs )

Prerequisite course

Mathematics - III

Course

Objective 1. To Understand the perception of the power of numerical techniques. 2. To Understand numerically different kinds of problems occurring in engineeringand

technology.

Course Outcome The Students will be able to 1. Understand the basic knowledge on solution of eigen values

2. Use interpolation and approximation to solve engineering problem.

3. Discuss the numerical differentiation and integration.

4. Apply initial value problems for solving first order differential equation.

5. Apply the boundary value problems in ordinary and partial differential equations. 6. Solve problem in engineering field using numerical methods

UNIT I SOLUTION OF EQUATIONS AND EIGENVALUE PROBLEMS 12 Hrs

Solution of algebraic and transcendental equations - Fixed point iteration method – Newton Raphson method-

Solution of linear system of equations - Gauss elimination method – Pivoting - Gauss Jordan method –

Iterative methods of Gauss Jacobi and Gauss Seidel - Matrix Inversion by Gauss Jordan method - Eigen values

of a matrix by Power method.

UNIT II INTERPOLATION AND APPROXIMATION 12 Hrs

Interpolation with equal intervals - Lagrange's interpolation – Newton‘s divided difference Interpolation –

Cubic Splines - Interpolation with equal intervals - Newton‘s forward and backward difference formulae.

UNIT III NUMERICAL DIFFERENTIATION AND INTEGRATION 12 Hrs

Approximation of derivatives using interpolation polynomials - Numerical integration using Trapezoidal,

Simpson‘s 1/3 rule – Romberg‘s method - Two point and three point Gaussian quadrature formulae –

Evaluation of double integrals by Trapezoidal and Simpson‘s 1/3 rules


Date : 21.04.2017_ Date: 28.04.2017_



UNIT IV INITIAL VALUE PROBLEMS FOR ORDINARY DIFFERENTIAL EQUATIONS

12 Hrs

Single Step methods - Taylor‘s series method - Euler‘s method - Modified Euler‘s method - Fourth order

Runge-Kutta method for solving first order equations - Multi step methods - Milne‘s and AdamsBash forth

predictor corrector methods for solving first order equations.

UNIT V BOUNDARY VALUE PROBLEMS IN ORDINARY AND PARTIAL DIFFERENTIAL

EQUATIONS 12 Hrs

Finite difference methods for solving two-point linear boundary value problems - Finite difference techniques

for the solution of two dimensional Laplace‘s and Poisson‘s equations on rectangular domain – One

dimensional heat flow equation by explicit and implicit (Crank Nicholson) methods – One dimensional wave

equation by explicit method.

TOTAL: 60 Hours

TEXT BOOKS:

1. Grewal. B.S., and Grewal. J.S.,"Numerical methods in Engineering and Science", Khanna Publishers,

9th Edition, New Delhi, 2007.

2. Gerald. C. F., and Wheatley. P. O., "Applied Numerical Analysis", Pearson Education, Asia, 6th

Edition, New Delhi, 2006.

REFERENCES:

1. Chapra. S.C., and Canale .R.P., "Numerical Methods for Engineers, Tata McGraw Hill, 5 th Edition,

New Delhi, 2007.

2. BrianBradie. "A friendly introduction to Numerical analysis", Pearson Education, Asia, New Delhi,

2007.

3. Sankara Rao. K., "Numerical methods for Scientists and Engineers", Prentice Hall of India Private, 3rd



Date : 19.08.2017 Date: 03.10.2017




Course Code UCEE405

Course Name: Sensors and Transducers

L T P C

3 0 0 3

Year and Semester


( 3Hrs)

Prerequisite course

Basics of EEE.

Course

Objective

1. Expose to various sensors for Measuring Different Electrical parameters

2. To impart the knowledge of various transducers and implement in the data acquisition systems.

Course Outcome The Students will be able to 1. Illustrate the various types of transducers and measurement systems

2. Demonstrate the temperature measuring devices

3. Understand the operation of pressure and level measuring devices

4. Summarize the various parameter measuring devices

5. Distinguish various measurement devices in different application 6. Apply basic knowledge of measuring devices in various real time applications

UNIT I : TRANSDUCERS AND MEASUREMENTS 9 Hrs

Classification of transducers – Selection of transducers – Resistive, capacitive & inductive transducers –

Transduction principles– Elements of data acquisition system – A/D, D/A converters – Smart sensors. D.C &

A.C potentiometers, D.C & A.C bridges, voltmeters, ammeters, Instrument transformers. transformer ratio

bridges, self-balancing bridges. Interference & screening – Multiple earth and earth loops –Electrostatic and

electromagnetic interference – Grounding techniques.

UNIT II: TEMPERATURE MEASUREMENT 9 Hrs

Mechanical Type – Filled Thermometers – Liquid Filled – Gas Filled – Vapour Filled –Bimetallic

Thermometer-Thermostat – Electric Type – RTD – Thermistor, Thermocouple, IC Thermometer – Non

Contact Total Radiation Pyrometer – Optical Pyrometer.

UNIT III: PRESSURE & LEVEL MEASUREMENTS 9 Hrs

Pressure: Monometers – Elastic Transducers – Bourdon Gauge – bellows – diaphragm –DPcell- Calibration of

Pressure Gauge using Dead Weight Testers. -Pressure Switch-Vacuum: McLeod Gauge, Thermal Conductivity

Gauge – Ionization Gauge - Flow Measurement: Orifice, Venturi, Nozzle, Pitot Tube, Turbine Flow meter, Hot

wire Anemometer. Level Measurement: Float Level, surge type, Differential Pressure Type, Electrical Type-


Date : 19.08.2017 Date: 03.10.2017



Resistance and Capacitance.

UNIT IV: DISPLACEMENT, FORCE, TORQUE & VIBRATION MEASUREMENT 9 Hrs

Load Cells – Different Types – Potentiometer –Strain Gauges Resistive and Semiconductor – Different Forms

– Measurement Circuits – Use in Displacement, Force and Torque& speed Measurement. LVDT

Characteristics – Measurement Circuits –Use in Displacement – RVDT for angular measurement. Piezo

Electric Transducer – Different Types – Characteristics – Measurement Circuits –Application in Acceleration

and Vibration Measurement. Optical Encoder for Displacement and Velocity Measurement.

UNIT V: MISCELLENEOUS MEASUREMENTS 9 Hrs

Measurement of viscosity, density, humidity, Ph, CO2, toxic gases, explosion monitors, gas analyzers, oil mist

detector, IC sensors, SMART Sensor- wireless sensors-micro sensors

TOTAL: 45 Hours

TEXT BOOKS:

1. A.K. Sawhney, A Course in Electrical & Electronic Measurements & Instrumentation ‗, Dhanpat Rai

and Co, 2004.

2. J. B. Gupta, A Course in Electronic and Electrical Measurements ‗, S. K. Kataria & Sons, Delhi,2003.

3. Doebelin E.O. and Manik D.N., Measurement Systems – Applications and Design, Special Indian

Edition, Tata McGraw Hill Education Pvt. Ltd.,2007

REFERENCS:

1. H.S. Kalsi, Electronic Instrumentation ‗, Tata McGraw Hill, II Edition 2004. 2. D.V.S. Moorthy, Transducers and Instrumentation ‗, Prentice Hall of India Pvt Ltd, 2007.

3. Martin Reissland, Electrical Measurements ‗, New Age International (P) Ltd., Delhi, 2001. 4. Alan. S. Morris, Principles of Measurements and Instrumentation, 2nd Edition, Prentice Hall of India,

2003




Course Code UBEE404

Course Name : Linear Integrated Circuits

L T P C

3 0 0 3

Year and Semester

II Year (IV Semester ) Contact hours per week

( 3Hrs )

Prerequisite course

Digital logic circuits

Course

Objective 1. To understand the basic principles, configurations and practical limitations of the

various applications of op-amp.

2. To analyze, design and explain the characteristics and applications of op-amp

amplifier.


1. Understand the fabrication of ICs. 2. Design and Analyze the terminal characteristics and fundamental circuits based on op-

amps.

3. Analyze feedback and its effect on the performance of op-amp.

4. Develop active filters.

5. Formulate various applications of op-amps and IC 555. 6. Design the op-amps based circuits.

UNIT I : IC FABRICATION 9 Hrs

IC classification - fundamental of monolithic IC technology, epitaxial growth, masking and etching, diffusion

of impurities - Realization of monolithic ICs and packaging - Fabrication of diodes, capacitance, resistance and

FETs.

UNIT II: CHARACTERISTICS OF OPAMP 9 Hrs

Ideal OP-AMP characteristics - DC characteristics - AC characteristics - differential amplifier - frequency

response of OP-AMP - Basic applications of op-amp – Inverting and Non-inverting Amplifiers-V/I & I/V

converters, summer, differentiator and integrator.

UNIT III: APPLICATIONS OF OPAMP 9 Hrs

Instrumentation amplifier - Log and Anti-log Amplifiers - first and second order active filters – comparators -

multi-vibrators - waveform generators - clippers, clampers, peak detector, S/H circuit, D/A converter (R- 2R

ladder and weighted resistor types), A/D converters using op-amps.


Date : 19.08.2017_


Date: 03.10.2017_




Date : 19.08.2017_


Date: 03.10.2017_

UNIT IV: SPECIAL ICs 9 Hrs

Functional block, characteristics & application circuits with 555 Timer IC-566 voltage controlled oscillator IC-

565 - phase lock loop IC - Analog multiplier ICs.

UNIT V: APPLICATION ICs 9 Hrs

IC voltage regulators –LM78XX,79XX Fixed voltage regulators - LM317, 723 Variable voltage regulators -

switching regulator – SMPS - LM 380 power amplifier- ICL 8038 function generator IC - Functional block -

characteristics & application circuits with 555Timer IC-566 voltage controlled oscillator IC - 565-phase lock

loop IC - Analog multiplier ICs.

TOTAL : 45 Hours

TEXT BOOKS:

1. David A. Bell, Op-amp & Linear ICs‗, Oxford, 2013.

2. D.RoyChoudhary, SheilB.Jani, Linear Integrated Circuits‗, II edition, New Age, 2003.

3. Ramakant A.Gayakward, Op-amps and Linear Integrated Circuits‗, IV edition, Pearson Education,

2003

REFERENCES:

1. Fiore, Op-amps & Linear Integrated Circuits Concepts & Applications‖, Cengage, 2010.

2. Floyd, Buchla, Fundamentals of Analog Circuits, Pearson, 2013.

3. Jacob Millman, Christos C.Halkias, ‗Integrated Electronics - Analog and Digital circuits system‘, Tata McGraw

Hill, 2003


Date : 19.08.2017 Date: 03.10.2017 _




Course Code UCEE401

Course Name : Control Systems

L T P C

3 1 0 4

Year and Semester


( 4Hrs )

Prerequisite course

Mathematics, Circuit Analysis & Electrical Machines

Course

Objective

1. To understand the use of transfer function models for analysis physical systems and introduce the control system components.

2. To provide adequate knowledge in the time response of systems and steady state error analysis.


1. Outline the basics of control system 2. Analyze the time response of various systems and tuning techniques of controllers

3.Analyze the frequency response of a system and design compensators

4. Apply concepts of state variables

5. Apply concepts of controlability and observability techniques 6. Illustrate various process control systems

UNIT - I: - BASICS OF CONTROL SYSTEM 12 Hrs

Basic elements in control systems – Open and closed loop systems – Electrical analogy of mechanical and

thermal systems – Transfer function – Synchros – AC and DC servomotors – Block diagram reduction

techniques – Signal flow graphs.

UNIT- II: - TIME RESPONSE 12 Hrs

Time response – Time domain specifications – Types of test input –I and II order system response –Error

coefficients – Generalized error series – Steady state error –Root locus construction- Effects of P, PI, PID

modes of feedback control –Time response analysis.

UNIT - III: - FREQUENCY RESPONSE & COMPENSATOR DESIGN 12 Hrs

Frequency response – Bode plot – Polar plot – Determination of closed loop response from open loop response - Correlation between frequency domain and time domain specifications-Routh Hurwitz criterion –Nyquist

stability criterion.

UNIT-IV STATE VARIABLE ANALYSIS 12 Hrs

Concept of state variables –State variable formulation – Non uniqueness – State transition matrix – Eigen

values – Eigen Vectors – Stability - Concepts of controllability and observability.


Date : 19.08.2017 Date: 03.10.2017 _



UNIT - V DESIGN OF CONTROL SYSTEMS 12 Hrs

Design Specification – Controller Configuration – PID Controller – Compensation schemes – Effect of Providing Lag, Lead , and Lag - Lead compensation on system performance and design.

TOTAL :60 Hours

TEXT BOOKS :

1. M.Gopal, Control Systems Princples and Design, 4th Edition, McGraw Hill Education (india) Pvt Ltd,2016

2. I.J. Nagrath & M. Gopal, Control Systems Engineering‗, New Age International Publishers, 2003.

3. S.K.Bhattacharya, Control System Engineering, 3rd Edition, Pearson, 2013.

REFERENCES :

1. Richard C.Dorf and Robert H.Bishop, Modern control systems , Pearson Education , Third impression , 2009

2. Benjamin C.Kuo, Automatic Control systems, PHI Learning Private Ltd, 2010.

3. K. Ogata, Modern Control Engineering‗, 5th edition, PHI Learning Private Ltd, 2011.

4. S.Palani, Anoop. K.Jairath, Automatic Control Systems including Mat Lab, Vijay Nicole/ Mcgraw Hill Education, 2013




Course Code

UBEE402

Course Name :

Electromagnetic Theory

L T P C

3 1 0 4

Year and Semester

II Year ( IV Semester ) Contact hours per week ( 4Hrs )

Prerequisite course

NIL

Course

Objective 1. To understand Concepts of different Coordinate systems, Electrostatics,

Magnetostatics and their applications.

2. To analyze Electrodynamic fields and Electromagnetic waves.

Course Outcome The Students will be able to 1. Understand the basics of electric and magnetic fields

2. Calculate electric and magnetic fields from stationary and dynamic charge and current

distributions.

3. Solve simple electrostatic boundary problems.

4. Describe simple models for electromagnetic interaction with media

5. Demonstrate the concepts behind electromagnetic waves6. Apply the concept of

Electromagnetic fields in real time.

UNIT I INTRODUCTION 12 Hrs

Sources and effects of electromagnetic fields - Vector fields - Different co-ordinate systems – Divergence

theorem – Stoke‘s theorem

UNIT- II ELECTROSTATICS 12 Hrs

Coulomb‘s Law - lectric field intensity – Field due to point and continuous charges - Gauss‘s law and

application- Electrical potential - Electric field and equipotential plots- Electric field in free space,

conductors, dielectric - Dielectric polarization, Electric field in multiple dielectrics - boundary conditions -

Poisson‘s and Laplace‘s equations - Capacitance-energy density - Dielectric strength.

UNIT- III:- MAGNETOSTATICS 12 Hrs

Lorentz Law of force - magnetic field intensity - Biot-savart Law - Ampere‘s Law - Magnetic Field due

tostraight conductors, circular loop, infinite sheet of current - Magnetic flux density (B) – B in free space,

conductor - magnetic materials - Magnetization - Magnetic field in multiple media - Boundary conditions-

Scalar and vector potential - Magnetic force – Torque-Inductance-Energy - Density – Magnetic circuits.


Date : 19.08.2017


Date: 03.10.2017




Date : 19.08.2017


on Date: 03.10.2017

UNIT- IV:- ELECTRODYNAMIC FIELDS 12 Hrs

Faraday‘s laws - induced emf – Transformer and motional EMF - Maxwell‘s equations (differential and

integral forms) – Displacement current –Relation between field theory and circuit theory.

UNIT –V:- ELECTROMAGNETIC WAVES 12 Hrs

Generation – Electro Magnetic Waveequations – Wave parameters; velocity, Intrinsic impedance,

propagation constan – Waves in free space, lossy and lossless dielectrics, conductors-skin depth, Poynting

vector – Plane wave reflection and refraction.

Total : 60 Hours

TEXT BOOKS:

1. Mathew N. O. Sadiku, ‗Principles of Electromagnetics‘, 4 th Edition ,Oxford University Press Inc. First

India edition, 2009.

2. Ashutosh Pramanik, ‗Electromagnetism – Theory and Applications‘, PHI Learning Private Limited,

New Delhi, Second Edition-2009.

3. K.A. Gangadhar, P.M. Ramanthan ‗ Electromagnetic Field Theory (including Antennaes and wave

propagation‘, 16th Edition, Khanna Publications, 2007.

REFERENCES:

1. Joseph. A.Edminister, ‗Schaum‘s Outline of Electromagnetics, Third Edition (Schaum‘s Outline Series),

Tata McGraw Hill, 2010

2. William H. Hayt and John A. Buck, ‗Engineering Electromagnetics‘, Tata McGraw Hill 8th Revised

edition, 2011.

3. Kraus and Fleish, ‗Electromagnetics with Applications‘, McGraw Hill International Editions, Fifth

Edition, 2010.

4. Bhag Singh Guru and Hüseyin R. Hiziroglu ―Electromagnetic field theory Fundamentals‖, Cambridge

University Press; Second Revised Edition, 2009


Date : 06.03.2017 Date: 03.04.2017




Course Code UBMCCPB

Course Name :

Pneumatics, Hydraulics & Electrical

Control System Laboratory

L T P C

0 0 2 1

Common for BE (ME, EEE, MECH)

Year and Semester

III Year ( VI Semester ) Contact hours per week

( 2Hrs )

Prerequisite course

Nil

Course

Objective

To know the method of programming the microprocessor and also the design, modeling &

analysis of basic electrical, hydraulic & pneumatic Systems.


1. Experiment with hydraulic circuits using various types of electro-hydraulic elements.

2. Demonstrate pneumatic circuits for simple applications using pneumatic elements.

3. Construct experiment on Electro Hydraulic Pneumatic logic circuits.

4. Test for operational sequence in multiple cylinders

5. Illustrate the operation of electro pneumatic circuits 6. Infer knowledge on speed control of cylinder using flow control valve

HYDRAULICS

1. Study of hydraulic symbols &components

2. Reading a ,Hydraulics circuits

3. Setting pressure of the hydraulic power pack

4. Study and operation of a double acting cylinder using 4/2 hand lever operated DCV

5. Study and operation of unidirectional flow control valve

6. Study and operation of speed control of cylinder with Bidirectional flow control valve

7. Study and operation of non-return valve (check valve)

8. Study and operation of sequence valve

PNEUMATICS

9. Operation of a single acting cylinder using 3/2 spring return DCV

10. Operation of a double acting cylinder using 3/2 hand lever operated DCV

11.Operation of a double acting cylinder using memory valve

12. Automatic Operation of a double acting cylinder using limit switches

13. Operation of a double acting cylinder using pilot operated spring returned 4/2 DCV


Date : 06.03.2017 Date: 03.04.2017



14.Speed control of double acting cylinder using flow control valve (Meter in

circuit) 15.Speed control of double acting cylinder using flow control

valve(Meterout circuit) 16.Multiple cylinders operation normal sequencing (Two

cylinders –A+ B+ A- B-)

ELECTRO PNEUMATICS

17.Operation of a single acting cylinder using single solenoid valve

18.Operation of a double acting cylinder using single solenoid valve

19.Operation of a double acting cylinder using double solenoid valve

20.Multiple cylinders normal sequencing operation

(Two cylinders –A+ B+ A- B-) using electro pneumatic circuit

TOTAL : 30 Hours




Date : 19.08.2017


Date: 03.10.2017_


Course Code UBEE4PA

Course Name : Integrated Circuits Laboratory

L T P C

0 0 2 1

Year and Semester


( 2Hrs )

Prerequisite course

Digital logic circuits

Course

Objective

1. To understand the Boolean functions and gray coding.

2. To understand the encoder/decoder, synchronous and Asynchronous circuits.

Course Outcome The Students will be able to 1. Illustrate the Boolean Functions, Adder/ Subtracter circuits.

2. Analyze the Parity generator and parity checking.

3. Infer the multiplexer and demultiplexer.

4. Examine the VCO and PLL ICs.

5. Construct the4-bit shift registers in SISO, SIPO, PISO, PIPO modes.

6. Design and implementation of 4- bit modulo counters as synchronous and

Asynchronous types.

LIST OF EXPERIMENTS

1. Implementation of Boolean Functions, Adder/ Subtracter circuits.

2. Code converters: Excess-3 to BCD and Binary to Gray code converter and vice-versa

3. Parity generator and parity checking

4. Encoders and Decoders

5. Counters: Design and implementation of 4- bit modulo counters as synchronous and Asynchronous

types using FF IC‘s and specific counter IC.

6. Shift Registers: Design and implementation of 4-bit shift registers in SISO, SIPO, PISO, PIPO modes

using suitable IC‘s.

7. Study of multiplexer and demultiplexer

8. Timer IC application: Study of NE/SE 555 timer in A stable, Monostable operation.

9. Application of Op-Amp: inverting and non- inverting amplifier, Adder, comparator, Integrator and

Differentiator.

10. Study of VCO and PLL ICs:

i. Voltage to frequency characteristics of NE/ SE 566 IC.

ii. Frequency multiplication using NE/SE 565 PLL IC.

Total :30 Hours


Date : 06.03.2017_ Date:03.04.2017_




Course Code UBMCC05

Course Name :

Pneumatics, Hydraulics and


L T P C

3

0

0

3

(Common to BE – MECH, EEE & ME)

Year and Semester


( 3Hrs )

Prerequisite course

NIL

Course

Objective

1. Have an integrated understanding of the scientific and engineering principles related to

Hydraulics and pneumatics

2. Have an integrated understanding of hydraulic circuits, pneumatic circuits and Electro

Hydraulic Pneumatic logic circuits.


1. Understand the various properties of fluids- losses during flow with fundamentals.

2. Infer knowledge about the selection of pumps for different applications.

3. Illustrate hydraulic circuits using various types of electro-hydraulic elements.

4. Construct pneumatic circuits for simple applications using pneumatic elements.

5. Develop simple Electro, Hydraulic, Pneumatic and combinational logic circuits.

6. Design of hydraulic circuits, pneumatic circuits and Electro Hydraulic Pneumatic logic

circuits.

UNIT 1:FLUID POWER SYSTEMS AND FUNDAMENTALS 9 Hrs

Introduction to fluid power - Advantages of fluid power - Application of fluid power system - Types of fluid

power systems - Properties of hydraulic fluids – General types of fluids – Fluid power symbols. Basics of

Hydraulics-Applications of Pascals Law- Laminar and Turbulent flow –Reynold‗s number – Darcy‗s equation

– Losses in pipe, valves and fittings.

UNIT 2:HYDRAULIC SYSTEM & COMPONENTS 9 Hrs

Sources of Hydraulic Power - Pumping theory – Pump classification – Gear pump, Vane Pump, piston pump,

construction and working of pumps – pump performance – Variable displacement pumps - Fluid Power

Actuators - Linear hydraulic actuators – Types of hydraulic cylinders –Single acting, Double acting special

cylinders like Tanden, Rodless, Telescopic, Cushioning mechanism, Construction of double acting cylinder,

Rotary actuators – Fluid motors, Gear, Vane and Piston motors.


Date : 06.03.2017_ Date:03.04.2017_



UNIT 3:DESIGN OF HYDRAULIC CIRCUITS 9 Hrs

Construction of Control Components - Directional control valve – 3/2 way valve – 4/2 way valve– Shuttle

valve – check valve – pressure control valve – pressure reducing valve, sequence valve, Flow control valve –

Fixed and adjustable - electrical control solenoid valves - Relays, ladder diagram. Accumulators and

Intensifiers: Types of accumulators – Accumulators circuits, sizing of accumulators, intensifier – Applications

of Intensifier – Intensifier circuit.

UNIT 4:PNEUMATIC SYSTEMS AND COMPONENTS 9 Hrs

Pneumatic Components: Properties of air – Compressors – Filter, Regulator and Lubricator Unit –Air control

valves, Quick exhaust valves, pneumatic actuators. Fluid Power Circuit Design, Speed control circuits,

synchronizing circuit, Pneumo-hydraulic circuit, Sequential circuit design for simple applications using

cascade method.

UNIT 5:DESIGN OF PNEUMATIC CIRCUITS 9 Hrs

Servo systems – Hydro Mechanical servo systems, Electro hydraulic servo systems and proportional valves.

Fluidics – Introduction to fluidic devices, simple circuits, Introduction to Electro Hydraulic Pneumatic logic

circuits, ladder diagrams, PLC applications in fluid power control - Fluid power circuits - failure and

troubleshooting

TOTAL : 45 Hours

TEXT BOOKS:

1. Anthony Esposito, ―Fluid Power with Applications‖, Pearson Education 2005.

2. Majumdar S.R., ―Oil Hydraulics Systems- Principles and Maintenance‖, Tata McGraw- Hill, 2001.

REFERENCES:

1. Srinivasan.R, ―Hydraulic and Pneumatic controls‖, Vijay Nicole, 2006.

2. Shanmugasundaram.K, ―Hydraulic and Pneumatic controls‖, Chand & Co, 2006.


Date : 19.08.2017 Date: 03.10.2017_




Course Code UBEE4PB

Course Name : Transducers Laboratory

L T P C

0 0 2 1


Year and Semester


( 2Hrs )

Prerequisite

course

NIL

Course

Objective

1. To introduce various transducers and the data acquisition systems 2. To expose various sensors for Measuring Different Electrical parameters.


1. Illustrate the loading effect of potentiometer.

2. Analyze the Strain gauge & load cell characteristics.

3. Infer the Characteristics of LVDT.

4. Understand the operation of VCO and PLL ICs.

5. Construct the current and pressure converters.

6. Explain the operation of Venturi meter and Orifice meter.

LIST OF EXPERIMENTS

1. Loading effect of potentiometer.

2. Strain gauge & load cell characteristics.

3. Capacitive transducers.

4. Photoelectric tachometer & Piezoelectric transducers.

5. Hall effect transducers.

6. Characteristics of LVDT.

7. Characteristics of thermocouple, Thermistor and LDR.

8. Step response characteristics of RTD and thermocouple.

9. P/I and I/P converters.

10. Digital transducer – shaft angle encoder.

11. Measurement of flow using Venturi meter and orifice meter.


Date : 19.08.2017 Date: 03.10.2017_



12. Calibration of Pressure gauge.

13. Calibration of Temperature sensor.

14. Torque measurement.

15. Viscosity measurement.

16. Level measurement using d/p transmitter.

17. UV – visible spectrophotometer.

18. PH meter standardization and measurement of PH values of solutions.

Total:30 Hours


Date : 11.07.2017 Date: 03.10.2017




Course Code UCLECPE

Course Name : Spoken English-IV

L T P C

0 0 2 1


Year and Semester


( 2 Hrs )

Prerequisite course

NIL

Course

Objective

1. To make the students to learn the corporate culture and master the professional ethics

2. Prepare them to achieve their organizational goals


1. Improvise on the usage of grammar and vocabulary in all circumstances

2. Carry oneself expressing behavioral ethics

3. Collaborate with individual such as to improve pronunciation

4. Distinguish between standards and illustrate a change in listening and speaking skills

5. Formulate and apply various forms of written communications that are learnt

6. Participate actively in the class and understand concepts. Will be ready to handle large

groups without any fear


Training the students on basic grammar and foundation and laying the standard platform - A complete standard

syllabus of Cambridge is used. The main part of the 1st semester is to cover the major tenses (Present tense,

Present Continuous, Past Tense, Past Continuous, Present Perfect, and Present Perfect continuous).

UNIT II: PROFESSIONAL ETHICS : 6 Hrs

How to address the gathering, people, authorities, open forum, how to conduct the meetings, huddle and

calibration - Learning about organizational behaviors, achieving organizational goals, nurturing professional

integrity.


Date : 11.07.2017 Date: 03.10.2017



How to write memos, emails, short notes, drafting of letters , requesting leave, permission, reports,

requisitions, approvals and indents.

6 Hrs UNIT III: INTERACTIVE ENGLISH

Second level: The main objective is English for International communication. This course contains

conversations, snapshots, readings, activities, a greater variety and amount of listening materials and more

visuals to introduce vocabulary, more opportunities to build fluency and up-to-date art and design. The course

covers the fours skills of listening, speaking, reading and writing as well as improving pronunciation and

building vocabulary.

UNIT IV: LISTENING AND SPEAKING

Basics of International listening, reading, writing and speaking skills.

6 Hrs

UNIT V: WRITTEN ENGLISH 6 Hrs

TOTAL: 30 Hours

TEXT BOOKS:


2. Communication Skills

REFERENCE BOOKS:





Course Code

UBEE505 Course Name :

Power Electronics

L T P C

3 1 0 4

Year and Semester

III Year ( V Semester ) Contact hours per week

( 4Hrs )

Prerequisite course

Electronic Devices

Course

Objective 1. To understand the operation, characteristics and performance parameters of Power

electronics Swithching devices and controlled rectifiers.

2. To analyze the performance of Choppers, inverters, AC voltage controllers and Cycloconverters.

Course Outcome The Students will be able to 1. Compare characteristics of switching devices

2. Evaluate the performance of phase controlled converters

3. Design DC-DC converter with given characteristics

4. Analyze the operation of inverters

5. Understand the operation of AC voltage controllers.

6. Apply the concept of power Electronics devices.

UNIT I:- POWER SEMICONDUCTOR DEVICES 12 Hrs

Study of switching devices, Diode, SCR, TRIAC, GTO, BJT, MOSFET, IGBT – Static and Dynamic

characteristics - Triggering and commutation circuit for SCR- Design of Driver and snubber circuit

UNIT- II:- PHASE-CONTROLLED CONVERTERS 12 Hrs

2-pulse, 3-pulse and 6-pulse converters – performance parameters – Effect of source inductance- Gate Circuit

Schemes for Phase Control–Dual converters.

UNIT- III:- DC TO DC CONVERTER 12 Hrs

Step-down and step-up chopper-control strategy–Forced commutated chopper – Voltage commutated, current

commutated, Load commutated, Switched mode regulators- Buck,boost, buck- boost converter - Introduction

to Resonant Converters.


Date : 19.08.2017


Date: 03.10.2017


Date : 19.08.2017 Date: 03.10.2017



UNIT- IV:- INVERTERS 12 Hrs

Single phase and three phase voltage source inverters(both 120° mode and 180° mode)–Voltage & harmonic

control - PWM techniques: Sinusoidal PWM, modified sinusoidal PWM - multiple PWM – Introduction to

space vector modulation –Current source inverter.

UNIT –V:- AC TO AC CONVERTERS 12 Hrs

Single phase and Three phase AC voltage controllers – Control strategy Power Factor Control Multistage

sequence control - single phase and three phase cyclo converters – Introduction to Matrix converters.

TOTAL : 60 Hours

TEXT BOOKS:

1. M.H.Rashid, ‗Power Electronics: Circuits, Devices and Applications‘, Pearson Education, PHI Third


2. P.S.Bimbra ―Power Electronics‖ Khanna Publishers, third Edition, 2003.

3. L. Umanand, ― Power Electronics Essentials and Applications‖, Wiley, 2010.

REFERENCES:

1. Joseph Vithayathil,‘ Power Electronics, Principles and Applications‘, McGraw Hill Series,6th Reprint,

2013.

2. Ashfaq Ahmed Power Electronics for Technology Pearson Education, Indian reprint, 2003.

3. Philip T. Krein, ―Elements of Power Electronics‖ Oxford University Press, 2004 Edition.

4. Ned Mohan, Tore. M. Undel and, William. P. Robbins,‗ Power Electronics: Converters, Applications

and Design‘, John Wiley and sons, third edition,2003.

5. Daniel.W.Hart, ―Power Electronics‖, Indian Edition, Mc Graw Hill, 3rd Print, 2013.

6. M.D. Singh and K.B. Khanchandani, ―Power Electronics,‖ Mc Graw Hill India, 2013.


Date : 19.08.2017 Date: 03.10.2017


CBCS CURRICULUM (2016 -17) (Regulation – B)



Course Code UBEE508

Course Name : Marine Electrical Technology

L T P C

3

1

0

4

Year and Semester

III Year (V Semester ) Contact hours per week

( 4Hrs )

Prerequisite course

DC &AC Machines

Course

Objective

1. To expose the students to the concepts about Generators on Board and their

Protection

2. To learn about the marine cables,hazardous area and equipments


1. Illustrate the procedure for producing electricity on board ships through

`alternators and associated controls

2. Infer knowledge on importance of generator load sharing, change over

procedure for ships and preferential trips

3. Explain maintenance of circuit breaker

4. Identify hazards associated with batteries during operation and in the battery

rooms

5. Summarize the method of finding cable faults and design features

of alternators

6. Utilize knowledge on insulations used in marine cables

UNIT I: GENERATORS ON BOARD AND PROTECTION 12 Hrs

Ship electrical layout - Main Generator and Emergency Generator operation on board - standard output

voltage frequency and power - Governor droop characteristics and load sharing - AVR droop characteristics -

Testing of generator protection devices - AVR maintenance Procedure - Winding in classes of Insulation in

Main Generator - Meggering the rotor of brushless alternator - Protection and Safety - Case study of a faulty

synchronization - water cooling system - Fuel used and protection devices in Emergency generator - Setting

OCR in Generator - Generator Preventive Maintenance - Emergency Power Supplied equipments -

Precautions for Supplying large capacity motor - Fire precautions in engine room - location of fire detectors in

engine room.


Date : 19.08.2017 Date: 03.10.2017




UNIT II: MAIN SWITCH BOARD 12 Hrs

MSB –Synchronization control in MSB, Generator load sharing, change over procedure between ship and

shore supply. Distribution branches and timing in preferential trip system, ACB ,VCCB Maintenance, Auto

start sequence on recovering power to MSB and its purpose, MSB Bus Tie, Engine Room ventilation,

accommodation ventilation accommodation, COP trip , Bilge Ballast.

UNIT III: EMERGENCY SWITCH BOARD, EMERGENCY BATTERY AND TRANSFORMER

12 Hrs

Insulated Neutral and earthed system, Fault finding, Neutral earthing system in Main power distribution

system, Protective devices on Distribution board. Types of Batteries used in ships, maintenance and

operational procedures, Preventive maintenance of emergency battery. Hazards associated when working with

batteries and in the battery room. Transformer types, location and testing on board, welding transformer safety

procedure.

UNIT IV: MARINE CABLES 12 Hrs

Categorize the class of insulation used in marine cables, Types of cables used for different location, Cable

glanding procedure, Precautions on working in electrical and electronic equipment‘s. Recognize the

importance of proper ventilation when using volatile electro-cleaners, varnishes and paints having solvents-

State the maximum safe current a human body can tolerate- State the first aid to be administered to a person

exposed to electric shock-Describe the actions to be taken in the instance of fire in the main generator panel.

UNIT V: HAZARDOUS AREA AND EQUIPMENTS 12Hrs

Hazardous zones on board, Category of Electrical equipment in different hazardous zonesinship, Risk

assessment, log entries work permit procedures when working in electrical equipment, Construction of

switches in hazardous area, Illumination in hazardous zones, maintenance of electrical equipment in hazardous

zones, List the logic provided for safety in doing routine maintenance on explosive proof lights-State

requirement for safety flashlights and maintenance procedures. Intrinsically safe electrical fitting in hazardous

zones, pulley belt specification in hazardous zones.

TOTAL :60 Hours


Date : 19.08.2017 Date: 03.10.2017




TEXT BOOKS

1. Elstan A. Fernandez ―Marine Electrical Technology ― 6th

edition, shroff publishers and distributers

Pvt. Ltd.,2013

REFERENCE BOOKS:

1. G.O. Watson, Marine electrical practice‗, 6th edition.

2. H.D. Mc George, Marine electrical equipment and practice, 2nd edition.

3. Edmund G.R. Krall, Reeds Advanced Electro technology for engineers- vol.7

4. D.A. Taylor, Marine control Practice‗.

5. Dennis T. Hall, Practical Marine Electrical Knowledge.

6. J.Cowley, The running and maintenance of marine machinery.

7. Nagrath I. J and Kothari D. P. ‗Electric Machines‘, Fourth Edition, Tata McGraw Hill Publishing & Co

Ltd,New Delhi.




Date : 19.08.2017_ Date: 03.10.2017



Course Code UCEE503

Course Name : Microprocessor and Microcontroller

L T P C

3 1 0 4

Year and Semester


( 4Hrs )

Prerequisite course

Digital Logic circuits

Course

Objective

1. To understand the Architecture of 8085 microprocessor and 8051 microcontroller

2. To Study the advanced microprocessor and controller based system design.


1. Understand the Architecture of 8085& 8086 microprocessor

2. Learn and write the Assembly language programs using 8085.

3.Study the Peripheral Interfacing Concepts

4. Understand the Architecture and Interrupts of microcontroller 8051.

5. Understand the microcontroller programming and applications.

6. Illustrate the architecture of microprocessor, microcontroller and applications.

UNIT–I ARCHITECTURE OF 8085 AND 8086 MICROPROCESSOR 12 Hrs

Generic Microcomputer – 8085: Functional Block diagram – Signals – Memory interfacing – I/O Ports and data

transfer concepts – Timing diagram – Interrupt structure - 8086: Architecture - Memory segments & internal

Registers – BIU & EU – Memory interfacing with 8086.

UNIT – II PROGRAMMING THE 8085 12 Hrs

8085 instruction set and Addressing Modes – Assembly language format – Data transfer, Data manipulation

and control instructions – Programming - Loop structure with counting and indexing – Look up table –

Subroutine Instruction, Stack.

UNIT – IIIPERIPHERALINTERFACING 12 Hrs

Architecture and programming of ICs: 8255 PPI, 8259 PIC, 8251 USART, 8279Key board display controller

and 8254 Timer/ Counter – Interfacing with 8085 - A/D and D/A converter interfacing.

UNIT – IV MICROCONTROLLER 8051 12 Hrs

Architecture of 8051 - Instruction format and addressing modes – Interrupt structure –Timer –I/O ports –

Serial communication, Arithmetic programming.




Date : 19.08.2017_ Date: 03.10.2017


UNIT - V MICRO CONTROLLER PROGRAMMING & APPLICATIONS 12 Hrs

Data Transfer, Manipulation, Control & I/O instructions – Simple programming exercises – key board and

display interface – Temperature control system - stepper motor control.

TOTAL:60 Hours

TEXT BOOKS:

1. 1 Krishna Kant, ―Microprocessor and Microcontrollers‖, Eastern Company Edition, Prentice Hall of India,

New Delhi , 2007.

2. R.S. Gaonkar, ‗Microprocessor Architecture Programming and Application‘, with 8085, Wiley Eastern Ltd.,

New Delhi, 2013.

3. Soumitra Kumar Mandal, Microprocessor & Microcontroller Architecture, Programming & Interfacing using

8085,8086,8051,McGraw Hill Edu,2013

REFERENCES:

1. Douglas V. Hall, ‗Micro-processors and interfacing‘ Tata Mcgraw hill, 2nd Indian edition, New

Delhi, 2009

2. Sunil Mathur, Microprocessor 8086, Architecture, Programming and interfacing, PHI Learning Pvt.

Ltd.2011.

3. Kenneth Ayala, ‗The 8051Microcontroller‘, Thomson, 2005




Date : 27.01.2017


Date: 03.10.2017_



Course Code UBMEC01

Course Name : Marine Engineering – I

L T P C

3 0 0 3

(Common to BE – Mechanical, BE – EEE, BE - NA&OE)

Year and Semester III Year ( V Semester ) Contact hours per week ( 3Hrs ) Prerequisite course DC & AC Machines

Course Objective 1. To impart knowledge in the Marine diesel engines, types of Marine boilers and

refrigeration and air-conditioning

2. To understand the Ships and machinery system


1. Illustrate the fundamentals in lubrication, lubricants and lub oil systems.

2. Explain the classification society rules on engine construction.

3. Classify the boiler types and its mounting, combustion, feed system, feed water

treatment system.

4. Demonstrate the parts of marine steam turbine.

5. Outline the importance in automation of ship propulsion plants.

6. Analyze the psychometric chart and understand the ships and machinery systems.

UNIT I MARINE DIESEL ENGINE 9 Hrs

Ships and machinery - design and selection considerations - Marine diesel engines generalengine principles -

Low speed and medium speed diesel engines - Constructional features – Fuels - fuel oil system - Scavenging

and turbo charging - Starting and reversing systems - controls and safety devices, governing - Lubrication,

Lubricants and lub oil systems - cooling systems-torqueand power measuremen - fuel consumption's

characteristics - engine lead tests and generalcharacteristics - Heat balance - waste heat recovery system.

UNIT II MARINE DIESEL ENGINE SHAFTING 9 Hrs

Engine dynamics - torsional vibration of engine and shafting - axial shaft vibration - critical speed engine

rating, rating corrections, trial tests etc - Relationship of engine to the propeller classification society rules on

engine construction - Engine room arrangement and engine mounting study of different types of marine

engines available in the world market.

UNIT III MARINE BOILERS 9 Hrs

Marine boilers types - fire tube and water tube boilers - boiler arrangements - steam to steam boilers - double

evaporation boilers - exhaust gas heat exchangers - auxiliary steam plant systems - exhaust gas boilers -




Date : 27.01.2017


Date: 03.10.2017_


composite boilers - Boiler mounting, combustion, feed system, feed water treatment, Feed pumps, condensers,

air rejecters, deaerators, boiler operation, coal fired boilers.

UNIT IV MARINE STEAM TURBINES 9 Hrs

Marine Steam turbines - Types of turbines, compounding - reheat turbines, turbine construction, rotors, blades,

casing, Gland sealing, diaphragms, nozzles, bearings, etc. Lubrication systems, expansion arrangements,

control, gearing operating procedure.

UNIT V MARINE GAS TURBINES, REFRIGERATION & AIR CONDITIONING 9 Hrs

Marine gas turbines - fundamentals of G.T - Structure of gas turbines - gearing, operational features, controls,

gearing, combined cycles - Nuclear propulsion - physical principles of the operation of nuclear reactors – use

of nuclear propulsion on seagoing vessels. Automation of ship propulsion plants. Maintenance requirements

and reliability of propulsion plants - Air Conditioning and Refrigeration - Definition and purpose Psychometric

– psychometric properties of air-Psychometric chart – Adiabatic saturation - Psychometric process Sensible

heating and cooling - Humidification and dehumidification - cooling and humidification - Cooling and

dehumidification-heating and humidification, Heating and dehumidification, adiabatic mixing of air streams-

cooling and heating load calculation Summer and winter air conditioning - Estimation of the state of supply air

to the air conditioned space- Quantity of air supply etc. for simple winter air conditioning systems.

TOTAL : 45 Hours

TEXT BOOK:

1. D. A. Taylor, ―Introduction to Marine Engineering‖, Butterworth-Heinemann publication, 2nd

Edition, 1996.

2. A. J. Wharton, ―Diesel Engines by‖, Butterworth-Heinemann publication, 3rd

Edition, Reprint on 2013.

REFERENCES:

1. Harrington, ―Marine Engineering‖, SNAME Publications, 1992.

2. Pounder. C.C, ―Marine Diesel Engines‖, Newnen – Butterworths Publication, London, 8th Edition, 2003.

3. E.A stoke ―Naval Architecture (Reeds Marine Engineering and Technology Series)‖, Reeds Vol 4, Thomas Reed

Publications; 4th Revised edition, 1991.

https://www.google.co.in/search?tbo=p&tbm=bks&q=inauthor%3A%22D%2BA%2BTaylor%22




Date : 19.08.2017_ Date: _03.10.2017_



Course Code

UCEE511

Course Name :

Communication Engineering L T P C

3 0 0 3

Year and Semester


( 3Hrs )

Prerequisite course

Electron Devices And Circuits

Course

Objective

1. To study about different methods of digital and analog communication and their

significance

2. To study about data network, optical fiber and satellite communications

Course Outcome The Students will be able to 1. Summarize the different modulation techniques methods of analog communication and

their significance.

2. Analyze the Digital Communication methods for high bit rate transmission.

3. Illustrate the concepts of source and line coding techniques for enhancing rating of

Transmission of minimizing the errors in transmission.

4. Utilize the MAC used in communication systems for enhancing the number of users.

5. Illustrate various media for digital communication.

6. Understand about data network, optical fiber and satellite communications.

UNIT I ANALOG COMMUNICATION 9 Hrs

AM – Frequency spectrum – vector representation – power relations – generation of AM – DSB, DSB/SC,

SSB, VSB AM Transmitter & Receiver; FM and PM – frequency spectrum – power relations : NBFM &

WBFM, Generation of FM and DM, Amstrong method & Reactance modulations : FM & PM frequency.

UNIT - II DIGITAL COMMUNICATION 9 Hrs

Pulse modulations – concepts of sampling and sampling theorems, PAM, PWM, PPM, PTM, quantization and

coding: DCM, DM, slope overload error. ADM, DPCM, OOK systems – ASK, FSK, PSK, BSK, QPSK,

QAM, MSK, GMSK, applications of Data communication.

UNIT – III SOURCE CODES, LINE CODES & ERROR CONTROL 9 Hrs

Primary communication – entropy, properties, BSC, BEC, source coding : Shaum, Fao, Huffman coding –

noiseless coding theorem, BW – SNR trade off codes: NRZ, RZ, AMI, HDBP, ABQ, MBnB codes –

Efficiency of transmissions – error control codes and applications – convolutions & block codes.




Date : 19.08.2017_ Date: _03.10.2017_


UNIT - IV MULTIPLE ACCESS TECHNIQUES & NETWORK PROTOCOL 9 Hrs

Spread Spectrum & Multiple Access techniques: FDMA, TDMA, CDMA, SDMA application in wire and

wireless communication – Advantages (merits), Data Communication codes – error control – Serial and

parallel interface – telephone network – data modem – ISDN, LAN, ISO-OSI seven layer architecture for

WAN.

UNIT - V SATELLITE,OPTICAL FIBRE –POWERLINE,SCADA COMMUNICATIONS 9 Hrs

Orbits – Types of satellites – frequency used link establishment, MA techniques used in satellite

communication – earth station; aperture actuators used in satellite – Intelsat and Insat – fibers – types –

sources, detectors used, digital filters, optical link: power line carrier communications: SCADA

TOTAL: 45 Hours

TEXT BOOKS:

1. Taub & Schiling ‖Principles of Communication Systems ― Tata McGraw Hill 2007.

2. Roy Blake, Electronic Communication Systems‗, Thomson Delmar, 2nd Edition, 2002

REFERENCES:

1. Sklar ‖Digital Communication Fundamentals and Applications‖ Pearson Education,2001.

2. Baryle, Memuschmidt, ‖Digital Communication‖, Kluwer Publication,2004.

3. Wayne Tomasi, Electronic Communication Systems‗, Pearson Education, Third Edition, 2001.




1

PROGRAM BE - Electrical and Electronics Engineering

Course Code UBEE513

Course Name :

Maintenance of Marine Electrical

Equipment

L T P C

3

0

0

3

Year and Semester


( 3Hrs )

Prerequisite course

DC & AC Machines

Course

Objective

1. To learn about maintenance of marine cables, cable trays, circuit breakers, generator,

motor and power supplies.

2. To learn about topology and maintenance of automation equipments on board.


1. Understand the maintenance of electrical equipments and safety precautions.

2. Explain the maintenance of electrical motors.

3. Demonstrate the maintenance of lighting systems.

4. Illustrate the maintenance of generator and emergency power supply.

5. Apply the concepts of sensors/controllers and automation systems in onboard.

6. Apply the maintenance procedures of onboard ship equipments.

UNIT I MAINTENANCE OF CABLE TRAYS, CIRCUIT BREAKERS ON BOARD

9 Hrs

Procedure for installation of cable trays - Cable Protection methods - Procedure to check the insulation of

cables on board - Procedure to maintain the insulation resistance of the cable - Procedure to maintain the

circuit breakers - vacuum Circuit breakers on board - Safety precautions to be carried out while working with

cables and cable trays on board.

UNIT II MAINTENANCE OF ELECTRICAL MOTORS ON BOARD 9 Hrs

Over hauling of Induction motors - Procedure to replace the bearing of motors - Maintaining insulation

resistance of Induction motor - Procedure to replace the brushes in DC motors - Procedure to work on a

flooded motor - Safety precautions to be carried out while working with Electrical Motors on board.


Date : 19.08.2017_


Date: 03.10.2017





on Date: 03.10.2017

UNIT III MAINTENANCE OF LIGHTING ON BOARD

9 Hrs

Types of light fittings on board, Maintenance of Hazardous zone light fittings - Maintenance on navigational

light fittings - Maintenance of Deck lights and Indoor Light fittings - Safety precautions to be carried out while

working with Electrical Motors on board

UNIT IV MAINTENANCE OF GENERATOR AND EMERGENCY POWER SUPPLIES ON BOARD

9 Hrs

Types of Generator used on board - Maintenance on Main Generator - Overhauling of main generator -

Fabrication of AVR - Maintenance of AVR used in main generator - Types and maintenance of batteries used

on board - Types of power controller used on board for UPS - Maintenance of UPS.

UNIT V MAINTENANCE ON SENSORS/ CONTROLLERS AND AUTOMATION EQUIPMENTS

ON BOARD 9 Hrs

Maintenance of Controllers used in Main Engine control panel - Boiler control panel - Refer Containers -

Steering Gear Control Panel - Procedure for maintenance and installation of PLC on board.

TOTAL : 45 Hours

TEXT BOOKS:


edition, shroff publishers and distributers

Pvt. Ltd.,2013.

2. D.A. Taylor ,Marine Control. Practice.

REFERENCE BOOKS:

1. J Cowley,The Running and maintenance of marine machinery .

2. John .W. Webb, Programmable Logic controllers.


Date : 19.08.2017_




Date : 19.08.2017 Date: 03.10.2017



Course Code

UBEE514

Course Name:

Distributed Computer Control

System

L T P C

2

0

0

2

Year and Semester


( 2Hrs )

Prerequisite course

Control System

Course Objective

1. To give basic knowledge about Distributed control system.

2. To impart knowledge about HART and FIELD bus & PLC and its programming


1. Understand the basics of Distributed Control System

2. Assess Hart and Field bus & Network Topology

3. Analyze PLC in the Control system using

4. Apply Fuzzy logic for various applications

5. Construct Simple controller using Fuzzy logic

6. Apply suitable control techniques for various systems

UNIT 1: DISTRIBUTED CONTROL SYSTEM 6 Hrs

Evolution – Architectures – Comparison – Local control unit – Process interfacing issues – Communication

facilities. Operator interfaces - Low level and high level operator interfaces - Operator displays -Engineering

interfaces – Low level and high level engineering interfaces – General purpose computers in DCS.

UNIT II: HART AND FIELD BUS 6 Hrs

Evolution of signal standards – HART communication protocol – Communication modes – HART networks –

Control system interface – HART and OSI model – Filed bus introduction – General field bus architecture –

Basic requirements of field bus standard – Field bus topology – Inter-operability.

UNIT III: PLC 6 Hrs

Programming PLC in ladder Logic, Inter logic, Functional Block Diagram, structured text for Basic Level,

Temperature, Flow - Case study of bottle filling system - Introduction to SCADA System Basic building

blocks of Computer controlled systems - Designing analog system for a SCADA system for level – Direct

digital Control




Date : 19.08.2017 Date: 03.10.2017


UNIT IV: FUZZY SYSTEMS 6 Hrs

Classical sets – Fuzzy sets – Fuzzy relations – Fuzzification – Defuzzification –Fuzzy rules. Membership

function – Knowledge base – Decision-making logic – Optimisation of membership function using neural

networks – Adaptive fuzzy system –Introduction to Genetic Algorithm.

UNIT V: APPLICATION OF FLC 6 Hrs

Fuzzy logic control – Inverted pendulum –Home heating system –Introduction to neuro fuzzy controller.

TOTAL :30 Hours

TEXT BOOKS:

1. John. W. Webb Ronald A Reis - Programmable Logic Controllers - Principles and Applications,

Fifth edition, Prentice Hall Inc., New Jersey, 2003.

2. Frederic P .Miller, McBrewster John,Agnes F .Vandome, Distributed Control System ,VDM

publishing, 2010.

REFERENCES:

1. Michael P. Lukas, Distributed Control System ‗, Van Nostrand Reinhold Co., Canada,1986





Course Code UBEE515

Course Name : Electrical Estimation and Wiring

L T P C

2 0 0 2

Year and Semester


( 2Hrs )

Prerequisite course

Basics of EEE

Course

Objective

1. To learn about the general Electrical wiring setup and maintenance of automation

equipments.

2. To learn about estimation and costing of repairs and maintenance of electrical devices

and equipment.


1. Illustrate the domestic and industrial wiring system and I.E Rules.

2. Demonstrate the estimation method and tools.

3. Explain the estimating and costing methods for domestic and industrial wiring.

4. Develop a layout / wiring diagram for domestic and industrial wiring.

5. Infer the estimating and costing of repairs and maintenance of electrical equipments.

6. Apply and maintain the electrical equipments in good working condition.

UNIT I ELECTRICAL WIRING AND I.E.RULES 6 Hrs

Types of wires, wiring system, Specifications of Different types of wiring materials, Accessories, Wiring tools,

Wiring circuits, Domestic and industrial panel wiring, I.E. rules for wiring, IE Act-2003

UNIT II ELEMENTS OF ESTIMATING 6 Hrs

Definition of Estimation‖ - Types of estimation and estimation tools - Overhead and service charges - Purchase

procedure.

UNIT III ESTIMATING AND COSTING OF DOMESTIC AND INDUSTRIAL WIRING 6 Hrs

Layout and wiring diagram for residential building and industrial wiring - Selection of number of circuit for

project as per IE rules - Estimation for residential wiring and industrial wiring - Estimating and Costing of

Service Connection (Domestic and Industrial)

UNIT IV SURVEY WORK FOR DOMESTIC AND INDUSTRIAL SERVICE 6 Hrs

Survey work for domestic and industrial service connection - Lay out / wiring diagram of service connection -

List of materials and accessories along with specifications required for given project work - Estimation of


Date : 19.08.2017_


Date: 03.10.2017





Date: 03.10.2017

service connection for domestic and industrial(1-phase and 3-phase)service connections - I.E. rules pertaining

to above wiring.

UNIT V ESTIMATING AND COSTING OF REPARIS AND MAINTENANCE OF ELECTRICAL

DEVICES AND EQUIPMENT 6 Hrs

List of tools used for repairs & maintenance work - Preparation of cost schedule for repair and maintenance of

electric fan, automatic electric iron, single phase transformer, mixer grinder, D.O.L Starter

TOTAL : 30 Hours

TEXTBOOKS:


edition, shroff publishers and distributers Pvt.

Ltd.,2013.

2. Electrical Wiring, Estimating And Costing By S.L. Uppal& G.C. Garg, Khanna Publishers, 2008.

REFERENCES:

1. G.O. Watson, ‗Marine electrical practice‗, 6th edition.

2. H.D. Mc George, ‗Marine electrical equipment and practice‗, 2nd edition.

3. Edmund G.R. Krall, ‗Reeds Advanced Electro technology for engineers- vol.7

4. D.A. Taylor, ‗Marine control Practice‗.

5. Dennis T. Hall, ‗Practical Marine Electrical Knowledge.

6. J.Cowley, ‗The running and maintenance of marine machinery‗.


Date : 19.08.2017_




Date : _19.08.2017_ Date: _03.10.2017


PROGRAM BE –ELECTRICAL AND ELECTRONICS ENGINEERING

Course Code UCEE5PA

Course Name :

Microprocessor and Microcontroller

Laboratory

L T P C

0

0

2

1

Year and Semester


( 2Hrs )

Prerequisite course

NIL

Course

Objective

1. To learn about basic arithematic & interfacing operation performed using

Microprocessor & Microcontroller.

2. To understand about the basic concepts of Electrical Safety,Electrical Wiring and

Familiarization with meters & tools.

Course Outcome The Students will be able to 1. List the 8085 and 8086 Assembly language programs such as addition, subtraction,

multiplication and division.

2. Develop program to find the Largest Number among N Numbers.

3. Illustrate the program for ascending and descending order.

4. Experiment the program for 16 bit arithmetic operations.

5. Develop the program for 8085 assembly language hardware interfacing.

6. Design and implement the program to generate a 1 KHz Square wave at SOD pin of

8085.


8085 Microprocessor based Assembly Language Programs

1 Programs for 8 bit Arithmetic Operations

2 Largest and smallest Number from the array

3 Ascending and Descending Order sorting of an array

4 Hex / ASCII/ BCD code conversions.

5 Programs for 16 bit Arithmetic Operations

6 Interface Experiments: Simple experiments using 8251 and 8253.




Date : _19.08.2017_ Date: _03.10.2017


8051 Microcontroller based Assembly Language Programs

7 Stepper Motor Control

8 Traffic Light Control

9 Analog to Digital Converter

interface 10 Digital to Analog Converter

interface.

TOTAL :30 Hours





Date : 19.08.2017


Date: 03.10.2017


Course Code UBEE5PB

Course Name : Power Electronics Laboratory

L T P C

0 0 2 1

Year and Semester

III Year ( V Semester ) Contact hours per

week( 2 Hrs )

Prerequisite course

NIL

Course

Objective

1. To understand the switching characteristics of various power electronics devices such as SCR,TRIAC,MOSFET and IGBT.

2.To learn the operation and performance parameters of controlled rectifier,choppers and inverters.


1.Understand the operation of power electronics switching devices

2.Apply the concept of controlled rectification.

3. Analyze the use of inductors and capacitors in choppers, inverters and converters

4. Demonstrate the operation of inverters

5. Illustrate the operation of resonant converters.

6. Simulate converters and inverters.


1. Characteristics of SCR

2. Characteristics of TRIAC

3. Characteristics of MOSFET and IGBT

4. Transient characteristics of SCR and MOSFET

5. AC to DC fully controlled converter

6. AC to DC half-controlled converter

7. Step down and step up MOSFET based choppers

8. IGBT based single-phase PWM inverter

9. IGBT based three-phase PWM inverter

10. Resonant DC-to-DC converter

TOTAL : 30 Hours.





Course Code

UBEE5PC

Course Name :

Marine Electrical Technology

Laboratory

L T P C

0

0

2

1

Year and Semester


( 2Hrs )

Prerequisite course

Nil

Course

Objective

1. To get hands on experience on panel board wiring, layout and tracing wiring drawing

2. To have knowledge on battery maintenance, soft starter and testing of sensors


1. Construct Panel board wiring

2. Examine the Layout and tracing wiring drawing

3. Identify the types of starter operation

4. Demonstrate the battery maintenance.

5. Identify the contacts of contactor 6. Experiment with bilge alarm, Soft Starters and testing of sensors

LIST OF EXERCISES:

1) D.O L Starter

2) Forward Reverse Starter

3) Two Speed Starter

4) Auto Transformer Starter

5) Star Delta Starter

6) Air Compressor Starter

7) Bilge Alarm

8) Auto/Standby/Manual Operation Of Essential Pumps

9) Battery Charger With Batteries

10) Soft Starters (Using PWM With IGBT and SCR Firing Technique)

11) Testing Of Sensors

TOTAL : 30 Hours.


Date : _13.03.2015_


Date: 03.10.2017


`


Date : 11.07.2017_

Document Approved in ―Academic Council‖ held

on

Date: 03.10.2017



Course Code

UBLECPF

Course Name :

Personality Development Programme

L T P C

0 0 2 1

Year and Semester

III Year ( V Semester ) Contact Hrs. per week

( 2Hrs )

Prerequisite course

NIL

Course

category

General Foundation Core / Professional Elective EEC - 7

Course Objective

1. Provide students with a cohesive and integrated Personality Development Programme

2. Complements the academic programme and the student's long-term career

objectives.

Course Outcome

The student will be able to :

1. Apply effective leadership styles and tools in their daily functioning.

2. Manage the dynamics of diverse interpersonal relationships to stimulate

effective work relations..

3. Demonstrate a good understanding of effective business communications 4. Explain the importance of motivation for employees, leaders, and the

organization and understand the link between motivation and performance.

5. Achieve better results through effective time management techniques. 6. Demonstrate a cohesive and integrated Personality Development Program

UNIT 1: LEADERSHIP 6 Hrs.

Introduction to leadership - Leadership power - leadership styles - leadership in administration.

UNIT 2: INTERPERSONAL RELATIONS 6 Hrs.

introduction to interpersonal relations - analysis of different ego states - analysis of transactions - analysis of

strokes - analysis of life position

.

UNIT 3: COMMUNICATION 6 Hrs.

Introdctuion to communciation - flow of communciation - listening, barriers of communciation - how to overcome barriers of communication.

UNIT 4: MOTIVATION 6 Hrs.

Introdcution to motivation, relvance and types of motivtion, motivating the subordinates, analysis of motivtion.


`


Date : 11.07.2017_

Document Approved in ―Academic Council‖ held

on

Date: 03.10.2017


UNIT 5: TIME MANAGEMENT 6 Hrs.

Time as a resource, identify important time wasters, individual time management styles, techniques for better

time management

.

Total: 30 Hours.

TEXT BOOKS:

1. Barun K Mitra, ―Personality Development and Soft Skills‖, Oxford University Press, 2011.

2. Bhaskara Rao V and Kameswari Y, ―Successful Career - Soft skills and Business English,

Personality and Career plan‖, B S Publications, New Delhi.




Date : 19.08.2017_ Date: 03.10.2017



Course Code UCEE604

Course Name :

Process control and Marine

Automation

L T P C

3

1

0

4

Year and Semester


( 4Hrs )

Prerequisite course

NIL

Course

Objective

1. Understand knowledge on advanced control techniques used onboard ships

2. Be informed of measuring and control equipments


1. Understand and explain the concept of MarineEngine starting systems

2. Describe the operation of integratedenginecontrolsystems

3. Illustrate the operation of variousMarinenavigationsystems

4. Infer the operation of PLC &SCADA systems in ships .

5. Analyse the use of Mobilesatelliteservices on board

6. Demonstrate the operation of bridge equipements used in ships.

UNIT- I INTRODUCTION TO PROCESS CONTROL AND MARINE AUTOMATION 12 Hrs

Need for process control – Interacting and non – interacting systems – Continuous and batch process – Servo

and regulator operation – Introduction to different Marine Engine Starting – systems –Gyroscope, autopilot,

steering gear working principle – types of steering.

UNIT –II MARINE ENGINE ALARM SYSTEMS 12 Hrs

Introduction to Engine alarm system-Engine alarm systems, extension alarm system, fire & CO2 alarm

system, integrated engine room control – Turbine speed control.

UNIT-III PLC&SCADA SYSTEM IN SHIPS 12 Hrs

Blockdiagram – I/O modules – operation of PLC – features & applications – Communications –Basic relay

operations – timers – counters – arithmetic & logical operations – bit operations – subroutines – ON/OFF

control – PID control – Alarms – Introduction to SCADA systems – Marine Applications.




Date : 19.08.2017_ Date: 03.10.2017


UNIT-IV MARITIME MOBILE SATELLITE SERVICE 12 Hrs

Basic Knowledge of Satellite Communication – Inmarsat – Types of stations in Maritime Mobile Satellite

Services – VHF Radio Installations – MFIHF radio installation frequencies – Sources of Energy – Batteries –

Survival craft radio equipment – SART – EPIRB – VHF – DSC – EPIRB – COSPAS – SARSAT.

UNIT-V ELECTRONIC NAVIGATION SYSTEMS 12 Hrs

Electronic Charts Display and Information System – Echo sounders and Speed measurement – Speedlog –

Types of Speedlog – Error sources on the various types of logs – Calibrations of the log – Global Positioning

System – DGPS – Gyro Compass – Automatic Pilot – RADAR – Various types of RADAR.

TOTAL :60 Hours.

TEXT BOOKS:

1. L.Tetley & D.Calcutt ,―Electronic Navigation system‖- Butterworth-Heinemann publication, 2001.

2. Capt.A.G.Bhatia ―ModernElectronic NavigationAid‖, Lata Publications, 12th Edition, 2015.

3. Mike Harris, ―Communication at Sea‖, Sheridan House publication, 2003.

REFERENCES:

1. N.S.Nagaraja ,―Elements of Electronic Navigation‖, McGraw Hill Education, 2nd edition, 2004.

2. EdrichFernandas , ―Advanced Electronic Navigation‖, Pro Navigator book publishers , 1999.

3. ―GMDSS Manual‖ published by International Maritime Organization, 2011.




Date : 19.08.2017 Date: 03.10.2017



Course Code UBEE602

Course Name : Digital Signal Processing

L T P C

4 0 0 4

Year and Semester


( 4Hrs )

Prerequisite course

Engineering Mathematics

Course

Objective

1. To study the various signals and systems & their mathematical representations

2. To study various transformation techniques & their computations.


1. Analyze different signals and systems.

2. Design of FIR and IIR digital filters.

3. Determine discrete Fourier transform using FFT

4. Design FIR and IIR filters.

5. Explain and discuss the architecture of DSP processors.

6. Understand the various transformation & their computations

UNIT- I:- INTRODUCTION 12 Hrs

Classification of systems: Continuous, discrete, linear, causal, stable, dynamic, recursive, time variance –

classification of signals: continuous and discrete – energy and power – mathematical representation of signals

– spectral density – sampling techniques, quantization, quantization error, Nyquist rate, aliasing effect.

UNIT- II:- DISCRETE TIME SYSTEM ANALYSIS 12 Hrs

Z-transform and its properties – inverse z-transforms – difference equation – Solution by z transform –

application to discrete systems Stability analysis – frequency response – Convolution – Discrete Time Fourier

transform , magnitude and phase representation.

UNIT- III:- DISCRETE FOURIER TRANSFORM & COMPUTATION 12 Hrs

Discrete Fourier Transform- properties, magnitude and phase representation –Computation of DFT using FFT

algorithm – DIT &DIF using radix 2 FFT – Butterfly structure.

UNIT- IV:- DESIGN OF DIGITAL FILTERS 12 Hrs

FIR & IIR filter realization – Parallel & cascade forms – FIR design: Windowing Techniques –Need and

choice of windows – Linear phase characteristics – Analog filter design Butterworth and Chebyshev




Date : 19.08.2017 Date: 03.10.2017


approximations – IIR Filters, digital design using impulse invariant and bilinear transformation – m Warping,

pre warping.

UNIT- V:- DIGITAL SIGNAL PROCESSORS 12 Hrs

Introduction – Architecture – Features – Addressing Formats – Functional modes -Introduction to Commercial

DS Processors.

TOTAL : 60 Hours.

TEXTBOOKS:

1. J.G. Proakis and D.G. Manolakis, ‗Digital Signal Processing Principles, Algorithms and Applications‗,

Pearson Education, New Delhi, PHI. 2003.

2. S.K. Mitra,‗Digital Signal Processing' A Computer Based Approach‗, McGraw Hill Edu,2013

3. Robert Schilling & Sandra L.Harris, Introduction to Digital Signal Processing using Matlab, Cengage

Learning,2014.

REFERENCES:

1. Poorna Chandra S, Sasikala. B ,Digital Signal Processing, Vijay Nicole/TMH,2013.

2. B.P.Lathi, ‗Principles of Signal Processing and Linear Systems‗, Oxford University Press, 2010

3. Taan S. ElAli, ‗Discrete Systems and Digital Signal Processing with Mat Lab‗,CRC Press, 2009.

4. Sen M.kuo, woonseng…s.gan, ―Digital Signal Processors, Architecture, Implementations

&Applications, Pearson,2013

5. Dimitris G.Manolakis, Vinay K. Ingle, applied Digital Signal Processing, Cambridge, 2012.

6. Lonnie C.Ludeman ,Fundamentals of Digital Signal Processing,Wiley,2013




Date : 19.08.2017_ Date: 03.10.2017



Course Code

UBEE601

Course Name :

Design of Electrical Machines

L T P C

3

1

0

4

Year and Semester III Year ( VI Semester ) Contact hours per week

( 4 Hrs ) Prerequisite course DC and AC machines

Course Objective 1. To implement the design of DC machines, transformers and induction motors

2. To find out the dimension of various parts of the machine and to examine various losses in

the machines.


1. Demonstrate the basic steps involved in design of electrical machines

2. Examine and analyze the performance of electrical machines

3. Develop the design parameters as per performance requirements

4. Design transformers, induction machines, dc machines and synchronous machines.

5. Determine the losses and efficiency in the DC and AC machines

6. Understand the different types of motors ,transformers and synchronous machine

UNIT - I INTRODUCTION 12 Hrs

Major considerations in Electrical Machine Design - Electrical Engineering Materials –Spacefactor – Choice

of Specific Electrical and Magnetic loadings – Thermal considerations – Heatflow – Temperature rise –Rating

of machines – Standard specifications.

UNIT - II DC MACHINES 12 Hrs

Output Equations – Main Dimensions - Magnetic circuit calculations – Carter‗s Coefficient –Net length of Iron

–Real & Apparent flux densities – Selection of number of poles- Design of Armature –Design of commutator

and brushes – performance prediction using design values.

UNIT – III TRANSFORMERS 12 Hrs

Output Equations – Main Dimensions -KVA output for single and three phase transformers –Window space

factor – Overall dimensions – Operating characteristics – Regulation – No load current – Temperature rise in

Transformers – Design of Tank – Methods of cooling of Transformers.




Date : 19.08.2017_ Date: 03.10.2017


UNIT – IVINDUCTION MOTORS 12 Hrs

Output equation of Induction motor – Main dimensions – Length of air gap-Rules for selecting rotor slots of

squirrel cage machines – Design of rotor bars & slots- Design of end rings –Design of wound rotor – Magnetic

leakage calculations – Leakage reactance of poly phase machines- Magnetizing current – Short circuit current -

Circle diagram –Operating characteristics.

UNIT - V SYNCHRONOUS MACHINES 12 Hrs

Output equations – choice of loadings – Design of salient pole machines –Short circuit ratio –shape of pole

face – Armature design – Armature parameters – Estimation of air gap length –Design of rotor – Design of

damper winding – Determination of full load field mmf – Design of field winding – Design of turbo alternators

– Rotor design.

TOTAL : 60 Hours.

TEXT BOOKS:

1. Sawhney, A.K., 'A Course in Electrical Machine Design', Dhanpat Rai& Sons, NewDelhi6th Edition,

2006.

2. Sen, S.K., 'Principles of Electrical Machine Designs with Computer Programmes', Oxford and IBH

Publishing Co. Pvt. Ltd., New Delhi, 2006

3. M.V.Deshpande ―Design and Testing of Electrical Machine Design‖ Wheeler Publications, 2010

REFERENCES:

1. A.Shanmugasundaram, G.Gangadharan, R.Palani 'Electrical Machine Design DataBook, New Age

Intenational Pvt. Ltd., Reprint 2007.

2. R.K.Agarwal ― Principles of Electrical Machine Design‖ Esskay Publications, Delhi, 2002.




Date : 19.08.2017_ Date: 03.10.2017



Course Code UBEE608

Course Name : Transmission & Distribution

L T P C

3 0 0 3

Year and Semester


( 3Hrs )

Prerequisite course

Knowledge of Basic Electrical Engineering, Electromagnetic

Theory

Course

Objective

1. To develop expressions for the computation of transmission line parameters and to

obtain the equivalent circuits for the transmission lines

2. To analyses the voltage distribution in insulator strings and cables and methods to

improve the same.


1. Understand transmission elements in power system

2. Summarize the modeling of transmission and distribution components and analyze its

Performance

3. Apply the concepts of transmission line into real time transmission networks.

4. Select a suitable insulator & design the transmission line for the required sag.

5. Develop network models of different types of transmission lines and assess their

Performance.

6. Analyze the underground cable grading and earthing types and their basis for selection.

UNIT- I STRUCTURE OF POWER SYSTEM 9 Hrs

Structure of electric power system: generation, transmission and distribution – Types of AC and DC

distributors – distributed and concentrated loads – interconnection – EHVAC and HVDC transmission -

Introduction to FACTS.

UNIT- II TRANSMISSION LINE PARAMETERS 9 Hrs

Parameters of single and three phase transmission lines with single and double circuits - Resistance,

inductance and capacitance of solid, stranded and bundled conductors – Symmetrical and unsymmetrical

spacing and transposition - application of self and mutual GMD – skin and proximity effects – interference

with neighboring communication circuits - Typical configurations, conductor types and electrical parameters

of EHV lines – corona discharges




Date : 19.08.2017_ Date: 03.10.2017


UNIT- III MODELLING AND PERFORMANCE OF TRANSMISSION LINES 9 Hrs

Classification of lines – short line, medium line and long line equivalent circuits, phasor diagram, attenuation

constant, phase constant, surge impedance; transmission efficiency and voltage regulation, real and reactive

power flow in lines, Power – circle diagrams, surge impedance loading, methods of voltage control – Ferranti

effect.

UNIT – IV INSULATORS AND CABLES 9 Hrs

Insulators – Types, voltag distribution in insulator string, improvement of string efficiency, testing of

insulators – Underground cables – Types of cables, Capacitance of Single-core cable, Grading of cables,

Power factor and heating of cables – Capacitance of 3 – core belted cable – D.C cables.

UNIT –V:- MECHANICAL DESIGN OF LINES AND GROUNDING 9 Hrs

Mechanical design of transmission line – sag and tension calculations for different weather conditions –

Tower spotting – Types of towers – Substation Layout (AIS, GIS) – Methods of grounding.

TOTAL : 45 Hours

TEXT BOOKS:

1. D.P.Kothari, I.J. Nagarath, ‗Power System Engineering‘, Tata McGraw-Hill Publishing Company

limited, New Delhi, Second Edition, 2008.

2. C.L.Wadhwa, ‗Electrical Power Systems‘, New Academic Science Ltd, 2009.

3. S.N. Singh, ‗Electric Power Generation, Transmission and Distribution‘, Prentice Hall of India Pvt.

Ltd, New Delhi, Secon Edition, 2011.

REFERENCES:

1. B.R.Gupta, , S.Chand, ‗Power System Analysis and Design‘New Delhi, Fifth Edition, 2008.

2. Luces M.Fualken berry , Walter Coffer, Electrical Power Distribution and Transmission‘, Pearson

Education, 2007.

3. Hadi Saadat, ‗Power System Analysis,‘ PSA Publishing; Third Edition, 2010.

4. J.Brian, Hardy and Colin R.Bayliss ‗Transmission and Distribution in Electrical Engineering‘,

Newnes; Fourth Edition, 2012.

5. G.Ramamurthy, ―Handbook of Electrical power Distribution,‖ Universities Press, 2013.





Course Code UBEE611

Course Name : Electrical Power Plant Engineering

L T P C

3 0 0 3

Year and Semester


( 3Hrs )

Prerequisite course

Nil

Course

Objective 1. To understand the various components of Power plants.

2. To understand the operations and applications of different types of power plants.


1. Understand the various types of Power Plants.

2. Infer the operation of steam power plant.

3. Discuss the nuclear energy types and hydel power plants.

4. Explain the types and operation of diesel and gas power plant

5. Discuss the various types of power plants and its load sharing economics.

6. Analyze the types of power plants and its load sharing economics.

UNIT I INTRODUCTION TO POWER PLANTS AND BOILERS 9 Hrs

Layout of Steam , Hydel , Diesel , MHD, Nuclear and Gas turbine Power Plants – Combined Power cycles –

comparison and selection – Load duration Curves – Steam boilers and cycles – High pressure and Super

Critical Boilers – Fluidised Bed Boilers.

UNIT II STEAM POWER PLANT 9 Hrs

Fuel and ash handling – Combustion Equipment for burning coal – Mechanical Stokers – Pulveriser –

Electrostatic Precipitator – Draught – Different Types – Surface condenser types – cooling Towers.

UNIT III NUCLEAR AND HYDEL POWER PLANTS 9 Hrs

Nuclear Energy- Fission and Fusion Reaction – Types of Reactors – Pressurized water reactor – Boiling water

reactor – Waste disposal and safety Hydel Power plant – Essential elements – Selection of turbines –

governing of Turbines – Micro hydel developments.

Document Prepare din― Board of Studies‖ held on

Date : 19.08.2017_


Date: 03.10.2017



Document Prepare din― Board of Studies‖ held on Document Approved in ― Academic Council‖ held on

Date : 19.08.2017_ Date: 03.10.2017


UNIT IV DIESEL AND GAS TURBINE POWER PLANT 9 Hrs

Types of diesel plants, components , Selection of Engine type and applications – Gas turbine power plant –

Fuels – Gas turbine material – open and closed cycles reheating – Regeneration and intercooling –combines

cycle.

UNIT V OTHER POWER PLANTS AND ECONOMICS OF POWER PLANTS 9 Hrs

Geo thermal – OTEC – tidel – Pumped storage – Solar central receiver system Cost of electric Energy – Fixed

and operating costs – Energy rates – Types tariffs – Economics of load sharing – comparison of various

powerplants.

TOTAL :45 Hours

TEXT BOOKS:

1. Arora S.C and Domkundwar S, ―A Course in Power Plant Engineering, DhanpatRai,2001

2. P.K. Nag, Power Plant Engineering, Tata McGraw – Hill Publishing Company Ltd., Third Edition, 2008

REFERENCES:

1. M.M. El-Wakil, Power Plant Technology, Tata McGraw – Hill Publishing Company Ltd., 2010.

2. K.K.Ramalingam , ― Power Plant Engineering ―, Scitech Publications, 2002.

3. Godfrey Boyle, Renewable energy, Open University, Oxford University Press in association with the Open

University, 2004


Date : 19.08.2017_ Date: 03.10.2017





Course Code UAEE609

Course Name : Electrical Hybrid Vehicles

L T P C

2 0 0 2

Year and Semester

III Year (VI Semester ) Contact hours per week

( 2 Hrs )

Prerequisite course

Basics of EEE

Course

Objective 1. To understand the concept of electrical hybrid vehicles and to learn electrical vehicle

operation and control

2. To provide basic knowledge about Suspension, Brakes, Aerodynamics and Safety.


1. Understand the Hybrid vehicles by their energy source

2. Recall the power generation for Hybrid vehicles

3. Explain the complete operation of Hybrid vehicles

4. Explain the complete automated operation of Hybrid vehicles

5. Determine and maintenance of proper road network.

6. Compile automatic controlled electrical vehicles.

UNIT I INTRODUCTION TO ELECTRIC AND HYBRID VEHICLES 6 Hrs

Electric and hybrid vehicles – flexible fuel vehicles (FFV) – solar powered vehicles – magnetic Track vehicles

– fuel cells vehicles – Configuration and performance of electrical vehicle – traction motor characteristics –

active effort – transmission requirement – vehicle performance and energy consumption.

UNIT II POWER SYSTEM AND NEW GENERATION VEHICLES 6 Hrs

Hybrid Vehicle engines – Stratified charge engines – lean burn engines – low heat rejection engines –

hydrogen engine – HCCI engine –VCR engine – surface ignition engines – VVTI engines – High energy and

power density batteries – fuel cell – solar panels – flexible fuel systems.

UNIT III VEHICLE OPERATION 6 Hrs

Computer Control for pollution and noise control and for fuel economy – Transducers and actuators

Information technology for receiving proper information and operation of the vehicle like optimum speed and

direction.


Date : 19.08.2017_ Date: 03.10.2017




UNIT IV VEHICLE AUTOMATED TRACKS 6 Hrs

Preparation and maintenance of proper road network – National highway network with automated roads and

vehicles – Satellite control of vehicle operation for safe and fast travel – GPS.

UNIT V SUSPENSION, BRAKES, AERODYNAMICS AND SAFETY 6 Hrs

Air suspension – Closed loop suspension, compensated suspension, antiskid braking system, retarders,

regenerative braking and safety gauge air backs-crash resistance – Aerodynamics for modern vehicles, safety

systems, materials and standards.

TOTAL : 30 Hours.

TEXT BOOKS:

1. Modern Vehicle Technology by Heinz.

2. Bosch Hand Book, SAE Publication,, 2000

REFERENCES:

1. Light weight electric for hybrid vehicle design.

2. Advance hybrid vehicle power transmission, SAE.

3. Noise reduction, Branek L.L., McGraw Hill Book company, New York, 2002.


Date : 19.08.2017_ Date: 03.10.2017





Course Code UBEE610

Course Name :

Electrical Energy Generation

Utilization & Conservation

L T P C

3 0 0 3

Year and Semester


( 3 Hrs )

Prerequisite course

Basics of Electrical Engineering

Course

Objective

1. To introduce the concept of Electrical Energy Generation, Utilization & Conservation 2. To understand the importance of energy conservation


1. Outline and review the properties of different electric heating system. 2. Develop Illumination Schemes for residential, commercial, street lighting, and

sports ground

3. Illustrate the working of traction system.

4. Design energy efficient electrical system for home and industries.

5. List the detail idea of effective power utilization.

6. Examine the basic domestic electric wiring.

UNIT I POWER GENERATION 9 Hrs

Review of conventional methods – thermal, hydro and nuclear based power generation – Nonconventional

methods of power generation – fuel cells - tidal waves – wind – geothermal –solar - bio-mass –municipal

waste. Cogeneration. Effect of distributed generation on power system operation.

UNIT II ECONOMIC ASPECTS OF GENERATION 9 Hrs

Economic aspects of power generation – load and load duration curves –number and size of units – cost of

electrical energy – tariff. Economics of power factor improvement – power capacitors –power quality –

Importance of electrical energy conservation – methods –energy efficient equipments. Introduction to energy

auditing.

UNIT III ILLUMINATION 9Hrs

Importance of lighting – properties of good lighting scheme – laws of illumination – photometry - types of

lamps – lighting calculations – basic design of Illumination Schemes for residential, commercial, street

lighting, and sports ground - energy efficiency lamps.


Date : 19.08.2017_ Date: 03.10.2017




UNIT IV INDUSTRIAL HEATING AND WELDING 9 Hrs

Role of electric heating for industrial applications – resistance heating – induction heating – dielectric heating

– electric arc furnaces – Brief introduction to electric welding –welding generator, welding transformer and its

characteristics.

UNIT V ELECTRIC TRACTION 9 Hrs

Merits of electric traction – requirements of electric traction system – supply systems – mechanics of train

movement – traction motors and control – braking – recent trends in electric traction.

TOTAL : 45 Hours.

TEXT BOOKS:

1. C.L. Wadhwa, Generation, Distribution and Utilization of Electrical Energy‗, New Age International

Pvt. Ltd, 2003.

2. B.R. Gupta, Generation of Electrical Energy‗, Eurasia Publishing House (P) Ltd, New Delhi, 2003.

REFERENCES:

1. H. Partab, ‗Art and Science of Utilisation of Electrical Energy‗, Dhanpat Rai and Co, New Delhi,

2004.

2. E. Openshaw Taylor, ‗Utilization of Electrical Energy in SI Units‗, Orient Longman Pvt. Ltd, 2003.

3. J.B. Gupta, ‗Utilization of Electric Power and Electric Traction‗, S.K. Kataria and Sons, 2002.

4. Donals L. Steeby,‘ Alternative Energy Sources and Systems‘, Cengage Learning, 2012




Date : 27.01.2017 Date: 03.10.2017



Course Code

UBMEC02

Course Name : Marine Engineering – II

L T P C

3

0

0

3

(Common to BE – Mechanical, BE – EEE, BE - NA&OE)

Year and Semester


( 3Hrs )

Prerequisite course

Nil

Course

Objective

1. To impart knowledge in the structural components of ships

2. To understand about the marine thermal system and marine pumps and valve


1. Understand and classify the various types of piping system fitted-in ships

2. Explain the Auxiliary systems and Ballast systems.

3. Discuss the function of dry Cargo handling equipment

4. Outline the Steering gears in marine use

5. Distinguish the types for marine propulsion

6. Discuss the Importance of refrigerants

UNIT I: MARINE PUMPS, PIPES AND VALVES 9 Hrs

Marine and special duty pumps – Details of pumps for marine purpose viz. condenser circulating pumps.

Condensate and drain pumps, boiler feed pumps, bilge and ballast pumps, rotary pumps – ejectors – purpose of

ejectors – details of construction – Marine piping – various types of piping system fitted in ships – Expansion

arrangements for pipes, valves, types used in Marine Practice – Materials and corrosion in pipes – color codes

for pipes.

UNIT II: MARINE THERMAL SYSTEM 9 Hrs

Aux systems – Air compressors, boilers, heat exchangers, cooling, evaporators, distillers – waste heat recovery

systems – hot water, drinking water, cooling water and sea water systems – Fuelsystems – lubricating oil

system – filters, coolers, centrifuges and clarities – Bilge and Ballastsystems – sewage disposal, Oily water

separator, incinerator, galley Equipments.




Date : 27.01.2017 Date: 03.10.2017


UNIT III: STRUCTURAL COMPONENTS OF SHIPS 9 Hrs

Deck machine and hull equipment – mooring – anchor handling – cargo handling – dry Cargo handling

equipment – winches, cranes, Cargo gears – patent hatch covers, bulk heads, liquid cargo, tanker cargo, pipe

layout systems – loading – unloading – ventilation and cleaning of tankers – L.S.A. Boats & rafts, emergency

equipment – water tight doors, stabilizers and bowthruster.

UNIT IV: POWER TRANSMISSION SYSTEM 9 Hrs

Steering gears in marine use – different types – description – construction, operation and maintenance –

Shafting arrangements – stern tubes and glands – oil – Lubricated stern tubes – shaft seals shaft alignment –

Thrust block – reduction gearing – Propulsion – types for marine propulsion – constructional details – fixing,

maintenance and operation – stabilizers – Engine room cranes, chain blocks – tackles – Anchors, anchor

cables.

UNIT V: MARINE REFRIGERATION 9Hrs

Safety systems – firefighting equipments – Instrumentation & Control, watch keeping systems – UMS classes

– Air Compressors, heat exchanger, Refrigeration, definition and purpose – Principle of operation of Simple

vapor compression system – Representation on t-s and p-h charts – Estimation of co-efficient of performance

and refrigerant flow rate – Factors affecting coefficient of performance – Absorption refrigeration system –

Comparison with vapor compression system – Principle of operation of vapor absorption system like aqua

ammonia system, Electrolux system, Lithium bromide absorption refrigeration system etc. –Steam jet

refrigeration system working and principle – Refrigerants – Classification and designation – properties and

requirements – Important refrigerants like NH3, CO2, Methyl chloride, Methylene chloride, Freon‗s etc. –

Factors influencing selection of refrigerants – Secondary refrigerants.

TOTAL : 45 Hours.




Date : 27.01.2017 Date: 03.10.2017


TEXT BOOKS:

1. Albert Edward Tompkins, ―Marine engineering by Tompkins‖, Wentworth Press publisher, 2016.

2. M. G. khetagurov, ―Marine Auxiliary Machinery and systems‖, Honolulu, Hawaii : University

Press of the Pacific, 9th

Edition 2004.

REFERENCES:

1. Harrington, ―Marine Engineering‖, SNAME Publications, 1992.

2. Pounder. C.C, ―Marine Diesel Engines‖, Newnen – Butterworths Publication, London, 8th

Edition,

2003

3. D. A. Taylor, ―Introduction to Marine Engineering‖, Butterworth-Heinemann publication, 2nd

Edition, 1996.

4. E.A stoke ―Naval Architecture (Reeds Marine Engineering and Technology Series)‖, Reeds Vol 4,

Thomas Reed Publications; 4th Revised edition, 1991.

https://www.google.co.in/search?tbo=p&tbm=bks&q=inauthor%3A%22D%2BA%2BTaylor%22




Date : 19.08.2017 Date: 03.10.2017



Course Code

UBEE6PA

Course Name :

Process Control And Marine

Automation Laboratory

L T P C

0

0

2

1

Year and Semester III Year (VI Semester ) Contact hours per week ( 2 Hrs ) Prerequisite course NIL

Course Objective 1.Working and maintenance of Temperature, Pressure, Flow, Level and other measuring equipment

2.To analyze and Design tune process (PID) controllers


1. Illustrate Proportional, Integral, Derivative (PID) Control Tuning.

2. Analyze the operation Derivative (PID) Control, Tuning.

3. Infer the operation and performance of SCADA system.

4. Illustrate the operation and control of control loops.

5. Construct the Characteristics of control valve with and without positioned.

6. Design the SCADA system.

List of Experiments

1. Response of different order processes with and without transportation lag

2. Response of P+I+D controller.

3. Characteristics of control valve with and without positioner.

4. Closed loop response of flow control loop.

5. Closed loop response of level control loop.

6. Closed loop response of temperature control loop.

7. Closed loop response of pressure control loop.

8. Tuning of PID controller.

9. Response of cascade control system.

10. Designing of SCADA system for Switching on and off a motor using Graphical User

Interface

11. Design a SCADA system for automatic temperature controlling with remote manual over ride.

TOTAL : 30 Hours.




Date : 19.08.2017 Date: 03.10.2017



Course Code UCEE6PB

Course Name :

Digital signal processing Laboratory

L T P C

0 0 2 1

Year and Semester


( 2Hrs )

Prerequisite course

Nil

Course Objective

1. To implement the processing techniques using the instructions of TMS320c5x.

2. To implement the IIR and FIR filter using MATLAB.


1. Understand the Sampling and effect of aliasing

2. Analyze the nature of various signals generated using Matlab

3. Infer the operation and performance of Decimation by polyphase decomposition

4. Distinguish and understand the Linear and circular convolution techniques.

5. Analyze the nature of signal using FFT. 6. Design of FIR and IIR filters using Matlab.

List of Experiments :

USING TMS320C5X/TMS320C 67XX/ADSP 218X/219X/BS531/532/561

1. Study of various addressing modes of DSP using simple programming examples

2. Implementation of Linear and Circular Convolution

3. Sampling of input signal and display

4. Waveform generation

5. Implementation of FIR filter

USING MATLAB

1. Generation of Signals

2. Linear and circular convolution of two sequences

3. Sampling and effect of aliasing

4. Design of FIR filters




Date : 19.08.2017 Date: 03.10.2017


5. Design of IIR filters

6. Calculation of FFT of a signal

7. Decimation by polyphase decomposition

TOTAL :30 Hours.




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Course Code UBEE706

Course Name : Solid State Drives

L T P C

3 1 0 4

Year and Semester IV Year ( VII Semester ) Contact hours per week

( 4Hrs ) Prerequisite course Electrical Machines & Power Electronics

Course Objective 1. To understand steady state operation and transient dynamics of a motor load system.

2. To analyze and design the current and speed controllers for a solid state AC and DC drives.


1. Illustrate the steady state operation and transient dynamics of a motor load system. 2. Analyze the operation of solid state DC drive.

3. Explain and understand the operation and performance of Induction motor drives.

4. Examine the operation and control of synchronous motor drives. 5. Construct the current and speed controllers for Electric drives. 6. Design the controllers for AC and DC motor drives.

UNIT- I:- DRIVE CHARACTERISTICS 12 Hrs

Electric drive – Equations governing motor load dynamic – steady state stability – multi quadrant Dynamics –

acceleration, deceleration, starting & stopping – typical load torque characteristics – Selection of motor.

UNIT- II:- CONVERTER / CHOPPER FED DC MOTOR DRIVE 12 Hrs

Steady state analysis of single and three phase converter fed separately excited DC motor drive – continuous and

discontinuous conduction – Time ratio and current limit control – 4 quadrant operation of converter/ chopper fed drive.

UNIT- III:- INDUCTION MOTOR DRIVES 12 Hrs

Stator voltage control–energy efficient drive–v/f control–constant airgap flux–field weakening mode voltage / current fed inverter – closed loop control.

UNIT- IV:- SYNCHRONOUS MOTOR DRIVES 12 Hrs

V/F control and self control of synchronous motor – Margin angle control and power factor control – permanent magnet

synchronous motor.

UNIT –V:- DESIGN OF CONTROLLERS FOR DRIVES 12 Hrs

Transfer function for DC motor / load and converter – closed loop control with Current and speed feedback – armature

voltage control and field weakening mode – Design of controller‘s – current controller and speed controller – converter

selection and characteristics.

TOTAL : 60 Hours.




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TEXT BOOKS:

1. Gopal K.Dubey, Fundamentals of Electrical Drives, Narosa Publishing House, Reprint 2017

2. Bimal K.Bose. Modern Power Electronics and AC Drives, Pearson Education, 2002.

3. R.Krishnan, Electric Motor & Drives: Modeling, Analysis and Control, Prentice Hall of India, 2001.

REFERENCES:

1. John Hindmarsh and Alasdain Renfrew, ―Electrical Machines and Drives System,‖ Elsevier 2012.

2. Shaahin Felizadeh, ―Electric Machines and Drives‖, CRC Press(Taylor and Francis Group), 2013.

3. N.K.De., P.K.SEN‖Electric drives‖ PHI, 2012.

4. Vedam Subramanyam, ‖Thyristor Control of Electric Drives‖, Tata McGraw Hill, 2007





Course Code

UBEE702

Course Name : High Voltage on Merchant Ships

L T P C

3

1

0

4

Year and Semester IV Year (VII Semester ) Contact hours per week

( 4Hrs ) Prerequisite course Power electronics

Course Objective 1. To understand the various types of over voltages in power system and protection methods.

2. To study the nature of Breakdown mechanism in solid, liquid and gaseous dielectrics and to

learn the testing of power apparatus and insulation coordination


1. Classify the various causes and effects on power system.

2. Summarize Electrical Breakdown In Gases, Solids And Liquids

3. Explain principles of generation and measurement of high voltages and high currents in any

electrical apparatus.

4. Distinguish the various testing methods to test the High Voltage components.

5. Discuss the HV application on marine system

6. Compare the most suitable equipment for performing specific testing on high-voltage

applications.

UNIT I : OVER VOLTAGES IN ELECTRICAL POWER SYSTEMS 12 Hrs

Level of voltage – Causes of over voltages and its effect on power system – Lightning, switching surges and temporary

over voltages – protection against over voltages – Operation & types of lightning arrestor.

UNIT II: ELECTRICAL BREAKDOWN IN GASES, SOLIDS AND LIQUIDS 12 Hrs

Ionization process – Townsend‗s current growth equation – Breakdown in Electronegative gases – Streamer theory

Paschen‗s Law – Gaseous breakdown in uniform and non-uniform fields – corona discharges – Vacuum breakdown –

conduction and breakdown in pure and commercial liquids – breakdown mechanisms in solid and composite dielectrics.

UNIT III: GENERATION & MEASUREMENT TECHNIQUES 12 Hrs

Generation of High DC voltages and AC voltages – Resonant transformer – Generation of impulse voltages & currents

– Marx circuit – Generation of switching surges – Generation of impulse currents – Tripping and control of impulse

generators.

UNIT IV: HIGH VOLTAGES SYSTEM ON MARINE APPLICATION 12 Hrs

Discuss the safety precautions associated with operation of high voltage system on electric propulsion-Procedure for

megger testing high voltage system – Types of circuit breakers – vacuum and gas filled used in high voltage systems and

their maintenance procedures – precautionary measures to be taken in the maintenance of HV system with reference to


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EPTW (Electric Permitto Work), earthing-Down, circuit-earthing, and Bus-Bar earthing – periodic maintenance required

in HV System- Testing of motor, Alternator

UNIT V: HIGH VOLTAGE TESTING & INSULATION COORDINATION 12 Hrs

High voltage testing of electrical power apparatus – Insulators, bushings, transformers, circuit breakers, cables – power

frequency, impulse voltage and DC testing – International and Indian standards – Insulation Coordination.

TOTAL : 60 Hours.

TEXT BOOK:

1. M.S. Naidu and V. Kamaraju, High Voltage Engineering‘, Tata McGraw-Hill Education Pvt. Ltd, 2013.

2. Estan Ferdandez,‗ Marine Electrical Technology 7th Edition, 2014

REFERENCES:

1. E. Kuffel and W.S. Zaengl, High Voltage Engineering Fundamentals‗, Pergamonpress, Oxford, London, 2000.

2. Estan Ferdandez,‗ Marine Electrical Technology 7th Edition, 2014

3. W. Lows , Electricity applied to marine Engineering‗




Date : 19.08.2017_ Date:03.10.2017



Course Code UBEEC02

Course Name :

Marine Control Engineering and

Automation

L T P C

4

0

0

4

Year and Semester

IV Year (VII Semester ) Contact hours per week

( 4Hrs )

Prerequisite course

Control systems

Course

Objective

1. Understand knowledge on advanced control techniques used onboard ships

2. Identify and analyze the safety control systems.

Course Outcome The Students will be able to 1. Describe the basics of control system

2. Analyze the automatic process control systems

3. Illustrate the operation of ship control and automation of ship applications

4. Understand the different kind of valves and actuators

5. Discriminate the different types of controls on ships and their applications.

6. Enumerate the advanced controllers and actuators.

UNIT I: CONTROL SYSTEMS 12 Hrs

Introduction to control system – block diagrams for control systems – open loop and closed loop feedback

control comparison of closed and open loop feed forward control Feed forward modifications and adaptive

controls – Regulator and servo mechanism – Proportional plus integral plus derivative controls. Use of various

contro modes.

UNIT II AUTOMATIC CLOSED LOOP PROCESS CONTROL SYSTEMS 12 Hrs

The dynamics of a simple servo mechanism for angular position control – Introduction to the dynamics of

simple servomechanism for angular position control – Process control system – Automatic closed loop process

– Control system dynamic characteristics of processes – Analog computer and simulation – Introduction, Basic

concepts – Analog computers – Simulation – The use of digital computer in the simulation control system –

Hybrid computers




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UNIT III TRANSMISSION 12 Hrs

Pneumatic and electric transmission – suitability for marine use – Pneumatic and types of controller hydraulic

– Electric and electronic controllers for generation of control action – Time function controllers Computer

based Automation – PLC control and instruments – SCADA system – DCS system – PLC application on

Purifier – Boiler – Main Engine control – Net working and protocol

UNIT IV CORRECTING UNITS 12 Hrs

Diaphram actuators – Valve positioners – piston actuators – Electro pneumatic transducers – Electro hydraulic

actuators and electric actuators – control valves.

UNIT V APPLICATION OF CONTROLS ON SHIPS 12 Hrs

Marine boiler automatic combustion control – Air/fuel ratio control – feed water control – single –two and

three element type – Fuel oil temperature control –control in main machinery units for temperature of

lubricating Oil– jacket cooling water, fuel valve cooling water, piston cooling water and scavenge air, fuel oil

viscosity control, bridge control of main machineries.

TOTAL: 60 Hours.

TEXT BOOKS:

1. Notes on Instrumentation and Control by G.J.Roy, (Eng. FIMARE, MRINA, Stanford Maritime London)

1994

REFERENCES:

1. Gordob Boyd and Leslie Jackson ―Reed‘s Marine Instrumentation & Control‖, Vol 10, 5

th Edition, 2013.




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Course Code

UCEE705

Course Name :

Marine Electrical System Design and

Layout

L T P C

3 0 0 3


( 3Hrs ) Prerequisite course Electrical Estimation

Course Objective 1. To implement the Wiring on Panel for Starters, Light Connection and Marine Accessories. 2. To understand different types of cable trays.

Course Outcome The Students will be able to 1. Construct Wiring on Panel for Starters, Light Connection and Marine Accessories.

2. Understand the Sizing of Cable and selection of type for a given load.

3. Outline regular Maintenance of a high power VFD

4. Demonstrate rewinding of a motor

5. Demonstrate the different types of Cable trays used in ships

6. Demonstrate the BOW Thrusters and Shaft Motors

UNIT I: CONTROL AND CHARACTERISTICS OF INDUCTION MOTOR DRIVES 9 Hrs

Three phase induction motor – principle and operational characteristics – starting of induction motor – method of starting

– Direct on-line starters – Star – delta starter – auto – transformer starter – starting of special high torque induction

motors – Reversing – speed control of induction motor.

UNIT II: PWM FOR INVERTER FED VARIABLE FREQUENCY DRIVES 9 Hrs

Design and Analysis of Inverters: Voltage Source Inverter - Harmonics - PWM Techniques - Matrix Converter-V/F

Control-Design of LC Filter for Inverters-Multi level inverter-Simulation using MATLAB.

UNIT III: BATTERIES AND BATTERY CHARGING 9 Hrs

Classification of Batteries – Electrical characteristics of Batteries – Methods of Charging: Charging with supply from a

DC source – Charging with supply from an AC Source-Single Rate and Double Rate Battery Chargers – Automatic

Thyristor controlled Battery charger – Battery Installation and Safety measures – SOLAS Regulations.

UNIT IV: ELECTRIC CABLES AND INSULATIONS 9 Hrs

Introduction to cables – Types of cables – Wiring on panel starters – Light Connection and marine accessories – Sizing

of cables –Routing a cable – Different types of cable trays used in ships-crimping the lug - BOW thrusters and Shaft

motors – Classes of cable Insulations – Insulating materials – Temperature ratings – Conductor insulation.




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UNIT V: ELECTRICAL DRAWING & LAYOUT 9 Hrs

Single line diagram – Schematic power distribution diagrams – cable layout drawing – Electrical panel drawing – Trace

and analyze the circuit diagrams and trouble shoot electric systems logically – Design of Uninterruptible Power Supply

– Marine Electrical switch boards.

TOTAL : 45 Hours.

TEXT BOOKS:

1. R.Krishnan, Electric Motor & Drives: Modelling, Analysis and Control, Prentice Hall of India, 2001.

2. D.P.Kothari , I.J. Nagarath, ‗Power System Engineering‘, Tata McGraw-Hill Publishing Company limited, New

Delhi, Second Edition, 2008.

3. Elstan A. Fernandez, ‗Marine Electrical Technology‘, Fifth Edition, 2011.

4. L. Umanand, ― Power Electronics Essentials and Applications‖, Wiley, 2010

REFERENCES:

1. M.H.Rashid, ‗Power Electronics: Circuits, Devices and Applications‘, Pearson Education, PHI Third Edition,

New Delhi, 2004.

2. P.S.Bimbra ―Power Electronics‖ Khanna Publishers, third Edition, 2003.

3. Bimal K.Bose. Modern Power Electronics and AC Drives, Pearson Education, 2002

4. C.L.Wadhwa, ‗Electrical Power Systems‘, New Academic Science Ltd, 2009.





Course Code UBEE712

Course Name : Special Electrical Machines

L T P C

3 0 0 3


( 3Hrs ) Prerequisite course DC and AC Machines

Course Objective 1. To impart knowledge on Construction, principle of operation and performance of synchronous

reluctance motors, Stepper motors and Switched Reluctance motors

2. To analyze the performance of permanent magnet brushless DC motors and synchronous motors

Course Outcome The Students will be able to 1. Understand Construction, types, operation and applications of synchronous reluctance motors.

2. Observe the performance of Stepper motors.

3. Analyze the operation Switched Reluctance motors. 4. Understand the operation of permanent magnet brushless DC motors.

5. Evaluate the performance of permanent magnet synchronous motors

6. Simulate the performance of special electrical machines and their application to power

systems.

UNIT I SYNCHRONOUS RELUCTANCE MOTORS 9 Hrs

Constructional features – Types – Axial and Radial flux motors – Operating principles – Variable Reluctance Motors –

Voltage and Torque Equations – Phasor diagram - performance characteristics –Applications.

UNIT- II STEPPER MOTORS 9 Hrs

Constructional features – Principle of operation – Variable reluctance motor – Hybrid motor – Single and multi-stack

configurations – Torque equations –Modes of excitation – Characteristics – Drive circuits – Microprocessor control of

stepper motors – Closed loop control-Concept of lead angle – Applications.

UNIT- III SWITCHED RELUCTANCE MOTORS (SRM) 9 Hrs

Constructional features – Rotary and Linear SRM - Principle of operation –Torque production –Steady state performance

prediction – Analytical method -Power Converters and their controllers Methods of Rotor position sensing – Sensor less

operation – Characteristics and Closed loop control Applications.

UNIT- IV PERMANENT MAGNET BRUSHLESS D.C. MOTORS 9 Hrs

Permanent Magnet materials – Minor hysteresis loop and recoil line-Magnetic Characteristics – Permeance coefficient –

Principle of operation – Types – Magnetic circuit analysis – EMF and torque equations – Commutation – Power

Converter Circuits and their controllers –Motor characteristics and control– Applications.


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Date: 03.10.2017

UNIT –V PERMANENT MAGNET SYNCHRONOUS MOTORS (PMSM) 9 Hrs

Ideal PMSM – EMF and Torque equations – Armature MMF – Synchronous Reactance – Sine wave motor with

practical windings - Phasor diagram –Torque/speed characteristics -Power controllers – Converter Volt-ampere

requirements– Application.

TOTAL : 45 Hours

TEXT BOOKS: 1.K.Venkataratnam, Special Electrical Machines, Universities Press (India) Private Limited, First Edition

reprinted in 2013.

2.E.G. Janardanan, Special electrical machines, PHI learning Private Limited, Delhi, 2014.

REFERENCES:

1. R.Krishnan, Switched Reluctance Motor Drives –Modeling Simulation, Analysis, Design and Application, CRC

Press, New York, 2001.


Date : 19.08.2017





Course Code UBEE711

Course Name : Embedded System Design

L T P C

3 0 0 3

Year and Semester IV Year (VII Semester ) Contact hours per week ( 3Hrs ) Prerequisite course Digital logic Circuits, microprocessors

and microcontroller.

Course Objective 1. To understand basic of Embedded system and its Networking

2.To analyze and design the RTOS and applications.

Course Outcome The Students will be able to 1. Understand the basic of Embedded system

2. Discuss the concept of Embedded Networking..

3. Understand the Embedded Product Development Life Cycle 4. Design embedded system in RTOS

5. Construct the current and speed controllers for Electric drives.

6. Illustrate and design the hardware using Embedded System..

UNIT I: INTRODUCTION TO EMBEDDED SYSTEMS 9Hrs

Introduction to Embedded Systems – The build process for embedded systems- Structural units in Embedded processor ,

selection of processor & memory devices- DMA – Memory management methods- Timer and Counting devices,

Watchdog Timer, Real Time Clock, In circuit emulator, Target Hardware Debugging.

UNIT II: EMBEDDED NETWORKING 9 Hrs

Embedded Networking – Introduction – I/O Device Ports & Buses – Serial Bus communication protocols – RS232

standard – RS422 – RS485 – CAN Bus -Serial Peripheral Interface (SPI) –Inter Integrated Circuits (I2C) – need for

device drivers.

UNIT III: EMBEDDED FIRMWARE DEVELOPMENT ENVIRONMENT 9 Hrs

Embedded Product Development Life Cycle – objectives – different phases of EDLC – Modeling of EDLC – issues in

Hardware-software Co-design – Data Flow Graph – state machine model, Sequential Program Model – concurrent

Model – object oriented Model.

UNIT IV: RTOS BASED EMBEDDED SYSTEM DESIGN 9 Hrs

Introduction to basic concepts of RTOS- Task, process & threads, interrupt routines in RTOS – Multiprocessing and

Multitasking – Preemptive and non-preemptive scheduling – Task communication shared memory – message passing –

Inter process Communication – synchronization between processes – semaphores, Mailbox, pipes, priority inversion,

priority Inheritance – comparison of Real time Operating systems: Vx Works, чC/OS-II, RT Linux.


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9 Hrs UNIT V: EMBEDDED SYSTEM APPLICATION DEVELOPMENT

Case Study of Washing Machine – Automotive Application – Smart card System Application.

TOTAL: 45 Hours.

TEXT BOOKS:

1. Rajkamal, ‗Embedded System-Architecture, Programming, Design‗, McGraw Hill,2013.

2. Peckol, ―Embedded system Design‖, John Wiley & Sons,2010

3. Lyla B Das,‖ Embedded Systems-An Integrated Approach‖, Pearson, 2013

REFERENCES:

1. Shibu. K.V, ―Introduction to Embedded Systems‖, Tata Mcgraw Hill,2009.

2. Elicia White,‖ Making Embedded Systems‖, O‗ Reilly Series,SPD,2011.

3. Tammy Noergaard, ―Embedded Systems Architecture‖, Elsevier, 2006.

4. Han-Way Huang, ‖Embedded system Design Using C8051‖, Cengage Learning,2009.

5. Rajib Mall ―Real-Time systems Theory and Practice‖ Pearson Education, 2007




Date : _19.09.2017_ Date: 03.10.2017



Course Code

UBEE508

Course Name :

Marine Electrical Protection and

Switch Gears

L T P C

3

1

0

4

Year and Semester


( 4Hrs )

Prerequisite course

Transmission and Distribution

Course Objective 1. To learn various earthing practices usage of symmetrical components to estimate fault

current

2. Introduce students to power system protection and switchgear.

Course Outcome The Students will be able to 1. List the various protection schemes in power system network.

2. Compare the different protective devices for power system components.

3. Identify the protective component based on the fault condition in power system network. 4. Select applications of the relays, circuit breakers, grounding for different elements of

power system are also discussed in the subject.

5. Discuss recovery, Re-striking voltage, Oil circuit Breaker, Air Blast circuit Breakers, SF6

Circuit Breaker.

6. Distinguish Rotor, Stator faults, inter turn faults and their protection component based on

the fault condition in power system network.

UNIT I : INTRODUCTION 12 Hrs

Principles and need for protective schemes – nature and causes of faults – types of faults –fault current calculation

using symmetrical components – Power system earthing – Zones of protection and essential qualities of protection -

Protection scheme.

UNIT II: OPERATING PRINCIPLES AND RELAY CONSTRUCTIONS 12 Hrs

Electromagnetic relays – Over current, directional, distance and differential under frequency relays – static relays.

UNIT III: APPARATUS PROTECTION 12 Hrs

Apparatus – protection for transformer, generator, motor, protection of bus bars, transmission lines – CTs and PTs and

their applications in protection schemes – Describe cables suitable for use in locations subject to high temperatures

with oil mist or vapor.

UNIT IV: THEORY OF CIRCUIT INTERRUPTION 12Hrs

Physics of arc phenomena and arc interruption – Re-striking voltage & Recovery voltage, rate of rise of recovery

voltage – resistance switching – current chopping – interruption of capacitive current – DC circuit breaking.




Date : _19.09.2017_ Date: 03.10.2017


UNIT V: CIRCUIT BREAKERS 12Hrs

Types of Circuit Breakers – Air blast, Air break, oil, SF6 and Vacuum circuit breakers – comparative merits of

different circuit breakers – Testing of circuit breakers.

TOTAL : 60 Hours.

TEXT BOOKS:

1. B. Ravindranath and N. Chander, Power System Protection & Switchgear‗, New Age International (P)

Limited, 2014 (2nd Edition).

2. Badri Ram, Vishwakarma, Power System Protection and Switchgear‗, Tata McGraw hill, 2001.

REFERENCES:

1. Sunil S. Rao, Switchgear and Protection‗, Khanna publishers, New Delhi, 11th Edition reprint 3rd

Edition,2008

2. C.L. Wadhwa, Electrical Power Systems‗, Newage International (P) Ltd., 2006.

3. M.L. Soni, P.V. Gupta, V.S. Bhatnagar, A. Chakrabarti, A Text Book on Power System Engineering‗,

Dhanpat Rai& Co., 2008.

4. Y.G. Paithankar and S.R. Bhide, ‗Fundamentals of Power System Protection‗, PrenticeHall of India Pvt. Ltd.,

New Delhi, 2003.





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Date: 03.10.2017


Course Code

UBEE7PA

Course Name :

High Voltage and Switch Gear

Laboratory

L T P C

0

0

2

1


( 2Hrs ) Prerequisite course Nil

Course Objective 1. To acquire hands on experience on the operation and maintenance of switch gears like

ACB, VCB & SF6

2. To acquire hands on experience on the protection systems used in switchboard


1. Interpret to select the appropriate setting, time calculation for various protective relay

2. Apply the high voltage safety precaution and procedures

3. Demonstrate the mechanism of operation circuit breakers

4. Demonstrate to trace out the marine electrical circuit diagrams

5. Determine the characteristics of relay operation 6. Identify the parts of alternator, relay and circuit breakers

LIST OF EXERCISES:

1. Construction of High voltage generation on board.

2. Separation of high and low voltage distribution system.

3. Earth fault monitor and isolating arrangements in main bus bar.

4. Study the construction & operation of high voltage switch gear like ACB.

5. Study the construction & operation of high voltage switch gear like VCB.

6. Study the construction & operation of high voltage switch gear like SF6.

7. Isolation and withdrawal procedure of circuit breaker for repair and replacement.

8. Arrangement of key operated interlocks, tracing of shipboard electrical circuit diagrams

and importance of correct sequence of operation.

9. Testing of VCB, ACB & SF6 breakers under over voltage /under voltage fault conditions.

10. Testing of VCB, ACB & SF6 breakers under over current & earth fault conditions.

TOTAL:30 Hours.





Course Code UCEE7PB

Course Name : Marine Automation Laboratory

L T P C

0 0 2 1

Year and Semester


( 2Hrs )

Prerequisite course

NIL

Course

Objective

1. Understand knowledge on advanced control techniques used in onboard ships

2. Identify and analyze the control systems.

Course Outcome The Students will be able to 1. Develop a PLC program for controlling the electrical equipments

2. Utilize the functions available in PLC to write a program

3. Design controllers using Lab VIEW software

4. Use Lab VIEW software to control Pressure to current converters and current to

Pressure converters.

5. Use Lab VIEW software to control pressure and Flow.

6. Design a mini project using LabVIEW.

LIST OF EXPERIMENTS

1. Motor ON/OFF Control Using PLC

2. ON / OFF delay timer using PLC

3. Sequential Control of different loads using PLC

4. ON/ OFF Buzzer using PLC

5. Forward & Reverse direction control of motor using PLC

6. Determination of control valve characteristics using LabVIEW

7. Current to Pressure converter using LabVIEW

8. Pressure to Current Converter using LabVIEW

9. Pressure and Flow control using LabVIEW

10. LabVIEW based Mini Project.

TOTAL: 30 Hours.


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Course Code UBMPCPY

Course Name : Minor Project

L T P C

0 0 4 2

Common for BE (ME, PE, H&OE, MECH, EEE, NA&OE) & BBA (SHIPPING) & BSC (NS)

Year and Semester


( 2Hrs )

Prerequisite course

NIL

Course

Objective 1. To Develope a minor project with apply the Technical Knowledge they studied.

2. To analyze and design the minor Project.


1. Apply the knowledge studied.

2. Analyze the real time problem in technical and societal challenges.

3. Compare the Existing and proposed system

4. Apply concept to do the project

5. Create the minor project. .

6. Illustrate and design the minor level project successfully.

MINOR PROJECT

The students will be allotted minor project from the department and they will have to complete the project and

submit the report for evaluation.

TOTAL: 60 Hours.




Date : 19.08.2017 Date: 03.10.2017



Course Code

UBEE801

Course Name : Mobile Communication

L T P C

3 0 0 3

Year and Semester IV Year ( VIII Semester ) Contact hours per week ( 3Hrs ) Prerequisite course Communication Engineering

Course Objective 1. To study the fundamentals of Mobile radio propagation and Cellular Concepts 2. To familiarize about Wireless Systems and Standards

Course Outcome The Students will be able to 1. Understand about cellular concept including handoff mechanism, cell coverage and capacity

2. List the mobile radio propagation models for indoor and outdoor conditions.

3. Analyze the digital modulation and equalization techniques suitable for mobile

communication

4. Select speech coding and multiple access techniques for mobile communication.

5. Understand the international wireless network standards

6. Develop the basic cellular concepts like mobile radio propagation models for indoor and outdoor conditions, handoff mechanism, cell coverage and capacity.

UNIT – I CELLULAR CONCEPT AND SYSTEM DESIGN FUNDAMENTALS 9 Hrs

Introduction to wireless communication – Evolution of Mobile Communications – mobile radio systems – Examples,

trends in cellular radio and personal communications – Cellular concept – Frequency reuse – channel assignment hand

off – interference and System capacity, tracking and grade of service, improving coverage and capacity in cellular

systems.

UNIT - II MOBILE RADIO PROPAGATION 9 Hrs

Free space propagation model – reflection – diffraction – scattering – link budget design – outdoor propagation models –

indoor propagation models – small scale multi path propagation – impulse model –small scale multipath measurements –

parameters of mobile multipath channels – types of small scale fading.

UNIT - III MODULATION TECHNIQUES AND EQUALIZATION 9 Hrs

Modulation techniques: Minimum shift keying, Gaussian MSK, performance of MSK modulation in slow-flat fading

channels – M-ary QAM – Equalization – Survey of equalization techniques – linear equalization, non-linear

equalization, algorithms for adaptive equalization – Diversity Techniques – RAKE receiver.




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UNIT - IV CODING AND MULTIPLE ACCESS TECHNIQUES 9 Hrs

Coding: Vocoders, Linear Predictive Coders – Selection of Speech Coders for Mobile Communication – GSM Coders –

Multiple Access Techniques – FDMA, TDMA, CDMA and SDMA – Capacity of Cellular CDMA

.

UNIT - V WIRELESS SYSTEMS AND STANDARDS 9 Hrs

Evolution of Wireless network, Second and Third generation wireless network and Standards – Wireless local loop

Technology – blue tooth, GSM Technology – IS-95 CDMA Technology – Digital Enhanced Cordless

Telecommunications.

Total : 45 Hours

TEXT BOOKS:

1. Wireless Communications, Principles, Practice – Theodore, S. Rappaport, 2nd Ed., PHI, 2002

2. Wireless Communications-Andrea Goldsmith, Cambridge University Press, 2005

3. Mobile Cellular Communication – Gottapu Sasibhushana Rao, Pearson Education, 2012.

REFERENCES:

1. Principles of Wireless Networks – Kaveh Pah Laven and P. Krishna Murthy, PE. 2002

3. Wireless Communication and Networking – William Stallings, PHI, 2003

4. Wireless Communication – Upen Dalal, Oxford Univ. Press.

5. Wireless Communications and Networking – Vijay K. Gary, Elsevier.




Date : 19.08.2017 Date: 03.10.2017



Course Code UBEE802

Course Name : Flexible AC Transmission Systems

L T P C

3 0 0 3

Year and Semester IV Year ( VIII Semester ) Contact hours per week

( 3Hrs ) Prerequisite course Power System Analysis

Course Objective 1. To understand the importance of FACTS device in power systems. 2. To learn different types of FACTS device.

Course Outcome The Students will be able to 1. Illustrate the concept of FACTS. 2. Analyze the SVC and its applications.

3. Infer the importance of TSC and its applications.

4. Investigate the VSC based FACTS Controllers.

5. Discuss the co-ordination of FACTS Controllers. 6. Explain the FACTS devices and its applications.

UNIT I: INTRODUCTION 9 Hrs

Reactive power control in electrical power transmission lines –Uncompensated transmission line – series compensation

–Basic concepts of Static Var Compensator (SVC) – Thyristor Controlled Series capacitor (TCSC) – Unified power

flow controller (UPFC).

UNIT II : STATIC VAR COMPENSATOR (SVC) AND APPLICATIONS 9 Hrs

Voltage control by SVC – Advantages of slope in dynamic characteristics –Influence of SVC on system voltage –

Design of SVC voltage regulator –Modelling of SVC for powerflow and fast transient stability –

Applications:Enhancement of transient stability–Steadystate power transfer –Enhancement of power system damping.

UNIT III : THYRISTOR CONTROLLED SERIES CAPACITOR (TCSC) &APPLICATIONS 9 Hrs

Operation of the TCSC – Different modes of operation – Modelling of TCSC –Variable reactance model –Modelling for

Power Flow and stability studies. Applications:Improvement of the system stability limit – Enhancement of system

damping.




Date : 19.08.2017 Date: 03.10.2017


9 Hrs UNIT IV: VOLTAGE SOURCE CONVERTER BASED FACTS CONTROLLERS

Static Synchronous Compensator (STATCOM) – Principle of operation – V-I Characteristics – Applications: Steady

state power transfer-enhancement of transient stability –prevention of voltage instability – SSSC – operation of SSSC

and the control of power flow – modelling of SSSC in load flow and transient stability studies.

UNIT V: CO-ORDINATION OF FACTS CONTROLLERS 9 Hrs

Controller interactions – SVC – SVC interaction – Co-ordination of multiple controllers using linear control techniques –

Control coordination using genetic algorithms.

TOTAL: 45 Hours.

TEXTBOOKS:

1. R.Mohan Mathur, Rajiv K.Varma, ―Thyristor - Based Facts Controllers for Electrical Transmission

Systems, IEEE press and John Wiley & Sons, Inc, 2002.

2. Narain G. Hingorani, ―Understanding FACTS -Concepts and Technology of Flexible AC Transmission

Systems, Standard Publishers Distributors, Delhi- 110006, 2011.

REFERENCES:

1. V.K.Sood,HVDC and FACTS controllers – Applications of Static Converters in Power System, Kluwer

Academic Publishers, 2004.

2. K.R.Padiyar, FACTS Controllers in Power Transmission and Distribution, New Age International (P)

Limited, Publishers, New Delhi, 2008.

3. Xiao – Ping Zang, Christian Rehtanz and Bikash Pal, ―Flexible AC Transmission System: Modelling and

Control‖ Springer, 2012.




Date : 13.03.2015 Date: 03.10.2017



Course Code UBBSC01

Course Name : Total Quality Management

L T P C

3 0 0 3

Common for BE(EEE) &BE (Mech)

Year and Semester IV Year (VIII Semester ) Contact hours per week ( 3Hrs ) Prerequisite course Principles of management

Course Objective 1. To actively involves every function and every employee in satisfying customers needs, both

internal and external.

2. It depends on and creates a culture in an organisation which involves everybody in quality

improvement.


1. Explain the evolution of quality.

2. Demonstrate the strategic quality planning, quality statements. 3. Discuss the techniques of management.

4. Summarize the tools of management techniques. 5.Understand the quality system

6. Summarize the elements, documentation, quality auditing.

UNIT I INTRODUCTION 9 Hrs

Introduction – Need for quality – Evolution of quality – Definition of quality – Dimensions of manufacturing and service

quality – Basic concepts of TQM – Definition of TQM – TQM Framework – Contributions of Deming, Juran and

Crosby – Barriers to TQM.

UNIT II TQM PRINCIPLES 9 Hrs

Leadership – Strategic quality planning, Quality statements - Customer focus – Customer orientation, Customer

satisfaction, Customer complaints, Customer retention – Employee involvement – Motivation, Empowerment, Team and

Teamwork – Recognition and Reward – Performance appraisal – Continuous process improvement – PDSA cycle, 5s,

Kaizen – Supplier partnership – Partnering, Supplier selection, Supplier Rating.

UNIT III TQM TOOLS & TECHNIQUES I 9 Hrs

The seven traditional tools of quality – New management tools – Six-sigma: Concepts, methodology, applications to

manufacturing, service sector including IT – Bench marking –Reason to bench mark, Bench marking process – FMEA –

Stages, Types.

UNIT IV TQM TOOLS & TECHNIQUES II 9 Hrs

Quality circles – Quality Function Deployment (QFD) – Taguchi quality loss function – TPM –Concepts, improvement

needs – Cost of Quality – Performance measures.




Date : 13.03.2015 Date: 03.10.2017


UNIT V QUALITY SYSTEMS 9 Hrs

Need for ISO 9000- ISO 9000-2000 Quality System – Elements, Documentation, Quality auditing- QS 9000 – ISO

14000 – Concepts, Requirements and Benefits – Case studies of TQM implementation in manufacturing and service

sectors including IT.

Total : 45 Hours.

TEXT BOOK:

1. Dale H.Besterfield, Carol Besterfield – Michna, Glen H. Besterfield, Mary Besterfield – Sacre, Hermant –

Urdhwareshe, RashmiUrdhwareshe, Total Quality Management, Revised Third edition, Pearson Education, 2011

2. ShridharaBhat K, Total Quality Management – Text and Cases, Himalaya Publishing House, First Edition 2002.

REFERENCES:

1. James R. Evans and William M. Lindsay, ―The Management and Control of Quality, 6thEdition, South-

Western (Thomson Learning), 2005.

2. Oakland, J.S. ―TQM – Text with Cases, Butterworth – Heinemann Ltd., Oxford, 3rd Edition,2003.




Date : 19.08.2017_ Date: 03.10.2017



Course Code UBEE8PA

Course Name : Project Work

L T P C

0 0 12 6

(Common for BE (ME, PE, H&OE, MECH, EEE, NA&OE) & BBA (SHIPPING) & BSC (NS)

Year and Semester IV Year (VIII Semester ) Contact hours per week ( 12Hrs ) Prerequisite course NIL

Course Objective 1. To design a project by applying the engineering concepts 2. To develop theproject with prototypes and analyze the work using simulations

Course Outcome The Students will be able to 1. Discuss the real time problem to face technical and societal challenges

2. Do Survey different technical journals.

3.Compare the existing and proposed systems

4. Illustrate the project work done 5.Design project simulation tools needed

6.Build and implement the project with required specifications

PROJECT WORK

The students will be allotted project from the department and they will have to complete the project and

submit the report for evaluation.

Total: 90 Hours.

department of electrical & electronics …m).pdf · specialization involving complex...

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