Published by the Department of Electrical and Electronic ... · B.Sc. Engineering in Electrical and...

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Published by the Department of Electrical and Electronic Engineering

Bangabandhu Sheikh Mujibur Rahman Science and Technology University (BSMRSTU)

Gopalganj-8100 Telephone (Registrar): +88-02-6682257

Fax: +88-02-6682173 E-mail: [email protected]

Website:http://www.bsmrstu.edu.bd/b/dept.php?id=EEE

Chairman of the Department Japatosh Mondal

Editorial Committee Moudud Ahmed Ashraful Hossain Howlader Naim Ferdous

Cover Design Suvradip Biswas (20141206037)

Edition 1

st Edition, December 2016

Bangabandhu Sheikh Mujbur Rahman Science & Technology University

(BSMRSTU) at a Glance

Bangabandhu Seikh Mujbur Rahman Science and Technology University (BSMRSTU) is a public research university founded in 2011 in Gopalganj district. The university sprang as a part of government‟s „Vision 2021‟ project as this was planned to be made as the first digital university of this country. The university is affiliated by University Grants Commission (UGC), Bangladesh.It aims to provide its students with world class education to build a humanely developed and strong country, and thus pave the way to fulfill government‟s goal to build a thriving and dignified nation.

Location & Its Surroundings The campus is located at Gobra, a union under Gopalganj Sadar Upazilla. It is nearly 4.5 kilometers away from Gopalganj town. Sheikh Fazilatunnesa Mujib Eye Hospital and Training Institute is sited within 2 km south from the campus. Dhaka-Khulna Highway (R856) passes through the east side of the campus keeping a distance of about 500 meters. Also, the beautiful river Madhumati is about 500 meters away to the west side of the campus.

Faculties and Departments The university by now has introduced 23 departments under eight faculties and two institutes though in 2011, its journey began with only four departments. All the departments offer at least Undergraduate degrees while some tend to convene Postgraduate degrees as well. The list of the departments following their faculties goes as follows: Engineering Faculty:

Department of Computer Science and Engineering Department of Electrical and Electronic Engineering Department of Applied Physics, Electronics and Communication

Engineering Department of Applied Chemistry and Chemical Engineering

Science Faculty: Department of Mathematics Department of Statistics Department of Physics Department of Chemistry Department of Environmental Science and Disaster Management

Life Science Faculty: Department of Pharmacy Department of Biotechnology and Genetic Engineering Department of Biochemistry and Molecular Biology

Business Studies Faculty: Department of Management Studies Department of Accounting and Information System Department of Marketing

mailto:[email protected]

http://www.bsmrstu.edu.bd/b/dept.php?id=EEE

https://en.wikipedia.org/wiki/University_Grants_Commission_%28Bangladesh%29

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Social Science Faculty: Department of Economics Department of Public Administration Department of Sociology Department of International Relation

Humanities Faculty: Department of English Department of Bangla

Law Faculty: Department of Law

Agricultural Faculty: Department of Agriculture

Institutes: Bangladesh Institute of Liberation War and Bangladesh Studies

Undergraduate Programmes Four Years Bachelor of Science in Engineering Four Years Bachelor of Science (Honors) Four Years Bachelor of Pharmacy Four Years Bachelor of Business Administration Four Years Bachelor of Arts (Honors) Four Years Bachelor of Laws

Postgraduate programmes Masters of Science in Engineering/ Masters of Engineering (M.Sc Engg./ M. Engg.), Masters of Science (M.Sc) or Masters of Arts (M.A.) programmes in the following departments

Department of Applied Physics, Electronics and Communication Engineering

Department of Mathematics Department of Management Studies Department of English Department of Electrical & Electronics Engineering (EEE) is going to

offer M. Sc in Engg. / M. Engg.) programme soon.

Language of instruction Official language of instruction and academic evaluation is English; however, faculty members may use native language in their classes.

Academic facilities The university has various facilities to provide the students with prodigious educational environment.

Library facilities The central library of BSMRSTU, Ekushey February Library is a reservoir of a large collection of books, journals, magazines to support students with wide range of information and reference. The students are allowed to use this library in office hours from 9 am to 5 pm in the weekdays. They are also entitled to

borrow books for a petite period of time. Each year the library collects large amount of journals, reference books and magazines. A new automated library system is now under construction.

Campus Life The university holds 55 acres of geographical campus which is aesthetically organized with gardens of exotic species of trees, plants and shrubs. Among them mostly are of flower and fruit species. Hence, anyone can easily experience the host of butterflies and birds in their natural habitat provided by the university ground. In addition, a vast area of lush green paddy field lays around three sides of the campus. The beautiful Madhumati river also passes beside the campus. The campus is also decorated with colorful electric lamps which contribute to create an eye soothing view at night.

Accommodation The university has three residential halls for students, two for male students and one for females. Each hall can provide at least 250 students with comfortable and healthy accommodation. The halls have common rooms which put up with televisions, various indoor games facilities for students. The halls arrange to serve three meals daily. Now, there are two dormitories for teachers. Two more halls for male students, one for female students and two dormitories for teachers are under construction at this moment.

Sports and Entertainment Each year the university arranges different sport competitions among the departments such as-football, volleyball, cricket, badminton and the like. Different types of cultural and religious functions are regularly arranged in the university campus with fervor and festivity.

Transportation The university operates its own shuttle bus service between Gopalganj town, neighboring upazillas and the campus every weekday. In every weekend there are special bus services from campus the nearest divisional city, Khulna. For this the university has its own transport vehicles. These include six buses, one air conditioned bus for teachers, three microbuses for teachers and staff. There is also an ambulance for any kind of medical emergency. Soon some more vehicles are going to be added to the transport system of the university. EEE Association, BSMRSTU The EEE Association of BSMRSTU is a student organization formed and operated by the Department of EEE. All the teachers and students of this department are members. This association has its own constitution. All the activities are operated according to this constitution. A committee is formed each year to take important decisions and run the association. The committee members are selected among teachers and students for various posts according to the constitution. Some of the main activities of EEE association go as follows- Arranging seminars, workshops and project presentation Arranging cultural functions on various occasions Arranging meeting to take important decisions for the department

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Medical Center There is a medical center in the campus which provides student with basic medical facilities and health care. There are necessary medical equipments, doctors and nurses. It supports the students with emergency treatment, medical consulting, and in some cases medicine for free of cost.

Food and Stationary There is a coffee shop and stationary shop in the campus. Here students can buy fast foods, snacks and stationary items.

Other Facilities: There are also some other facilities in the campus like a Bank, a water treatment plant, a mosque while a temple is under construction.

Admission Process

Under Graduate Admission Every year admission circular is published intake fresh undergraduate students. Students, who have all requirements required for applying, are eligible to apply for admission tests. Whole process is accomplished online.

Post Graduate Admission All the decision about post graduate admission is made by the academic committee of respective departments.

Department of Electrical and Electronic Engineering at a Glance Department of EEE is one of the reputed departments of Bangabandhu Sheikh Mujibur Rahman Science and Technology University (BSMRSTU).The department provides unique opportunities for students to get quality education in the field of Electrical and Electronic Engineering. It began the academic journey from 2012. Since then it has been widely recognized for its excellent research and teaching capabilities throughout the country and the world. The graduates of this department are trusted to be recruited in both academia and industries of well reputation, and also it is hoped that they will succeed in the future. The department is going to provide an outstanding research environment complemented by teaching eminence for its students to flourish as good human beings with expertise in their fields. The student bodies of this department often make industrial tours; arrange seminars and practical demos, lecture series to develop their skills.

Mission and Vision of Department of EEE The mission of this department is to advance knowledge and to educate students in science, technology, and other areas that will best serve the nation and the world in the 21

stcentury to say the least. The department is committed to

generating, disseminating, and preserving knowledge, and to working with others to bring this knowledge to the frontier of great challenges of the world. Department of EEE is dedicated to providing its students with an education that combines rigorous academic study and the excitement of discovery with the support and intellectual stimulation of a diverse campus community. It seeks to develop in each student of the department the ability and passion to work wisely, creatively, and effectively for the betterment of humanity.

EEE under Graduate Program The bachelor of science of EEE curriculum covers fundamental aspects of Electrical and Electronic technology emphasizes basic principles and using these principles teaches the students to reach optimal design solutions for engineering problem. The four year program is devoted to Engineering mathematics, Electrical Circuits, Electrical Machines and Circuits, Analog -Digital and Power Electronics, Electromagnetic study, Electrical Measurement and Instrumentation, Control System Engineering, Switch gear and Protection Engineering, Communication Engineering and other recent topics of Electrical and electronic engineering. The curriculum includes theoretical courses, laboratory works, and first hand learning from industrial training and field trips.

Post Graduate Program The post graduate program is currently under process of this department.

Research Facilities The department of Electrical and Electronics Engineering are endowed with many advanced instruments and equipments with laboratories for pursuing in depth research in various electrical and electronic engineering problems. At present Electrical and Electronic Engineering Department has following laboratory installations-

1. Circuit Lab 2. Electronics Lab 3. Electrical and Electronic Circuit Simulation Lab 4. Electrical Machine Lab 5. Digital Electronics Lab 6. Power Electronics Lab 7. Microcontroller, Interfacing and System Design Lab 8. Power System and Switchgear Lab 9. Nonconventional Energy Lab 10. High Voltage Engineering Lab(Under construction) 11. Communication Theory Lab 12. Control System Lab (Under construction) 13. PLC based Industrial Automation Lab (Under construction)

Faculty Members

1. Japatosh Mondal Assistant Professor & Chairman Department of Electrical and Electronic Engineering B.Sc. Engineering in Electrical and Electronic Engineering (EEE) from Rajshahi University of Engineering and Technology (RUET) M.Sc. Engineering in Electrical and Electronic Engineering (EEE) from Khulna University of Engineering and Technology (KUET) Research Interest: Optical Fiber Communication, Optoelectronics, Energy conservation, Switch gear and Protection, Industrial Automation.

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2.Moudud Ahmed Assistant Professor Department of Electrical and Electronic Engineering B.Sc. Engineering in Electrical and Electronic Engineering (EEE) from Chittagong University of Engineering and Technology (CUET) M. Sc. Engineering in Electrical and Electronic Engineering (EEE) from Khulna University of Engineering and Technology (KUET) Research Interest: Power System Stability and Control, Micro-grid, Renewable Energy and Power Electronics.

3.Ashraful Hossain Howlader Lecturer Department of Electrical and Electronic Engineering B.Sc. Engineering in Electrical and Electronic Engineering (EEE) from Rajshahi University of Engineering and Technology (RUET) M. Sc. Engineering in Electrical and Electronic Engineering (EEE), Khulna University of Engineering and Technology (KUET) (On going) Research interests: Nano-electronics, Nano-materials, Semiconductors, Optoelectronics and Photonics.

4. Naim Ferdous Lecturer Department of Electrical and Electronic Engineering B.Sc. Engineering in Electrical and Electronic Engineering (EEE) from Bangladesh University of Engineering and Technology (BUET) M. Sc. Engineering in Electrical and Electronic Engineering (EEE) from Khulna University of Engineering and Technology (KUET) (on going) Research interest: Digital Signal processing, Microwave Engineering, Communication

Bangabandhu Sheikh Mujibur Rahman Science and

TechnologyUniversity, Gopalganj – 8100

Bangladesh

Academic Rules and Regulations [Effective from Session 2016-2017]

Academic Ordinance for Bachelors Degree 1. Definitions

1.1

„University‟ means the Bangabandhu Sheikh MujiburRahman Science and TechnologyUniversity abbreviated as BSMRSTU, Gopalganj-8100.

1.2 „Vice-Chancellor‟ means the Vice-Chancellor of the University. 1.3 „Regent Board‟ means the Regent Board of the University. 1.4 „Academic Council‟ means the Academic Council of the University. 1.5 „Faculty‟ means the Faculty of the University.

1.6 „Committee of Courses and Studies‟ means the Committee of Courses for Undergraduate and Postgraduate Studies of a Degree Awarding Department of the University formed as per the statute of the University.

1.7 „Academic Committee‟ means academic committee of the department formed as per the statute of the University.

2. Faculties, Departments and Degrees Offered Faculties Departments Degrees Offered

Faculty of Engineering

1. Computer Science and Engineering B.Sc. Engg. in CSE

2. Electrical and Electronic Engineering

B.Sc. Engg. in EEE

3. Applied Physics, Electronics and Communication Engineering

B.Sc. Engg. in APECE

4. Applied Chemistry and Chemical Engineering

B.Sc. Engg. in ACCE

Faculty of Science

1 Mathematics B.Sc.(Hons.) in MAT

2. Statistics B.Sc.(Hons.) in STA

3. Physics B.Sc.(Hons.) in PHY

4. Chemistry B.Sc.(Hons.) in CHE

5. Environmental Science and Disaster Management

B.Sc.(Hons.) in EDM

Faculty of Business Studies

1. Management Studies BBA in MGT

2. Accounting and Information Systems

BBA in AIS

3. Marketing BBA in MKT

Faculty of Humanities

1. English B.A.(Hons.) in ENG

2. Bangla B.A.(Hons.) in BAN

Faculty of Life

1. Pharmacy B.Pharm.(Hons.)

2. Biotechnology and Genetic B.Sc. in BGE

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Science Engineering

3. Biochemistry and Molecular Biology

B.Sc.(Hons.) in BMB

Faculty of Social

Science

1. Economics BSS in ECO

2. Sociology BSS in SOC

3. Public Administration BSS in PAD

4. International Relations BSS in IR

Faculty of Law

1. Law LLB (Hons.)

Faculty of Agriculture

1.Agriculture B.Sc.(Hons.) in AGR

3. Admission, Registration and Counseling

3.1 Admission

The Admission Committee as per the rules of the University will conduct the admission process for Bachelors Degree. The student will be admitted in the first semester of an academic year in the individual department of different faculties. 3.2 Cancellation of Admission

Admission will be cancelled if a student fails to attend at least 25% of the lectures of the major theory courses within the first 20 lecture days. 3.3 Readmission

A student will be allowed readmission only once in the 1st year 1

st semester of the

next academic session if he/she attends at least 25% of lectures of the major theory courses of the 1

st year 1

st semester within the first 20 lecture days. For

other years, if a student cannot complete a semester successfully, he/she will be allowed readmission in that semester of the next academic session for two times only by paying requisite semester fees, prescribed by the University.

3.4 Registration

Every selected candidate, unless he/she has already been registered, shall get himself/herself registered with the university and enrolled as a fulltime student. 3.5 Counseling

After admission, a batch of students will be assigned to a student adviser from the teacher of their department to guide them through the semester system. The assigned teacher will advise and counsel the students and maintain a student‟s card containing complete academic records and other information of the students.

4. Academic Calendar

4.1 Number of Semesters

There will be two semesters in an academic year. The beginning and end of each

semester (26 weeks) will be announced in an academic calendarat the beginning

of every semester. Friday and Saturday will be the weekly holidays.

4.2 Duration of a Semester

The duration of each semester will be as follows:

Semester Number of weeks

Classes

Preparatory Leave

Examination

Inter Semester Break

16

2

5

3

Total 26

4.3 Inter-semester Break

The inter-semester break will be utilized for the publication of results and

holding supplementary examination (if required). This break may also be utilized

for internship, industrial attachment training, field work, etc.

5. Syllabus, Courses and Credits

5.1 Syllabus Committee of Courses and Studies of a department will select and approve the major and non-major courses proposed by the Academic Committee of the concerned department to develop the complete syllabus. Every syllabus will have 140-160 credits in 8 semesters. The Committee of Courses and Studies will also approve the panel of question setters and script examiners of the department. 5.2 Courses

Every major and non-major course shall have a course code, course number, course title and credit. 5.2.1 Major and Non-Major Courses: Every department will develop the courses to be offered by that particular department. These courses include major subjects for the respective department as well as non-major subjects for other departments. Courses for non-major subjects will be developed with close cooperation of the departments concerned; keeping into consideration the need of the students. 5.2.2 Course Code: A three-letter symbol will represent the department‟s abbreviated name as follows:

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5.2.3 Course Number: A three-digit number for each course will be used as follows: The first digit (1-4), second digit (1-8) and the third digit (1-9) will represent the academic year, the semester and the courses (theoretical, lab and viva-voce) of a department, respectively.

5.2.4 Course Title: Every course will have a short representative course title. If any course has theory and practical parts, then it will be split into two courses.

5.3 Course Credits

5.3.1 Theoretical: Number of lectures per week per semester will be considered as the number of credit of the course.

5.3.2 Practical Classes: Number of class-hours of a practical class will be twice the number of credits.

5.3.3 Seminar, Project, Fieldwork, Viva-voce, etc.: Creditswill be assigned by the Committee of Courses and Studies of the respective department.

5.4 Course Instruction

The course teacher will supply a copy of the detailed plan of the course instruction

with information about the number of lectures per topic, number and types of

assignments, number and dates of class and lab tests. A course teacher must take at

least 36 lectures for a 3 credit course. Number of lectures for other credit courses

shall be proportional. The course teacher will deliver lectures and supply course

materials. All presentation, seminar and assignment of the student should be in

English. However, a student may answer in final examination either in English or in

Bengali or as directed by the Departmental Academic Committee.

6. Course Registration, Improvement and Promotion

6.1 6.2

Course Registration A student has to register 15-28 credits of courses for every semester. For a student of the 7

th and 8

th semesters, the condition for maximum

credit requirement may be relaxed. If a student has to repeat a course that is not offered any more, he/she may take an equivalent course proposed by the Academic Committee of the Department. A student will register for his/her incomplete courses and courses with„F‟ grades, if offered, from the preceding semesters along with courses from the current semester. Otherwise, s/he will take the courses when the desired course is offered next time. Promotion For promotion from one year to the next, a student must obtain a minimum yearly grade point average (YGPA) of 2.0 and complete 20 credits successfully.

7. Examination System

A student will be evaluated on the basis of his/her class attendance, Assignment & presentation, Midterm/ class test or lab test, and semester final examination for theoretical and/or lab courses. The project work/thesis/internship report will be assessed by the internal and external examiners along with its presentation and an oral examination.

(a)Faculty of Engineering.

CSE Computer Science and Engineering

EEE Electrical and Electronic Engineering

APECE Applied Physics, Electronics and Communication Engineering

ACCE Applied Chemistry and Chemical Engineering

(b) Faculty of Science

MAT Mathematics

STA Statistics

PHY Physics

CHE Chemistry

EDM Environmental Science and Disaster Management

(c) Faculty of Business Studies

MGT Management Studies

AIS Accounting and Information Systems

MKT Marketing

(d) Faculty of Humanities

ENG English

BAN Bangla

(e) Faculty of Life Science

PHR Pharmacy

BGE Biotechnology and Genetic Engineering

BMB Biochemistry and Molecular Biology

(f) Faculty of Social Science

ECO Economics

SOC Sociology

PAD Public Administration

IR International Relations

(g) Faculty of Law

LLB Law

(h) Faculty of Agriculture

AGR Agriculture

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7.1 Distribution of Marks The marks of a given course will be as follows:

(a) Theoretical Course

Class Attendance 10%

Assignment & Presentation 10%

Midterm/ Class test 20%

Semester Final Examination 60%

Total 100%

(b) Laboratory Course/Field Work Lab Attendance 10%

Assignment & Presentation 10%

Midterm/ Lab test 20%

Practical/Design Work/Report 60%

Total 100%

(c) Project Work/Thesis/Internship

Project work/Thesis/Internship Evaluation by Internal Examiner (Supervisor) and External Examiner (outside the University). Average marks of two examiners will be used for grading.

70%

Presentation and Oral Examination 30%

Total 100%

7.2 Class / Lab Attendance

Attendance Marks

90% and above 10

85% to less than 90% 9






less than 60% 0

7.3 Assignment & Presentation and Midterm/Class Test or Lab Test

7.3.1 For each theoreticalcourse there shall be Assignment &

presentation and Midterm/ Class test or Lab test Examinations.

7.3.2 The Midterm/Class test and Lab tests shall be of one hour duration and two hours duration respectively and shall be held during as the departmental scheduled time.

7.3.3 The dates for the midterm/ Class test and Lab tests shall be fixed and announced by the respective examination committee.

7.3.4 All marks of the assignment & presentation, midterm/class test or lab test Examinations and semester final examination of a course shall be submitted to the Chairman of the Examination Committee and the Controller of Examination in a sealed envelope by the concerned course teacher.

7.3.5 Midterm scripts may be examined by the course teacher or external examiner (outside this university) recommended by the examination committee.

7.4 Project Work/Thesis

7.4.1 Project work/research work for a thesis shall be carried out under the supervision of a teacher of the relevant department. A co-supervisor from within or outside the Department/University may be appointed. The Academic Committee will appoint the supervisor and co-supervisor (if any). The tentativeProject/research proposal and the title of the Project /thesis, submitted by the student in consultation with the supervisor, shall be approved by the Academic Committee of the department.

7.4.2 The Project Work/Thesis must be carried out in this University. In special circumstances, it may be carried out at a place or places recommended by the supervisor and approved by the Academic Committee.

7.4.3 A seminar shall have to be presented by the student on the progress of his/her project work/thesis after the completion of course work.

7.4.4 Every student shall submit the required number of written copies of his/herproject work /thesis to the Chairman of the department, through his/her supervisor. Theproject work/thesis should demonstrate an evidence of satisfactory knowledge in the field of research undertaken by the student.

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7.4.5 Every student submitting a thesis in partial fulfillment of the requirement of a degree shall be required to appear at an oral examination, on a date either in May (for the odd semester) or in November (for the even semester), fixed by the Chairman of the Examination Committee in consultation with the supervisor.

7.5 Final Examination The final examination procedure will be as follows:

7.5.1 Examination Procedure: The final examination will be

arranged and conducted by separate examination committee for each semester in every teaching department. The questions for the final examination will be prepared by two examiners: internal and or external. The examination committee may recommend two examiners for any course for the final examination. The examination committee will moderate the questions. The two examiners will examine and mark the answer scripts separately. Two marks will be averaged or added (for the two sections) by the examination committee. If the marks of two examiners differ by 20% or more the concerned answer scripts will be examined by a third examiner, recommended by the examination committee and the two close marks among the three will be averaged by the tabulators, giving advantage to the examinees. Class participation and final examination marks will be added together to get the final grade.

7.5.2 Duration of Theoretical Examination: For theoretical courses of all

semesters, there should be a 3hour final examination for every course.

7.5.3 Duration and Procedure of Laboratory Examination There will be a final practical examination of 3- 6 hours duration

for Lab courses at the end of each semester. The examination will be conducted by two or three examiners nominated by the relevant Examination Committee. One of the examiners will be from outside this university (or department).

7.6 Criteria for Sitting at an Examination 7.6.1 Students having 75% and above percentage of total major

and non-major course classes in a semester will be eligible to sit for the examination.

7.6.2 Students having less than 75% but having 60% or more of the total major and non-major course classes in a semester will be eligible to sit for the examination with a fine of Taka. 1000/-(one thousand).

7.6.3 Students having less than 60% of the total major and non-major course classes will not be eligible to sit for the examination.

7.7

Supplementary Examination The academic committee of a department may arrange a supplementary examination after an even semester for the students who could not complete a course or courses, if the incomplete course /courses are not available in any subsequent semester. The supplementary examination (if any) will never be arranged for any practical and viva-voce courses.

8. Grading System and Merit Position 8.1 Letter Grade (LG) and Grade Point (GP): Letter Grade and

corresponding Grade-Point will be awarded as follows:-

Numerical grade Letter Grade

(LG)

Grade Point

(GP/unit credit)

80% or above A+ 4.0

75% to less than 80% A 3.75

70% to less than 75% A- 3.5

65% to less than 70% B+ 3.25

60% to less than 65% B 3.0

55% to less than 60% B- 2.75

50 %to less than 55% C+ 2.5

45% to less than 50% C 2.25

40% to less than 45% D 2.0

less than 40% F 0.0

8.2 GPA/YGPA/CGPA

8.2.1 GPA: Grade Point Average (GPA) is the weighted average

of the grade points obtained in all the courses completed by a student in a semester. GPA is computed as follows:

n

1i

i

n

1i

ii

C

GC

GPA

where, n is the number of courses offered during the semester, Ci is the number of credits allotted to a particular course and Gi is the grade point earned for that course.

8.2.2 YGPA:Yearly Grade Point Average (YGPA)shall be

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calculated for each academic year as follows:

2

1j

j

2

1j

jj

C

GC

YGPA

where, j is the number of semester, C j is the number of

credits allotted in a semester and G j is the GPA earned for

that semester.

8.2.3

8.3

CGPA: Cumulative Grade Point Average (CGPA) will be calculated by using the following formula

m

1k

k

m

1k

kk

C

GC

CGPA

where, k is the number of years and m is the total number of years being considered, Ck is the total number of credits registered during a year and Gk is the YGPA of that particular year. Merit Position: Merit position of a student for each academic year of each degree-awarding department shall be determined on the basis of his/her YGPA of that particular year. Merit position for the award of the bachelor‟s degree will be based on CGPA of all the academic years.

9. Graduation Criteria

9.1 Total Credits and CGPA: A student has to earn all the credits as prescribed by the Committee of Courses and Studies for the session he/she is registered and he/she must also earn a CGPA of 2.00 or higher.

9.2 Total Years: A student must successfully complete the courses of all the semesters within a maximum period of six academic years; otherwise he/she will be dropped out from the University. 9.3 Distinction

Candidates for four year Bachelors Degree will be awarded the degree with Distinction if his/her CGPA is 3.75 or above and s/he does not have any „F‟ grade in any semester

10. Examination Committee

10.1 Formation of the Examination Committee

The Examination Committee shall be nominated by the departmental Academic Committee and will be approved and reported to the Academic Council by the Vice-Chancellor. There will be an examination committee for each semester of an academic year. The examination committee shall consist of 5-7 members: (a) Chairman of the committee, (b) 2-3 other members belonging to the department, (c) 1-3 members from the related teaching departments and (d) one expert member (not below the rank of an Associate Professor) from outside the University. A teacher shall be an expert member in one examination committee only of a department.

10.2 Functions of the Examination Committee

10.2.1 Propose the names of the question setters and script/dissertation/project/ in-plant training report examiners (an external setter and examiner shall not be below the rank of an Assistant Professor) from the previously approved panel of examiners.

10.2.2 Moderate the questions of all courses of the semester final examination.

10.2.3 Prepare the examination schedule to conduct the examinations properly.

10.2.4 10.2.5

Make necessary arrangements for holding the Theoretical, Laboratory and Viva-voce examinations. Take the Viva Voce examination.

10.2.6 Recommend the names of three tabulators for approval of the Vice-Chancellor.

10.2.7 Finalize the results.

10.3 Major Duties of the Chairman of an Examination Committee

10.3.1 Call meetings of the Examination Committee, 10.3.2 Either to send the moderated question papers to the

Controller of Examinations for printing or to take necessary steps for printing the questions in his/her own care.

10.3.3 Issue instructions to the examiners as per approval of the Examination Committee concerned and to see that instructions issued are properly followed.

10.3.4 Hand over the marks received from the examiners to the tabulators.

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11. Duties and Responsibilities of Question Setters and Script

Examiners 11.1 If a question setter or a script examiner is unable to accept the

appointment, he/she should immediately inform the Controller of Examinations. In case an examiner after receiving the scripts becomes unable to examine them, he/she should immediately return the scripts to the Chairman of the Examination Committee.

11.2 The question setters and the script examiners should send their remuneration bills to the Controller of Examination. All postal and other incidental expenses incurred by the setters/examiners in connection with the examination will be paid by the University on presentation of duly signed bill for the same, supported by vouchers.

11.3 If an examiner is unable to accept or intends to relinquish his/her appointment, the Examination Committee concerned shall recommend new question setter and/or script examiner to the Controller of Examinations. 11.4 All manuscripts of question papers shall be sent by the setters in a sealed envelope to the Chairman of the Examination Committee who shall then call a meeting of the Examination Committee for arranging the moderation of the papers.

11.5 The question papers, scripts and any other documents in connection with the examination would be handed over officially/personally or sent by insured post to the Chairman of the relevant Examination Committee.

11.6 The marks of all examinations shall be submitted to the Chairman of the Examination Committee, either personally in a sealed cover or in a doubly sealed insured cover, if sent by post. A copy should also be submitted separately to the Controller of Examinations of the University.

11.7 Marks and scripts must not be sent in the same packet. 11.8 The question setter should as far as practicable, avoid a marked

change of standard questions from the previous year but shall not be required to set the same type of questions every year. The question shall be so framed that there is no ambiguity of meaning and the originality and individuality of the candidates is encouraged.

11.9 The question setter shall be guided by the level of knowledge required and the scope of the courses of examination as mentioned in the syllabus and the textbook, if any, recommended by the University from time to time.

11.10 All corrections and alterations in the manuscripts, question papers, marks placed in the script entered in the mark sheets must invariably be initialed by the person making the correction. Over-writing in the case of marks should be avoided. The wrong figures should be crossed out and the correct figures written in convenient places. Doubtful entries should be indicated by words as well.

11.11 If in the course of examining the answer scripts the examiner has reasons to suspect that unfair means have been adopted by any candidate, he/she should at once submit confidential report to the Chairman of the relevant Examination Committee giving the grounds for his/her suspicion.

11.12 The marks of each course of examination or a section thereof should be entered in the mark sheets in ink and be submitted to the Chairman of the relevant Examination Committee. A copy should also be submitted separately to the Controller of Examinations of the University. 11.13 Immediately on receipt of each packet of answer scripts, the examiner should count the script and verify the information given in the statement regarding the details of the answer scripts sent. If any discrepancy be discovered, it should at once be brought to the notice of the Chairman of the Examination Committee with a report of the statement which should be filled in and returned to the Chairman of the Examination Committee immediately after receiving the answer scripts, so that prompt action may be taken about the matter. 11.14 Special Responsibility of the Question Setters

11.14.1 The manuscripts of the questions are to be written in English/Bengali. The manuscripts of questions should be clear and legible so as to ensure accuracy in printing, 11.14.2 No copy of the manuscript framed by a setter should be retained and all rough draft and memorandum connected therewith should be destroyed immediately after their use. 11.14.3 The setter must put his signature at the bottom of each page of the manuscript.

12. Effect and Review of the Ordinance This ordinance shall be effective from the Academic Session 2015-2016. The ordinance may be reviewed by the Academic Council on recommendation of a Faculty or the Academic Committee of a department. The decision of the Vice-Chancellor, for any matter that does not cover this Ordinance, will be final.

21 22

Department of Electrical & Electronic Engineering

(EEE)

Undergraduate Studies Syllabus for B.Sc. Engineering

Effective from session: 2016 – 2017

Chapter 1 Courses for B.Sc. in Electrical and Electronic Engineering

1.1 Course Identification System: Each course is designated by a three-letter symbol for department abbreviation followed by a three-digit number to characterize the course. An extra letter may be used after the three digits to specify the department taking the non-major course Course Number: The three-digit number will be used as follows- First digit: The first digit of the three digit number corresponds to the Class-year. Second Digit: If the second digit is less than five (0 to 4) that indicates first semester and greater than four (5 to 9) indicates second semester. Third Digit: The third digit is reserved to identify different areas within a department. A department may use the digits 0 and 2 for major theory, 1 and 3 for major practical, 4 and 6 for minor theory, 5 and 7 for minor practical, 8 for thesis/projects/others and 9 for viva-voce. XXX Course Title

The second digit (0 to 4) indicates semester-I/1

st Semester

(5 to 9) indicates semester-II/2nd

semester

1st digit the class, year

Three letter Dept. identification code

1 0

3 2

5 4

7 6

9 8

Major Theory

Major LAB

Non-major Theory

Non-major LAB

Thesis/Project/Others

Viva-voce

23 24

1.2 Credit Requirements The minimum hours to be completed for obtaining the degree of B.Sc. Engineering in Electrical and Electronic Engineering is 202 of which 118 hours are for theoretical courses, 84 hours for laboratory courses and two weeks Industrial Training with a total credit of 160.0. A viva-voce board will be arranged in each semester depending on practical courses only which will be added to lab credit. The semester-wise distribution of credits of different years is listed below:

Year Semester Theory

Hour

Lab

Hour

Total

Hour

Total

Credit

1 1 2 2 3 3 4 4

1 2 1 2 1 2 1 2

14 17 14 15 16 15 15 12

8.50 7.50

9.00

10.5

10.5 13.5 11.0 13.5

22.5 24.5 23.0 25.5 26.5 28.5 26.0 25.5

18.25 20.75 18.50 20.25 21.25 21.00 20.50 18.75

Sub-total 118 84 202 159.25

Two weeks Industrial Training 0.75

Total 160.0

1.3 Distribution of Courses

SlNo. CourseType Credit %

1 Major Course

Core Courses

Theory 67 41.87

Lab 28.5 17.81

2 Elective Courses

Theory 15 9.38

Lab 3.75 2.34

Sub-Total 114.25 71.40

3 Non-Major Courses

a Humanities Theory 8 5.00

Lab 1 0.63

Sub-Total 9 5.63

b Basic Sciences Theory 26 16.25

Lab 1.5 0.94

Sub-Total 27.5 17.19

c Basic Engg. Theory 6 3.75

Lab 3.25 2.03

Sub-Total 9.75 5.78

1.4 Core Courses Some of the core courses are identified as pre-requisite courses. A pre-requisite course is one which is required to be completed before some other course(s) can be taken. Any such course, on which one or more subsequent courses build up, may be offered in each of the two regular semesters.

1.4.1 Core Courses (EEE)

Sl.

No.

Course

Number

Course Title Credit

Hour

1 EEE101 Electrical Circuits 3.0

2 EEE102 Electrical Circuits Lab 1.5

3 EEE151 Electrical Circuits 3.0

4 EEE152 Electrical Circuits Lab 1.5

5 EEE202 Electrical Service Design 0.75

6 EEE211 Electronics 3.0

7 EEE212 Electronics Lab 1.5

8 EEE231 Electrical Machine 3.0

9 EEE232 Electrical Machine Lab 1.5

10 EEE250 Electrical and Electronic Circuit Simulation Lab 1.5

11 EEE251 Measurement and Instrumentation 3.0

12 EEE252 Measurement and Instrumentation Lab 0.75

13 EEE261 Electronics 3.0

14 EEE262 Electronics Lab 1.5

15 EEE271 Electrical Machine 3.0

16 EEE272 Electrical Machine Lab 1.5

17 EEE281 Electromagnetics 3.0

18 EEE301 Signals and Linear Systems 3.0

19 EEE309 Project 0.75

20 EEE311 Digital Electronics 3.0

21 EEE312 Digital Electronics Lab 1.5

22 EEE321 Power Electronics 3.0

23 EEE322 Power Electronics Lab 1.5

25 26

24 EEE341 Numerical Methods for Engineering 3.0

25 EEE342 Numerical Methods for Engineering Lab 1.5

26 EEE361 Communication Theory 4.0

27 EEE362 Communication Theory Lab 1.5

28 EEE363 Electronic Circuit for Communication System 2.0

29 EEE369 Industrial Training 0.75

30 EEE371 Control System 3.0

31 EEE372 Control System Lab 1.5

32 EEE381 Microprocessor, Interfacing and System design 3.0

33 EEE382 Microprocessor, Interfacing and System design Lab

1.5

34 EEE391 Power System 3.0

35 EEE392 Power System Lab 1.5

36 EEE401 Digital Signal Processing 3.0

37 EEE402 Digital Signal Processing Lab 1.5

38 EEE409 Project and Thesis 1.0

39 EEE411 Power System Protection 3.0

40 EEE412 Power System Protection Lab 1.5

41 EEE413 Electrical Properties of Materials 3.0

42 EEE459 Project and Thesis 3.0

43 EEE491 Microcontroller and PLC based System Design 3.0

44 EEE492 Microcontroller and PLC based System Design Lab

1.5

Total 95.5

1.4.2 Core Courses (Humanities)

Sl.

No.

Course

Number Course Title

Credit

Hour

1 ENG105 Technical English 2.0

2 ENG106 Technical English Lab. 1.0

3 AIS215 Industrial Management and Accountancy 2.0

4 BLB305 Bangabandhu in Engineeting and Professional Ethics

2.0

5 ECO307 Economics 2.0

Total 9.0

1.4.3 Core Courses (Mathematics)

Sl.

No.

Course

Number Course Title

Credit

Hour

1 MAT105 Engineering Mathematics

(Differential Calculus & Integral Calculus)

3.0


(Linear Algebra & Coordinate Geometry)

3.0


(Ordinary & Partial Differential

Equations)

3.0

4 MAT205 Engineering Mathematics V

(Complex Variable & Vector Analysis)

3.0

5 MAT257 Engineering Mathematics V

(Fourier Analysis & Laplace

Transformation)

3.0

Total 15.0

1.4.4 Core Courses (Physics)

Sl.

No.

Course

Number Course Title

Credit

Hour

1 PHY115 Physics

(Waves and Oscillations, Optics and

Thermal Physics)

3.0

2 PHY116 Physics Lab. 0.75

3 PHY165 Physics

(Modern Physics, Nuclear Physics and

Quantum Mechanics)

2.0

Total 5.75

1.4.5 Core Courses (Chemistry)

Sl.

No.

Course

Number Course Title

Credit

Hour

1 CHE185 Chemistry 3.0

2 CHE186 Chemistry Lab. 0.75

Total 3.75

1.4.6 Core Courses (CE)

Sl.

No.

Course

Number Course Title

Credit

Hour

1 CE126 Engineering Drawing 1.0

Total 1.0

1.4.7 Core Courses (ME)

Sl.

No

.

Course

Number Course Title

Credit

Hour

1 ME205 Mechanical Engineering Fundamentals 3.0

2 ME206 Mechanical Engineering Fundamentals Lab. 0.75

Total 3.75

27 28

1.4.8 Core Courses (CSE)

Sl.

No.

Course

Number Course Title

Credit

Hour

1 CSE195 Programming Language 3.0

2 CSE196 Programming Language Lab. 1.5

Total 4.5

1.4.9 Core Course (Statistics)

Sl.

No.

Course

Number Course Title

Credit

Hour

1 STA167 Statistics for Engineers 3.0

Total 3.0

1.5 Elective Courses

From Year-4, Semester-1, Department of EEE starts offering elective courses under 2 major groups viz. Power, Electronics and Communication. Rules for distributing major groups are as follows:

1. Students will be assigned one of the two groups as major by taking written options from the students. For regular students, this will be done in Year-3, Semester-2.

2. Maximum number of students in any group as major will be N/2, where N is

the number of students in a batch. 3. Major group assignment will be based on options and CGPA of first five

terms from Year-1, Semester-1 to Year-3, Semester-1. 4. A student will have to take 5 elective theory courses from the respective

major group. 5. Students will be assigned their Year-4 projects/ thesis from the area of their

respective major group. 6. Maximum class size of an elective course for regular students will be (N/2).

However, a student who has previously failed in an elective course will be allowed to re-regular regardless of the class size.

7. In case of any unforeseen situation or ambiguity, the department will take an

appropriate decision.

1.5.1 Power Group

Sl.

No

Course

Number Course Name

Credit

Hour

1 EEE421 Power System II 3.0

2 EEE422 Power System II Lab 1.5

3 EEE423 High voltage engineering 3.0

4 EEE451 Electrical Machine III 3.0

5 EEE452 Electrical Machine III Lab 1.5

6 EEE471 Non-conventional Energy 3.0

7 EEE472 Non-conventional Energy Lab. 0.75

8 EEE473 Power Plant Engineering and Economy 3.0

1.5.2 Electronics and Communication Group

Sl.

N

o.

Course

Number Course Name

Credit

Hour

1 EEE431 Digital Communication 3.0

2 EEE432 Digital Communication Lab 1.0

3 EEE441 Microwave Engineering 3.0

4 EEE442 Microwave Engineering Lab 1.0

5 EEE443 Optoelectronics 3.0

6 EEE453 Optical Fiber Communication 3.0

7 EEE461 VLSI 3.0

8 EEE462 VLSI Lab 1.5

9 EEE463 Computer Networks & Data Communication 3.0

10 EEE481 Mobile Cellular Communication 3.0

11 EEE482 Mobile Cellular Communication Lab 0.75

12 EEE483 Telecommunication Engineering 3.0

13 EEE493 Biomedical Engineering 3.0

29 30

Chapter 2 Course Offering

Courses are offered to the students as per following arrangement:

Year-1 Semester-1

Course No. Course Title Contact hrs/week

Credit

EEE101 Electrical Circuits 3 3.0

EEE102 Electrical Circuits I Lab. 3 1.5

MAT105 Engineering Mathematics

(Differential Calculus & Integral

Calculus)

3 3.0


(Linear Algebra & Coordinate

Geometry)

3 3.0

ENG105 Technical English 2 2.0

ENG106 Technical English Lab. 2 1.0

PHY115 Physics

(Waves and Oscillations, Optics and

Thermal Physics)

3 3.0

PHY116 Physics Lab. 3/2 0.75

CE126 Engineering Drawing 2 1.0

Viva Voce(EEE102, PHY116, CE126 and ENG106)

Total 18.25

Year-1 Semester-2

Course No.

Course Title Contact hrs/week

Credit

EEE151 Electrical Circuits 3 3.0

EEE152 Electrical Circuits Lab. 3 1.5


(Ordinary & Partial Differential

Equations)

3 3.0

PHY165 Physics

(Modern Physics, Nuclear Physics and

Quantum Mechanics)

2 2.0

STA167 Statistics for Engineers 3 3.0

CHE185 Chemistry 3 3.0

CHE186 Chemistry Lab. 3/2 0.75

CSE195 Programming Language 3 3.0

CSE196 Programming Language Lab. 3 1.5

Viva Voce (EEE152, CSE196 and CHE186)

Total 20.75

Year-2 Semester-1

Course No.


Credit

EEE202 Electrical Service Design 3/2 0.75

EEE211 Electronics 3 3.0

EEE212 Electronics Lab. 3 1.5

EEE231 Electrical Machine 3 3.0

EEE232 Electrical Machine Lab. 3 1.5

ME205 Mechanical Engineering Fundamentals 3 3.0

ME206 Mechanical Engineering Fundamentals Lab. 3/2 0.75

MAT205 Engineering Mathematics V

(Complex Variable, & Vector Analysis)

3 3.0

AIS215 Industrial Management and Accountancy 2 2.0

Viva Voce (EEE212, EEE232, ME206 and EEE202)

Total 18.50

Year-2 Semester-2

Course No.


Credit

EEE250 Electrical and Electronic Circuit Simulation Lab

3 1.5

EEE251 Measurement and Instrumentation 3 3.0

EEE252 Measurement and Instrumentation Lab 3/2 0.75

EEE261 Electronics 3 3.0

EEE262 Electronics Lab. 3 1.5

EEE271 Electrical Machine 3 3.0

EEE272 Electrical Machine Lab. 3 1.5

EEE281 Electromagnetics 3 3.0


(Fourier Analysis & Laplace

Transformation)

3 3.0

Viva Voce (EEE262, EEE272, EEE252, EEE250)

Total 20.25

31 32

Year-3 Semester-1

Course No.


Credit

EEE301 Signals and Linear Systems 3 3.0

EEE309 Project 3/2 0.75

EEE311 Digital Electronics 3 3.0

EEE312 Digital Electronics Lab. 3 1.5

EEE321 Power Electronics 3 3.0

EEE322 Power Electronics Lab. 3 1.5

EEE341 Numerical Methods for Engineering 3 3.0

EEE342 Numerical Methods for Engineering Lab. 3 1.5

BLB305 Bangabandhu in Engineeting and Professional Ethics

2 2.0

ECO307 Economics 2 2.0

Viva Voce(EEE309, EEE312, EEE322 and EEE342)

Total 21.25

Year-3 Semester-2

Course No.


Credit

EEE361 Communication Theory 4 4.0

EEE362 Communication Theory Lab. 3 1.5

EEE363 Electronic circuit for communication system 2 2.0

EEE369 Industrial Training* 0.75

EEE371 Control System 3 3.0

EEE372 Control System Lab 3 1.5

EEE381 Microprocessor, Interfacing and System design 3 3.0

EEE382 Microprocessor, Interfacing and System design Lab

3 1.5

EEE391 Power System 3 3.0

EEE392 Power System Lab. 3 1.5

Viva Voce (EEE362, EEE372, EEE382 and EEE392)

Total 21.75

*EEE369 Industrial Training: Students will be attached with the industries/service agencies for two weeks after completing their Third year second semester (before starting Fourth year) to gain practical knowledge. Without satisfactory completion of this course the student will not fulfill the requirements of B. Sc. Engineering Degree.

Year-4 Semester-1

Course

No.

Course Title Contact

hrs/week

Credit

EEE409 Project and Thesis 1.0

EEE401 Digital Signal Processing 3 3.0

EEE402 Digital Signal Processing Lab 3 1.5

EEE411 Power System protection 3 3.0

EEE412 Power System protection Lab 3 1.5

EEE **** Elective I 3 3.0

EEE **** Elective I Lab 3 1.5

EEE **** Elective II 3 3.0

EEE 413 Electrical Properties of Materials 3 3.0

Viva Voce (EEE402, EEE412 and Elective I Lab)

Total 20.5

Year-4 Semester-2

Course

No.

Course Title Contact

hrs/week

Credit

EEE459 Project and Thesis 3.0

EEE491 Microcontroller and PLC based System

Design

3 3.0

EEE492 Microcontroller and PLC based System

Design Lab

3 1.5

EEE **** Elective III 3 3.0

EEE **** Elective III Lab 3 1.5

EEE **** Elective IV 3 3.0

EEE **** Elective IV Lab 3/2 0.75

EEE **** Elective V 3 3.0

Viva Voce (EEE492, Elective III Lab and Elective IV

Lab)

Total 18.75

2.2 Elective Course divisions

Five elective courses (Elective I – Elective V) are offered to the students

according to the following list.

33 34

Elective I

Group

Course

Numbe

r

Course Title

Credit Hour

Indiv

. Total

Power EEE421 Power System II 3.0 4.5

EEE422 Power System II Lab 1.5

Electronics &

Communication

EEE431 Digital Communication 3.0 4.5

EEE432 Digital Communication Lab 1.5

EEE441 Microwave Engineering 3.0 4.5

EEE442 Microwave Engineering Lab 1.5

Elective II

Group Course

Number Course Title

Credit

Hour

Power EEE423 High voltage engineering 3.0

Electronics &

Communication

EEE443 Optoelectronics 3.0

Elective III

Group Course

Number

Course Title Credit Hour

Indiv. Total

Power EEE451 Electrical Machine III 3.0 4.5

EEE452 Electrical Machine III Lab 1.5

Electronics &

Communication

EEE461 VLSI 3.0 4.5

EEE462 VLSI Lab 1.5

Elective IV

Group Course

Number

Course Title Credit Hour

Indiv. Total

Power EEE471 Non-Conventional Energy 3.0 3.75

EEE472 Non-Conventional Energy

Lab

0.75

Electronics &

Communication

EEE481 Mobile Cellular

Communication

3.0

3.75

EEE482 Mobile Cellular

Communication Lab

0.75

Elective V

Group Course

Number Course Title

Credit

Hour

Power EEE473 Power Plant Engineering and Economy

3.0

EEE453 Optical Fiber Communication 3.0

EEE463 Computer Networks & Data Communication

3.0

EEE483 Telecommunication Engineering 3.0

EEE493 Biomedical Engineering 3.0

3.1 Core Courses Offered by the Department of EEE

Year-1 Semester-1

EEE101 Electrical Circuits I

3 Credits, 3 hours/week

Circuit Variables and Elements: Voltage, current, power, energy, independent and dependent sources, resistance.

Basic Laws of Electrical Circuits: Ohm‟s law, Kirchoff‟s Current Law (KCL) and Kirchoff‟s Voltage Law (KVL).

Simple Resistive Circuits: Series and parallel circuits, voltage and current division, Source transformation, wye-delta transformation.

Techniques of Network Analysis: Nodal and Mesh analysis including super node and super mesh.

Network Theorems: Thevenin‟s, Norton‟s and superposition theorems with applications in circuits having independent and dependent sources, maximum power transfer condition and reciprocity theorem.

Energy Storage Elements: Inductors and capacitors, their characteristics, series-parallel combination of inductors and capacitors.

Alternating Current Basics: Instantaneous,average and R.M.S values, form factor, peak factor , effective current and voltage, average power, phasors and complex quantities, impedance, real, reactive and apparent power, power factor,power factor improvement

Responses of RL and RC Circuits: Natural and step responses.

Chapter 3 Course Contents

35 36

Magnetic Quantities and Variables: Flux, permeability and reluctance, magnetic field strength, magnetic potential, flux density, magnetization curve, Laws in magnetic circuits: Ohm‟s law and Ampere‟s circuital law. Series, parallel and series-parallel magnetic circuits.

Book Recommended: 1. Introductory Circuit Analysis – Robert L.Boylestad 2. Electric Circuits – Nelson and Reidel 3. Fundamentals of Electric Circuits- C. K. Alexander, M. N O.Sadiku 4. Linear Electric Circuits-W.L.Cassell 5. Introduction to Electric Circuits-Richard C. Dorf, James A. Svoboda

EEE102 Electrical Circuits I Lab.

1.5 Credits, 3 hours/week Laboratory experiments based on theory and concepts learnt in EEE101.

MAT105 Engineering Mathematics I

(Differential Calculus & Integral Calculus)


Differential Calculus: Limits, continuity and differentiability.Successive differentiation of various types of functions. Leibnitz‟s theorem, Rolle‟s theorem, Mean value theorem, Taylor‟s and McLaurin‟s theorems in finite and infinite forms. Lagrange‟s form of remainders.Cauchy‟s form of remainders.Expansion of functions, evaluations of indeterminate forms of L‟Hospital‟srule.Partialdifferentiation.Euler‟stheorem.Tangent and normal.Sub tangent and subnormal in Cartesian and polar co-ordinates. Determination of maximum and minimum values of functions. Curvature, Asymptotes, curve tracing.

Integral Calculus: Definition, Integration by the method of substitution, integration by parts.Standard Integrals.Integration by successive reduction.Definite Integrals, its properties and use in summing series.Walli‟sformulae.Improper integrals. Beta function and Gamma function, Area under a plane curve and area of a region enclosed by two curves in Cartesian and polar co-ordinates, Trapezoidal and Simpson‟s rule, Volumes and surface areas of solids of revolution.

MAT107 Engineering Mathematics II

(Linear Algebra & Coordinate Geometry)


Linear Algebra: Introduction to systems of linear equations.Gaussian elimination.Definition of matrices.Algebra of matrices. Transpose of a matrix and inverse of matrix.

Factorization, Determinants. Quadratic forms. Matrix polynomials.Euclidean n-space.Linear transformation from IR

n to IR

m.Properties of Linear transformation

from IRn to IR

m.Real vector spaces and subspaces.Basis and dimension.Rank and

nullity.Inner product spaces.Gram-Schmidt process and QR-decomposition. Eigenvalues and eigenvectors.Diagonalization.Lineartransformations.Kernel and Range.Application of linear algebra to electric networks.

Coordinate Geometry: Coordinate Geometry of 2-dimension-change of axis, Transformation of coordinates, Simplification of equations of curves. Coordinate geometry of 3 dimension system of coordinates, distance between two points, section formula, projection, direction cosines, equations of planes and lines.

ENG105 Technical English


Grammar (12%): Grammatical principles, modals, phrases & idioms, affixes, sentence structures, why & yes/no questions, conditional sentences.

Vocabulary (8%): GRE,Technical& scientific vocabulary, defining terms.

Writing –5+7+4+4=20%

(a)Technical Writing-12% (i) Paragraph writing. Interpreting from table /data/ wagon wheel / graph /figure (At least 150 words)-5% (ii) Opinion based essaywritings (At least 250 words)-7% (b) Others-4%+4 %=8%

(i)Business letters, job application, memos, quotation, tender notice

Reading (2 passages)-10%+10%=20% Reading approaches, Comprehension of technical & non-technical materials-skimming, scanning, inferring & responding to context Passages must be paragraph types with letter marks (A, B, C, D………..) Options:- Write correct letter in boxes from letter marks (A, B, C, D………..) passages which match with each sentence, Or, Matching with events from letter marks (A, B, C, D………..) passages Or, List of headings Or, Statements agree with information (True/False/Not Given) Or, Fill up with appropriate word from the passages without list Or, Fill up with appropriate word from the passages with list (synonyms word) Or, multiple choice

ENG106 Technical English Lab.

1.0 Credits, 2 hours/week

Lab-60%; Quizzes-30%; 10% attendances

http://www.google.com.bd/search?tbo=p&tbm=bks&q=inauthor:%22Richard+C.+Dorf%22

http://www.google.com.bd/search?tbo=p&tbm=bks&q=inauthor:%22James+A.+Svoboda%22

37 38

Spoken English: 30%

Introduction to phonetic symbols, dialogue, responding to particular situations, extempore speech, and cue card on situational condition/himself/herself.

Listening: 30% Fill the gaps, multiple choice, etc. from CD recorder

PHY115 Physics I

(Waves and Oscillations, Optics and Thermal Physics)

3 Credits; 3hours/week

Waves and Oscillations: Simple harmonic motion, Differential equation of simple harmonic oscillator, total energy and average energy, combination of simple harmonic oscillations, spring mass system, torsional pendulum; two body oscillation, reduced mass, damped oscillation, forced oscillation, resonance, vibrations of membranes and columns, progressive wave, power and intensity of wave, stationary wave, energy calculation of progressive and stationary wave, group and phase velocities, sound waves-Doppler Effect, Sabine‟s formula, architectord acoustics.

Optics: Defects of images: Spherical aberration, astigmatism, coma, distortion, curvature, chromatic aberration, theories of light, Haygen‟s principle; Interference of light: Young‟s double slit experiment, displacement of fringes and its uses, Fresnel bi-prism, interference in thin film, Newton‟s rings, interferometers; Diffraction: Diffraction by single slit, diffraction from a circular aperture, resolving power of optical instruments, diffraction at double slit and N-slits, diffraction grating; Polarization: production and analysis of polarized light, Brewster‟s law, Malus law, polarization by double refraction, Nicol prism, optical activity, polarimeters, optics of crystal optical effect in crystal, laser, nonlinear optics.

Thermal Physics: Heat and work, Zeroth law of thermodynamics, thermometer, thermocouple, the first law of thermodynamics and its applications; Kinetic theory of gases- kinetic interpretation of temperature, specific heats of ideal gases, equipartition of energy, mean free path, work done by gas, isothermal and adiabatic relations, vandarwaal‟s equation of state, Maxwell‟s distribution of molecular speeds, reversible and irreversible processes, Carnot‟s cycle, second law thermodynamics, Carnot‟s theorem, entropy, thermodynamic functions, Maxwell relations, Clausius and Clapeyron equation.

PHY116 Physics I Lab.

0.75 Credits; 3/2 hours/week Laboratory experiments based on theory and concepts learnt in PHY115.

CE126 Engineering Drawing


Introduction: lettering, numbering and heading; Instrument and their use; sectional views and isometric views of solid geometrical figures. Plan, elevation and section of multistoried building; building services drawings; detailed drawing of lattice towers.

Viva Voce Central viva based on EEE102, PHY116, CE126 and ENG106

Year-1 Semester-2

EEE151 Electrical Circuits II

Prerequisite EEE 101


Analysis of Single Phase AC Circuits: Series and parallel RL, RC and RLC circuits, Resonance in AC circuits, application of network theorems in AC circuits. Circuits with non-sinusoidal excitations, transients in AC circuits,

Analysis of Poly Phase Circuits: Poly phase supply, 3-phase conditions, balanced and unbalanced circuits, power calculation. Magnetically couple circuits: Self and mutual inductances, coupling co-efficient, reflected impedance, transfer impedance.

Two Port Networks (TPN): Two port networks (symmetrical & asymmetrical),determination of two port parameters, relationship between two port parameters, iterative impedance, image impedance, characteristic impedance, image propagation function, reflection of voltage, current and power; insertion loss.

Filter: Passivefilters, impedance matching of filters, Butterworth and Chebychev filters.

Book Recommended:

1. Alternating-Current Circuits - R.M. Kerchne, G.F. Corcoran 2. Introductory Circuit Analysis – Robert L.Boylestad 3. Fundamentals of Electric Circuits- C. K. Alexander M. N. O.Sadiku, 4. Linear Electric Circuits-W.L.Cassell

EEE152 Electrical Circuits II Lab.


Laboratory experiments based on theory and concepts learnt in EEE151.

39 40

MAT157 Engineering Mathematics III

(Ordinary & Partial Differential Equations)


Ordinary Differential Equations: Degree and order of ordinary differential equations, formation of differential equations by various methods, solution of first order differential equations. Solution of general linear equations of second and higher orders with constant coefficients, applications. Solution of homogeneous linear equations of the higher order when the dependent or independent variables are absent. Solution of differential equations by the method based on the factorization of the operators. Frobeniousmethod. Legendre and Bessel‟s function.

Partial Differential Equations: Introduction.Linear and non-linear first order equations. Standard forms. Linear equations of higher order.Equations of the second order with variable coefficients.Wave equations.Particular solution with boundary and initial conditions.

STA167 Statistics for Engineers


Statistics: Meaning & Scope, Variables and Attributes, Collection and presentation of Statistical data, Frequency Distribution and Graphical Representation.

Analysis of Statistical Data: Location, Dispersion and their measures.Skewness, Kurtosis and their measures. Moment and cumulates, Regression and correlation

Elements of Probabilities: Concept of probability, Sample Space, Events.Union and Intersection of Events.Probability of Events.Laws of probability.Conditional Probabilities. Bays probability. Chebysec's Inequality.

Random Variables and Probability Distribution: Basic concepts.Discrete and continuous Random variables.Density and distribution functions.Mathematical Expectation and variance. Conditional Expectation and conditional variance.Expected values and variances of the density distributions. Moments and Cumulant generating functions.Characteristicfunction.Study of Binomial, Poisson, Normal. Geometric, Multinomial, uniform, exponential, Gamma, distributions.

Sampling Distributing:

Study of 2Distribution, T-Distribution and F-Distribution, Properties, uses &

Applications.

Elements of Point Estimations: Basic Concepts. Consistent estimates. Unbiased estimates. Mean and variance of estimates.Principle of Maximum Likelihood. Illustration from Binomial, poission& Normal Distributions

Decision Rules: Statistical decisions; Statistical hypothesis; Critical region, Best critical region; Two types of errors; procedure of Test of hypothesis; Most powerful test, standard Errors. Test of Significance: Est. of single mean & single variance. Comparison of two sample Means, proportions and Variances. Exact test for 2*2 tables. Test for r*c tables. Three-Way contingency tables.

PHY165 Physics II

(Modern Physics, Nuclear Physics and Quantum Mechanics)

2 Credits, 2 hours /week

Atomic Structure: Rutherford scattering, atomic structure (Bohr model, Thomson model, Rutherford model), Zeeman effect.

Structure of Matter: Classification of solids, crystal structure of solids, Bragg‟s law, distinction between metal, insulator and semiconductor.

Modern Physics: Galilean relatively and Einstein‟s special theory of relativity; Lorentz transformation equations, Length contraction, time dilation and mass-energy relation, photoelectric effect, Compton effect, De‟Broglie matter waves.

Nuclear Physics: Constituent of atomic nucleus, Nuclear binding energy, different types of radioactivity, radioactive decay law; Nuclear reactions, nuclear fission, nuclear fusion.

Mechanics: Linear momentum of a particle, linear momentum of a system of particles, conservation of linear momentum, some applications of the momentum principle; Angular momentum of a particle, angular momentum of a system of particles, Kepler‟s law of planetary motion, the law of Universal Gravitation, the motion of planets and satellites.

Introductory Quantum Mechanics: Wave function, uncertainty principle, postulates, Schrödinger time independent equation, expectation value, probability, particle in a Zero potential, calculation of energy.

CHE185 Chemistry

3 Credits, 3 hours/week Atomic Structure, quantum numbers, Pauli‟s exclusion principle, electronic configuration, periodic table, properties and uses of noble gases, different types of chemical bonds and their properties, molecular structures of compounds, selective organic reactions. Different types of solutions and their compositions.

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Phase rule, phase diagram of monocomponent system. Properties of dilute solutions.Thermochemistry, chemical kinetics, chemical equilibrium.Ionization of water and pH concept.Electrical properties of solution.

CHE186 Chemistry Lab.

0.75 Credits, 3/2 hours/week Volumetric analysis: acid-base titration, oxidation-reduction titrations, determination of Fe, Cu and Ca volumetrically.

CSE195 Programming Language

3 credits, 3 hours/week Introduction to digital computers. Programming languages, algorithms and flow charts.

Structured programming using C: Variables and constants, operators, expressions, control statements, functions, array, pointer, structure union, user defined data types, input-output files.

Object oriented programming using C++: Introduction, classes and objects; polymorphism; function and operator overloading; inheritance.

CSE196 Programming Language Lab.

1.5 credits, 3 hours/week Laboratory experiments based on theory and concepts learnt in CSE195.

Viva Voce Central viva based on EEE152, CSE196 and CHE186.

Year-2 Semester-1

EEE202 Electrical Service Design

0.75 Credits, 3/2 hours/week Familiarization with electric switches: electrical fittings and fixtures. Wire wrapping; Soldering; Electrical symbols; Connection of tube light, staircase lighting, flickering lighting, moving lighting, simple traffic signals, calling bells, etc. Design of PCB layout: etching, trouble shooting, soldering &de-soldering. Wiring system design, drafting, estimation: Design for illumination and lighting. Electrical installation system design: substation, BBT and protection, air conditioning, heating and lifts. Design for intercom, public address systems, telephone system and LAN. Design of security system including CCTV, fire

alarm, smoke detector, burglar alarm and sprinkler system.A design problem on a multi-stored building.

EEE211 Electronics I

Prerequisite EEE101


P-N Junction as a Circuit Element: Intrinsic and extrinsic semiconductors, operational principle of p-n junction diode, contact potential, biasing of diode, current-voltage characteristics of a diode, simplified DC and AC diode models, dynamic resistance and capacitance.

Diode Circuits: Half wave and full wave rectifiers, rectifiers with filter capacitor, characteristics of a Zener diode, Zener shunt regulator, clamping and clipping circuits.

Bipolar Junction Transistor (BJT): Current components, BJT characteristics and regions of operation, BJT as an amplifier, biasing the BJT for discrete circuits, small signal equivalent circuit models, BJT as a switch.

BJT Amplifier Circuits: Voltage and current gain, input output impedance of common base, common emitter and common collector amplifier circuits, multistage amplifiers.

Metal Oxide Semiconductor Field Effect Transistor (MOSFET): Structure and physical operation of an enhancement MOSFET, threshold voltage, body effect, current-voltage characteristics of an enhancement MOSFET, biasing discrete and integrated amplifier circuits, single–stage MOS amplifiers, MOSFET as a switch, introduction to VMOS and CMOS inverter. Differential and multistage amplifiers, small-signal operation, differential and common mode gains

Junction Field-Effect-Transistor (JFET): Structure and physical operation of JFET, transistor characteristics, pinch-off voltage.

Book Recommended:

1. Microelectronic circuits- A.S. Sedra ,K.C. Smith

2. Electronic Principles - Albert Malvino 3. Electronic Devices and Circuit Theory - Robert L. Boylestad, Louis

Nashelsky 4. Principles of Electronics-V.K Mehta, Rohit Mehta 5. Basic Electronics: Solid State-B.L. Theraja

EEE212 Electronics I Lab.


http://www.goodreads.com/author/show/1172098.B_L_Theraja

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EEE231 Electrical Machine I

Prerequisite EEE101

3 credits, 3 hours/week

DC Generator: Types, no-load voltage characteristics, buildup of a self-excited shunt generator, critical field resistance, load-voltage characteristic, effect of speed on no-load and load characteristics and voltage regulation.Armature reaction, losses and efficiency, Parallel operation of DC generators.

DC Motor: Torque, counter emf, speed, torque-speed characteristics, starting and speed regulation. Speed control by converter and chopper, Crane, traction and hoist application of DC motor, Choice of DC motors for different applications.

Transformer: Ideal transformer- transformation ratio, no-load and load vector diagrams; actual transformer- equivalent circuit, regulation, short circuit and open circuit tests. Three phase transformer and its V-connection, Scott connections, three phase operation of single-phase transformer; Vector group of three phase transformers. Determination of transformer constants and polarity, Harmonics in polyphase transformers, Induction voltage regulators; Autotransformers: three phase and single phase, Power transformers: bushing, Cooling, Tap Changing and parallel operation

Book Recommended: 1. Electric Machines - C.I. Hubert 2. Direct and Alternating Current Machinery - Rosenblatt, Friedman 3. Electrical Machines – S K Bhattacharya 4. A text book of Electrical Technology(Vol. II)-B.L. Theraja,

A.kThereja

EEE232 Electrical Machine I Lab.


ME205 Mechanical Engineering Fundamentals


Introduction to Sources of Energy: Steam generating units with accessories and mountings; steam turbines, condensers, vapor cycles.

Internal Combustion Engine: Introduction to internal combustion engines & their cycles, gas turbines.

Refrigeration and Air Conditioning: Applications; refrigerants, different refrigeration methods.

Fluid Machinery: Fluid flow, measurements of flow, friction in flow, centrifugal pumps, fans, blowers & compressors.

Fundamental of Conduction, Convection and Radiation: One dimensional steady state conduction in plated pipes; Critical thickness of insulation.

ME206 Mechanical Engineering Fundamentals Lab.

0.75 Credits, 3/2 hours/week Laboratory experiments based on theory and concepts learnt in ME205.

MAT205 Engineering Mathematics IV

(Complex Variable, & Vector Analysis)


Complex Variable: Complex number system. General functions of a complex variable. Limits and continuity of a function of complex variable and related theorems.Complex differentiation and the Cauchy-Riemann equations. Mapping by elementary functions. Infinite series.Convergence and uniform convergence. Line integral of a complex function. Cauchy‟s integral formula.Liouville‟stheorem.Taylor‟s and Laurent‟s theorem.Singularpoints.Residue, Cauchy‟s residue theorem.Contour integration, conformal mapping.

Vector Analysis: Scalars and vectors, equality of vectors, addition and subtraction of vectors, geometrical interpretation. Multiple product of vectors. Linear dependence and independence of vectors.Differentiation and Integration of vectors together with elementary applications.Line, Surface and volume integrals. Gradient of a scalar functions, divergence and curl of a vector function, various formulae. Integrals form of gradient, divergence and curl. Divergence theorem, Stoke‟s theorem, Green‟s theorem and Gauss‟s theorem

AIS215 Industrial Management and Accountancy


Industry: Types of Industry, Commerce – Hindrance removed by Commerce, Business Environment. Sole Proprietorships: Features, Advantages, Disadvantages of Sole Proprietorship, Sustainability of Sole proprietorships. Partnership: Features, Advantages, Disadvantages, the Partnership Contract. Joint Stock Company: Characteristics, Advantages, Disadvantages, Types, Comparison between Public and Private Ltd Company and Formation of company.

http://www.goodreads.com/author/show/1172098.B_L_Theraja

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Fundamentals of Management: What is management? Management Function, Levels of Management, Management roles, Core Management skills, Principles of Management. Organizing the Business: Formal and Informal Organization, Centralization and Decentralization, Principles of Organizing, Functional Structure, Product Structure, Terrestrial Structure, Matrix Structure, Multiple Structure.

Accountings: History, Scope and Nature of Accounting, Information and Uses

Transaction: Meaning and Features, Double entry System, Characteristics, Account – Meaning, Classification, Rules for Determining Debit and Credit, Accounting.Equation, Accounting cycle.

Journal: Meaning, Features, Necessity, Types, Practical Problems.

Ledger: Definition, Advantages, Classification, Rules, Practical Problems.

Cash book: Features, Advantages, Double and Triple Column Cash Book, Discount.

Trial Balance: Meaning, Characteristics, Objects, Practical problems,

Income Tax: Practices, Income Tax Law.

Preparation of Financial Statements.

Viva Voce Central viva based on EEE202, EEE212, EEE232 and ME206

Year-2 Semester-2

EEE250 Electrical & Electronic Circuit Simulation Lab


Simulation laboratory based on EEE101, EEE151, EEE211 and EEE261 theory courses. Students will verify the theories and concepts learned in on EEE 101, EEE151, EEE211 and EEE261 using simulation software like PSpice and MATLAB. Students will also perform specific design of electrical (DC and AC) and electronic circuits theoretically and by simulation.

EEE251 Measurement and Instrumentation Prerequisite EEE211


Introduction: Applications, functional elements of a measurement system and classification of instruments (Ammeter, Voltmeter, wattmeter, AVO meter, Energy meter, Ampere-hour meter, CRO).

Measurement of Electrical Quantities: Current and voltage, power and energy measurement.Current and voltage, power and energy measurement Current and potential transformer.

Transducers: Mechanical, electrical and optical transducers.

Measurement of Non-Electrical Quantities: Temperature, pressure, flow, level, strain, force and torque, earthquake, speed, frequency, phase difference.

Basic Elements of DC and AC Signal Conditioning: Instrumentation amplifier, noise and source of noise, noise elimination compensation, function generation and linearization, A/D and D/A converters, sample and hold circuits.

Data Transmission and Telemetry: Methods of data transmission, DC/AC telemetry system and digital data transmission.Recording and display devices.Data acquisition system and microprocessor applications in instrumentation.

Books recommended: 1. Measurement & Instrumentation – A. K. Sawhney 2. Measurement & Instrumentation – Harries K. Forrest

EEE252 Measurement and Instrumentation Lab.

0.75 Credits, 3/2 hours/week Laboratory experiments based on theory and concepts learnt in EEE251.

EEE261 Electronics II

Prerequisite EEE211


Frequency Response of Amplifiers: Poles, Zeros and Bode plots, amplifier transfer function, techniques of determining 3 dB frequencies of amplifier circuits, frequency response of single-stage and cascade amplifiers, frequency response of differential amplifiers.

Operational Amplifiers (Op-Amp): Properties of ideal OP-Amps, non-inverting and inverting amplifiers, integrators, differentiator, weighted summer and other applications of Op-Amp circuits, Schmitt trigger, comparator, Differential and Common gain, effects of finite open loop gain and bandwidth on circuit performance, logic operation of Op-Amp, DC imperfections. DC analysis, small-signal analysis of different stages, gain and frequency response of 741 OP-Amp

Feedback Amplifier: Properties, feedback amplifiers with different topologies, stability, frequency compensation.

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Active Filters: Different types of filters and specifications, transfer functions, realization of first and second order low, high and band pass filters using OP-Amps.

Oscillators and Timing Circuits: Sinusoidal oscillators, Phase shift oscillator, resonant circuit oscillator, general form of oscillator circuit, crystal oscillators. Multi-vibrators, IC 555 and its applications.VCO, PLL and blocking oscillator.

Power Amplifiers: Classification of output stages, Class A, B and AB output stage, Class C and Class D. push-pull Class B and C amplifiers and their design Heat sink.

Book Recommended:

1. Operational Amplifiers and Linear IntegratedCircuits- R.F. Coughlin, F.F. Driscoll

2. Integrated Electronics – Analog and Digital Circuits and Systems - Jacob Millman,

Christos C. Halkias

3. Electronic Devices and Circuit Theory - Robert L. Boylestad, Louis Nashelsky

4. Op-Amps and Linear Integrated Circuits-Ramakant A. Gayakwad

EEE262 Electronics II Lab.



EEE271 Electrical Machine II

Prerequisite EEE231 3 credits, 3 hours/week

Three Phase Induction Motor: Rotating magnetic field, equivalent circuit, vector diagram, torque-speed characteristics, effect of changing rotor resistance and reactance on torque-speed curves, motor torque and developed rotor power, no-load test, blocked rotor test, starting and braking and speed control.

Single Phase Induction Motor: Theory of operation, equivalent circuit and starting.

Synchronous Generator: Windings, excitation systems, equivalent circuit, vector diagrams at different loads, factors affecting voltage regulation, synchronous impedance, synchronous impedance methods of predicting voltage regulation and its limitations. Parallel operation: necessary conditions, synchronizing, circulating current and vector diagram.

Synchronous Motor: Operation, effect of loading under different excitation condition, effect of changing excitation, V-curves and starting.

Special types motor: Universal motor, Stepper motor, permanent magnet motor, Hysteresis motor and Reluctancemotor.

Book Recommended:

1. Electric Machinery Fundamentals- S.J. Chapman. 2. Alternating Current Machines- A. F. PuchsteinT. C. Lloyd, A. G. Conard 3. A Textbook of Electrical Technology - AC and DC Machines- B. L.

Theraja, A. K. Theraja

EEE272 Electrical Machine II Lab


EEE281 Electromagnetics

Prerequisite: MAT107, MAT157


Review of Vector Analysis: Coordinate Systems, Vector algebra, gradient, divergence and curl.

Static Electric Field: Postulates of electrostatics, Coulomb‟s law for discrete and continuously distributed charges, force, field intensity, flux density, Gauss‟s law and its applications, electric potential due to charge distribution, conductors and dielectrics in static electric field, boundary conditions; capacitance- electrostatic energy and forces, energy in terms of field equations, capacitance calculations of different geometries; boundary value problems- Poisson‟s and Laplace‟s equations in different co-ordinate systems, method of images, graphical field mapping.

Static Magnetic Field: Postulates of magneto statics, Biot-Savart‟s law, Ampere‟s law and applications, vector magnetic potential, magnetic dipole, magnetization, magnetic field intensity, permeability, boundary conditions for magnetic field, magnetic energy, magnetic forces, torque and inductance of different geometries.

Time Varying Fields and Maxwell’s Equations: Faradays law of electromagnetic induction, Maxwell‟s equations- differential and integral forms, boundary conditions, potential functions; time harmonic fields and Poynting theorem, depth of penetration, internal impedance, and power loss.

Plane Electromagnetic Wave: Plane wave in lossless media- Doppler effect, transverse electromagnetic wave, Polarization of plane wave; plane wave in lossy media- low loss dielectrics, good

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conductors; transmission line analogy- reflection coefficient, transmission coefficient, characteristics impedance, standing wave ratio, group velocity, instantaneous and average power densities, normal and oblique incidence of plane waves at plane boundaries for different polarization.

Book Recommended:

1. Fundamentals of Engineering Electromagnetics- D.K. Cheng

2. Fields and wave in communication electronics- S.RamoJ.R. Whinnery,T. Van Duzer

3. Electromagnetics for Engineers- F. T. Ulaby

4. Elements of Electromagnetics- Matthew N. O. Sadiku

5. Introduction to electromagnetic fields-Clayton R. Paul, S. A. Nasar


(Fourier Analysis & Laplace Transformation)

3 Credits, 3 hours/week Fourier analysis: Real and complex forms. Finite Fourier transforms. Fourier integral. Fourier transforms and their uses in solving boundary value problems.

Laplace Transformation: Definition, Laplace transforms of some elementary functions. Sufficient conditions for existence of Laplace transforms. Inverse Laplace transforms. Laplace transforms of derivatives. Some special theorems on Laplace transforms. Partial fraction. Solution of differential equations by Laplace transforms. Evaluation of improper integrals.

Viva Voce Central viva based on EEE250, EEE252, EEE262 and EEE272.

Year-3 Semester-1

EEE301 Signals and Linear Systems

Prerequisite EEE101, MAT 257


Classification of Signal and Systems: Signals- classification, basic operation on signals, elementary signals, representation of signal using impulse function; systems- classification.

Properties of Linear Time Invariant (LTI) Systems: Linearity, causality, time invariance, memory, stability, invertibility.

Time Domain Analysis of LTI Systems: Differential equations- system representation, order of the system, solution techniques, zero state and zero input response, System properties: impulse

response – convolution integral, determination of system properties; state variable- basic concept, static equation and time domain solution.

Frequency Domain Analysis of LTI Systems: Fourier series- properties, harmonic representation, system response, frequency response of LTI systems; Fourier transformation- properties, system transfer function, system response and distortion less systems.

Applications of Time and Frequency Domain Analysis: Solution of analog electrical and mechanical systems, amplitude modulation and demodulation, time-division and frequency-division multiplexing. Laplace Transformation: Properties, inverse transform, solution of system equations, system transfer function, system stability and frequency response and application.

Analogous Systems: Electrical, mechanical and electro-mechanical systems.

Book Recommended:

1. Continuous and Discrete Signals and Systems- S.S.Soliman, M.D. Srinath

2. Signal Processing and Linear Systems- B.P. Lathi

3. Analysis of Linear Systems- David K. Cheng

4. Signals and Systems- Simon Haykin, Barry Van Veen

5. Linear Circuit Analysis:Time Domain, Phasor, and Laplace Transform Approaches-Raymond A. DeCarlo , Pen-Min Lin

EEE309 Project

0.75 Credits, 3/2 hours/week The students are required to undertake a projectin the field of Electrical and Electronic Engineering which would be a design work. The objective is to provide an opportunity to the students to develop initiative, creative ability, confidence and engineering judgment.

EEE311 Digital Electronics

Prerequisite: EEE211


Analysis and Synthesis of Digital Logic Circuits: Number system and codes.Boolean algebra, De Morgan‟s law, logic gates and truth tables, combinational logic design, minimization techniques, implementation of basic static logic gates in CMOS and BiCMOS. Arithmetic and data handling logic circuits, decoders and encoders, multiplexers and combinational circuit design.

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http://www.amazon.com/Raymond-A.-DeCarlo/e/B001IU2IQK/ref=ntt_athr_dp_pel_1

http://www.amazon.com/s/ref=ntt_athr_dp_sr_2?_encoding=UTF8&field-author=Pen-Min%20Lin&ie=UTF8&search-alias=books&sort=relevancerank

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Programmable Logic Devices: Logic arrays, Field Programmable Logic Arrays and Programmable Read Only Memory. Sequential Circuits: Different types of latches, flip-flops and their design using ASM approach, timing analysis, timing analysis and power optimization of sequential circuits.Modular sequential logic circuit design: Shift registers, counters and their applications.

Books recommended: 1. Modern Digital Electronics – R. P. Jain 2. Digital Systems: Principles and Applications- Ronald J. Tocci 3. Digital Logic and Computer Design- M. Morris Mano, 4. Digital Logic Circuit Analysis and Design- Victor P.NelsonH. Troy

Nagle, Bill D. Carroll, J. David Irwin

EEE312 Digital Electronics Lab.

1.5 credits, 3hours/week Laboratory experiments based on theory and concepts learnt in EEE311. Design of simple systems using the principles learned in EEE312.

EEE321 Power Electronics

Prerequisite EEE211

3 Credits, 3 hours/week Power Semiconductor Switches and Triggering Devices: BJT, MOSFET, SCR, IGBT, GTO, TRIAC, UJT and DIAC. Rectifiers: Uncontrolled and controlled single phase and three phase.

Regulated Power Supplies: Linear-series and shunt, switching buck, buck boost, boost and cuk regulators. AC voltage controllers, single and three phase. Choppers.DC motor control.Single phase cyclo-converter.

Inverters: Single phase and three phase current and voltage source. AC motor control.Stepper motor control.Resonance inverters. Pulse width modulation control of static converters.

Books Recommended: 1. Power Electronics, circuits, devices and applications- Muhammed H.

Rashid 2. Introduction to Power Electronic- Daniel W. Hart

EEE322 Power Electronic Lab

1.5Credits, 3 hours/week Laboratory experiments based on theory and concepts learnt in EEE321. Design of simple systems using the principles learned in EEE321.

EEE341 Numerical Methods for Engineering

Prerequisite CSE195


Introduction: Motivation and errors in numerical techniques, Taylor series. Finite Difference Calculus: Forward, backward, divided, and central difference and difference of a polynomial.

Interpolation and Extrapolation: Newton‟s formula, lagrange, spline, chebyshev and inverse; extrapolation.

Nonlinear Equations: Iteration, bisection, false position, Raphson, Secant and Muller‟s methods.

Simultaneous Linear Algebraic Equations: Cramer‟s rule, inversion of matrices, Gauss elimination, Gauss-Jordon method, factorization and Gauss-Siedel iteration methods. Curve Fitting: Linear and polynomial regression, fitting power, exponential and trigonometric functions, Ordinary differential equations: initial value problem, Taylor‟s series method, Picard‟s method of successive approximation, Euler‟s method and Runge-Kutta method. Boundary value problems.

Numerical Integration: General quadrature formula, trapezoidal rule and Simpson‟s rule; numerical differentiation.

Book recommended: 1. Numerical Methods for Engineers – Steven C. Chapra, Raymond P.

Canale 2. Computer Applications for Numerical Methods- S S Kuo 3. Introductory Methods of Numerical Analysis- S S Sastry 4. Numerical Analysis-A. R. Vasishtha, vipinVasishtha, 5. Numerical Methods using Matlab- John H. Mathews, Kurtis D. Fink

EEE342 Numerical Methods for Engineering Lab.


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BLB305 Bangabandhu in Engineering and Professional Ethics


Sociology: Scope.Some basic concepts.Social evolution and techniques of production, culture and civilization.Social structure of Bangladesh.Population and world resources.Oriental and Occidental societies, Industrial revolution. Family-urbanization and industrialization. Co-operative and Socialist movements.

Professional Ethics: History and Development of Engineering Ethics: Study of Ethics in Engineering. Applied Ethics in engineering.Human qualities of an engineer.Obligation of an engineer to the clients and to other engineers.Measures to be taken in order to improve the quality of engineering profession.

Ethical Expectations: Employers and Employees inter-professional relationship, maintaining a commitment of Ethical standards.Desired characteristics of a professional code.Institutionalization of Ethical conduct cyber law moral thoughts.

Bangbandhu in Science and Technology

ECO307 Economics


Introduction: Definition of Economics.Economics and Engineering.

Micro-Economics: The theory of demand and supply and their elasticities.Pricedetermination.Nature of an economic theory, applicability of economic theories to the problems of developing countries.Indifference curve technique.Marginal analysis. Production, production function, types of productivity. Rational region of production of an engineering firm. Concepts of market and market structure. Cost analysis and cost function. Small scale production and large scale production. Optimization.Theory of distribution.

Macro-Economics: Savings, investment, employment, National income analysis.Inflation.Monetary policy, fiscal policy and trade policy with reference to Bangladesh.Economics of development and planning.

Viva Voce Central viva based on EEE309, EEE312, EEE322 and EEE342.

Year-3 Semester-2

EEE361 Communication Theory


Overview of Communication Systems: Basic principles, fundamental elements, system limitations, message source, bandwidth requirements, transmission media types, bandwidth and transmission capacity.

Noise: Source, characteristics of various types of noise and S/N ratio.

Information Theory: Measure of information, source encoding, error free communication over a noisy channel, channel capacity of a continuous system and channel capacity of a discrete memory less system, communication entropy, data compression.

Communication Systems: Analog and digital communication, carrier, baseband, band pass and broadband communication; broadcast- and point to point- mode of communication.

Continuous Wave Modulation: AM- DSB, SSB, VSB, QAM, spectral analysis of each type, envelope and synchronous detection; angle modulation- instantaneous frequency, FM, PM, spectral analysis, demodulation of FM and PM.

Pulse Modulation: Sampling- sampling theorem, Nyquist criterion, aliasing, instantaneous and natural sampling; PAM principle, bandwidth requirements; PCM- quantization principle, quantization noise, non-uniform quantization, signal to quantization error ratio, demodulation of PCM, DPCM and DM principle, adaptive DM; line coding formats and bandwidths.

Digital Modulation: ASK principle, bandwidth requirements, detection, noise performance; PSK principle, bandwidth requirements, detection, DPSK, QPSK- noise performance, FSK- principle, continuous and discontinuous phase FSK, detection of FSK, MSK- bandwidth requirements.

Concept of Multiplexing: TDMA, FDMA and CDMA

Communication Systems Design: Design parameters, channel selection criteria and performance simulation Brief Introduction to Some Communication Systems: Mobile cellular communication system, Fiber optic communication system, Microwave communication system &Satellite communication.

Books Recommended:

1. Modern Digital and Analog Communication System- B.P. Lathi

2. Communication Systems- Simon Haykin

EEE362 Communication Theory Lab.

1.5 Credits, 3 hours/week Laboratory experiments based on theory and concepts learnt in EEE361. Design of simple systems using the principles learned in EEE361.

http://www.amazon.com/Simon-Haykin/e/B000APRPVW/ref=sr_ntt_srch_lnk_1?qid=1338700073&sr=1-1

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EEE363 Electronic Circuit for Communication System


Radio communications: Properties and propagation of radio waves. Radio Receivers: Receiver types, TRF and super heterodyne receivers, AM & FM Receiver.

Television: Introduction, principle of operation, transmitter and receiver and their circuits. Receiving and transmitting antenna. Camera tube, Picture tube, Electron beam scanning, T-lines, balum, duplexer, vestigial side-band filters and their circuits. Introduction to color TV, VCD, DVD, CCTV, CATV, MATV, TV Booster. Radar: Introduction, radar-equation, Pulse and MTI Radar, CW and FM Radar: Delay lines and cancellers, range getting.

Introduction to Telephony system.

Book recommended:

1. Television Fundamentals – Fowler and Liport 2. Basic TV-B.Grob 3. Radio & TV engineering-A.G Mihal 4. Digital Television Systems –Marcelo S. Alencer 5. Radio Receiver Design- K.R Sturlen

6. Telecommunication switching systems and networks-ThiagarajanViswanathan

*EEE369 Industrial Training:

0.75 Credits For 2 Weeks Students will be attached with the industries/service agencies for two weeks after completing their Third year second semester (before starting Fourth year) to gain practical knowledge. Without satisfactory completion of this course the student will not fulfill the requirements of B. Sc. Engineering Degree

EEE371 Control System


Introduction to Control Systems: Linear system models- transfer function, block diagram and signal flow graph (SFG).

State Variables: SFG to state variables, transfer function to state variable and state variable to transfer function.

Feedback Control System: Closed loop systems, parameter sensitivity, transient characteristics of control systems, effect of additional pole and zero on the system response and system types and steady state error. Routh stability criterion.

Analysis of Feedback Control System: Root locus method and frequency response method.

Design of Feedback Control System: Controllability and observability, root locus, frequency response and state variable methods.

Digital Control Systems: Introduction, sampled data systems, stability analysis in Z-domain.

Books Recommended: 1. Modern Control Engineering- Katsuhiko Ogata 2. Modern Control Systems- R.C. Dorf, R.H. Bishop 3. Control System Engineering- N.S. Nise 4. Automatic ControlSystems–B. C.Kuo

EEE372 Control System Lab.


EEE381 Microprocessor, Interfacing and System Design

Prerequisite EEE311, EEE321


Fundamental Concepts: Microprocessor: A programmable device; microcomputer components and support ICs, building blocks of MPU based systems, microprocessor buses, programming principles using MASM, microprocessor instructions.

16-bit Architecture: Pin diagram and functions, memory organization, bus activities, register layout, internal processing blocks.

Instruction Set: Classifications of instructions, addressing modes, address computing chart.

I/O Controller Programming: Port definition and read/write instructions, parallel I/O programming using 8255, serial I/O programming using 8251, display programming using 8279 and LCD, keyboard programming using 8279 and discrete components, generation of timing functions using 8253 PIT controller.

Interrupt Structure: Interrupt terminologies, hardware and software interrupt, multiple interrupt management.

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Data Conversion Algorithm: Number system and BCD arithmetic, BCD2BIN conversion, BIN2BCD conversion, binary multiplication, binary division.

System Design (8086 based digital weighing machine: DWM) Top down/Bottom up design concept, hardware block diagram, control program flow chart, weight/rate acquisition and processing and display, cost computation and processing and display.

Advanced Microprocessors and Microcontrollers: History of the evolution of MPU/MCU, multitasking systems, PVAM operation of Intel high performance architecture, overview of 80286 architecture, instruction and programming; overview of 80386 architecture, instruction and programming; overview of CISC and RISC microcontrollers, instruction and programming.

Books Recommended:

1. Assembly Language Programming and Organization of the IBM PC- Y. Yu C. Marut

2. Microprocessor and Interfacing- D.V. Hall 3. Microprocessors and Microcomputer Based System Design- Mohamed

Rafiquzzaman 4. Intel Microprocessors- Barry B. Brey

EEE382 Microprocessor, Interfacing and System design Lab.


EEE391 Power System I

3 Credits, 3 hours/week Line Representation: Equivalent Circuit of Short, Medium and Long Line: T and π representation, exact solutions, equivalent circuit of long transmission line.Underground and overhead lines. Mechanical Characteristics of Transmission Line: Sag and stress analysis, effect of wind and ice loading, supports at different elevation, conditions of erection, and effects of temperature changes. Network Representation: Single line and reactance diagram of power system and per unit representation. Fault Analysis: Symmetrical fault calculation, symmetrical components, and sequence impedance and sequence networks, different unsymmetrical fault calculation Load Flow Studies: Gauss – Seidel method. Control of voltage, real power and reactive power.Reactive power compensation.

Voltage Control in Transmission Line: Tap changing transformers, Voltage regulator, booster transformers, induction regulator, shunt capacitor Power Factor Control in Transmission Line: Static condenser, Ferranti effect, synchronous condenser.

Recent Trends in Transmission System: Overview of flexible ac transmission system (FACTS), high voltage dc transmission system (HVDC) and SCADA.Power system harmonics.

Books Recommended: 1. Elements of Power SystemAnalyis –William D.Stevenson, Jr. 2. Electrical Power Systems- Ashfaq Hossain 3. Principle of Power Systems- V.K. Mehta, Rohit Mehta 4. Electrical Power Generation, Transmission and Distribution-S.N.

Singh

EEE392 Power System I Lab.

1.5 Credits, 3 hours/week Laboratory experiments based on theory and concepts learnt in EEE 391.

Viva Voce Central viva based on EEE362, EEE369, EEE372, EEE382 and EEE392.

Year-4 Semester-1

EEE409 Project and Thesis


The students are required to undertake a project in the field of Electrical and Electronic Engineering. The objective is to provide an opportunity to the students to develop initiative, creative ability, confidence and engineering judgment. The results of the work should be submitted in the form of a dissertation, which should include appropriate drawings, charts, tables, references etc.

EEE401 Digital Signal Processing

Prerequisite MAT205, MAT257


Introduction to Digital Signal Processing (DSP): Discrete-time signals and systems, analog to digital conversion, impulse response, finite impulse response (FIR) and infinite impulse response (IIR) of discrete time systems, difference equation, convolution, transient and steady state response.

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Discrete Transformations: Discrete Fourier series, discrete-time Fourier series, discrete Fourier transform (DFT) and properties, fast Fourier transform (FFT), inverse fast Fourier transform, Z-transformation- properties, transfer function, poles and zeroes and inverse Z-transform.

Correlation: Circular convolution, auto correlation and cross correlation.

Digital Filters: FIR filters- linear phase filters, specifications, design using window, optimal and frequency sampling methods; IIR filters- specifications, design using impulse variant, bi-linear z-transformation, least square methods and finite precision effects.

Books Recommended:

1. Discrete-Time Signal Processing- A.V. Oppenheim, R.W. Schafer, J.R. Buck

2. Discrete Signal Processing – Principle, Algorithms and Applications- John G. Proakis, Dimitris G. Manolakis

3. Digital Signal Processing – A Computer Based Approach-S. K. Mitra

EEE402 Digital Signal Processing I Lab.

1.5 credits, 3 hours/week Laboratory experiments based on theory and concepts learnt in EEE 400. Design of simple systems using the principles learned in EEE 400.

EEE411 Power System protection


Purpose of power system protection,Criteria for detecting faults: over current, differential current, difference of phase angles, over and under voltages, power direction, symmetrical components of current and voltages, impedance, frequency and temperature. Electromechanical, electronic and digital relays: Basic modules, over current, differential, distance and directional. Trip circuits. Different protection schemes for generator, transformer, motor, bus bar, transmission lines. Protection of ring mains and radial feeders.Miniature circuit breakers and fuses. Fuse: Commercially available fuses, their constructions, characteristics and applications. Circuit breakers: Principle of arc extinction, selection criteria and ratings of circuit breakers, types-air, oil, SF6, vacuum, ABCB, ACB, MCCB.

Books Recommended:

1. Switchgear Protection and Power Systems- Sunil S. Rao

2. Power System Operation and Control-B.Wollenberg, A. Wood

EEE412 Power System Protection Lab


Laboratory experiments based on theory and concepts learnt in EEE 412.

EEE413 Electrical Properties of Materials

Prerequisite PHY165


Atoms and Aggregates of Atoms: Bohr atomic model, shell model.

Bonding and Types of Solids: Primary bonding, secondary bonding, mixed bonding.

Crystal Structures: Types of crystals, lattice and basis, Bravais lattice and Miller indices.

Classical Theory of Electrical and Thermal Conduction: Scattering, mobility and resistivity, temperature dependence of metal resistivity, Mathiessen‟s rule, Hall Effect and thermal conductivity.

Modern Theory of Metals: Determination of Fermi energy and average energy of electrons, classical and quantum mechanical calculation of specific heat.

Dielectric Properties of Materials: Polar and nonpolar dielectrics, dielectric constant, polarization- electronic, ionic and orientational; internal field, Clausius-Mosotti equation, spontaneous polarization, frequency dependency of dielectric constant, dielectric loss, piezoelectricity, Ferro electricity.

Magnetic Properties of Materials: Magnetic moment, magnetization and relative permeability, different types of magnetic materials, origin of ferromagnetism and magnetic domains, coercive force, polycrystalline and permanent magnetic materials, introduction to superconductivity: Zero resistance and Meissner effect, Type I and Type II superconductors and critical current density.

Band Theory of Solids: Band theory from molecular orbital, Bloch theorem, Kronig-Penny model, effective mass, density of states.

Quantum Mechanics: Wave nature of electrons, Schrödinger‟s equation, one dimensional quantum problems- infinite quantum well, potential step and potential barrier; Heisenberg‟s uncertainty principle and quantum box.

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Carrier Statistics: Maxwell-Boltzmann and Fermi-Dirac distributions, Fermi energy.

Books Recommended:

1. Principles of Electronic Materials and Devices- S.O. Kasap

2. Electrical Engineering Material-A. J. Dekkar

Viva Voce Central viva based on EEE409, EEE402, EEE412 and Elective I Lab

Year-4 Semester-2

EEE459 Project and Thesis


The students are required to undertake a project in the field of Electrical and Electronic Engineering. The objective is to provide an opportunity to the students to develop initiative, creative ability, confidence and engineering judgment. The results of the work should be submitted in the form of a dissertation, which should include appropriate drawings, charts, tables, references etc.

EEE491 Microcontroller and PLC based System Design

Prerequisite EEE 381


Review of 8 bit/ 16 bit CISC/RISC microcontrollers: Hardwire architecture, First access register file, instruction pipelining.

System Design: Digital taximeter, prepaid energy meter, VVVF driven and the like, advances in system design.

PLC Introduction to Programmable Logic Controllers (PLC), PLC Hardware, block diagram,Definitions of Allen-Bradley conditional inputs and outputs , logic and number systems, timers and counters,I/O configuration and downloading PLC programs,Programming Terminals and Peripherals, Relay Logic, Selection and connection of controlling devices, Development of P.L.C programs,Installation and troubleshooting sensors wired as sinking or sourcing current , P.L.C. applications.

Books Recommended:

1. PIC Microcontrollers-An Embedded systems approach to Microcontrollers,3e- Bates

2. 8051 Microcontrollers: An Application Based Introduction- Calcutt 3. Programming the PIC Microcontrollers with Mbasic- Smith

EEE492 Microcontroller and PLC based System Design Lab

1.5 Credits, 3 hours/week Laboratory experiments based on theory and concepts learnt in EEE 491. Design of simple systems using the principles learned in EEE 491.

Viva Voce Central viva based on EEE459, EEE492, Elective III Lab and Elective IV Lab

4.0 Elective Courses offered by the Department of EEE

4.1 Power Group

EEE421 Power System II


Inductance and Capacitance of Overhead Power Line: Flux linkages, inductance due to external flux, inductance of single-phase two-wire line, composite conductor lines, G.M.D, 3-phase line with equilateral and with unsymmetrical spacing, parallel circuit of 3-phase line, and use of tables. Electric field, capacitance of two wire line, three-phase lines with symmetrical & with equilateral spacing, effect of earth Generalized Line Constants: General line equations in terms of ABCD constants, relations between constants, charts of line constants, constants of combined networks measurement of line constants. Insulators for Overhead Lines: Types of insulators, their constructions and performance, potential distribution in a string of insulators, string efficiency, methods by equalizing potential distribution, special types of insulators, testing of insulators. Insulated Cables: Underground cables vs. overhead lines, insulating materials, electro static stress grading, three core cable-dielectric losses and heating, modern developments oil filled and gas filled cables, measurements of capacitance, cable testing, corona & corona power loss. Stability: Swing equation, power angle equation, equal area criterion, multi-machine system, step-by-step solution of swing equation, factors affecting transient stability. Power distribution: DC and AC distribution calculation for different network configuration, typical layout of a substation.

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Books Recommended: 1. Power System Analysis- J.J. Grainger, W.D. Stevenson 2. Power System Analysis–Hadi Saadat 3. Electrical Power Generation, Transmission and Distribution- S.N.

Singh 4. Principles of Power System- V.K. Mehta, Rohit Mehta

EEE422 Power System II Lab


EEE423 High Voltage Engineering


Ionization and Decay Process: Townsend‟s first and second ionization coefficient. Electric breakdown in gases. Townsend‟s criterion for spark breakdown. Sparking potential. Penning effect. Corona discharges, power loss calculation. Breakdown of solid and liquid, dielectrics. Generation of High Voltage: Alternating voltage, transformer cascade. Impulse voltage generator and its mathematical analysis. Design consideration of impulse generators. Triggering of impulse generators. DC voltage doubler and cascade circuits. Electrostatic generator, voltage stabilization. Measurement of High Voltage: Measurement of high ac, dc, and impulse voltages and currents. High Voltage Testing: destructive and non-destructive high voltage testing of electrical equipment, impulse testing. Transient overvoltage and insulation coordination, Test of dc and ac cable, Series resonant circuit for high voltage ac testing. Electrostatic voltmeter, sphere gap. Potential divider. Oil testing. Design consideration of transmission line based on direct stroke. High voltage lightning arrester.

EEE451 Electrical Machine III


Special Machines: Series universal motor, permanent magnet DC motor, unipolars and bipolar brush less DC motors, stepper motor and control circuits. Reluctance and hysteresis motors with drives circuits, switched reluctance motor, electro static motor, repulsion motor, synchronous and control transformers. Permanent magnet synchronous motors.

Acyclic Machines: Generators, conduction pump and induction pump.

Magneto Hydrodynamic Generators: Fuel cells, thermoelectric generators, flywheels, vector control, linear motors and traction.

Photovoltaic Systems: Stand alone and grid interfaced.

Wind Turbine Generators: Induction generator, AC-DC-AC conversion.

EEE452 Electrical Machine III Lab


EEE471 Non-Conventional Energy

3 Credits, 3 hours/week Solar Geometry: Motion of the earth about the sun, Angle of declination, Solar time, Location of the sun relative to a horizontal plane. Solar Intensities: Solar spectrum and intensities above the atmosphere, Instrumentation for measuring solar intensities, solar intensities at earth level normal to the sun, Insolation on surfaces, Direct and Diffuse Radiation. Solar Heating & Storage Systems: Energy Flow and Efficiency of Flat-Plate collectors, Frames, Boxes, Insulation and Glazing, Absorber plates and Heat-transfer Fluids. Sensible heat storage, Phase-change storage and Other types of storages. Silicon Solar Cells: Principles, Efficiency and efficiency limiting factors. Design consideration, cell fabrication, Construction of Solar Modules & Panels. Other Cells and Materials: MIS Solar cells and other Device structures, Cell Materials. Other Nonconventional Sources of Energy: Biomass; Wind power; Water power & Tidal power.

EEE472 Non-Conventional Energy Lab

0.75 Credits, 3/2 hours/week


EEE473 Power Plant Engineering and Economy


Power Plants General layout and principles, steam turbine, gas turbine, combined cycle, hydro and nuclear. Plant performance and operation characteristics,

http://www.tatamcgrawhill.com/html/9780070487390.html

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Atomic power plant Nuclear fission and fusion; energy release; moderation, control, cooling and shielding aspects. Factor, place, utility and effects on environment and human beings.

Selection of Location Technical, economical (Efficiency, heat rate and incremental rate, load division between generating units for economy, economic conductor selection, Kelvin‟s law.) and environmental factors (forces on bus section in case of short circuit), load forecasting, load shearing (base load & peak load plant), Optimum load scheduling, transmission line loss ,chronological load curves to distribute load among units Graphical method for location of distribution systems.Bus system layout.Importance of current limiting reactors.

Generation Scheduling Deterministic and probabilistic generation, load curves- demand factor, diversity factor, load duration curve, energy load curves, load factor, capacity factor, plant factor, electricity tariff formulation and type.

4.2 Electronics & Communication Group

EEE431 Digital Communication


Introduction: Communication channels, mathematical model and characteristics, probability and stochastic process.

Source Coding: Mathematical models of information, entropy, Huffman code and linear predictive coding.

Digital Transmission System: Base band digital transmission, inter-symbol interference, bandwidth, power efficiency, modulation and coding trade-off.

Receiver for AWGN Channels: Correlation demodulator, match filter demodulator and maximum likelihood receiver.

Channel Capacity and Coding: Channel models and capacities and random selection of codes.

Block Codes and Conventional Codes: Linear block codes, convolution codes and coded modulation, Spread spectrum signals and system.

Communication Systems Design: Design parameters, channel selection criteria and performance simulation

EEE432 Digital Communication Lab.


EEE441 Microwave Engineering


Transmission Lines: Voltage and current in ideal transmission lines, reflection, transmission, standing wave, impedance transformation, smith chart, impedance matching and lossy transmission lines. Waveguides: General formulation, modes of propagation and losses in parallel plate, rectangular and circular waveguides, and transit time effect, velocity modulation, space charge wave.

Microstrips: Structure and characteristics.

Rectangular Resonant Cavities: Energy storage, losses and Q. Radiation: Small current element, radiation resistance, radiation pattern and properties, Hertzian and half wave dipoles.

Antennas: Mono pole, horn, rhombic and parabolic reflector, antenna, array and Yagi-Uda antenna.

Microwave tubes: Klystron amplifier, multi-cavity klystron amplifier, Reflex Klystron oscillator, magnetron, TWT amplifier, BWO.

EEE442 Microwave Engineering Lab.


EEE443 Optoelectronics


Optical Properties of Semiconductor: Direct and indirect band-gap materials, radiative and non-radiative recombination, optical absorption, photo-generated excess carriers, minority carrier life time, luminescence and quantum efficiency in radiation.

Properties of Light: Particle and wave nature of light, polarization, interference, diffraction and blackbody radiation.

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Light Emitting Diode (LED): Principles, materials for visible and infrared LED, internal and external efficiency, loss mechanism, structure and coupling to optical fibers.

Stimulated Emission and Light Amplification: Spontaneous and stimulated emission, Einstein relations, population inversion, absorption of radiation, optical feedback and threshold conditions.

Semiconductor Lasers: Population inversion in degenerate semiconductors, laser cavity, operating wavelength, threshold current density, power output, hetero-junction lasers, optical and electrical confinement. Introduction to quantum well lasers.

Photo Detectors: Photoconductors, junction photo-detectors, PIN detectors, avalanche photodiodes and phototransistors.

Solar Cells: Solar energy and spectrum, silicon and Schottkey solar cells.

Modulation of Light: Phase and amplitude modulation, electro-optic effect, acousto-optic effect and magneto-optic devices, introduction to integrated optics.

Books Recommended:

1. Fiber optic communications-Joseph C. Palais 2. Optoelectronics: An Introduction-J. Wilson, J. Hawkes 3. Optoelectronics and photonics Principles and Practices-S.O. Kasap

EEE453 Optical Fiber Communication


Light Propagation through Optical Fiber: Ray optics theory and mode theory.

Optical fiber: Types and characteristics, transmission characteristics, fiber joints and fiber couples.

Receiver Analysis: Direct detection and coherent detection, noise and limitations.

Transmission Limitation: Chromatic dispersion, nonlinear refraction, four wave mixing and laser phase noises.

Optical Amplifier: Principle, application, and limitations of laser and fiber amplifiers, EDFA. Optical networks, fiber installation and optical measurement

Multi-Channel Optical System: Frequency division multiplexing, wavelength division multiplexing and co-channel interference.

Chromatic Dispersion: Normal and anomalous dispersion, higher order dispersion, modal dispersion and PMD. Nonlinear effects- self phase and cross-phase modulations, four wave mixing. Scattering, leakage and absorption losses.

EEE461 VLSI


VLSI technology: Top down design approach, technology trends and design styles.

Review of MOS transistor theory: Threshold voltage, body effect, I-V equations and characteristics, latch-up problems, NMOS inverter, CMOS inverter, pass-transistor and transmission gates.

CMOS circuit characteristics and performance estimation: Resistance, capacitance, rise and fall times, delay, gate transistor sizing and power consumption.

CMOS circuit and logic design: Layout design rules and physical design of simple logic gates.

CMOS subsystem design: Adders, multiplier and memory system, arithmetic logic unit.Programmable logic arrays.I/O systems. VLSI testing

EEE462 VLSI Lab


This course consists of two parts. In the first part, students will perform experiments to verify practically the theories and concepts learned in EEE461. In the second part, students will design simple systems using the principles learned in EEE461.

EEE463 Computer Networks & Data Communication

3Credits, 3 hours/week

Introduction: Uses of computer networks to computer communication networks and layered architecture view, LAN, WAN, Packet switching and fast packet switching, Reference models, The OSI reference model, The TCP/IP reference model, A comparison of the OSI and TCP reference models.

The Data Link Layer: Data link layer design issues, Elementary data link protocols, An unrestricted simplex protocol, A simplex stop and wait protocol, Sliding windows protocols, HDLC-High-level data link Control, Data link layer in the internet, The data link later in ATM.

http://www.google.com.bd/search?tbo=p&tbm=bks&q=inauthor:%22Joseph+C.+Palais%22

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The Network, Transport and Application Layers: The IP protocol, IP address, Sub nets, Internet control protocols, Mobile IP, Routing algorithms. Introduction to TCP, connectionless and connection oriented protocol, Flow control in Transport layer, Network security, DNS-domain name system, Electronic mail, FAX, The World Wide Web.

Multiple Access Protocols: ALOHA, Carrier Sense Multiple Access (CSMA) protocols, Collision-free protocols, Limited contention protocols, Wavelength division multiple access protocols, Wireless LAN protocols, CSMA/CA, CSMD/CD: Persistent and non-persistent algorithms, Ethernet network, Different network devices: Hubs, Bridges, Switches, Router/Gateway, Spanning tree

EEE481 Mobile Cellular Communication


Introduction: Concept, evolution and fundamentals, analog and digital cellular systems.

Cellular Radio System: Frequency reuse, co-channel interference, cell splitting and components

Mobile Radio Propagation: Propagation characteristics, models for radio propagation, antenna at cell site and mobile antenna. Frequency Management and Channel Assignment: Fundamentals, spectrum utilization, fundamentals of channel assignment, traffic and channel assignment.

Handoffs and Dropped Calls: Reasons and types, forced handoffs, mobile assisted handoffs and dropped call rate.

Diversity Techniques: Concept of diversity branch and signal paths, carrier to noise and carrier to interference ratio performance.

Multiplexing: TDM- principle, receiver synchronization, frame synchronization, TDM of multiple bit rate systems; FDM- principle, demultiplexing; WDM, multiple access network- TDMA, FDMA, CDMA- spread spectrum multiplexing, coding technique and constraints of CDMA.

Digital Cellular Systems: Global system for mobile, time division multiple access and code division multiple access. GSM, AMPS, GPRS, EDGE, W-CDMA, 3rd generation of mobile communication, Packet switching and data communication

EEE482 Mobile Cellular Communication Lab

0.75 Credits, 3/2 hours/week Laboratory experiments based on theory and concepts learnt in EEE 481.

EEE483 Telecommunication Engineering

3 Credits, 3 hour/week

Introduction: Principle, evolution, networks, exchange and international regularly bodies.

Telephone Apparatus: Microphone.Speakers, ringer, pulse and tone dialing mechanism, side-tone mechanism, local and central batteries and advanced features. Switching System: Introduction to analog system, digital switching system-space division switching, blocking probability and multistage switching, time division switching and two dimensional switching, SPC, TST, STS. Traffic Analysis: Traffic characterization, grades of service, network blocking probabilities, delay system and queuing.

Modern Telephone Services and Network: Internet telephony, fascimile, integrated services digital network; asynchronous transfer mode and intelligent networks, introduction to cellular telephony and satellite communication. Radar: Introduction, radar-equation, Pulse and MTI Radar, CW and FM Radar: Delay lines and cancellers, range getting.

EEE493 Biomedical Engineering

3 Credits, 3 hours/week Medical terminology, cell physiology, membrane potential, action potential, excitation and rhythmically. Rhythmic excitation of heart. Transducers used in medical diagnostics. Biomedical Instrumentation: Normal Electrocardiograph, ECG simulator, Watch filter, ECG amplifier, pulse beat monitor, pace marker, galvanic skin resistance detector, respiratory and suction apparatus. Electronic stethoscope. Electronic clinical thermometer, blood flow and pressure monitoring recorders, metabolic rate measurement. Special topics: Bio-telemetry, application of ultrasonic and laser in biology and medicine. Clinical X-ray equipment. Fluoroscopy. Infrared heating.

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Postgraduate Studies Academic Ordinance and Syllabus for Postgraduate Studies for the Award

of Master of Science in Engineering/ Master of Engineering in Department

of Electrical & Electronic Engineering (EEE).

Effective from Session: 2016 – 2017

Master of Science in Engineering/ Master of Engineering

1. Definitions: 1.1 „University‟ means the Bangabandhu Sheikh Mujibur Rahman Science &

Technology University abbreviated as BSMRSTU, Gopalganj-8100. 1.2 „Regent Board‟ means the Regent Board of the University. 1.3 „Academic Council‟ means the Academic Council of the University. 1.4 „Committee of Courses and Studies‟ means the Committee of Courses for

Undergraduate and Postgraduate Studies of a Degree Awarding Department of the University formed as per statute of the University.

1.5 „Faculty‟ means the Faculty of the University. 1.6 „Academic Committee‟ means academic committee of the department

formed as per statute of the University. „BAS‟ means the Board of Advanced Studies of BSMRSTU.

1.7 „BAS‟ means the Board of Advanced Studies of BSMRSTU.

BAS shall consist of the following members: i) Dean of the faculty ii) All Chairmen of the departments in the faculty iii) One Professor/Associate Professor nominated from each department by the Academic Committee *At Least 40% members will fulfill the quorum.

: : :

Chairman Member Member

2. Degree awarding departments: The university shall have the following post-graduate degree awarding department under the Faculty of Engineering. i) Department of Computer Science and Engineering (CSE)

ii) Department of Electrical and Electronic Engineering (EEE)

iii) Department of Applied Physics, Electronics and Communication Engineering (APECE)

3. Degree Offered: The post graduate degree to be offered under this ordinance are as follows:

3.1 Master of Science in <Name of the Department> 3.1.1 Master of Science in computer science and Engineering abbreviated as

M. Sc. Engg.in CSE. 3.1.2 Master of Science in Electrical and Electronic Engineering abbreviated

as M.Sc. Engg. in EEE. 3.1.3 Master of Science in Applied Physics, Electronics and Communication

Engineering abbreviated as M. Sc. Engg. in APECE.

3.2 Master of Engineering in <Name of the Department> 3.2.1 Master of Engineering in Computer Science and Engineering

abbreviated as M. Engg in CSE. 3.2.2 Master of Engineering in Electrical and Electronic Engineering

abbreviated as M. Engg. in EEE. 3.2.3 Master of Engineering in Applied Physics, Electronics and

Communication Engineering abbreviated as M. Engg. in APECE. 3.3 The above degree may be offered in any other department approved by

Regent Board on the recommendation of the Academic Council.

4 Admission Requirements and Procedure: 4.1 (a) For admission to the courses leading to the award of the degree of M.

Sc. Engg., a candidate must have obtained B. Sc. Engg. or an equivalent degree in the relevant/ related field with good academic records with at least a CGPA ≥3.25 in the scale of 4.00, from any recognized Institute/University. (b) For admission to the courses leading to the award of the degree of M. Engg., a candidate must have obtained B. Sc. Engg. or an equivalent degree in the relevant/ related field with good academic records with at least a CGPA ≥2.50 in the scale of 4.00, from any recognized Institute/University.

4.2 Application for admission to the above courses shall be invited through regular means of advertisement and shall be received through prescribed application from.

4.3 On the recommendation of Committee of Courses and Studies, the rules for admission into various departments of the Institute for post-graduate Studies may be amended from time to time by the Academic Council through BAS.

4.4 For admission a candidate may be required to appear at a written/oral test conducted by a Selection Committee as constituted by the respective Committee of Courses and Studies.

4.5 Every selected candidate shall get himself registered with the Institute.

4.6 Each student shall be assigned an adviser by the respective Committee of Courses and Studies from the teachers of the department. Prior to each enrollment and course registration for any semester, the Adviser/Supervisor (as appointed by Articles 8.10 of this Ordinance) shall check and approve the student‟s schedule for subjects, Prerequisites as recommended by the Selection Committee and total credit hours.

4.7 Every registered candidate shall get himself enrolled on payment of prescribed fees and other dues before the commencement of each semester.

4.8 Eligibility for the admission of foreign students in the aforementioned post-graduate program will be examined by the equivalence committee.

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5 Academic Regulations: 5.1 The minimum duration of the M.Sc. Engg. (Thesis group)/M. Engg. (non

Thesis group) course shall be of three semesters. A candidate for the master‟s degree must complete all requirements for the degree within three academic years from the date of his first admission.

5.2 There shall be two semesters in one academic year. Duration of each semester shall not be less than 25 weeks including course registration, class/thesis work and examination.

5.3 Academic progress shall be measured in terms of credit hours earned by a student. One credit hour for theory course shall normally require one hour of class attendance per week for one semester. While one credit hour for thesis, Project or laboratory class should normally require three hours of work per week for one semester. The number of credit hours for each subject shall be as specified in the syllabus of the respective department.

5.4 Minimum requirements of the theory and thesis/project credit hours to be earned by students for different degrees are as outline in the following table:

Degree Theory Thesis Project/Laboratory Total

M. Sc. Engg. 18 18 - 36

M. Engg. 27 - 9 36

5.5 There shall be two categories of students, namely full time students and

part time students. 5.1.1 Students, serving in different organizations may be admitted as part time

students with a written consent from the employer. A part time student may be assigned a maximum of 9 credit hours of course work in a semester.

5.1.2 Full time students must register for a minimum of 12 credit hours and a maximum of 15 credit hours per semester. A full time student shall not be allowed to be in the employment of any organization (even as part time employee). However, they may be awarded teaching/research assistantship. A student already in employed may be admitted as full time students only if he is on leave or deputation from his employer.

5.1.3 If a full time student gets an employment while he/she is in a running semester, he/she may be allowed to continue the rest of that semester with prior approval of the Chairman of the department and the employer.

5.6 The subject that shall be offered in any semester shall be as determined by the relevant department.

5.7 After the first semester the Committee of Courses and Studies may consider a student‟s application to transfer the credits earned elsewhere if the following conditions are fulfilled. i) The credits should be earned from a recognized Institution or University.

ii) Maximum 50% Credit-Hours in course work may be transferred. iii) Credits earned before five academic years from the date of application will not be considered. iv) Only B+ or higher grades will be considered. The student‟s performance in the first semester and the standard and application of the courses studies elsewhere should be specially considered in giving such approval.

6 Grading System: 6.1 Numerical marks may be made in answer scripts, tests etc. for assessing

the performance of the students but all the final grading shall be made in letter grade/grade point as follows:

Numerical Marks Letter Grade Grade Point Performance

90% and above A+ 4.0 Excellent

≥80% but <90% A 3.5 Very good

≥70% but <80% B+ 3.0 Good

≥60% but <70% B 2.5 Average

≥50% but <60% C 2.0 Pass

Below 50% F 0.0 Fail

Incomplete I --- ---

Satisfactory S --- ---

Unsatisfactory U --- ---

Withdrawn W --- ---

F- Subject in which the students get F grades shall not be counted towards credit hour requirements and for the calculation of Grade Point Average (GPA). I - Given only when a student is unable to complete the course because of circumstances beyond his control. It must be made up by the close of the next two semesters or the incomplete grade becomes a failure. He/ She may however, be allowed to register without further payment of tuition fees for the course. S - or U - Satisfactory or unsatisfactory. Used only as final grade for thesis/ Project and non-credit courses. Grade for thesis or project which will be continuing shall be recorded as „In progress‟. If however, thesis is discontinued “Incomplete” grade shall be recorded. W- Officially withdrawn from a course. A student must withdraw officially from a course within two working weeks of the commencement of the semester or else his grade in that course shall be recorded as „F‟ unless he/she is eligible to get a grade of I (incomplete). A student may be permitted to withdraw and change his/her course within the specified period with the approval of his/her adviser and Chairman of the department.

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6.2 The Grade Point Average (GPA) shall be computed for each semester as follows:

n

i

i

n

i

ii

C

GC

GPA

1

1

Where n is the number of courses completed during the semester, Ci is the number of credits allotted to a particular course and Gi is the grade point corresponding to the letter grade for that course. A cumulative Grade Point Average (CGPA) shall also be computed at the end of second and subsequent semesters. The CGPA will be computed as follows:

m

j

j

m

j

jj

T

TS

CGPA

1

1

Where m is the total number of semesters being considered, Sj is the CGPA of the j-th semester and Tj is the total number of credits registered during j-th semester. Both GPA and CGPA will be rounded off to the second place of decimal for reporting.

6.3 On the written request from a student, a maximum of two courses, having B or C grade in each, may be ignored for the calculation of CGPA. In such case, the CGPA must not be less than 2.65 in the remaining courses.

6.4 Courses in which a student gets F grade shall not be counted towards credit hour requirements and for the calculation of GPA.

6.5 A student shall get I grade in a course with prior permission from the Chairman of the Department if he/she is unable to complete the course due to any unavoidable circumstances. He/she has to complete the course within the next two consecutive semesters; otherwise, he/she will get F grade in that course. He/she may, however, be allowed to register that course without further payment of course registration fees.

6.6 Satisfactory (S) and unsatisfactory (U) shall be used for grading of thesis/project and non-credit prerequisite courses. If, however, thesis is discontinued an I grade shall be recorded.

6.7 Official withdrawal: A student may withdraw from the program for a total period of Three academic years for Masters student, on the recommendation of the supervisor (and co-supervisor, if any) with prior permission from the chairman of the department, if he/she is unable to

continue the program due to any unavoidable circumstances of his/her own or of the Institute.

7 Conduct of Examination: 7.1 For all Masters Degree in Engineering in addition to tests, assignments

and/or class test during the semester as may be given by the teachers(s) concerned, there shall be a written examination at the end of the semester and/or other tests for each of the subjects offered in a semester. The dates of such examination will be announced by the Chairman of the respective department at least two weeks before the commencement of the examinations. The final grade in a subject shall be based on the performance in all tests, assignments and/or examinations.

7.2 Examination Committee: The examination committee shall be nominated by the departmental academic committee and will be approved by the vice chancellor. There will be an examination committee for each semester of an academic year. The examination committee shall consist of 5 members: (a) chairman of the committee, (b) 3 other members belonging to department and (c) one expert member from outside the department/University.

7.3 Each examiner will submit the final grades obtained by student(s) in each subject in prescribed form to the Chairman of the department. The Chairman of the department will appoint tabulators for each semester, subject to the approval of the Vice Chancellor. Two copies of the tabulation sheet will be prepared for a semester, (i) One for Controller of Examination and (ii) One for Chairman of the department.

7.4 Cumulative grades earned by a student shall be announced by the office of the Controller of Examination at the end of each semester. Students may collect a copy of transcript from the Controller of Examination at the end of each semester, on payment of the prescribed fees.

7.5 The respective teacher(s) of each theory course offered in a semester will be the paper setter and script examiner for the semester examination.

7.6 No student will be allowed to register a course for grade improvement. A student having an F grade in a compulsory course (if any) shall be allowed to repeat.

7.7 Credit Transfer: On the recommendation of the respective BAS and by the approval of the Academic Council, a student may be allowed to transfer a maximum of 50% of the required theory courses of this University completed by the student at other universities/institutions where he/she enrolled earlier for M.Sc. program provided that the courses were not taken earlier than 3 (three) calendar years from the date of his/her first enrollment in the respective program in this University. In addition, the student must obtain a minimum Grade Point of 3.00 out of 4.00 or its equivalent in each course to be transferred and the courses should be equivalent to the approved courses of this University.

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8 Qualifying Requirements: 8.1 The qualifying requirement of the degree is that a student must earn a

minimum grade point average of 2.65 for M.Sc. Engg./M. Engg degree, based on the weighted average in his course work. GPA ia calculated as

GPA = (CiGi) / Ci, where, Ci is the credit hour in a particular subject

and Gi is the grade point corresponding to the grade obtained by the student in that subject. GPA and CGPA will be rounded off to the second place of decimal.

8.2 The C grades up to a maximum of two subject may be ignored for calculation of grade point average (GPA) at the written request of the student provided he/she has completed the total course credit hour requirement with a minimum weighted GPA of 2.65 in the remaining subjects. No subject shall be repeated unless it is compulsory requirement of the degree as department by the Committee of Courses and Studies. Performance in all the subjects shall be reflected in the transcript.

8.3 If F grade is obtained in three or more subjects by a student, he/she shall not be allowed to continue the program.

8.4 If the end of the 1st semester, the GPA falls below 2.5 (including C grades)

he/she shall not be allowed to continue the program. 8.5 In addition to successful completion of course work every student shall

submit a thesis on his/her research work or report on his/her project work fulfilling the requirements as details in Articles 8,9,10 M.Sc. Engg./M. Engg.students should preferably have a publication/ paper.

9. Thesis/Project. for M.Sc. Engineering/M. Engg.: 9.1 Research work for a thesis/project shall be carried out under the

supervision of full time teacher who is a member of Committee of Courses and Studies to the relevant department. A co-supervisor from within or outside the department/ Institute may be appointed. The tentative research proposal of thesis/project and the supervisor and co-supervisor (if any) shall be approved by the BAS on recommendation of Committee of Courses And Studies before the completion of course work requirements of the student concerned.

9.2 The research work must be carried out in this Institute. In special circumstances it may be carried out at a place(s) recommended by the supervisor in consultation with the Chairman of the department and approved by the BAS.

9.3 A seminar shall have to be presented by M.Sc. Engg. student on the progress of his/her research work, within the next semester after completion of course work. The Chairman of the department will keep a record of it send a report to the Director in prescribed form.

9.4 Every student shall submit to the Chairman of the department, through his/her supervisor requirement number of type written copies of his/her thesis/project report in the approved format on or before a date to be fixed by the Chairman of the department in consultation with the supervisor concerned.

9.5 The student shall certify that the research work was done by his/her and that the same work has not been submitted elsewhere for any degree or award (except for publication).

9.6 The thesis/project should demonstrate an evidence of satisfactory knowledge in the field of research undertaken by the student and must be an original contribution to engineering/science and worth of publication.

9.7 Every student submitting a thesis/project report in partial fulfillment of the requirement of a degree shall be required to appear at an oral examination , on a date or dates fixed by the Chairman of the department in consultation with supervisor and must satisfy the examiners that he/she is capable of intelligently applying the results of this research to the solution of problem, of undertaking independent work, and also afford evidence of satisfactory knowledge related to the theory and technique used in his research work.

9.8 The Chairman of the department will arrange to keep a record of the thesis/Project examination in tabulation sheet and send a report to the Director in prescribed format, along with the comments of the thesis examiners. In this report he will also confirm that the student has completed the course and other requirements (if any) for the award of the degree.

10. Striking off and removal of names from the rolls: The name of the student shall be struck off and/ or removed from the rolls of the University on the following grounds: i) Unsatisfactory progress of the student reported by the supervisor through the ACPG and approved by the BAS. ii) Forced to discontinue his/her studies under disciplinary rules. iii) Withdrawal of his/her name from the roll-sheet of the University. iv) Non–payment of dues of the University and the Halls of residence within a prescribed period.

11. Academic fees: The amount of academic fees shall be decided by the University from time to time.

12. Effect and Reviewed of the Ordinance: This ordinance shall be effective from the academic session 2015-16. The ordinance may be reviewed by the Academic Council on recommendation of the Faculty to ordinance committee. If there arises any matter that does not cover this ordinance, the decision of the Vice chancellor will be the final.

**** **** **** ****

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Syllabus for Master of Science in Engineering/ Master of Engineering

Course Structure for Postgraduate Programs of the Department of Electrical

and Electronic Engineering

Elective Courses

Course No. Course Title Credit

Hours

EEE 6000 Thesis/ Project 18/ 9

EEE 6001 Engineering Analysis 3

EEE 6002 Estimation and Identification Techniques 3

EEE 6003 Selected Current Topics in EEE 3

Energy System

Course No. Course Title Credit Hours

EEE 6101 Energy Conversion 3

EEE 6102 Rural Energy System 3

EEE6103 Renewable Energy 3

EEE6104 Unconventional Energy Sources and Energy Converters

3

EEE 6105 Physical System Modeling 3

Control System

EEE 6201 Modern Control Theory 3

EEE 6202 Introduction to Adaptive Control 3

EEE 6203 Optimal Control Theory 3

EEE6204 Robust Control Systems 3

EEE 6205 Digital Control Theory 3

EEE 6206 Multivariable Control Systems 3

EEE6207 Microprocessor Based Industrial Control 3

EEE6208 Artificial Neural Networks 3

EEE6209 Neural Network and It's Applications 3

Power System

EEE 6301 Advanced Power System Analysis 3

EEE 6302 Power System Stability

EEE 6303 Advanced Power System Stability 3

EEE 6304 Optimization of Power System Operation 3

EEE 6305 Power System Planning 3

EEE 6306 Computer Aided Power System Design 3

EEE 6307 Power System Reliability 3

EEE 6308 Power System Control and Instrumentation 3

EEE6309 Power System Transients 3

EEE 6310 Advanced Protective Relaying 3

EEE6311 Generalized Machine Theory 3

EEE6312 Reliability Analysis and Predication 3

Power Electronics and Drives

EEE 6401 Power Electronics Converters I 3

EEE 6402 Power Electronics Converters II 3

EEE6403 Electric Drives 3

EEE 6404 Modeling & Control of Electric Drives 3

EEE 6405 Power Electronics Applications in Power Systems

3

Electronics

EEE6501 Integrated Circuit Technology 3

EEE6502 Linear and Digital IC Applications 3

EEE6503 VLSI System Design 3

EEE6504 Computer Aided VLSI Design 3

EEE 6505 Gaseous Electronics 3

EEE 6506 Biomedical Electronics 3

EEE 6507 Laser Theory 3

EEE 6508 Carbon Nanomaterials and Technology 3

EEE 6509 Advanced Solid State Electronics 3

Information and Telecommunication

EEE 6601 Information and Coding Theory 3

EEE 6602 Statistical Signal Theory 3

EEE6603 Satellite Communication 3

EEE 6604 Data Communication 3

EEE6605 Cellular Mobile Communication 3

EEE6606 Optical Fiber System 3

EEE6607 Advanced Optical Fiber Communication 3

EEE 6608 Advanced Digital Signal Processing 3

EEE 6609 Digital Circuit Design 3

EEE 6610 Digital Filter Design 3

EEE 6611 Digital Image Processing 3

EEE 6612 Spread Spectrum Communication 3

EEE 6613 Statistical Modeling 3

EEE 6614 Advanced Wireless Communication 3

Electromagnetics and Microwaves

EEE 6701 Advanced Electromagnetic Theory 3

EEE 6702 Antennas and Propagation 3

EEE6703 Computational Electromagnetics 3

EEE6704 Microwave Solid State Devices 3

EEE 6705 High Power Microwave Devices 3

EEE 6706 Plasma Engineering-I 3

EEE 6707 Plasma Engineering-II 3

EEE 6708 Relativistic Electron Beam Technology 3

EEE 6709 Fusion Science and Technology 3

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Computer Aided Systems

EEE 6801 Mordern Architecture of Microprocessor & Microcomputer

3

EEE 6802 Design and Organization of Microcomputer 3

EEE 6803 Computer Simulation of Electrical & Electronic Circuits

3

EEE 6804 Computer in Electrical Engineering 3

EEE 6805 Computer aided instrumentation and sensor application

3

EEE 6806 Computer aided optoelectronics application 3

EEE 6807 Computer aided simulation of physical systems

3

EEE 6808 Applied Numerical Analysis 3

High Voltage Engineering

EEE 6901 Behavior of Dielectric under High Voltage 3

EEE 6902 Insulators for high voltage 3

EEE 6903 High voltage Power Equipment Engineering 3

EEE 6904 Insulating properties of Vacuum under high voltage

3

EEE 6905 Insulating properties of SF6 under high voltage

3

EEE 6906 HVDC power transmission 3

Detail Syllabus

EEE 6001: Engineering Analysis Credit: 3 Contact Hours/week: 3 Linear system analysis, linear algebra, state-space representation and analysis, sampled data systems, Z-transform, discrete time systems, complex planes. Calculus of variance, modeling and simulation techniques, computer methods and tools. Professional methods of dealing with problems. Mathematical and physical principles applied to problems of diverse topics in Electrical Engineering. Simulation Techniques; Statistical Methods.

EEE 6002: Estimation and Identification Techniques Credit: 3.00 Contact Hours: 3Hrs/Week Estimation: Signal and parameter estimation, linear estimation for discrete and continuous non stationary process, time invariant linear estimators, Bayesian estimation theory, properties of estimators, confidence interval, bias and variance, Cramer-Rao bounds, linear minimum variance estimation, maximum likely-hood estimation, least square estimation- ordinary, recursive and weighted average method of moments, conditional mean estimation, maximum a posterior estimation. System identification: Classical methods, cost functions, gradient

techniques, identification using stochastic approximation, quasi linearization, invariant imbedding and sequential identification.

EEE 6003: Selected Current Topics in EEE Credit: 3 Contact Hours/week: 3 The respective instructor will determine the detailed syllabus.

EEE 6101: Energy Conversion Credit: 3 Contact Hours/week: 3 Energy conversion process; Direct electrical energy conversion; Electromechanical energy conversion; Electrical energy conversion from integrated renewable energy sources.

EEE 6102: Rural Energy System Credit: 3 Contact Hours/week: 3 Role of energy; Rural energy flow in developing countries; Energy demand-supply balance; Impact of rural energy flow on rural development and physical quality of life; Economic constraints for sustaining the energy flow; Rural energy system simulation for development planning.

EEE 6103: Renewable Energy Credit: 3 Contact Hours/week: 3 Solar constant, solar flux at the earth‟s surface, beam and diffuse solar flux, and solar beam angles. Direct methods of using solar energy, including solar-thermal, solar-thermal-electric, solar photovoltaic, and passive solar heating and lighting. Indirect methods of using solar energy, including wind turbines, hydro-electric, and biomass. Different manifestations of biomass utilization are discussed, including combustion and biofuels. Hydrogen production from renewable energy, and the use of hydrogen in heat engines and fuel cells.

EEE 6104: Unconventional Energy Sources and Energy Converters Credit: 3 Contact Hours/week: 3 Review of various energy sources. Importance of unconventional sources such as solar, biogas, wind, tidal etc. Study of typical energy converters such as high performance motors, special generators driven by biogas engines, wind turbines etc.Mini-hydrogenerators. Modern state-of-the art and futuristic systems in this area.

EEE 6105: Physical System Modeling Credit: 3 Contact Hours/week: 3 Development of conceptual framework for physical system; Transformation of physical system into mathematical form; Protection and prediction of system response; System stability analysis; Controlling the system response; Policy prescription for optimum system response.

EEE 6201 : Modern Control Theory. Credit: 3 Contact Hours/week: 3 General introduction; State space concept; System design by state transition. method, Concept of controllability and observability. Optional control variational calculus method; Principle of maximum and dynamic programming. Stochastic and adaptive control processes. On-line computer control.

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EEE 6202 : Introduction to Adaptive Control Credit: 3 Contact Hours/week: 3 The underlying adaptive control schemes including Lyapunov based direct adaptive control scheme, self-tuning regulator and model reference adaptive control. Least squares estimate and the relevant issues in relation with parameter adaptation. Intelligent control; some simple iterative learning control schemes. Case studies of various engineering control problems will provide insight and useful design guideline

EEE 6203 : Optimal Control Theory Credit: 3 Contact Hours/week: 3 The Optimal control problem. Cost functional. Use of calculus of variations in optimal control. Optimization by Pontryagin‟s maximum principle and dynamic programming; applications. Linear regulator problems. Computational methods of solving two-point boundary value problems.

EEE 6204 : Robust Control Systems Credit: 3 Contact Hours/week: 3 Linear Quadratic Regulators: return ratio & difference, sensitivity function. Kalman's optimality condition. Gain/phase margins, robustness to time delay and nonlinearity. Characterization of sensitivity. Kharitonov theorem robustness. Singular values - properties, application in stability, robustness and sensitivity. Robustness of discrete time Linear Quadratic Regulator (LQR) systems.

EEE 6205 : Digital Control theory Credit: 3 Contact Hours/week: 3 Discrete-time signals and systems, Z-transform, pulse transfer functions. Compensator design by root locus, error coefficients and frequency response. State-space models of discrete time systems, controllability, observability, stability, state estimation, Kalman filtering. Linear regulation. Parameter estimation.

EEE 6206 : Multivariable Control Systems Credit: 3 Contact Hours/week: 3 Multivariable Systems: multivariable systems descriptions, zeros, poles and stability, Interaction and input-output paring. System Performance: performance specifications, system uncertainties, robust stability and performance. Frequency Domain Design: sequential loop design, characteristic locus method, Nyquist Array method. Optimal Design: Linear quadratic control, H-infinity control, predictive control.

EEE 6207 : Microprocessor Based Industrial Control Credit: 3 Contact Hours/week: 3 Process Control Computer Systems : Minis, micros, classification by hardware features and software facilities, performance evaluation techniques. Characteristics of Digital Processors Organization, instruction set, characteristics for process control, input/output arrangements, addressing techniques, memory systems. Process Control System Software : Review of availability of process control languages, application packages, operating system for real-time process control. System Selection Criteria : Specification,

environment, hardware and software requirements. Maintenance, procurement procedures, cost/ performance/availability ratios. Development Tools : Development systems for micros, software tools, logic analyzer, cross assemblers and compilers, simulators, emulators, in-house vs. turn-key trade off.

EEE 6208 : Artificial Neural Networks Credit: 3 Contact Hours/week: 3 Introduction & Motivation; Biological Neural Networks and simple models; The Artificial Neuron Model; Hopfield Nets; Energy Functions and Optimization; Perceptrons & Threshold Logic machines; Multilayer Networks-their variants and Applications; Capacity of Mutilayer Networks; Backpropagation; Recurrent Nets; Tree Structured Networks; Unsupervised Learning; Hebbian Learning, Principal Component Analysis; Competitive Learning, Feature Mapping, Self Organizing Maps, Adaptive Resonance Theory. Hardware Realization of ANNs. Recent Trends and Future Directions.

EEE 6209: Neural Network and It's Applications Credit: 3.00 Contact Hours/week: 3 Learning theory: Concept of learning, human learning Vs machine learning, human brain and neurons, artificial neural network, Hebbian learning, issues in machine learning, perceptron's, learning rules, multilayer perceptron's, internal representation, back propagation, cascade correlation and counter propagation networks, information theorybased learning, Baysian learning, simulated annealing, Boltzman machine, decision tree learning, adaptive resonance theory (ART) networks, ART1, ART2, Fuzzy ART mapping (ARTMAP) networks, self organizing map (SOM), Kohonen's feature map, learning vector quantization (LVQ) networks, auto associative networks, Applications: Applications of neural networks, real world problem solutions, classification, prediction, forecasting, segmentation object recognition, etc.

EEE 6301: Advanced Power System Analysis Credit: 3 Contact Hours/week: 3 Algorithms for formation of bus admittance and impedance matrices. Power flow solutions : Gauss Seidel, Newton Raphson, Fast decoupled power flow. Short circuit studies. Sparsity exploitation in power system studies. Static equivalents for power systems. Concepts of security states and security analysis in power systems. State estimation in power systems, Voltage stability analysis.

EEE 6302: Power System Stability Credit: 3.00 Contact Hours: 3 General theory of power transfer limits; Stability problems, steady state stability limits, dynamic and transient stability analysis; representation of synchronous machines and system in different frames of reference; Governors and excitation control system in stability; Small oscillation analysis; Stability analysis of two-machine and multi-machine system; Stability under different types of faults; Analysis of large disturbance in power system; Methods of improving stability; State variable representation and application to stability study; Application of Lyapunov‟s function in transient stability analysis.

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EEE 6303: Advanced Power System Stability Credit: 3 Contact Hours/week: 3 Voltage Stability: P-V and Q-V curves; Static analysis, sensitivity and continuation method; Dynamic analysis, local and global bifurcations; Control area, Margin prediction; Stability of AC-DC systems, Stability Analysis: Lyapnov's criteria, Energy functions for detailed & reduced order models, Stability boundary.

EEE 6304: Optimization of Power System Operation Credit: 3 Contact Hours/week: 3 General Principle of Optimization its application to power system planning, design and operation. Probability analysis for bulk power security and outage data. Economic operation of power system, economic operation of thermal plants, combined thermal and hydro-electric plants. Theory of economic operation of interconnected areas. Development and application of transmission loss formulae for economic operation of power systems. Methods of optimum scheduling and dispatch of generator

EEE 6305: Power System Planning Credit: 3 Contact Hours/week: 3 Basic objective of power system planning; Generation expansion planning process. Electrical demand forecasting; Current demand forecasting approaches. Generating planning; economic analysis, expected energy generation, expected fuel cost, Booth-Baleriux cummulant and segmentation methods. Probabilistic simulation of hydro and energy limited units. Expected energy production cost of interconnected systems. Economic aspects of interconnection. Different aspects of load management; effect of load management of reliability on production cost. Joint ownership of generation.

EEE 6306: Computer Aided Power System Design Credit: 3 Contact Hours/week: 3 Load flow study for large power system, optimal power flow studies, DOMMEL and TINNEY‟s method, digital computer methods of calculation of system generation schedule, computer controlled dynamic performance.

EEE 6307 : Power System Reliability Credit: 3 Contact Hours/week: 3 Basic Probability Theory : Review of probability concepts. Probability distributions. Application of binomial distribution to engineering problems. Probability distribution in reliability evaluation. Network modeling and evaluation of simple and complex systems. System reliability evaluation using probability distributions. Frequency and duration techniques. Generation System Reliability Evaluation : Concept of LOLP and E(DNS) : Evaluation of these indices for isolated systems. Generation system. Reliability analysis using the frequency and duration techniques. Transmission System Reliability Evaluation: Evaluation of the LOLP and E(DNS) indices for an isolated transmission system. Distribution System Reliability Evaluation : Reliability analysis of radial systems with perfect and imperfect switching.

EEE 6308 : Power Systems Control and Instrumentation Credit: 3 Contact Hours/week: 3 Control of voltage, frequency and tie-line power flows, Q-v and P-f control loops. Mechanism of real and reactive power control.Net interchange tie-line bias control. Optimal, sub-optimal and decentralized controllers. Discrete-mode AGC. Time-error and inadvertent interchange correction techniques. On-line computer control. Distributed digital control. Data acquisition systems. Emergency control, preventive control, system wide optimization, SCADA.

EEE 6309 : Power Systems Transients Credit: 3 Contact Hours/week: 3 Origin and nature of transients and surges. Surge parameters of plant. Equivalent circuit representations. Lumped and distributed circuit transients .Line energisation and de-energisation transients. Earth and earthwire effects. Current chopping in circuit breakers. Short line fault condition and its relation to circuit breaker duty. Trapped charge effects. Effect of source and source representation in short line fault studies. Control of transients. Lightning phenomena. Influence of tower footing resistance and earth resistance. Traveling waves in distributed parameter multiconductor lines, parameters as a function of frequency. Simulation of surge diverters in transient analysis. Influence of pole-opening and pole recolsing. Fourier integral and Z transform methods in power system transients. Bergeron methods of analysis and the use of the EMTP package.

EEE 6310: Advanced Protective Relaying Credit: Contact Hours/week: 3 Advanced protective relaying, Basic protection schemes, relay terminology, relay as comparators, static relays, Application of solid state devices, differential relaying systems, distance relaying schemes, protection of multiterminal lines, new types of relaying criteria, special problems, digital protection.

EEE 6311 : Generalized Machine Theory Credit: 3 Contact Hours/week: 3 Primitive machine representation, generalized torque equation, Park's transformation, dc machine, induction machine and synchronous machine representation, Equivalent circuits and fault analysis.

EEE 6312: Reliability Analysis and Predication Credit: 3.00 Contact Hours: 3 Reliability concept:Concept of reliability, mean time to failure, mean time between failures, down time, up time, type of failure, burn in, useful life and wear out periods , debugging bathtub curve. Combinatorial reliability: Series, Parallel, k-out-of m configurations, reliability evaluation of complex system by inspection, event space, path- tracing, decomposition, cut-set and tie-set methods. Matrix methods, criticaldependentfailures. Failure models: Failure data, failure modes, reliability in semester of hazard rate and failure density, hazard models-constant hazard, linearly increasing and linearly decreasing hazard models and their comparison waybill model, exponential hazard, piece wise linear models. System reliability: System reliability evaluation of series, parallel k-out-of m, standby configurations in semesters of hazard rates. Approximation and bounds,

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meantime of failure, Markov models. Computer methods of analysis, analogue and digital simulation, Monte Car 10 methods. Reliability improvement: Component improvement. Redundancy concepts, component and system redundancy, redundancy in digital systems, comparison of active and standby redundancy.

EEE 6401: Power Electronics Converters I Credit: 3 Contact Hours/week: 3 Power semiconductor devices: Structure, characteristics, ratings and protection. Single phase and 3-phase line commutated converters: Fully-controlled, half-controlled and dual converters. converters with improved performance. Single phase and 3-phase AC controller. cycloconverters. Static VAR compensators.

EEE 6402: Power Electronics Converters II Credit: 3 Contact Hours/week: 3 PWM ac-dc converter, PWM dual converter, Cycloinverters, Hybrid resonant dc-dc converters, Inverters for induction heating, resonant dc link inverters, dc-dc converters with different commutation schemes, PWM inverters, Switching dc power supplies power conditioners and uninterruptible power supplies.

EEE 6403 : Electric Drives Credit: 3 Contact Hours/week: 3 Motor Load dynamics. starting, Braking and speed control of DC and AC motors. DC drives; converter and chopper control. AC drives; Operation of induction and synchronous motors from voltage and current inverters. Transfer function and stability analysis Slip power recovery. Pump drives using AC line controller and self-controlled synchronous motor drives. Case study of Industrial drives.

EEE 6404 : Modeling & Control of Electric Drives Credit: 3 Contact Hours/week: 3 Modeling of AC and DC motors. DC Drives; Cascade control structure, symmetric optimization of speed loop. AC Drives; self controlled synchronous motor drive, inverter and cycloconverter-fed drives. Scalar and Vector control schemes for speed and torque regulation, Drives for traction and other applications.

EEE 6405 : Power Electronics Applications In Power Systems Credit: 3 Contact Hours/week: 3 Basics of flexible AC transmission systems, controlled rectifier and energy storage plants, Tap changers and phase shifters, Thyristor controlled VAR compensation and series compensation, modern (synchronous link converter) VAR compensators, unified power flow controller (UPFC) and interline power flow controller, power quality conditioners, power electronics in power generation.

EEE 6501 : Integrated Circuit Technology Credit: 3 Contact Hours/week: 3 IC components - their characterization and design. Analysis and design of basic logic circuits. Linear ICs. Large Scale Integration. Computer simulation of ICs

and layout design. High Voltage ICs. GaAs MESFET and GaAs ICs. Failure, reliability and yield of ICs. Fault modeling and testing.

EEE 6502 : Linear and Digital IC Applications. Credit: 3 Contact Hours/week: 3 Linear IC applications, Combinational and sequential circuits; Available IC gates and flip-flops. Design of Combinatorial circuits using Karnaugh map; Counters and Shift registers; Active filters using OP Amps; Precision wave shaping circuits; Switching circuits using OP Amps, TTL and CMOS gates.

EEE 6503 : VLSI System Design Credit: 3 Contact Hours/week: 3 Emphasis on the synthesis based approach to VLSI Design. Relevant issues related to physical design automation such as placement, floor planning, routing and compaction are covered. Combinational & sequential logic synthesis issues and algorithms are discussed. Detailed coverage of HDLs and high level synthesis algorithms and issues.

EEE 6504 : Computer Aided VLSI Design Credit: 3 Contact Hours/week: 3 Hardware Description Languages; Verifying behaviour prior to system construction simulation and logic verification; Logic Synthesis PLA based synthesis and multilevel logic synthesis; Logic optimization; Logic Simulation Compiled and event simulators; Relative advantages and disadvantages; Layout Algorithms Circuit partitioning, placement, and routing algorithms; Design rule verification; Circuit compaction; Circuit extraction and post-layout simulation; Automatic Test Program Generation; Combinational testing D Algorithm and PODEM algorithm; Scan-based testing of sequential circuits; Testability measures for circuits.

EEE 6505 : Gaseous Electronics. Credit: 3 Contact Hours/week: 3 Introduction; Motion of gas particles. Excitation and Ionization of gases; Mobility, Diffusion, Recombination; Basic process of spark breakdown, Glow discharge, Are discharge, High frequency discharge, Tigger discharge. Electrical breakdown in vacuum; Triggered vacuum gap switches.

EEE 6506 : Biomedical Electronics. Credit: 3 Contact Hours/week: 3 The need to study biological instrumentation; biological amplifiers and their interfacing with electrodes for activity monitoring solid state transducers for pressure flow, temperature and other physiological parameters and related instrumentation for long-term use. Low power consuming circuits especially for implantable pace makers; drift problem and its compensation, telemetry of biologicalsignals. Digital signal processing and imagery-construction suitable for scanning, for example, CAT, PET, NMR and ultrasonics with a special reference to instrumentation principles.

EEE 6507: Laser Theory Credit: 3.00 Contact Hours/week: 3

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Black body radiation and the plank law. Stimulated and spontaneous emission, atomic and spectral line width. 3-level and 4-level atomic systems. Laser operation under steady state condition. Laser output coupling and power. Q switching and model locking. Line broadening mechanisms: Homogeneous and inhomogeneous broadening. Open resonator and Gaussian beam, stability criterion for optical resonators. Principles of operation of gas, solid state and semiconductor lasers.

EEE 6508: Carbon Nanomaterials and Technology Credit: 3.00 Contact Hours/week: 3 Carbon materials, tight binding calculation of molecules and solids, structure of carbon nanomaterials (2D graphene, 1D nanoribbons and single wall carbon nanotube), electronic structure, synthesis, transport properties, phonon modes, Raman spectra, Electric properties, challenges and opportunities for nanoscience and technology, carbon nanodevices.

EEE 6509: Advanced Solid State Electronics Credit: 3.00 Contact Hours/week: 3 Solid-state electronics in modern life, bonding and types of solids , types of crystals, crystals directions and planes, reciprocal lattice, allotropy, crystal defects and their significance, non-ideal crystal structures, brillouin zones, Fourier analysis of the basis. Electrons in solid: Classical theory, temperature dependence resistivity, Matthiessen‟s rule, temperature dependence of carrier concentration and drift mobility, scattering in semiconductors, velocity-electric field relations in semiconductors, carrier transport, carrier generation and recombination, optical processes in semiconductors. Coming of the quantum age. The electron as a wave, Schrodinger equation, a confined electron, Heisenberg‟s uncertainty principle. Band theory of solids, direct and indirect semiconductors, band structure of some semiconductors, electron effective mass, density of states; Statistics: Boltzmanclassical statistics & Fermi-dirac statistics, free electron model. Lattice vibration: Vibration of crystals with monatomic basis, two atoms per primitive basis, quantization of elastic waves, phonon momentum, inelastic scattering by phonons, phonon heat capacity, anharmonic crystal interactions, thermal conductivity. Scattering in semiconductors, velocity-electric field relations in semiconductors, carrier transport, carrier generation and recombination, optical process in semiconductors.

EEE 6601 : Information and Coding Theory Credit: 3 Contact Hours/week: 3 Entropy and mutual information, rate distortion function, source coding, variable length coding, discrete memory less channels, capacity cost functions, channel coding, linear block codes, cyclic codes. Convolution codes, sequential and probabilistic decoding, majority logic decoding, burst error-correcting codes.

EEE 6602 : Statistical Signal Theory Credit: 3 Contact Hours/week: 3 Representation of deterministic signals : Orthogonal representation of signals. Dimensionality of signal spaces. Construction of orthogonal basis functions. Time-bandwidth relationship : RMS duration and bandwidth, uncertainty relations. Random Processes : Definition and classification, stochastic integrals, Fourier transforms of random processes, stationary and non-stationary processes, correlation functions. Ergodicity, power spectral density, transformations of random processes by linear systems. Representation of random processes (via sampling, K-L expansion and narrow band representations), special random processes (white Gaussian noise, Wiener-Levy processes, shot-noise processes, Markov processes). Optimum Filtering : Matched filters for deterministic signals in white and colored Gaussian noise. Wiener filters for random signals in white and colored Gaussian noise. Discrete and continuous time filters.

EEE 6603 : Satellite Communication Credit: 3 Contact Hours/week: 3 Introduction. Historical background and overall perspective; Satellite network modeling ; Link calculations; FM analysis; TV Transmission; Digital modulation; Error control; Multiple access; FDMA, TDMA, CDMA. Orbital considerations; Launching; Atmospheric effects; Transponders; Earth Stations; VSATs.

EEE 6604 : Data Communication Credit: 3 Contact Hours/week: 3 Review of data communication techniques. Data transmission, line coding, error control coding. Data switching, circuit switching, message & packet switching. Network model ISO-OSI model, primitives and services. Elements of queuing. Data link control Simplex, pipelined and sliding window protocols, simplex performance analysis. X 25 data link layer. Random access techniques. Pure, slotted and finite population ALOHAs. Stability in ALOHAs. Routing and congestion control Static, adaptive, centralized and distributed routing procedures, congestion control. Local Area Networks LAN topologies and protocols, IEEE 802x protocols, implementation and performance issues. High speed LANs. Transport layer. Quality of service, transport classes. Design issues, buffer management, synchronization. Session and presentation layer synchronization issues, formatting, data compression, data security.

EEE 6605 : Cellular Mobile Communication Credit: 3 Contact Hours/week: 3 Mobile Radio Channel Modeling; Modulation Techniques; Cellular System Concepts; Equalization, Diversity and Channel Coding; Speech Coding; Multiple Access Techniques; Case Study: GSM, IS-95 and IMT2000 WCDMA.

EEE 6606 : Optical Fibre System Credit: 3 ContactHours/week:3 Semiconductor Physics - Radiative recombination. Light Sources: LEDs and Lasers. Light Modulators, Amplifiers, EDFA. Light Detectors: Photo diode, PIN, and APD.

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Optical fibers - Mode theories, multimode and single-mode fibers, attenuation, dispersion, other loss mechanisms. Advanced optical fibers, PCF, POF, their fabrication, properties and applications. Coupling and Splice, fault detections.

EEE 6607 : Advanced Optical Fibre Communication Credit: 3 Contact Hours/week: 3

Fiber optic transmitter and receiver. Link analysis. Line Coding. Coherent optical communication systems. Multiplexing schemes. Optical networks: Local area networks, FDDI, SONET and SDH. Fiber optic sensors and signal processing. Optical Amplifiers, SOA. Photonic Switching. Design solutions in optical fibers. Optical interconnects, FTTH.

EEE 6608: Advancced Digital Signal Processing. Credit: 3 Contact Hours/week: 3 Introduction discrete time systems, Z- transforms; Flow graphs and matrix representation of digital network. Wave digital filters, Discrete Fourier transform, Fast Fourier transform, Digital filter design.

EEE 6609: Digital Circuit Design Credit: 3 Contact Hours/week: 3 The course will present advance techniques of digital circuit design. It will concentrate on the design of sequential circuits, micro programming viewed as a sequential circuit and fault tolerant design. Basic review of Combinational circuit design using k-map, multiplexers and EPROMs. Introduction to sequential circuits; fundamental mode circuits. Concept of state, construction of state diagrams. Event driven circuits using RS latch, multiplexers and EPROMs Clock driven circuits using JK flip-flops, counters and EPROMs. Microprogramming and use of AMD 2909 microsequencer and sequential circuits. Reliable design theory and techniques. Some examples like Data Acquinition system, microprocessor peripheral interface, digital printer interface and DMA controller will be taken up.

EEE 6610: Digital Filter Design Credit: 3 Contact Hours/week: 3 Discrete time signals and systems Z transforms. Structures for digital filters. Designs procedures for FIR and IIR Filters.

EEE 6611: Digital Image Processing Credit: 3 Contact Hours/week: 3 Digital Image Fundamentals; Image Enhancement in Spatial Domain: Gray Level Transformation, Histogram Processing, Spatial Filters; Image Transforms: Fourier Transform and their properties, Fast Fourier Transform, Other Transforms; Image Enhancement in Frequency Domain; Color Image Processing; Image Warping and Restoration; Image Compression; Image Segmentation: edge detection, Hough transform, region based segmentation; Morphological operators; Representation and Description; Features based matching and Bayes classification; Introduction to some computer vision techniques: Imaging geometry, shape from shading, optical flow; Laboratory

exercises will emphasize development and evaluation of image processing methods.

EEE 6612: Spread Spectrum Communication Credit: 3.00 Contact Hours/Week: 3 Introduction of spread spectrum communication system, CDMA evolution, basics of digital communication , CDMA coding, forward error control coding in spread spectrum systems, link structure of CDMA, CDMA communication on fading channels, call processing and handoff, power control, CDMA RF hardware, repeater, and cellular networks, analysis of wireless link, common air interface (CAI) parameters, PN offset planning, W-CDMA.

EEE 6613: Statistical Modeling Credit: 3.00 Contact Hours/week: 3 Review of probability and random variables, probability distributions and densities, joint distributions of random variables, Markov chains, random processes, characteristics of queueing process, Poisson process and exponential distribution, Erlang distribution. Markov processes: Basic concepts, M/M/m, M/M/m/K and M/M/m/K/C queuing systems, elements of the queuing model, application of birth and death processes to queuing theory, steady-state solution, balance equation, network of exponential servers, generating function, solution of queuing problems. Traffic model: Traffic flow in wireless communication, traffic intensity, blocked traffic and the utilization of some queuing systems, traffic model for new call arrival rate and handover call arrival rate. Analysis of call priority schemes: Different priority schemes, calculation of blocking probability, and forced-termination probability.

EE 6614: Advanced Wireless Communication Credit: 3.00 ContactHours/week:3 Overview of advanced wireless technologies, standardization trends in wireless communication, evolution of wireless technologies, understanding of LTE and LTE-advanced communications, network technologies for IMT-advanced and LTE-advanced communications, QoS requirements and key challenging issues for 3G and 4G communications, Application of cognitive radio in 4G communications, service provisioning for 3G, 4G and 5G communications, QoS provisioning for 4G and 5G communications. Overview of mobile WiMAX and its network architecture, basic concept of femtocell and its network architecture, basic concept of visible light communication (VLC) and its network architecture; Introduction to N-screen technology.

EEE 6701 : Advanced Electromagnetic theory Credit: 3 Contact Hours/week: 3 Transmission line theory; Green's function and integral transform techniques; Wave propagation and polarization parameters; reflection and transmission across an interface; waveguides, cavity resonators, scattering by cylinders, wedges, spheres etc. Geometric theory of diffraction

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EEE 6702 : Antennas and Propagation Credit: 3 Contact Hours/week: 3 Review of the theory of electromagnetic radiation. Introduction to various antenna types wire, loop and helix antennas, analysis using assumed current distribution. Aperture antennas: slot, waveguide, horn, reflector and printed antennas. Analysis using field equivalence principle and Fourier transform methods. Linear arrays. Broadband antennas. Antenna measurements.

EEE 6703 : Computational Electromagnetics Credit: 3 Contact Hours/week: 3 Review of analytical methods: Separation of variables conformal transformation: Green's function. Finite difference method: Iterative solution: relaxation and acceleration processes: Finite difference time domain method (FDTD); different boundary conditions. Finite element method: Discretization of solution region: shape functions: element matrices and global matrix; method of solution. Method of moments; Basis functions; weighted residuals; method of least squares; numerical integration

EEE 6704 : Microwave Solid State Devices Credit: 3 Contact Hours/week: 3 Two terminal devices and circuits : Junction diodes PIN, Schottky, Varactor, tunnel diodes. Design and analysis of switches, limiters, phase shifters, modulators, harmonic generators and parametric amplifiers. Transferred Electron Devices-Gunn, LSA. Avalanche Transit Time Devices-IMPATT, TRAPATT and their circuits. Bipolars, JFET and MESFET. Design of oscillators and amplifiers

EEE 6705 : High-Power Microwave Devices Credit: 3 Contact Hours/week: 3 Microwave amplifiers and oscillators; Principle of generation of millimeter and sub-millimeter waves from FAST WAVE devices (including FELs and Electron Cyclotron Masers), SLOW WAVE devices (including Klystrons, Magnetrons Cerenkov Masers, BWOs, RDGs and NWCGs), and PLASMA devices (including VIRCATORS and reditrons). Details study of electromagnetic Slow Wave Systems. General Properties of Slow Wave Structures, Analysis of Cold Slow Wave structures, Interaction of Electron Beam with Electromagnetic Field supported by Slow Wave Structures.

EEE 6706 : Plasma Engineering - I Credit: 3 Contact Hours/week: 3 General Concepts of Plasma; Generation and Application of plasma; Single particle and collective nature of Plasma; Motion of charged particles in Electric and Magnetic Fields; Fluid Theory of Plasma; waves in unmagnetized and magnetized plasmas; Diffusion and resitivity of Plasma.

EEE 6707 : Plasma Engineering - II Credit: 3 Contact Hours/week: 3 Equilibrium and stability of Plasma. Electron beam interaction with plasma; amplifying wave and absolute instability, interaction in a one dimensional system (Longitudinal and Transverse interaction), interaction with cold plasma in systems of finite transverse dimensions.

EEE 6708: Relativistic Electron Beam Technology. Credit: 3 Contact Hours/week: 3 Introduction to REB; Generation of REB; Propagation of REB. Theory of particle acceleration in liner accelerator. Special theory of Relativity; Dynamics of relativistic particles and electromagnetic fields.

EEE 6709 : Fusion Science And Technology. Credit: 3 Contact Hours/week: 3 Introduction to Nuclear Fusion; Fusion reaction and fuel resources; Plasma confinement, Tokamak confinement physics; Thermonuclear devices based on pinch effect; Mirror like devices. Fusion technology; Plasma heating; Introduction to a commercial Tokamak Fusion Power Plant.

EEE 6801: Mordern Architecture of Microprocessors and Microcomputers Credit: 3 Contact Hours/week: 3 Internal organization of the Intel 8085, M6800, Z80, M6809, Rockwell 6502, Intel 8086/88, M6800 and Z8000 Microprocessors. Comparison of the architectures based on hardware feature such as addressing modes interrupt structures, instruction execution, multiprogramming abilities and memory management. Bit-Slice processors: Basic structure of control unit of a microprocessor. Organization of bit slice processors like AM2903 and Intel 3008 Comparison with microprocessor chips. Architecture of microcomputers like SDK- 85, HP 5032, SDK- 86, single chip microcomputer 8748, intelligent CRT terminal, microprocessor development system like Intellect series II and III, BBC- microcontrollers PLCS, graphics processors and floppy disk controllers; arithmetic processors like Intel 8087 and 80287; EET processors and arry processors.

EEE 6802 : Design and Organization of Microcomputer Systems and

Application. Credit: 3 Contact Hours/Week: 3 Number system: Floating point arithmetic. Organization of a small computer control unit and I/O structures. Various aspects of machine language, Assembly language and assemblers. Typical programmable and non programmable peripheral support LSI. Single chip microprocessor. Microprocessor based signal processing and control instrumentation. Microprocessor based system design.

EEE 6803 : Computer Simulation of Electrical and Electronic Circuits. Credit: 3 Contact Hours: 3 Hrs/Week DC analysis of liner network; solution of simultaneous, sparse, linear equations; DC analysis of nonlinear circuits, transient analysis of linear and nonlinear circuits, hybrid analysis. Circuit models for common semiconductor devices like BJT, MOSFET, thyristor. Macromodels for analog ICs like the opamp. Implementation of a general purpose circuit analysis program like SPICE.

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EEE 6804 : Computer in Electrical Engineering. Credit: 3 Contact Hours/week: 3 Prerequisite: Students will be required to have a general knowledge about microcomputers and database and spread sheet programs. They are also required to have a fair knowledge of programming in either C or Pascal. Use of microcomputers in different fields of electrical engineering for design, simulation, analysis etc. Demonstration program development in one of the above fields.

EEE 6805 : Computer aided instrumentation and sensor application Credit : 3 Contact Hours/week : 3 Review of different types of sensors and their operation characteristics, Signal conditioning and driver circuits, ADC and DAC applications, Signal multiplexing, interfacing techniques interfacing external circuit with pc, serial and parallel port, port programming, reading data from outside pc, sending data to port loop and closed loop instrumentation Practical examples dealing with linear and angular displacement, force, light, temperature and acoustic signals. introduction to different types of standard interfacing bus such as GPIB, HPIB IEEE488 etc.

EEE 6806 : Computer aided Optoelectronics application Credit : 3 Contact Hours/ week: 3 Elements of optoelectronics Light and laser Light, Laser system. Photo detectors, Radiometry and light coupling systems and applications, fiber optics telephone link, optical imaging using CCD cameras, Laser scanning camera, interfacing camera with pc.

EEE 6807 : Computer Aided Simulation of Physical Systems Credit: 3 Contact Hours/week: 3 Basic concept of simulation, system modeling simulation of continuous and time discrete system, queuing simulation, pert network, simulation software, simulation examples of some real life physical systems of different types.

EEE 6808: Applied Numerical Analysis Credit: 3.00 Contact Hours/Week: 3 Introduction: Numerical Analysis, errors. Parallel and distributive computing using standard software, matrices, matrix equations, complex numbers, polynomials, plotting; solution of linear algebraic equations: LV decomposition and its applications, tridiagonal and band diagonal system of equations, singular value decomposition; sparse. Linear systems, and QR decomposition; Special functions: Incomplete Gamma function, error function, and chi-square probability function, exponential integrals; interpolation and extrapolation Time series analysis, spline interpolation, interpolation in two or more dimension; Parametric curves: Cubic curves, Hermite curves, and Bezicr curves ; Function approximation: Least square approximation, power regression, exponential regression, exponential regression; Fourier and spectral applications: Fast Fourier transforms, convolution, deconvolution, correlation, and autocorrelation using FFT, wavelet transforms; Numerical differential and integration: Quadrature, composite quadrature, Gaussian quadrature, multiple

integrals, automatic integration, solution of ordinary and partial differential equations.

EEE 6901 : Behavior of Dielectrics Under High Voltage Credit : 3 Contact Hours / week: 3 Classification of Electric Field, Schwaiger factor, Numerical estimation of Electric Fields. Charge Simulation Method. Breakdown mechanism: Development of Avalanches Streamer and Leader Processed, arcs: Intrinsic and practical strength of dielectrics. Time required for inception of breakdown channel and again of solid dielectrics; Treeing process. Insulation properties of vacuum and gases other than air. Gas insulated systems.

EEE 6902 : Insulators for high voltage Credit : 3 Contact Hours/weeks : 3 Introduction, functions of insulators, classification, insulation materials, manufacturing processes of different insulators, terminal fitting of insulators, insulator life, contamination, testing of insulators, remedies of flashover, insulators for special application, hot-sticks.

EEE 6903 : High Voltage Power Equipment Engineering Credit : 3 Contact Hours/weeks : 3 Basic Concept of circuit interruption, Impulse characteristics and corona, Lightning, traveling wave propagation, lightning protective devices, design of lightning proof transmission lines, grounding, Insulator co-ordination.

EEE 6904 : Insulating properties of vacuum under high voltage Credit : 3 Contact Hours/weeks : 3 Review of breakdown mechanism in air uniform and non uniform field, micro discharges, factors affecting breakdown in vacuum, electrode gap, electrode materials, surface contamination, area effect, temperature effect, type of applied voltage, breakdown under dc, ac impulse voltage, frequency of applied voltage, Effect of pressure recovery of insulation property after breakdown, flash over across solid used in vacuum, Remedies.

EEE 6905: Insulating properties of SF6 under high voltage Credit : 3 Contact Hours/weeks : 3 General properties of SF6 review of breakdown mechanism in gas, breakdown mechanism in SF6 are interruption, current chopping in SF6 mixture of SF6 with other gases, SF, insulated equipments. SF6 circuit breakers, SF6 insulated underground cables, SF6 insulated substations, SF6 gas filling and handling plants, Insulation co-ordination in SF6 insulated substations, Future trends.

EEE 6906 : HVDC power transmission Credit : 3 Contact Hours/weeks : 3 DC power transmission technology, HVDC converters system control, faults and protection, smoothing reactors, reactive power control, multi terminal dc system, analysis of ac/dc dynamic simulation of converters and dc systems.

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