UVCE 2K6 EEE Syllabus

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REGULATIONS GOVERNING THE B.E. DEGREE COURSES(2K6 -SEMESTER SCHEME)

EFFECTIVE FROM AUGUST 2006

A. TITLE AND DURATION OF THE COURSESA.1 The courses governed by AICTE shall be called the Degree Course in Bachelor of Engineering, in-short, BE and the course governed by Council of Architecture shall be called the Degree Course in Bachelor of Architecture, in short B.Arch.

A.2 The Courses governed by AICTE shall be of four academic years duration or 8 semesters and the course governed by Council of Architecture shall be of five academic year’s duration or 10 semesters. The duration of each semester is 16 weeks. The scheme of study and examination for 1 Year (I & II Semesters) will be the same for all the branches of Engineering under AICTE, except for Architecture branch.

A.3 The Calendar of events in respect of the course shall be as fixed by the University from time to time.

A.4 Examination in all the subjects of all the eight semesters of B.E. and 10 semesters of B.Arch will be conducted after the end of each semester, except when there are no candidates appearing for any subjects.

B. ADMISSIONSB.1. a) Admission to the First Year Course through Common Entrance Test / Aptitude test conducted by appropriate bodies of Government of Karnataka shall be open to student who have passed (i) The Two Years Pre-University Examination conducted by the Karnataka State Pre-University Board and (ii) Plus Two C.B.S.E. or I.C.S.E. with Physics, Chemistry and Mathematics as optional papers and English as a paper of study or any other examination recognized by the University as equivalent thereto.

b) Candidates belonging to all categories shall have secured a minimum of 35% percent marks in the aggregate of the three optional papers i.e. Physics, Chemistry, and Mathematics of Second Year of the qualifying Examination or at the Public Examination held at the end XII Year to be considered eligible for admission to first year B.E or B.Arch. by the University.

B.2 a) B.Sc., Graduates are also considered for admission to First Semester through Common Entrance Test / Aptitude test conducted by appropriate bodies of Government of Karnataka if they have secured a minimum of 50% marks in the aggregate of (i) Physics, Chemistry and Mathematics, (ii) Physics, Mathematics and Electronics (iii) Physics, Mathematics and Computer Science at the B. Sc. Examination. However, in case of Schedule Caste and Schedule Tribes or any other group classified by Government of Karnataka for such purposes the percentage of the aggregate - marks in the specified group of subjects shall not be less than 40%

b) Diploma holders in Architecture granted by the Board of Technical Examination in Karnataka or Equivalent who have obtained not less than 50% of the total maximum marks in the final examination leading to the said Diploma, provided that the minimum marks for the purpose of qualification specified above shall not be less than 35% in the case of candidates belonging to Scheduled Castes, Scheduled Tribes and Backward Tribes, or any other groups classified by the Government of Karnataka for such purposes, in the appropriate branch.

B.3 Diploma holders in appropriate Branch of Engineering granted by the Board of Technical Examination in Karnataka or equivalent who have obtained not less than 50% of the total maximum marks in the final examination leading to the said Diploma, are considered for admission to III Semester of Day and Evening courses of appropriate branches of Engineering. In case of candidates belonging to Schedule Castes, Schedule Tribes and Backward Tribes or any other group classified by the Government of Karnataka, the percentage of marks obtained should not be less than 40%.

Note : Students admitted on the basis of B.2 and B.3 are not eligible for exemption in any of the subjects of B.E. Degree Course or B.Arch.

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B.4 a) I) All the candidates irrespective of quota / category to which they belong to and admitted to UVCE at I Semester and III Semester of any branches or transferred to UVCE from any other University shall pass the following Audit subjects.

i) Kannada ii) Environmental Studies iii) Communication Skills and Technical Report Writing and iv) Indian Constitution

II) All the candidates irrespective of quota / category to which they belong to and admitted to UVCE at I Semester and III Semester of B.Arch or Transferred to UVCE from any other University shall pass the audit subject Kannada.

Each Audit subject shall be assessed for an Internal assessment marks of 50.The Internal assessment marks shall be based on 2 tests. The tests will have to be answered in “Blue Books”.

Provision is made for an additional test to be conducted at the end of the Semester to provide an opportunity to the student to improve the internal assessment marks, with the permission of the Departmental Chairman.The average of the marks obtained for any two tests and converted to 50 marks should be chosen for the award of internal assessment marks to the advantage of a student.If a candidate is absent to all the tests conducted, the internal assessment marks awarded will be zero.All audit subjects are considered as “Sessional subject” for which a student has to obtain a minimum of 20 out of 50 marks.

If a student fails to satisfy the sessional requirement of the audit subject, he / she can make it up during the next academic semester, with the consent of the Staff teaching the Audit subject and Chairman, to which the concerned candidate belongs to. A student shall attend a minimum of 75% of the total number of classes held in each of the audit subject. In case the candidate fails to attend 75% of the class held in audit subject, he / she will attend the same during the next academic year along with regular students.

Separate consolidated marks card inrespect of audit subjects shall be issued to the candidate, qualified for the degree of Engineering or B.Arch along with VIII Semester marks card in case of Engineering courses and X Semester marks card in case of Architecture course.

b) All the candidates admitted to III Semester of Engineering courses under Diploma quota have to complete the Bridge course subjects Mathematics I & Mathematics II before getting admitted to VII Semester. Those candidates admitted to III Semester Day and Part Time B.E Mechanical Engineering course have to complete one more Bridge course subject “Basic Electronics & C Programming”. Along with this condition the candidates have to satisfy regulation under H-Promotions and Eligibility for Examination.

C. REGISTRATION TO COURSE./EXAMINATION

C.1 Every candidate should register for each semester before the reopening of the Semester by paying the prescribed tution and other fees without fine and within the next two weeks by paying the prescribed fine.

C.2 Registration to University Examinations.(i) A candidate shall register for all the examination papers of that semester in which he is currently studying.

D. ATTENDANCE

D.1 A candidate shall undergo the prescribed course of study in the University Visvesvaraya College of Engineering, Bangalore University.

D.2 A student shall attend a minimum of 75% of the total number of classes held in each of the subject (Theory, Drawing and Practical) in each Semester.

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D.3 A candidate not obtaining 75% of the attendance as stated in D.2 shall not be permitted to take the concerned semester examination.

D.4 Candidate having less than 75% attendance in any subject have to repeat that particular semester along with the regular students of that semester during next academic year.

D.5 The basis for the calculation of attendance shall be the period prescribed by the University by its calendar.

E .INTERNAL ASSESSMENTE.1 whether theory or practical each paper shall have an internal assessment (IA) Marks as mentioned in the Scheme of study.

E.2 a) The I.A. marks in a theory paper shall be based on two tests, normally conducted during the 8th and 12th week of each semester as per the calendar of events fixed by the University. The tests will have to be answered in 'Blue Books' with Pages serially numbered. b) Provision is made for an additional test to be conducted at the end of the semester to provide an opportunity to the student to improve the Sessional marks, with the permission of the Departmental Chairman / Chairperson.

c) The average of the marks obtained from any two tests shall be chosen for the award of Sessional marks, to the advantage of a student. d) If a candidate is absent in all the tests, the Internal Assessment Marks will be awarded as zero in that paper.

E.3. In the case of practicals and drawings, 60% of the Internal assessment marks shall be assessed by the work done in the respective classes and Laboratory Record/ Drawing / Workshop models and Diary submitted thereon and 40% of the Internal Assessment marks by a test. In respect of Architecture Course 80% of the Internal assessment Marks shall be assessed by the work done in the class and 20% by a test.

E.4. Internal Assessment marks in case of Project Work, extensive Survey project and Educational Tours are to be awarded by the concerned teachers/guides and are also considered as Sessional subject for which a student has to obtain a minimum of the Internal Assessment marks as mentioned

of 25 and 25 out of 50) and as in E.6 (b).

E.5. The Internal Assessment marks awarded shall be displayed on the notice board of the respective Department latest by two weeks after the end of the semester and, certified copy with any corrections incorporated shall be forwarded to the University authorities as specified. The students are advised to maintain the blue books till one month from the date of announcement of results by the University.

E.6 ELIGIBILITY

a) There is no separate minimum requirement of I.A marks in each theory subject to be eligible to appear for the semester examination of Engineering courses. The minimum Class marks required in each subject is 50% of the Internal Assessment marks to appear for the examination of the Concerned Semester of Architecture Branch.

b) However, the minimum Sessional requirement specified in each of the Practicals, Drawing, project work, extensive survey projects and project tours is 50% of the Internal Assessment marks as mentioned in the Scheme (12 out of 25 marks) to be eligible to appear for the examination of the concerned semester.

c) Those students who fail to get the minimum Sessional I.A marks in anyone of the paper as per E.6 (b) is declared to have Not Satisfied the Session Requirements (NSSR) and is not permitted to go to the next Semester and also not permitted to appear for that Terminal Examination. To continue the course, they have to repeat the entire course work of that semester along with the regular students during the next academic year.

2K6 SYLLABUS

4F. MINIMUM FOR PASS, DECLARATION, AND CLASSIFICATION OF RESULTS

F.1. a) For a pass in semester a candidate shall secure a minimum of 35% of the marks prescribed for each paper in the University Examination (Theory, Practical, Drawing, Project work, Viva Voce etc.) and 40% marks in the total aggregate of all papers and their internal Sessional marks prescribed for that semester in the first appearance.

b) For a Pass in each subject a candidate of Architecture course shall secure a minimum of 35% of the marks prescribed for a subject in the University Examination (Theory, Practical, Drawing, Project work, Viva-Voce etc) and 40% in overall aggregate of marks of all subjects put together (including Class marks or Internal assessment, Viva-Voce, Practical and Theory exam)

F.2. Those students who pass in all the papers as stated in F.1 but fail to get the aggregate percentage of marks are declared to have failed in the examination. However, they may be permitted to withdraw only theory subjects to make up the deficiency in aggregate. F.3. The candidates who do not satisfy F.1 shall be deemed to have failed and have to appear in the failed papers at the University Examination on the next occasion. There will however, be no change in the internal marks allotted to the candidate, except when the student repeats the semester as provided in E.6 (b) or F.4.

F.4. Provision is made for one and only one rejection of results of all the papers in each semester if the candidate decides to reappear for all papers of that - semester. Such rejection should be made within 30 days of announcement of result, by making a written application through the Principal of the College, to the Registrar (Evaluation).

If such rejection is in respect of the results of all the papers of one semester, he will have the option to repeat his studies for that semester and earn fresh internal Assessment marks as well and gets the benefit of first appearance. The earlier rejection of the results however cannot be revoked.

F.5. The results of any semester will be declared as passed or failed as the case may be in accordance with Regulation F.1

F.6. To be eligible for the award of the B.E. Degree in any branch or B.Arch, a candidate shall have completed the scheme of training and passed in all papers prescribed for the course.

F.7. Further to regulation F5, the following classification will be made in the declaration of results (i) of each semester and (ii) the final declaration of successful candidates for the degree course.(1) First Class with Distinction(2) First Class and(3) Second Class

F.8. a) For the declaration of class of each semester, the marks obtained by the candidate in the first appearance for that semester will be taken into account except as per clause F.4

b) Those students who pass all the papers of a semester in the First appearance as per the Regulation F.1 and also secure not less than 70% of the aggregate marks will be declared to have passed that examination in 'First Class with distinction'.

c) Those students who pass all the papers of a semester in First appearance as per Regulations F.1 and also secure 60% and above but less than 70% of the aggregate marks will be declared to have passed that examination in First Class. Also those students who fail in one or more subjects but passes in those subject(s) subsequently and secure 60% and above but less than 70% of the aggregate marks at the first appearance will be declared to have passed in First Class.

d) All the remaining successful candidates who pass all the papers of semester as per Regulation. F.1 will be declared to have passed in Second class.

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F.9. For the final declaration of successful candidates for the entire course, marks obtained by a candidate in the first appearance taking all the papers of VII and VIII semester Examinations will be considered for declaration of class as follows.

a) Candidates who secure 70% and above marks in the aggregate of VII and VIII Semesters, and also pass in all the papers of VII & VIII semester in First appearance subject to regulation F. 7. Will be declared to have passed the BE Degree Examination in First Class with Distinction and will be indicated in the degree certificate. b) Candidates who secure 60% and above but less than 70% marks in the aggregate of VII and VIII Semesters in First appearance subject to Regulation F.7 will be declared to have passed the B.E. Degree Examination in First Class and will be indicated in the degree certificate. (As in F.8. c above)

c) All other successful candidates satisfying Regulation F.1 and F.6 will be declared to have passed B.E. Degree Examination in Second Class.

d) Candidates who secure 70% and above marks in the aggregate of VII to X Semesters, and also pass in all the papers of VII to X semesters in First appearance subject to regulation F. 7. Will be declared to have passed the B.Arch Degree Examination in First Class with Distinction and will be indicated in the degree certificate. e) Candidates who secure 60% and above but less than 70% marks in the aggregate of VII to X Semesters in First appearance subject to Regulation F.7 will be declared to have passed the B.Arch. Degree Examination in First Class and will be indicated in the degree certificate. (As in F.8. c above)

F.10 RANK DECLARATION1. Only those students who pass all the semesters prescribed for the course in First Class are eligible for

the declaration of the Rank.2. The Ranking is done based on the cumulative total of all the aggregate marks (inclusive of I.A. marks)

scored in each of the semesters prescribed for the course. 3. Only first 10 ranks are declared for each branch.

F.11. MEDALS AND CERTIFICATESMedals and certificates are given to only those who become eligible for the award of the degree as per the conditions stipulated in each case of such award.

G. BENEFITS OF EXEMPTION

In case a candidate who pass all the subjects by scoring 35% in each subject but fails to get 40% in aggregate is permitted to withdraw only few theory subjects to make up 40% of marks in aggregate.

H. PROMOTIONS AND ELIGIBILITY FOR EXAMINATION

H.1 An academic year consists of Odd and Even Semester. A candidate is eligible for promotion to next academic year (starting with an Odd Semester) provided the candidate has not failed in more than 4 papers of the two semesters of the just previous academic year and has completed all papers of the examinations lower to the previous year. Not withstanding E6(c), there is total mobility from the Odd to the Even Semesters of any particular academic year. As an example, a candidate seeking eligibility to VII Semester should have passed all the papers up to and including IV Semester and should 'not have failed in more than 4 papers of V and VI Semester put together.

H.2. Candidates not covered by Regulation H.1 are not eligible for promotion to the next Semester till they qualify under regulation H.1

H.3. A candidate, who does not obtain eligibility to enter III Semester with in a period of three consecutive academic years from the date of admission, has to discontinue the course.However the candidate may get re-admitted to the I Semester of BE. Degree course of the University to continue the course.

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I. TRANSFER OF STUDENTS

1. Subject to the conditions like intake and approval by the University, Change of branch is allowed to III Semester only provided the candidate seeking the Change of branch has passed in all the papers of the I & II Semester of Engineering courses of UVCE.

2. Transfer of students from any other Universities of Karnataka State to Bangalore University will be permitted to the same branch only at the beginning of III Semester or V Semester and not beyond, provided he/she has passed in all the papers of the earlier semesters.

In addition he/she should get academic clearance from Dean Faculty of Engineering, Bangalore University, Bangalore who may suggest any additional papers to be studied by the candidate if necessary.

3. A candidate seeking transfer from another University under Regulation I.1 should have cleared all the subjects of the previous years/semesters prescribed by parent University and produce a certificate to that effect from the University Registrar before seeking transfer.

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Proceedings Extract of the meeting of the faculty of Engineering held on 23-05-2006 at 11.30 AM in the Seminar Hall, UVCE, KR Circle, Bangalore

Resolutions:

A. To stagger the subjects a) Physics – Theory & Practical b) Chemistry – Theory & Practical c) Mechanical Engineering Science & d) Workshop Practice, as shown below,

Branch Subjects to be studied duringI Sem II Sem

Civil, Mechanical and Electrical

Physics TheoryPhysics Practical Workshop Practice

Chemistry TheoryChemistry Practical Mechanical Engineering Science

Electronics, Computer Science & Engineering and Information Science Engineering

Chemistry TheoryChemistry Practical Mechanical Engineering Science

Physics TheoryPhysics Practical Workshop Practice

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BANGALORE UNIVERSITY

SCHEME OF STUDY AND EXAMINATION FOR I & II SEMESTER OF ALL ENGINEERING COURSES

2K6 SCHEME(EFFECTIVE FROM AUGUST 2006)

I SEMESTER

Sl No

Code No. Subject No. of Hr/weekTheory Pract

Duration of Exam

Theory Pract

Class / Sessional

Marks

Exam Marks

1. 6SM1101 Engineering Mathematics I 4 - 3 - 25 1002. 6CE1101 Engineering Mechanics 4 - 3 - 25 1003. 6EE1101 Electrical Sciences 4 - 3 - 25 1004. 6SP1101/

6SC1101Engineering Physics / Engineering Chemistry

4 - 3 - 25 100

5. 6SP1102/ 6SC1102

Physics lab / Chemistry lab - 3 - 3 25 100

6. 6CI3101 Programming in C 4 - 3 - 25 1007. 6CI3102 C Programming lab - 3 - 3 25 1008. 6EM1101/

6EM1102Mechanical Engineering Science / Workshop Practice

4/3 3 25 100

TOTAL200 800

1000

II SEMESTER

Sl No.

Code No. Subject No. of Hr/week Theory Pract

Duration of Exam

Theory Pract

Class / Sessional

Marks

Exam Marks

1. 6SM1201 Engineering Mathematics II 4 - 3 - 25 1002. 6CE1201 Strength of Materials 4 - 3 - 25 1003. 6EC1201 Basic Electronics 4 - 3 - 25 1004. 6SP1101/

6SC1101Engineering Physics / Engineering Chemistry

4 - 3 - 25 100

5. 6SP1102/ 6SC1102

Physics lab / Chemistry lab - 3 - 3 25 100

6. 6EM1201 Engineering Drawing - 3 3 - 25 1007. 6EM1202 Computer Aided Drafting (lab) - 3 - 3 25 1001. 6EM1101/

6EM1102Mechanical Engineering Science / Workshop Practice

4/3 3 25 100

TOTAL200 800

1000

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III SEMESTERSl No

Code No. Subject Teaching Department

No. of Hr/weekTheory Pract

Duration of Exam

Theory Pract

Class / Sessional

Marks

Exam Marks

Total Marks

1. 2K6SM301 Engineering Mathematics – III

Mathematics 4 - 3 - 25 100 125

2. 2K6EE301 Analog Electronic Circuits-I

EE 4 - 3 - 25 100 125

3. 2K6EE302 Electric Circuits EE 4 - 3 - 25 100 1254. 2K6EE303 Electrical

Machines I (DC Machines & Transformers)

EE 4 - 3 - 25 100 125

5. 2K6EE304 Electrical & Electronics Measurements

EE 4 - 3 - 25 100 125

6. 2K6EE305 Electronics laboratory I

EE - 3 - 3 25 100 125

7. 2K6EE306 Electrical Machines laboratory I

EE - 3 - 3 25 100 125

8. 2K6EE307 Electrical Circuits & Measurements laboratory

EE - 3 - 3 25 100 125

TOTAL 200 800 1000

IV SEMESTERSl No.

Code No. Subject Teaching Department

No. of Hr/week Theory Pract

Duration of Exam

Theory Pract

Class / Sessional

Marks

Exam Marks

Total Marks

1. 2K6SM401 Engineering Mathematics – IV

Mathematics 4 - 3 - 25 100 125

2. 2K6EE401 Analog Electronic Circuits-II

EE 4 - 3 - 25 100 125

3. 2K6EE402 Micro Electronics EE 4 - 3 - 25 100 1254. 2K6EE403 Signals and

Systems EE 4 - 3 - 25 100 125

5. 2K6EE404 * Object Oriented Programming Using C++

EE 4 - 3 - 25 100 125

6. 2K6EE405 Electrical Machines II (Induction Machines & Synchronous machines)

EE 4 - 3 - 25 100 125

7. 2K6EE406 Electrical Machines Laboratory II (Induction & Synchronous)

EE - 3 - 3 25 100 125

8. 2K6EE407 Electronics laboratory II

EE - 3 - 3 25 100 125

TOTAL 200 800 1000* NOTE: LAB PRACTICE-OBJECT ORIENTED PROGRAMMING USING C++ MARKS 15 OUT OF 25

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10V SEMESTER

Sl No.

Code No. Subject Teaching Dept


Duration of Exam

Theory Pract

Class / Sessional

Marks

Exam Marks

Total Marks

1. 2K6EE501 Control Systems Engineering

EE 4 - 3 - 25 100 125

2. 2K6EE502 Electrical Machine Design

EE 4 - 3 - 25 100 125

3. 2K6EE503 Transmission & Distribution

EE 4 - 3 -- 25 100 125

4. 2K6EE504 Power Electronics

EE 4 - 3 - 25 100 125

5. 2K6EE505 E M F Theory EE 4 - 3 - 25 100 1256. 2K6EE506 Electrical

Drawing EE 4 - 4 - 25 100 125

7. 2K6EE507 Power Electronics laboratory

EE - 3 - 3 25 100 125

8. 2K6EE508 Circuits and Control Simulation lab

EE - 3 - 3 25 100 125

TOTAL 200 800 1000

VI SEMESTERSl No.



Duration of Exam

Theory Pract

Class / Sessional

Marks

Exam Marks

Total Marks

1. 2K6EE601 Micro Processor & Micro Controller

EE 4 - 3 - 25 100 125

2. 2K6EE602 H V Engineering EE 4 - 3 - 25 100 1253. 2K6EE603 Advanced Control

Systems EE 4 - 3 - 25 100 125

4. 2K6EE604 Communication Systems

EE 4 - 3 - 25 100 125

5. 2K6EE605 AC / DC Drives EE 4 - 3 - 25 100 1256. 2K6EE606 Computer

Organization & Design

-- 4 - 3 - 25 100 125

7. 2K6EE607 Industrial Drives laboratory

EE - 3 - 3 25 100 125

8. 2K6EE608 Micro Processor & Micro Controller laboratory

EE - 3 - 3 25 100 125

TOTAL 200 800 1000

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VII SEMESTERSl No.



Duration of Exam

Theory Pract

Class / Sessional

Marks

Exam Marks

Total Marks

1. 2K6EE701 Power System I EE 4 - 3 - 25 100 1252. 2K6EE702 Non

Conventional Energy Sources

EE 4 - 3 - 25 100 125

3. 2K6EE703 Switch Gear & Protection

EE 4 - 3 - 25 100 125

4. 2K6EE704 Digital Signal Processing

EE 4 - 3 - 25 100 125

5. Elective I -- 4 - - - 25 100 1256. 2K6EE706 Power Systems

laboratory I EE - 3 - 3 25 100 125

7. 2K6EE707 DSP laboratory EE - 3 - 3 25 100 1258. 2K6EE708 Estimation,

Economics & Management

EE 4 - 3 - 25 100 125

TOTAL 200 800 1000

Elective I2K6EE705.1 Illumination Engineering 2K6EE705.2 Embedded System Design2K6EE705.3 Operating Systems 2K6EE705.4 Web Technologies2K6EE705.5 Digital Control Systems 2K6EE705.6 Linear Induction Motors2K6EE705.7 Advanced Electrical Machinery 2K6EE705.8 Programmable Logic Controllers

VIII SEMESTERSl No.



Duration of Exam

Theory Pract

Class / Sessional

Marks

Exam Marks

Total Marks

1. 2K6EE801 Power Electronics in Industry

EE 4 - 3 - 25 100 125

2. 2K6EE802 Power System II EE 4 - 3 - 25 100 1253. 2K6EE803 HVDC & FACTS EE 4 - 3 - 25 100 1254. 2K6EE804 Utilization of

Electric Power EE 4 - 3 - 25 100 125

5. Elective II EE 4 - 3 - 25 100 1256. 2K6EE806 Project Tour &

Industrial visit EE Project Tour involving visit to

Industries, Substations/Receiving stations, Hyde plant, Thermal plant and Nuclear plants within the state is for a duration not exceeding 5 days

50 -- 50

7. 2K6EE807 Power Systems laboratory II

EE - 3 - 3 50 100 150

8. 2K6EE808 Project laboratory EE - 3 - 3 50 100 1509. 2K6EE809 Seminar EE 3 hrs/week 25 - 25

TOTAL 300 700 1000

Elective II2K6EE805.1 Artificial Intelligence & Expert Systems 2K6EE805.2 Neural Network & Fuzzy Logic2K6EE805.3 Resonant Converters 2K6EE805.4 Computer Graphics2K6EE805.5 Power System Operation & Controls 2K6EE805.6 Transducers & Signal Conditioning2K6EE805.7 Energy Management & Auditing 2K6EE805.8 Power Supply System Design2K6EE805.9 Micro Electronics & Mechanical System 2K6EE805.10 Data Communication

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2K6 SYLLABUSI Semester B.E

6SM1101 ENGINEERING MATHEMATICS –I

(Common to Civil, Mechanical, Electrical, Electronics, Computer Science & Information Science)

Hours/Week: 4 Exams: 3 hrsTotal: 60 hrs Exam Marks – 100

PART - A Differential Calculus

Unit-I: Successive Differentiation:nth derivative of standard functions, Leibnitz theorem(without proof) and problems, Polar curves and angle between two polar curves, Pedal equation of polar curves 8hrsUnit-II: Rolle ’s Theorem, Lagrange and Cauchy mean value theorem (Geometrical meaning), problems, Taylor’s theorem for a single variable and Maclaurin’s expansion (Without proof), problems.

7hrsUnit-III: Partial differentiation: First and higher order derivatives, Euler’s theorem, Total differentiation, Differentiation of implicit functions and composite functions, Jacobians. 7hrsUnit-IV: Integral Calculus:Standard reduction formulae for definite and indefinite integrals, Tracing of standard curves, Cartesian and polar curves- Catenary, cissiod, Stropoid, Lemniscate, Astriod, Cycloid, Folium of Descartes, Three and four leaved roses. 8hrs

PART - BUnit-V: Differential Equations:Solutions of ordinary differential equations of first order and first degree: Homogeneous forms, Linear and Bernoulli equations, Exact and reducible to exact equations, using standard integrating factors- Orthogonal trajectories in Cartesian and polar forms. 8hrsUnit-VI: Infinite series:Convergence, Divergence and Oscillation of an infinite series, De Alembert’s ratio test, Cauchy’s root test, Raabe’s test (without proof) for series of positive terms, Alternating series, Absolute and conditional convergence, Leibnitz’s test (without proof) Summation of Binomial, Exponential and logarithmic series. 7hrsUnit-VII: Analytical Geometry in three dimensions:Cartesian co-ordinates in 3 dimensions- distance and division formulae- direction ratios and direction cosines- angle between direction cosines- angle between two lines. 7hrsUnit-VII: Equation of plane in different forms, Perpendicular distance of a point from a plane- angle between two planes , line of intersection of two planes, planes co-axial with given plane, equation of lines in different forms, perpendicular from a point onto a line, angle between a line and a plane, co-planarity of two lines, shortest distance between lines. 8hrs

Text Books:1. B. S. Grewal, “Higher Engineering Mathematics” 36th Edition, 2001, Khanna Publishers, Delhi.2. E. Kreyszig, “Advanced Engineering Mathematics” 8th Edition, 2004, John Wiley and sons.

Note: Question paper shell contain 8 questions, one question from each unit. Five questions to be answered choosing atleast 2 from each part.

2K6 SYLLABUS


6CE1101 ENGINEERING MECHANICS(Common to all branches except B.Arch)

Hours/Week : 4 Exam : 3 hrsTotal : 60 hrs Exam Marks – 100

PART A1. Introduction to Body forces, Surface forces, particles, rigid body, force and its characteristics,

principles of transmissibility of a force, system of forces, components of a force, Moment of a force, Moment of a force with respect to a point, couple, effect of force at another point, equations of static equilibrium, support conditions, free body diagrams 8 Hrs

2. Coplanar Concurrent force System: Resultant and equilibrium of coplanar concurrent forces, coplanar parallel forces, coplanar non-concurrent forces, force polygon and funicular polygon. Varignon’s Theorem, reactions of statically determinate beams subjected to various types of loads. 10 Hrs

3. Centroid and Center of gravity: First moment of area and centroid of simple geometric areas (from first principles) and composite areas (built up sections). Second moment of area, polar moment of inertia, and radius of gyration, product of inertia, parallel axes theorem, perpendicular axes theorem, moment of inertial of simple geometry (from first principles) and composite areas (built up sections). 8 Hrs

4. Trusses: Introduction, classification of trusses as simple, compound and complex. Analysis by the method of joints and method of sections. 6 Hrs

PART B5. Friction: Introduction, laws of dry friction, limiting friction, co-efficient of friction, angle of

friction, angle of repose. Equilibrium of a block on (horizontal, inclined plane), Equilibrium of block & wedge and equilibrium of ladder. 8 Hrs

6. Basic principles of dynamics: Kinematics and kinetics. Kinematics of rectilinear motion with uniform and variable acceleration. Kinematics of curvilinear motion, in vertical plane, equation to the path of projectile. 8 Hrs

7. Kinetics of rectilinear motion, Dynamic equilibrium, equations of equilibrium, kinetics of curvilinear motion, centrifugal force, banking and super elevation. 8 Hrs

8. Work and Energy: Kinetic and potential energy, principles of work and energy, work done by force on spring. Work done by a force, couple. Principle of Virtual Work 4 Hrs

References:

1. Hibbeler, R.C., Engineering Mechanics, Statics & Dynamics, Prentice Hall, New Jersey, Ninth Edition, 2001.

2. Beer & Johnston, Mechanics for Engineers, Statics & Dynamics, and McGraw Hill Book Company, New York, Third edition, 1998.

3. Merriam, J.L., Engineering Mechanics, Statics and Dynamics, John Wiley & Sons, New York, 1980.

4. Jindal, U.C., Engineering Mechanics, Statics – I, Galgotia Publication Pvt. Ltd., New Delhi, Second edition, 2003.

5. Jindal, U.C., Engineering Mechanics, Dynamics – II, Galgotia Publication Pvt. Ltd., New Delhi, Second Edition, 2004.

Question paper pattern :The question paper consists of 8 questions of 20 marks each.The students have to answer 5 full questions, selecting at least two questions from each PART.

2K6 SYLLABUS

14


6EE 1.01 ELECTRICAL SCIENCES(Common to all branches except B.Arch)


PART A

1. ELECTROMAGNETISM: Faraday’s laws of Electromagnetic induction, Lenz’s law, Concept of Inductance – Self and mutual, Inductance as a circuit element. 4 hrs

2. DC CIRCUITS: Concept of an Electric circuit, Kirchhoff’s laws. Analysis of DC circuit by (i)Network reduction method (ii) Kirchhoff’s laws (iii) Mesh current method. 8 hrs

3. AC CIRCUITS :A. SINGLE-PHASE CIRCUITS: Generation of ac power, Average and effective values of sine

wave, form factor and peak factor. Phasor representation, voltage, current and power relations in R-L, R-C and R-L-C circuits. Analysis of series, parallel, and Series-Parallel circuits.

B. THREE-PHASE CIRCUITS: Advantage of three phase systems. Star and delta connections. Relationship between line and phase values. Measurement of three phase power using two wattmeters in a three phase balanced system. 12 hrs

4. DC MACHINES :A. DC GENERATOR: Basic principle of working, constructional features, Lap and Wave Windings. Types of Generators, EMF equation, Concept of armature reaction and commutation. Characteristics and applications of DC machines.B. DC MOTOR: Principle of operation, back EMF, Torque equation, types of motors, characteristics and applications. Necessity of starters, three point starter (excluding design). 8 hrs

PART B

5. SINGLE PHASE TRANSFORMER: Principle of operation, Construction, EMF equation, Power losses and efficiency. Definition of Regulation, Open circuit and Short circuit tests. Predetermination of regulation and efficiency from OC and SC test data. All day efficiency. 8 hrs

6. THREE PHASE INDUCTION MOTOR: Constructional features, Principle of operation, Production of Torque, Slip, Torque-slip characteristics, losses and efficiency, Star-delta starter and applications.

6 hrs7. ALTERNATORS: Constructional features. Principle of operation, EMF equation considering

winding factors (Excluding derivation of winding factors) 6 hrs8. a) MEASURING INSTRUMENTS: Moving iron and moving coil meters-extension of ranges

Dynamometer type of wattmeter. Induction type energy meter. Megger 4 hrs b) INDUSTRIAL DRIVES: Different types of drives, Desirable characteristics of industrial drives, Drives for Traction, Paper mill, Textile, Mining, Elevator. 4 hrs

Reference Books :1. Electrical Technology - H. Cotton2. Electrical Engineering - Hughes3. Electrical Technology - B. L. Theraja4. Electrical Sciences - M. V. Rao5. Electrical Sciences - Yoganarasimhan6. Electrical Engineering - V. K. Mehta7. Basic Electrical Sciences - Prof. P. M. Chandrashekaraiah


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152K6 SYLLABUS

I/II Semester B.E ENGINEERING PHYSICS

(Common to all branches except B.Arch)


PART ABasic Physics

1. Physics of Vibrations: SHM and its expression and differential equation-Superposition of two linear SHMs-Lissagious figures. Damped Vibrations-Differential equations and its solutions critical damping, logarithmic decrement-analogy with electrical circuits. Forced vibration-differential equations-Amplitude, Velocity resonance, sharpness of resonance and quality factor. 5 hrs

2. Elasticity : Hooke’s law-definition and its limits, Elastic constants (definitions only) and Poisson’s ratio and its limitation-Derivation of relation between q, n, k, -torsion of Cylinder – theory – expression for couple per unit twist and n-bending of beams-expression for bending moment-single cantilever. 5 hrs

3. Cryogenics : Idea of throttle expansion of gases, Joule Thomson experiment, Expression for inversion temperature, Methods of production of low temperature, Linde’s air liquefier, adiabatic and nuclear demagnetization. Measurements of low temperature by different methods, platinum resistance thermometer-theory and construction. 4 hrs

Solid State Physics

1. Free electron theory of metals : Classical theory-Expression for drift velocity and electrical conductivity – Weidman Franz law – Specific heat.Review of Band theory of solids – forbidden band-allowed bands – classification of metals, semiconductors and insulators – examples. 5 hrs

2. Superconductivity : Temperature dependence of resistivity in normal and superconducting metals – magnetic effects – Meissner effect-type I and type II superconducting Temperature dependence of Hc – BCS theory-qualitative ideas-assumptions and results – mentions of high temperature super conductors – applications of super conductors – Supercon magnets – Maglev vehicles and SQUIDS.

3. Magnetic materials : Concept of magnetization-definition of magnetic susceptibility-dia, para-ferro, ferri materials – Langevin theory of dia and para magnetism (qualitative) – soft and hard magnetic materials – applications. 4 hrs

PART BModern Optics

1. Lasers : Spontaneous and stimulated emission of radiation – population inversion – optical resonator – necessary condition for laser action – construction and working of Ruby-Helium-Neon and semi conducting laser-applications of laser-laser welding, cutting, drilling and defense. 4 hrs

2. Fiber optics : Core and cladding-total internal reflection-Derivation of expression for numerical aperture and acceptance angle-types of optical fibers-attenuation-absorption-scattering-applications in communication-point to point (block diagram level only). 4 hrs

3. Hologaphy : Harmonic generation, optical mixing Fundamentals of holography, difference between photography and holography, Construction of hologram, recording and reproducing of three dimensional image, applications of holography (any two). 5 hrs

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Engineering Materials

1. Dielectric materials: Dielectric constants and definitions of polarization – different types of polarization – electronic, orientation, ionic – Clausius – Mossotti equation – Ferro and piezoelectric materials – applications of dielectric materials. 5 hrs

2. Physics of advanced materials : Ceramics – definition crystal structure – properties. “Glasses-definition-different types of glasses-properties-application. Nano-materials-properties-fabrications-carbon nano (general considerations) Applications, MEMS. 5 hrs

3. Liquid Crystal : Classification – Orientational order intramolecular forces – deformation of the director magnetic effects – optical properties – applications – LCD. 5 hrs


Reference Books :1. Modern Physics, Kenneth. S. Krane, John Wiely & Sons.2. Solid State Physics, S. O. Pillai, New Age International3. Elementary Solid State Physics, Ali-Omar, John Wiely & Sons4. Material Science, S. L. Kulkarni & K. C. Bhandari, New Age International5. Physics for Scientists & Engineers, Serway & Jewett, Thomson Book Collection6. Lasers-Principles, Types & Application, K. R. Nambiar, New Age International7. A Text Book of Engineering Physics, M.N. Avadhanulu & P. G. Kshirsagar,

S. Chand & Company8. Nanosystems-Molecular Machenary Manufacturing & Computation, K. Eric Drexler, John Wiely

and Sons9. Fundamentals & Applications of Ultrasonic waves, J. David N Dheeke & Cheek & Cheek, CRC

Press10. Laboratory manual in Applied Physics, H. Satyaseelan, New Age International

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I/II Semester B.E ENGINEERING CHEMISTRY



1. ELECTRONIC STRUCTURE OF SOLIDSIntroduction to solids, free electron theory, derivation of Ohm’s law, mechanism of conductivity, limitations; Band structure: MO theory, LCAO concept, bonding and antibonding orbitals, extension to a solid, metals, semiconductors and insulators and their typical conductivities, Semiconductors: intrinsic and extrinsic semiconductors (p and n type). Controlled valency semiconductors (Li and Ni oxides), Numerical problems. 7 hrs2. ELECTROCHEMICAL TECHNOLOGY Electrochemical cells : EMF of a cell-definition, origin, Reference electrode-Calomel electrode, Ag/AgCl electrode, ion-selective electrode-glass electrode. Determinations of pH using glass electrode, Concentration cells-types and their applications. Numerical problems. 3 hrsBattery technology : Battery-properties, classification. Cell reactions and performance of primary batteries-Zn-MnO2, metal – air battery, Secondary batteries – working principle, cell reactions and performance of Pb-acid battery, Ni-Cd battery, Li-MnO2 battery. Fuel cells – definition, advantages and limitations. Construction and cell reactions of H2-O2 fuel cell and methanol – oxygen fuel cell. 4 hrsCorrosion Engineering : Metallic corrosion-definition, electrochemical theory of corrosion, Forms of corrosion-differential aeration corrosion – pitting corrosion, waterline corrosion, stress corrosion. Factors affecting the rate of corrosion. Corrosion control – surface coatings, inorganic coatings- phosphating, anodizing, organic coatings – paints and enamels. Metal coatings – anodic metal coatings – galvanizing. Cathodic metal coatings – tinning. Corrosion inhibitors. Cathodic and anodic protection. 6 hrs

3. GREEN CHEMISTRYIntroduction, Principles, Atom economy : Concept, AE in oxidation of benzene & butane, synthesis of aldrin by Diels – Alder reaction; Waste : Production & Prevention, E-factor, synthesis of ibuprofen; Water as a reaction solvent : Concept & Synthesis of indole, reduction reactions; Microwave Irradiation in Organic synthesis : concept, advantages, synthesis of esters, oxidation reactions, amination of ketones; Ionic liquids : examples, concept, synthesis of 2 – phenylacrylic acid; Eco-friendly pesticides : DDT, pyrethroids; Biocatalysis : concept, advantages, synthesis of aminopenicillanic acid; Synthesis of vitamin C.

4. METAL FINISHING Polarisation, decomposition potential and overvoltage, Technological importance of metal finishing. Effect of plating variables on electrodeposits. Electroplating techniques – methods of electroplating, surface preparation, plating of Cr. Electroless plating of copper for PCB. 5 hrs

5. ENERGY Introduction to energy : Fuels – Definition, classification, importance of hydrocarbons as fuels.Petroleum products : Cracking – Fluidised catalytic cracking. Reforming of petrol, knocking mechanism. Octane number, prevention of knocking, antiknocking agents, cetane number, unleaded petrol. Power alcohol – advantages of alcohol blended petrol, Petrochemicals from methane, ethylene, acetylene and benzene.

Non convention energy : Introduction, types, solar energy and its significance. Solar energy conversion technology. Solar cell materials, Photovoltaic cell, Photogalvanic cell, chalcogen photoconductors. Applications. 7 hrs

6. HIGH POLYMERSDefinitions – Natural and synthetic polymers, mechanism of addition polymerization (free radical mechanism), degree of polymerization, glass transition temperature. Addition and condensation polymers.Resins and plastics : Differences between resins and plastics, thermoplastics and thermosetting plastics – manufacture, properties and applications of HDPE and LDPE, polystyrene, phenoloformaldehyde, Teflon, polymethyl methacrylates, polyurethanes and polycarbonates.

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Elastomers : Deficiencies of natural rubber, vulcanizations, advantages of synthetic rubber. Manufacture and uses of Neoprene and Buna-S.Adhesives : Manufacture and applications of epoxy resins. 6 hrs

7. NEW MATERIALSHigh Tc superconductors : Pervoskite, layered pervoskite and YBCO structures, valence states of Cu in high Tc oxides. Conducting polymers : PA, PPP, PPy and other; differences between conducting polymers and conventional conductors, soliton, polaron and bipolaron mechanisms. Nanomaterials : Illustration of changes in band structure between bulk materials, nanosheets, nanowires and nanoparticles, size dependent changes in band gap of semiconductors (CdS / CdSe as an example); preparation strategies. Fullerenes : Structure of C60; preparation, reactions : Friedal Crafts reaction, epoxidation, addition, halogenation. 5 hrsLiquid Crystals : Classification-Thermoptropic and lyotropic, chemical constitution and liquid crystalline behaviour, Applications; Memory materials : Introduction, shape memory effect, examples. Organic electronic materials. 2 hrs

Question paper pattern for theoryShall consists of 14 questions of 10 marks each (with sub divisions a and b with 6 and 4 marks) out of which 10 questions have to be answered (5 questions from each PART). While setting the question paper, 7 questions in PART-A and 7 questions in PART B have to be set. For PART A, questions should be drawn from the chapters 1-3 (Solid State Chemistry, Electrochemical Technology and Green Chemistry) and for PART B, questions should be drawn from the Chapters 4-7 (Metal finishing, Energy, High polymers and New Materials)

Reference Books :1. Solid State Chemistry and its applications by A. R West, John Wiley , 19872. Engineering Chemistry by P C Jain and Monica Jain, Dhanpatrai Publishing Co. Ltd. 3. Chemistry in Engineering and Technology Vol. 1 and Vol. 2 by J. C Kuriacose and J. Rajaram, Tata McGraw-Hill Publishing Company Ltd.4. Chemistry of Advanced Materials by C.N. R. Rao, Blackwell Scientific Publications.5. Solid State Chemistry Compounds by A. K. Cheethan and P. Day, Clarendon Press, Oxford, 1992.6. An introduction to electrochemistry by Glasstone, East-West Press Pvt. Ltd, 1985.7. Chemical and Electrochemical Energy Systems by R. Narayan and B. Viswanathan, University Press, 1998.8. Text book of Polymer science by F. W. Billmeyer, Jr., John Wiley and Sons, 1994.9. Engineering Chemistry by R. Gopalan, D. Venkappayya and Nagarajan, Vikas Publishing House Pvt. Ltd, 1999.10. Green Chemistry An Introductory Text by Mike Lancaster, Royal Society of Chemistry, 2002.11. Green Chemistry Environment Friendly Alternatives by Rashmi Sanghi and M. M. Srivastava, Narosa Publishing House, 2003.

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I/II Semester B.E PHYSICS LABORATORY


Exam marks : 100 Duration : 3 hrs / weekClass marks : 25

1. Density of Glass tube

2. Volume resonator

3. Sonometer

4. Diffraction grating

5. Air wedge

6. Newton’s ring

7. Experiment with laser

8. n by dynamic method

9. y by single cantilever

10. y by bending method

11. Experiment with fiber optics

12. Determination of Currie temperature of a ferromagnetic substance

13. Transistor characteristics

14. Temperature dependence of risibility of semiconductor

15. Measurement of dielectric constant and its temperature dependence

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I/II Semester B.E CHEMISTRY LABORATORY



For examination an experiment each from PART – A and PART – B shall be set. Under PART-A, a common experiment shall be set for all the candidates while under PART – B different experiment may be set.

PART – A1. Preparation of standard EDTA solution and determination of total hardness of water.2. Preparation of standard EDTA solution and determination of calcium oxide in the given sample of

cement solution (rapid EDTA method).3. Determination of Cu% in brass using standard sodium thiosulphate solution (brass solution to be

prepared by weighing the brass sample).4. Preparation of standard dichromate solution and determination of iron in the given sample solution

of haematite ore (external indicator method).5. Determination of manganous dioxide in the pyrolusite using potassium permanganate solution

(pyrolusite is to be weighed).6. Determination of chemical oxygen demand of the given industrial waste water sample.7. Estimation of Ca2+ ions in the solution of dolomite.8. Kinetics of acid hydrolysis of methyl acetate.

PART – B1. Determination of pKa value of a week acid using pH meter.2. Colorimetric determination of iron / copper / any other metal.3. Estimation of hydrochloric acid using standard sodium hydroxide solution conductometrically.4. Determination of coefficient of viscosity of a given liquid using Ostwald’s viscometer (density of

the liquid is to be given).

PART – C1. Demonstration of Chemistry software – Viscosity experiment, demonstration of IR spectroscopy.2. Demonstration of gravimetric estimation of nickel using dimethylglyoxime.3. Demonstration of organic compound synthesis using microwave irradiation (synthesis of asprin,

glucose pentaacetate, oxidation and reduction reactions).4. Demonstration of flamephotometric determination of sodium / potassium.

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I Semester B.E PROGRAMMING WITH C



PART – AChapter 1: Computer Fundamentals 6 hrsIntroduction to digital Computer, Input Devices, Output devices, Storage devices, Operating System, Unix Commands: ls, mkdir, rmdir, cp, mv, rm, type, cat, date, who, banner, pwd, chown.Chapter 2: Fundamentals of C 8 hrsIntroduction, Character Set, Identifier and Keywords, Constants and Variables, Character and Character Strings, Promotion and Typecasting, Labels, Data types, Operators and Expressions, Operator Precedence and Associativity, Basic Input and Output Statements, Library Functions, Programming Examples.Chapter 3: Control Statements 8 hrsIntroduction, if Statement, if-else statement, Multi-way decisions, Compound statements, Loops, for Loop, while loop, do-while loop, break statement, switch statement, continue statement, goto statement, Programming Examples.Chapter 4: Functions and Scope 8 hrsIntroduction, Necessity of Functions, Function Declaration and Definition, Classification of Functions, User defined and library functions, Function parameters, Return values, Recursion, Scope and Extent, Programming examples.

PART – BChapter 5: Arrays and Strings 8 hrsIntroduction, Necessity of Arrays, Multidimensional arrays, Sorting and Searching of Arrays, Strings, Arrays of strings, Addition and Multiplication of 2 Matrices, Functions in string.h, Programming examples.Chapter 6: Pointers 8 hrsIntroduction to Pointers, Declaration and Initializing of pointers, Accessing a variable through its pointer, Pointers and Arrays, Passing Arrays to Functions, Pointers and Functions, Accessing arrays inside functions, Programming Examples.Chapter 7: Structures and Unions 8 hrsIntroduction, Declaring and using Structures, Structure initialization, Operations on structures, Array of structures , Array within structure, Structures and Functions, Pointers to Structure, Pointers with in the Structure, Union, Differences between Structure and Union, Operations on a union, Programming Examples.Chapter 8: Dynamic Memory Allocation 4 hrsIntroduction, Library functions for dynamic memory allocation, Dynamic multi-dimensional arrays, Self Referential Structures, Singly linked list.Chapter 9: Files 2 hrsIntroduction, File structure, File-handling functions, File Types, Concatenation of files.

References:1. Mastering C: Venugopal K.R et al Tata McGraw Hill, 2006.

( Chapter: 1 to 7, 8.1 to 8.6, 8.10 to 8.13, 9, 10.1 to 10.4, 14.1 to 14.3, 15)2. Programming in ANSI C: Balaguruswamy E, Tata McGraw Hill 1992.3. Programming in C: Yashwanth Kanetkar P, BPB Publications, 1997.4. The C Programming Language: Kernighan B.W and Ritchei D.M, Prentice Hall, 1971.5. The C Odessey: Vijay Mukhy, BPB Publications.6. C – Aptitude: Venugopal K.R, et al, Tata McGraw Hill, 2006.

Question paper pattern :The question paper consists of 8 questions of 20 marks each.The students have to answer 5 full questions, selecting at least two questions from each

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I Semester B.E C PROGRAMMING LAB


1. a) Write a program to determine the mean, variance and standard deviation of n numbers.b) Write a Program to convert a given number in binary to decimal.

2. a) Write a program to find the smallest and largest element in an array.b) Write a program to concatenate two strings.

3. a) Write a program to find the sum of squares. b) Write a program to solve the quadratic equation for all conditions i.e., roots are equal, imaginary and distinct.

4. a) Write a program to print the reverse of an integer.b) Input ‘n’ integers (real, character) & store them in an array.

5. Write a program to sort the elements in ascending and descending order Using a) Bubble sort b) Selection Sortb)

6. a) Write a program to find whether the given string is a Palindrome or not.b) Write a program to insert an element into an array.

7. a) Write a program to calculate the grades of n students from three tests.b) Write a program to delete an element from an array.

8. a) Write a program to search an element using linear search.b) Write a program to find the factorial of a number using Recursion.

9. a) Write a program to search an element using binary search.b) Write a program to generate the Fibonacci series using recursion.

10. Input 2 matrices of size M X N and P X Q. Performa) Multiplication if they are compatible. b) Transpose of the resultant matrix. Print the result in matrix form with suitable headings.

11. Write a program to read and display details of students using structure.

12. a) Write a program to concatenate two filesb) Write a program to list files and directories on command line

13. Write a program to display Norm and Symmetry of Matrix.

14. Write a program to create and display the linked list.

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I/II Semester B.E 6EM1101 MECHANICAL ENGINEERING SCIENCES



PART - A

1. Energy and its Sources:Energy – renewable and non-renewable, thermal, hydroelectric, solar, wind, tidal, ocean and nuclear energy. 3 Hrs

2. Steam Generation Boilers – Fire tube (Vertical Fire tube Boiler) & Water tube boiler (Babcock & Wilcox Boiler). Concept of wet, dry and superheated stream, Enthalpy, Latent heat, dryness fraction and degree of superheat. and Entropy, Related numerical problems. 4 Hrs

3. Energy Conversion :Using the following

1) a) Steam turbines: impulse and reaction turbines. 2 Hrs

b) I.C. Engines: Diesel and petrol engines. Four stroke and two stroke engines. Indicated power and brake power, mechanical efficiency and thermal efficiency, Related numerical problems. 6 Hrs

2) a) Air Compressor : Use of compressed air. Working of compressor brief introduction and advantages of multi stage compressors.

2 Hrsb) Refrigeration and Air Conditioning: vapour compression and vapour absorption refrigeration’s, Principles of air conditioning 3 Hrs

PART – B4. Fasteners: Temporary and permanent fasteners, ISO thread profile, single and multi start threads, lead and pitch Left and right hand threads, Hexagonal and square head bolts and Nuts, Riveted joints- single riveting and double riveting and welded joints – T joint, V – Joint, Lap – Joint. 4 Hrs

5. Concept of Machines:Definition: Machines, Classification of machines, Kinematics links and Pairs. Types of Kinematics pairs (Sketches and description) 2 Hrs

6. Power Transmission: Belt, rope, chain and gear drives. Calculation of length of belt, velocity ratio, ratio of Tensions, power transmitted given the relevant formulae (derivation of formulae is Not included) 6 Hrs

7. Brakes, dynamometers and clutches: Functions and types of brake, dynamometers and clutches 2 Hrs

8. Bearings & Lubrication: Type of bearing, Journal bearing, & ball bearing Necessity of lubrication. Types of lubricants, properties of a good lubricant. 3 Hrs

9. Fundamentals of Mechatronics: General systems, Building Blocks of Mechatronics system, Conventional Systems V/s Mechatronics & examples. 3 Hrs

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PART - C

10. Basic principles, procedures, advantages and limitations. Applications and examples involved in the following processes.

a. Casting - 4 Hrsb Forging - 1 Hrc Rolling - 1 Hrd Drawing - 1 Hre Extrusion - 1 Hrf Welding - 3 Hrsg Brazing and soldering - 1 Hr

11. Machining:a. Lathe: Block diagram of lathe, Basic concepts in turning, taper turning and thread cutting

operations. Nomenclature of single point tool, 3 Hrsb. Drilling: Block diagram of radial drilling machine and nomenclature of twist drill and type of drilling operations. 3 Hrsc. Working of CNC Machine tool 2 Hrs

References :

1. Workshop Technology : Raghuwamashi2. Workshop Technology : Hajra Choudhary3. Elements of Mechanical Engineering : K.R.Gopalkrishna4. Theory of Machines : P.L. Ballaney5. Mechatronics :W Bolton

Note: Question paper shall contain 8 questions, one question from each unit. Five questions to be answered choosing atleast 2 from each part.

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I/II Semester B.E 6EM1102 WORKSHOP PRACTICE



Exercises in fitting shop comprising preparation of different joints using files, hacksaw, taps, dies and drills in 50mm by 6mm thick mild steel flats. 3 Models

Exercises in Welding shop comprising welding lap joint, butt joint, and L-Joint in 50mm wide by 6mm thick mild steel flats. 3 Models

Exercises in carpentry shop comprising planning and chiseling and preparation of different joints like dove-tail joint Tenon – Mortise joint and open bridle-mortise joint in 25mm x 50 mm cross section wood

3 Models.

Exercises in sheet metal shop comprising development and soldering of cylinder (base closed), cubical box, simple funnel (made of frustums of cones/Pyramids) and rectangular tray in 22 gauge (1.2 mm thick) G.I. sheet. 3 Models

Use of power tools to make one of the models in each shop

Total: 12 Models Scheme of Examination:-

Preparation of one model either at fitting shop or carpentry shop. Preparation of one model in either at welding shop or soldering shop. Viva – Voce.

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262K6 SYLLABUSII Semester B.E

6SM1201 ENGINEERING MATHEMATICS –II

(Common to Civil, Mechanical, Electrical, Electronics, Computer Science & Information Science)


PART - A Unit-I: Differential calculus:Indeterminate forms, evaluation of limits by L’ Hospital’s rule(without proof) , Taylor’s theorem for a function of two variables, Taylor’s and Maclaurin’s expansions, maxima and Minima, Approximation of errors, Methods of undetermined multipliers. 7 hrsUnit-II: Integral calculus:Double integrals, triple integrals, evaluation by change of order of integration, change of variables and application to area and volume. 7 hrsUnit-III: Vector differential calculus:Vector valued function of a single variable: Differentiation, geometrical meaning, examples. Scalar and vector fields, gradient of a scalar field-geometrical application- divergence and curl of a vector field – Laplacian – vector identities. 7 hrsUnit-IV: Vector integral calculus:Line, surface and volume integrals of a vector function: Green’s, Stokes and Gauss’s theorem (without proof) problems. Orthogonal curvilinear co-ordinates. 9 hrs

PART - B Unit-V: Differential Equations:Ordinary differential equation of first order and higher degree. Solvable for x, Solvable for p, Solvable for y, Clairaut’s equation, Singular solutions. 7 hrsUnit-VI: Second and higher order differential equations, Homogeneous linear equations with constant and variable co-efficients , problems. Non homogeneous linear equations with constant and variable co-efficients, problems, Method of variation of parameters, Method of undetermined co-efficients.

8 hrsUnit-VII: Lap lace transforms and Gamma and Beta functions:Definitions, Transforms of elementary functions, transforms of derivatives and integrals, Transforms of periodic functions, unit step functions, unit impulse functions. Inverse Lap- lace transforms, convolution theorem, solving systems of linear equations, Applications to Engineering problems.

9 hrsUnit-VIII: Gamma functions, Beta functions, Relation between Gamma and Beta functions, problems.

8 hrs

Text Books:1. B. S. Grewal, “Higher Engineering Mathematics” 36th Edition, 2001 Khanna Publishers, Delhi.2. E. Kreyszig, “Advanced Engineering Mathematics” 8th Edition, 2004, John Wiley and sons.

Note: Question paper shell contain 8 questions, one question from each unit. Five questions to be answered choosing atleast 2 from each part.

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6CE1201 STRENGTH OF MATERIALS(Common to all branches except B.Arch)


PART A1. Introduction to Body forces, surface forces, equilibrium of a deformable body, Normal stress, shear stress, allowable stress, stresses, deformation and strain. 4 Hrs 2. Mechanical properties of materials: Tension and compression test, stress strain diagram, stress strain behaviour of ductile and brittle materials, Hooke’s law, Poisson’s ratio, Saint Venant’s principle, Principle of superposition, Young’s Modulus, Secant Modulus, Ultimate stress, Rigidity Modulus, Bulk Modulus, relation between elastic constants, Compound bars, thermal stresses, stress concentration. Definition of stiffness and flexibility of axial bars in tension. 10 Hrs 3. Bending moment and shear force: Bending moment and shear force diagrams for statically determinate beams subjected to concentrated, uniformly distributed and varying loads, Moment diagrams by integration of shear, Shear diagrams by integration of load. 8 Hrs 4. Stresses in Beams: Basic Assumptions, flexure formula, application of flexure formula and concept of filched beam, transforming sections. The shear stresses in beams, shear flow in built up beams of different sectional shapes. 6 Hrs

PART B5. Deflection of Beams: Introduction to elastic curve, moment curvature relation, governing differential equation, boundary conditions, deflections of statically determinate beams by double integration and Macaulay’s method. 8 Hrs 6. Torsion: Introduction, Basic assumptions, Torsional formula, application of torsion formula for circular sections. Replacement of solid shaft by hollow shaft and saving in weight. Applications of Torsion theory to closed and open coiled helical springs. 8 Hrs 7. Compound stress: Transformation of stresses, strains, in two dimension, principal stress and strains, maximum shear stress and strains and construction of Mohr’s Circle for stresses and strains.

6 Hrs 8. Pressure Vessels: Thick and thin walled cylindrical and Spherical pressure vessels. 4 Hrs 9. Buckling of Columns: Introduction to critical load, Ideal column, Columns having different support, effective length, slenderness ratio, Rankine’s formula. 6 Hrs

References:

1. Popov Egor P., Engineering mechanics of solids, Pearson Education Asia, Second edition, 2001.

2. Singer Ferdinand L., Strength of materials, Harper international, Third Edition, 1980.

3. Crandall Stephen H., An introduction to the mechanics of solids, McGraw Hill Book Co. 1978.

4. Bansal R.K., A textbook of strength of materials, Laxmi publication (P) Ltd., New Delhi, 2001.

5. Lehri R.S., Strength of materials and Mechanics of structures, Katson publishing, New Delhi, 1980.

6. Prasad, V.S., Mechanics of Solids, Galgotia Publication (P) Ltd., New Delhi, 2000.


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6EC1201 BASIC ELECTRONICS (Common to all branches except B.Arch)


PART A1. Introduction to Electronics : What is electronics, Electronic Devices, Evolution of Electronics- Vacuum tubes to Integrated Circuits, Conduction in Semiconductor: Electrons and holes in an intrinsic semiconductor, conductivity of a semiconductor, carrier concentration in an Intrinsic semiconductor, donor and acceptor impurities , charge densities in a semiconductor, Fermi level in a semiconductor having impurities, life time of carriers, Hall effect. Introduction to Solar energy Conversion, Photovoltaics.

7 hrs2. Semiconductor – Diode Characteristics: Qualitative theory of a PN junction, PN Junction as a diode, Volt – Ampere characteristics , temperature dependence of P-N characteristics, half wave and full wave rectifiers, ripple factor, capacitor filter, Zener Diode- characteristics, Zener and avalanche breakdown, Zener regulated power supply. 7 hrs3. Transistor Characteristics : Junction transistor, transistor – current components, transistor as an amplifier, common base configuration, common – emitter configuration and Common Collector configuration with input and output characteristics, CE cutoff region, CE saturation region , large signal , DC and small-signal CE values of current gain, operating point, bias stabilization, decibel, Classification of amplifiers, RC coupled amplifier, frequency response, distortion in an amplifier, cascading transistor amplifiers 12 hrs 4. Theory of Sinusoidal oscillators: Concept of feedback, sinusoidal oscillators, working of RC phase shift, Colpitts and Hartley’s oscillator using BJT’s Expressions for frequency of oscillation (No derivation), crystal oscillator. 4 hrs

PART B5. Operational Amplifiers (OPAMP): Introduction, ideal OPAMP, need for OPAMP, OPAMP characteristics, OPAMP applications: voltage follower, addition and subtraction using OPAMP circuits, OPAMP integrating and differentiating circuits. 7 hrs6. Communication systems: Basic block diagram of communication systems: Radio AM & FM, TV, Overview of Mobile communication, Satellite communication, Modulation, Amplitude Modulation , Frequency spectrum, power relations, Phase and Frequency modulation ,comparison of AM and FM, radio telephony, super heterodyne receiver, Transmitters. 10 hrs7. Digital Electronics: Digital logic – Binary numbers base conversion, Octal and Hexadecimal numbers , binary addition and subtraction using One’s and Two’s complements, addition and subtraction in Binary, Octal and Hexadecimal Number systems, BCD and EX-3 addition and subtraction, numbers, binary logic symbols, basic theorems & properties of Boolean Algebra, De-Morgan’s theorem. AND OR logic gate realizations using Transistor – Transistor Logic (TTL) , MOS, CMOS , NMOS,PMOS . Symbols used for NOT, OR, AND, NAND , NOR, XOR gates and their truth tables, Realization of Boolean functions using basic gates. Realization of basic gates using universal gates. 10 hrs8. Introduction to Cathode Ray Oscilloscope (CRO) Basic block diagram, use of CRO for measurement of amplitude Frequency and Phase. 3 hrs

Reference Books:1.Basic Electronics M.V. Rao2.“Electronics Devices and Circuits” Millman and Halkai, TMH 1991 Reprint 20013.Electrical and Electronics Computer Engineering for Scientist and Engineers, 2nd edition K.A. Krishna Murthy and M Raghuveer, New Age International Publishers(Wiley Easter 2001 4.Electronics Communication Systems, George Kennedy (TMH 4th edition 5.Electronics Principles A.P. Malvino, TMH 6th edition6.Digital Logic and Computer Design, Morris Mano 7.Basic Electronics by Dr. H. N. Shivashankar and B. Basavasraju.8.Principles of solar energy by D. Yogi Goswami, Frank Kreith, Jan.F. Kreider., Eswar Press, Chennai. 9.Data Communication by William Schweber, Mcgraw Hill.

Note: Question paper shall contain 8 questions, one question from each unit. Five questions to be answered choosing at least 2 from each part.

2K6 SYLLABUS

29

2K6 SYLLABUS

II Semester B.E 6EM1201 ENGINEERING DRAWING


Workshop: 4 Hours/ week Max. Examination Marks:100Examination: 4 hours Internal Assessment Marks:25

Minimum Marks: 12(To be taught in First Angle Projection)

Fundamentals of Engineering Drawing:B.I.S. Conventions for Engineering Graphics, Dimensioning, Use of instruments, Simple geometrical constructions, construction of polygons, lettering, concept of R.F. (Representative Fraction) in scales.

9 HrsPART - A

Projection of Points:Concept of Orthographic Projection; Projection of points in different quadrants, emphasizing on I Angle Projection.Projection of Straight Lines: Projection of lines in simple positions, inclined to one plane and parallel to other plane, inclined to both planes. To find true length and true inclinations, given the projections. Practical problems.Projection of Plane Surfaces:Projection of regular hexagon and pentagon, square, rectangle & triangle without through holes (by change of position method.) 18 Hrs

PART - BProjection of Solids: Projection of the following simple and right regular solids: Prisms, Pyramids, Cones and Cylinders (without through holes), inclined to both HP & VP (by change of position method.) 9 Hrs

PART - CSection of Solids:Concept of auxiliary planes.To obtain sectional views and true shape of section when the section plane cuts the right regular solids viz. prisms, pyramids, cones and cylinders, without through holes, with section plane perpendicular to HP or VP. Projection of right regular solids viz. prisms, pyramids, cone, cylinder & their frustums and sphere and combination of any two of these solids. Simple machine parts. 24 Hrs.

Scheme of Examination:3 questions from PART – A i.e., ONE on Projection of Lines, One on practical problems involving Lines,ONE on plane Surfaces. Student to answer any TWO questions, each of 20 Marks 2 questions from PART – B. Student to answer any ONE question of 20 Marks3 questions from PART – C i.e., ONE on section of solids, ONE on Isometric projection of combination of any two geometrical solids, ONE on Isometric projection of machine parts. Student to answer any 2 questions of 20 marks each.

TEXT BOOKS:1. Engg Drawing Vol - I & Vol – II in Angle Projection Gopala Krishna K. R2. Engg Drawing in I Angle Projection Bhatt N.D 3. Machine drawing Gopala Krishna K.R

2K6 SYLLABUS

302K6 SYLLABUS

II Semester B.E 6EM1202 COMPUTER AIDED DRAFTING LABORATORY

Lab Hours/Week: 3 Max Examination Marks : 100Examination: 3 Hours Internal Assessment Marks: 25

Minimum Marks: 12

1. Introduction: System requirements for AUTOCAD, Starting AUTOCAD, Starting New Drawing, Understanding the Interface, Co-ordinate System, Set-up for a drawing, saving the drawing, Quitting AUTOCAD 6 Hrs

2. Drawing Objects: Points, Lines, Arcs, Circles, Regular Polygons, Rectangles, Poly lines, Doughnuts, Traces, Text, D Text, M Text, Style.

10 Hrs

3. Object Selection and Drawing Aids: Units, Limits, Grid, Snap, OSnap, Functional Keys, Layers.

4 Hrs

4. Controlling Drawing Display: Redraw, Regeneration, Zoom, Pan, View. 3 Hrs

5. Editing Object and Entities: Removing, Displacing, Duplicating, Orientation, Controlling Sizes, Changing Sizes along one direction, Filleting and Chamfering.

6 Hrs.

6. Dimensioning: Basic Dimensioning Terminology and different types of dimensioning – Aligned, Rotated, Base Line, Ordinate, Leader. Geometric Tolerance indicating surface finish symbols.

6 Hrs

7. Hatching and Blocks: Drawing hatch, Associative hatch, Editing hatch, Blocks- Concept, Creation, Editing & attributes. 3 Hrs

8. Isometric Drawing: Creating isometric drawing of engineering parts. 6 Hrs

9. 3D Modeling: Types, Techniques, Co-ordinate System, UCS, Wire frame, Surface and Solid, Viewing in 3D- V Point, D view, Solid modeling – extending, evolving, Boolean operations. Union, Subtraction, Intersection, Interference, Editing Solid Model Fitting, Chamfering, Sectioning, Slicing. 12 Hrs

10. Printing and Plotting of 2D & 3D objects: Creating Orthographic views multi views of Solid objects for printing. Printing of 2D objects. 4 Hrs

Reference: 1. AUTOCAD for Engineering & Designers by Sham Tickoo. Publication: Dream tech 2005.2. Engineering drawing by K.R.Gopala Krishna or N.D.Bhatt3. Engineering Graphics with AUTOCAD by James. D. Bethune. Publication: Pearson Education4. AUTOCAD manual from AUTO Desk Inc USA.

Scheme of Examination: 1. One Exercise on 2D drawing : 40 Marks 2. One exercise on 3D Solid Modeling : 40 Marks 3. Viva Voce : 20 Marks

2K6 SYLLABUS

31

Proceedings Extract of the meeting of the faculty of Engineering held on 23-05-2006 at 11.30 AM in the Seminar Hall, UVCE, KR Circle, Bangalore

Resolutions :

Each department has to ear mark two continuous hours on the days mentioned in the table shown :

Department Semester, Audit subject and the day on which the subject to be taughtIII Semester

KannadaIV Semester

Environmental Science

V SemesterTechnical Report

Writing

V SemesterConstitution of

IndiaArchitecture & Civil Monday Monday Monday MondayMechanical (Both Day & Evening)

Tuesday Tuesday Tuesday Tuesday

Electrical Wednesday Wednesday Wednesday WednesdayElectronics (Both Day & Evening)

Thursday Thursday Thursday Thursday

Computer Science & Engineering

Friday Friday Friday Friday

Information Science & Engineering

Saturday Saturday Saturday Saturday

2K6 SYLLABUS

32

ªÀÄÆgÀ£ÉÃ ¸É«Ä¸ÀÖgï ( ©. E. PÉÆÃ¸ïð) PÀ£ÀßqÀ ¥ÀoÀåPÀæªÀÄ

2 hrs/ week Sess. Maximum Marks 50Minimum Marks : 20

«ªÀgÀªÁzÀ ¥ÀoÀåPÀæªÀÄ :

(1) CPÀëgÀªÀiÁ¯É ¸ÀégÀ, ªÀåAd£ÀUÀ¼ÀÄ(2) UÀÄtÂvÁPÀëgÀUÀ¼ÀÄ(3) MvÀÛPÀëgÀUÀ¼ÀÄ(4) ¸ÁªÀiÁ£Àå §¼ÀPÉAiÀÄ ¥ÀzÀUÀ¼ÀÄ (ªÀåªÀºÁgÀ, DqÀ½vÀ, gÀPÀÛ¸ÀA§AzsÀzÀ

¥ÀzÀUÀ¼ÀÄ)(5) ¸ÀgÀ¼ÀªÁzÀ ¸ÀA¨sÁµÀuÉUÀ¼ÀÄ(6) ¸ÀtÚ PÀxÉUÀ¼ÀÄ (¥ÀAZÀvÀAvÀæ¢AzÀ DAiÀÄÝ ºÀvÀÄÛ PÀxÉUÀ¼ÀÄ)

¥Àæ±Éß¥ÀwæPÉ ªÀiÁzÀj:

¥ÀzÀUÀ¼À §gÀªÀtÂUÉ - 10 CAPÀUÀ¼ÀÄªÁPÀågÀZÀ£É - 10 CAPÀUÀ¼ÀÄC£ÀÄªÁzÀ - 10 CAPÀUÀ¼ÀÄ¸ÀtÚ ¸ÀA¨sÁµÀuÉ - 10 CAPÀUÀ¼ÀÄPÀxÉUÀ½AzÀ ¥Àæ±Éß – GvÀÛgÀ - 10 CAPÀUÀ¼ÀÄ

MlÄÖ - 50 CAPÀUÀ¼ÀÄ

¥ÀgÁªÀÄ±Àð£À UÀæAoÀUÀ¼ÀÄ:

1) Mackormack : Kannada (OUP), Oxford Univeristy Publication2) PÀ£ÀßqÀ ¥ÁoÀUÀ¼ÀÄ - ¨sÁUÀ : ¨ÉAUÀ¼ÀÆgÀÄ «±Àé«zÁå®AiÀÄ,

¥Àæ¸ÁgÁAUÀ.®Që÷ä£ÁgÁAiÀÄt ¨sÀlÖ, azÁ£ÀAzÀ ªÀÄÆwð

3) PÀ£ÀßqÀ ¥ÁoÀUÀ¼ÀÄ : PÉÃA¢æÃAiÀÄ ¨sÁgÀwÃAiÀÄ ¨sÁµÁ «eÁß£À ¸ÀA¸ÉÜ

ªÉÄÊ¸ÀÆgÀÄ.

2K6 SYLLABUS

33

ENVIRONMENTAL SCIENCE(AUDIT SUBJECT)


Unit 1 : The multidisciplinary nature of Environment studies Definition, Scope and importance of environment Need for public awareness

Unit 2 : Natural ResourcesRenewable and Non-renewable resources : Natural Resources and Associated problems a. Forest resources : Use and over exploitation, Deforestation, Case studies, Timber Extraction, Forest management.b. Water resources : Use and over utilization of surface and ground water, floods, Drought, Conflicts over water, Dams, Benefits and problems.c. Mineral resources : Use and exploitation, Mining, Environmental effects of Extraction and using mineral resources, Case studies.d. Food resources : World food problems, changes caused by agriculture and overgrazing, effects of modern agriculture, fertilizer-pesticide problems, water logging, salinity, Case studies.e. Energy resources : Growing energy needs, renewable and non-renewable energy sources, use of alternate energy sources, Case studies.f. Land resources : Land as a resource, land degradation, man induced landslides, soil erosion and desertification.E. Role of an individual in conservation of natural resources.F. Equitable use of resources for sustainable lifestyles.

(8 hrs)Unit 3 : Fundamentals of Ecology : Introduction and Scope Concept of an ecosystem. Structure and function of an ecosystem. Producers, consumers and decomposers. Energy flow in the ecosystem. Ecological succession. Food chains, food webs and ecological pyramids. Introduction, types characteristics feature structure and function of the following ecosystem.

a. Forest ecosystemb. Grassland ecosystemc. Desert ecosystemd. Aquatic ecosystems (ponds, streams, lakes, rivers, oceans, estuaries) (6 hrs)

Unit 4 : Biodiversity and its conservation Introduction-Definition : Genetic, species and ecosystem diversity. Biogeographical classification of India. Value of biodiversity : Consumptive use, productive use, social, ethical, aesthetic and option values. Biodiverstiy at Global, National and Local levels. India as a mega diversity Nation. Hot-spots of biodiversity. Threats to biodiversity, habitat loss, poaching of wildlife, man wildlife conflicts. Endangered and endemic species of India. Conservation of biodiversity : In situ and Ex-situ conservation of biodiversity.

(18 hrs)Unit 5 : Environmental pollution :Definition Causes, effects, and control measures of :-

Air pollution, Water pollution, Soil pollution, Marine pollution, Noise pollutionNoise pollution, Thermal pollution, Nuclear hazards

Solid waste management : Causes, effects and control measures of urban and industrial wastes, wasteland reclamation.

Role of an individual in prevention of pollution.2K6 SYLLABUS

34 Pollution case studies Disaster management : floods, earthquake, cyclone, droughts, tsunami and landslides.

( 8 hrs)Unit 6 : Social Issues and the Environment : From Unsustainable to Sustainable development Urban problems related to energy Water conservation, rain water harvesting and watershed management Resettlement and rehabilitation of people : its problems and concerns. Case studies Environmental ethics : Issues and possible solutions. Climate change, global warming, acid rain, ozone layer depletion, smog formation nuclear accidents and holocaust. Case studies Wasteland reclamation. Consumerism and waste products. Environment Protection Act (EPA) Air (Prevention and Control of Pollution) Act Water (Prevention and Control of Pollution) Act Wildlife Protection Act Forest Conservation Act Hazardous waste (management and prevention) Act and Rules Issues involved in enforcement of Environmental Legislation Public Awareness

(7 hrs)Unit 7 : Human Population and the Environment

Population growth, variation among Nations Population explosion-Family Welfare Programme Environment and Human health Human rights Value education HIV / AIDS Women and Child Welfare Role of Information Technology in Environment and human health Case studies

(6 hrs)Unit 8 : Field Work

Visit to a local area to document environmental assets-river / forest / grassland / hill / mountain. Visit to a local polluted site-urban / Rural / Industrial / Agricultural Study of common plants, insects, birds Study of simple ecosystems – pond, river, hill slopes etc. (Field work equal to 5 Lecture hours) Each student has to submit a field report on any one of the above topics which forms the basis for

evaluation of field work for – 20 marks.

2K6 SYLLABUS

35

COMMUNICATION SKILLS AND TECHNICAL REPORT WRITING (AUDIT SUBJECT)


1. Review of Grammar : Remedial work on Tenses, Concord, Voice, Reported Speech and Auxiliaries.

2. Writing Paragraphs :

Topic sentences and supporting sentences.

Using linkers in developing a paragraph.

Developing an outline into a paragraph.

3. Summarizing, abstracting, note taking and note making.

4. Presentation skills : Organization of a presentation; using blackboard, charts and digital media.

5. Job application, C.V.writing.

6. Preparation of Technical Reports, Questionnaires and Enquiry letters.

7. Speaking skills : Oral presentation, group discussion, facing interviews.

Reference Books:

1. G. S. Mudambadithaya, Communicative English for Professional Courses.2. Comprehend and Compose, Foundation Books, Cambridge University Press.

2K6 SYLLABUS

36INDIAN CONSTITUTION

(AUDIT SUBJECT)


Chapter 1 : Indian Constitution : Its Philosophy and FramingG. The Constituent AssemblyH. Preamble, Fundamental Rights and Fundamental DutiesI. Directives Principles of State PolicyJ. Amendment and Review of the Constitution

Chapter 2 : The Union & State Legislature Union Parliament State Legislature Law-Making Process Committee System

Chapter 3 : The Union & State Executive The President of India The Prime Minister and Council of Ministers The State Governor, Chief Minister and Council of Ministers Coalition Government

Chapter 4 : The Judiciary The Supreme Court of India Judicial Review Writs Judicial Activism and Public Interest Litigation

Chapter 5 : Issues Indian Federalism Human Rights and Environmental Protection Reservation and Social Justice Secularism

References :

1. D. D. Basu : Introduction to the Constitution of India2. Granville Austin : India’s Constitution – Cornerstone of a Nation3. Granville Austin : Working of a Democratic Constitution – The Indian Experience4. J. C. Johari : Indian Government and Politics, Vol. 1 & 25. J. R. Siwach : Dynamics of Indian Government & Politics6. D. C. Gupta : Indian Government & Politics7. M. V. Pylee : India’s Constitution8. K. K. Ghai : The Indian Constitution9. H. M. Rajshekar : Bharata Sarkara mattu Rajkiya10. M. P. Bhuvaneshwara Prasad : Bharata Samvidhanada Parichaya11. S. K. Kabburi : Bharata Samvidhana12. K. J. Suresh : Bharata Samvidhana13. D. T. Deve Gowda : Bharata Sarkara Mattu Rajkiya 14. Lohitashwa : Bharata Samvidhana

2K6 SYLLABUS

37

Scheme for Instruction and Examination for all the Engineering Courses(Semester Scheme)

Subject No. of Hrs/week

Examination marks

Internal assessment

marks

Duration of examination

Total marks

Auditing subject Environmental Studies

Theory-4 hrs.

Theory-70 Project Report-20

Test / Assignment – 10

Theory-3 hrs 100

Model question paper for Environmental Science Examination B.E/B.Tech Students (Common for all branches)(Audit Subject)Time – 3 hours Max. Marks : 70

Min. Marks : 30Pattern of Question Paper

Total : 70 MarksShort type questions :Sec A(12 questions of two marks each out of which students have to answer any 10) 10 x 2 = 20

Sec B (6 questions of five marks each out of which students have to answer any 04) 4 x 5 = 20

Essay type question :Sec C(5 questions of ten marks each out of which students have to answer any 03) 3 x 10 = 30

2K6 SYLLABUS

38

2K6 SEMESTER SCHEME

2K6BSM101 BRIDGE COURSE MATHEMATICS-I

Hours / Week-4 Examination hours -3Total hours-60 Examination Marks-100

1. Differential Calculus :UNIT I : nth derivative of standard functions, Leibnitz’s theorem (without proof)-problems.UNIT II : Polar curves-angle between the radius vector and the tangent-pedal equations.UNIT III : Partial differentiation, Euler’s theorem, Total differentiation, Differentiation of composite and implicit functions-Jacobians.

18 hrs2. Integral Calculus :UNIT IV : Reduction formulae, Reduction formula for

Multiple Integrals; Evaluation of double and

triple integrals with constant and variable limits.UNIT V : Gamma and Beta functions, Differentiation under the integral sign (constant limit only).

16 hrs3. Differential Equations :UNIT VI : Solutions of ordinary differential equations of first order and first degree-separation of variables, homogeneous equations, reducible to homogeneous equations, linear equations, Bernoulli’s equations, Exact equations, Reducible exact equations.

UNIT VII : Second and higher order linear differential equations with constant co-efficeints, complementary functions, particular integrals (standard types).

16 hrs4. Complex numbers :UNIT VIII : Algebra of complex numbers, Geometrical representation and polar form of complex numbers, Exponential form, De Moivre’s theorem (statement only), nth roots of a complex number.

10 hrs

Reference Books :1. E Kreyszig : Advanced Engineering Mathematics, 8th edition-New Age International.2. B.S. Grewal : Higher Engineering Mathematics, 39th edition-Khanna Publication.3. L. Pipes – Advanced Engineering Mathematics for Engineers and Physicists, McGraw Hill.

Examination :For the maximum marks of 100, 5 questions are to be answered out of 8 within 3 hrs. All questions carry equal marks.

Pattern of Question paper :1. Differential Calculus 3 questions2. Integral Calculus 2 questions3. Differential Equations 2 questions4. Complex numbers 1 question

2K6 SYLLABUS

39

2K6 SEMESTER SCHEME

2K6BSM201 BRIDGE COURSE MATHEMATICS-II

Hours / Week-4 Examination hours -3Total hours-60 Examination Marks-100

1. Analytical Geometry :UNIT I and II : Analytical geometry in 3 dimensions : Direction cosines and Direction ratios-planes-Straight lines-Angle between planes / Straight lines – Coplanar lines – Shortest distance between skew lines. 16 hrs

2. Differential Calculus :UNIT III : Mean value theorems – Rolle’s theorem (without proof), Lagrange’s and Cauchy’s mean value theorems – Taylor’s theorem for a function of single variable (without proof), Maclaurin’s series expansions – Indeterminate forms-L’Hospitals rule (without proof).

12 hrs3. Vector Calculus :UNIT IV and V : Velocity, Acceleration of a vector point function- Gradient, Divergence, Curl, Laplacian, Solenoidal and Irrotational vectors and their properties.UNIT VI : Vector integration – Line integral – Green’s, Gauss, Stoke’s theorem (without proof) – Simple problems with applications to Engineering problems.

18 hrs

4. Laplace Transforms :UNIT VII and VIII : Definition, transforms of elementary functions-transforms of derivatives and integrals-properties, periodic functions, unit step functions and unit impulse functions, Inverse transforms – properties-convolution theorem. Application to differential equations and simultaneous differential equations. 14 hrs

Reference Books :2. E Kreyszig : Advanced Engineering Mathematics, 8th edition-New Age International.3. B.S. Grewal : Higher Engineering Mathematics, 39th edition-Khanna Publication.4. L. Pipes – Advanced Engineering Mathematics for Engineers and Physicists, McGraw Hill.

Examination :For the maximum marks of 100, 5 questions are to be answered out of 8 within 3 hrs. All questions carry equal marks.

Pattern of Question paper :1. Analytical Geometry 2 questions2. Differential Calculus 1 question3. Vector Calculus 3 questions4. Laplace Transforms 2 questions

2K6 SYLLABUS

40

III SEMESTER B.E (ELECTRICAL & ELECTRONICS)2K6SM301 Engineering Mathematics – III

4 hrs/ week Max. marks 125.

Exam marks: 100 Sess. marks 25.

PART – A

UNIT-IFourier Series of periods 2π and 2l- complex from half range Fourier series-since series, Cosine seriesFinite Fourier since / coline transforms – Transforms of derivatives.UNIT-IIInfinite Fourier transforms and Inverse Fourier transforms – Simple Properties.Complex Fourier transforms, Fourier since/cosine transforms Convolution theorem & Perseval’s Identities (without proofs)Z transforms – definition, Standard forms, linearity property.UNIT-IIIBessel Functions: Solutions of the Bessel differential equation. The Bessel function, Recurrence relations, Orthogonality, Generating function.UNIT-IVLegendre Polynomials: Solution of the Legendre differential equation, Legendre Polynomials, Generating function, Recurrence relations.

PART – B

UNIT-VFormation of Partial differential equation: Solution by Lagrange’s method for first order Partial differential equation’s, Solution of standard types of non-linear Partial differentia equation’s – Charpit’s method.UNIT-VISolution of one dimensional wave equation by the method of separation of variables and by Fourier series method. Solution of one dimension heat equation by the method of separation of variables and by Fourier series method.UNIT-VIICurve fitting by the method of least squares Peanson’s coefficient of correlation Rank correlation, Regression lines – problems.UNIT-VIIIConditional probability, Baye’s theorem, Binomial/Poisson probability distribution, Normal probability distribution.

PATTERN OF QUESTION PAPER:The question paper contains two Parts namely PART-A and PART-B each containing 4 questions.

Five questions in all out of 8 questions are to be answered choosing atleast two from each PART.

DISTRIBUTION OF QUESTIONS:One question each from Unit-I to Unit-VIII

References :1. B. S. Grewal : Higher Engineering Mathematics, Khanna Publishers2. Ejvin Kreyzig : Advances Engineering Mathematics, John Wiley & Sons

2K6 SYLLABUS

41

III SEMESTER B.E (ELECTRICAL & ELECTRONICS)2K6EE301 Analog Electronic Circuits-I


Exam marks: 100 Sess. Marks 25.

PART-A

1. Linear Wave Shaping : RC High Pass & Low Pass Ckts. Analysis with Step, Exponential, Ramp, Pulse & Square Wave Inputs. Integrator & Differentiator. Compensated attenuators. 8 hrs

2. Non Linear Wave Shaping : Using SC & Zener Diodes, Diode Clipping Ckts, Study of Effect of Temperature, Diode Clamping Ckts, Clamping Ckts Theorem. 6 hrs.

1. Basics of Amplifiers : Different Types of Biasing Ckts for BJTs & JFETs Stability of Operating Point in BJTs Ckts, Stabilization of Q-point against Variations in ICBO, VBE, (hfe) in Transistor Ckts.

7 hrs.

2. Analysis of BJT and JFET amplifiers: h-parameter Model of Small Signal, Low Frequency BJT Amplifiers. Analysis of BJT Amplifiers in CE, CB & CC Modes, Comparison of Configuration. Small Signal Model of JEFT, Analysis of Low Frequency Common Source & Common Drain Amplifiers. Differential Amplifiers. 12 hrs.

3. High Input resistance BJT Circuits: Analysis of Emitter follower, Darlington emitter follower & Boot strapped emitter follower circuits. 4 hrs.

PART-B

4. Frequency Response of Amplifiers: Effect of coupling, emitter and bypass capacitors on low frequency response. Analysis of different types of coupled amplifiers like RC coupled, Transformer coupled & direct coupled amplifiers, Relative merits & demerits, Multistage amplifiers, Effect of cascading on amplifier response (both gain & frequency response), Gain bandwidth product, Low & High frequency compensation circuits. Tuned amplifiers, analysis of single tuned amplifiers, expression for tuning frequency, discussion on doubled tuned and stagger turned circuits, frequency response. 13 hrs.

5. BJT amplifiers at high frequencies: BJT hybrid- Pi model at high frequencies, Single stage CE transistor amplifier response. 3 hrs.

6. Large Signal Amplifier: Classification, AC load line, Analysis of class A, B & AB (Push Pull & Complementary symmetry) amplifiers, with respect to efficiency, Linearity, Harmonic distortion.

7 hrs.

REFERENCES :1. Pulse, digital & switching waveforms - Millman & Taub, McGraw Hill International Edition.2. Electronic Devices & Circuits - Millman & Halkias, McGraw Hill International Edition.3. Electronic Devices & Circuits Theory - Nashelsky & Boylested, PHI -EEE.4. Electronic Principles - Malvino, TMH Publications.5. Electronic Principles - Gray & Campbell, Wiley Eastern.6. Applied Electronics - Gray, Asia Publishing.


2K6 SYLLABUS

42

III SEMESTER B.E (ELECTRICAL & ELECTRONICS)2K6EE302 Electric Circuits



PART-A1. Basic Concepts : Linear, non-linear, unilateral, Bi-lateral circuits with examples. Independent and

dependent sources with examples. Source shifting and Transformation technique. The concept of loop current and node voltage analysis. Solution of Network by loop-current, node-voltage method and star-delta networks. 10 hrs

2. Network topology : Graph of a network, concept of a tree and links, incidence matrix, tie-set and cut-set schedule, solution of networks, Principle of duality in networks. 6 hrs

3. Network Theorems : Superposition, reciprocity, Thevenin’s, Norton’s, Maximum power transfer theorems, Millman’s theorem. 10 hrs

4. Resonant Circuits, Locus Diagrams, Coupled Circuits: Series and parallel resonance, frequency response of series and parallel Circuits. Solution of series and parallel networks using Locus diagrams.Mutual Inductance, coefficient of coupling, DOT convention, analysis of coupled circuits, conductivity equivalent coupled circuit. 8 hrs

PART-B

5. Polyphase Circuits: Analysis of balanced and unbalanced 3-phase circuits. Measurement of active and reactive power with balanced and unbalanced load. Basics of symmetrical components. 10 hrs

6. Transient Behavior and Initial Conditions in Network: Behavior of circuit elements under transient condition. Transient response of a circuit for AC & DC excitations. Importance of initial conditions. Evaluation of initial conditions in RL, RC and RLC circuits. 6 hrs

7. Laplace Transforms: Gate functions, signals, waveforms and waveform synthesis. Laplace transform of periodic functions, convolution theorem. Initial and final value theorems. Inverse Laplace Transformation, Transform Impedance and transform Networks. Response of RL, RC, RLC Circuits for different excitations, Impulse Response and step response of linear systems. 10 hrs

REFERENCES BOOKS :

1. Engineering Circuit Analysis - Hayt & Kimmerly.2. Theory and Problems of Electric Circuits (Schaum’s outline Series) – J A Edminister.3. Symmetrical components – P. Narayana Reddy4. Networks – Desur & Kuh (KUO). 5. Networks – Roy Chowdhary.6. Network Analysis – Umesh Sinha.


2K6 SYLLABUS

43

III SEMESTER B.E (ELECTRICAL & ELECTRONICS) 2K6EE303 Electrical Machines I (DC Machines & Transformers)



PART-A

1. D C Generator: Constructional features, EMF equation. Armature reaction - demagnetising and cross magnetising ampere turns. Commutation. Reactance voltage, Interpoles, compensating windings.

6 hrs

2. D C Generator Characteristics: Types - series, shunt compound and separately excited generators. Magnetisation characteristics. Critical field resistance. Load characteristics and critical load resistance. 6 hrs

3. D C Motors: Back emf, speed, torque of DC motors, Types- shunt series and compound - application. 6 hrs

4. Speed Control of DC Motors: Armature voltage and field current control of dc shunt motors. Series - parallel control of series motors. Motor starters. 6 hrs

5. Testing of DC Machines: Losses, efficiency and condition for maximum efficiency. Direct test and indirect tests: Hopkinson, Swinburne’s & Retardation tests. Load test. 6 hrs

PART-B

6. Transformers: General principle, transformer action, types of transformers. Constructional features, Conservator, Breather, Bushings, Cooling of transformer, EMF equation, Transformer analysis on no load and load, equivalent circuit, 3 phase transformer connections, Tertiary windings, Scott and open Delta connections.

Losses, separation of core loss into its components. Efficiency and condition for maximum efficiency, All day efficiency and Regulation. Predetermination of efficiency and regulation. Parallel operation of Single phase and Three phase transformers.

Current in rush, impact of over voltage and short circuit. No load and on load tap changers.20 hrs

7. Auto Transformer: Single phase and Three phase Auto transformers, advantages & disadvantages. 5 hrs

8. Testing of Single & Three phase Transformers: Polarity test, Short circuit and Open circuit tests, Sumpner’s test. 5 hrs

REFERENCES BOOKS :

1. Performance and Design of DC Machines - A E Clayton & N N Hancock.2. Electrical Technology: H Cotton.3. Performance & Design of AC Machines : M. G. Say.4. Theory of AC Machines - Langsdorf.5. Principles of AC Machines - Lawrence & Richards6. J & P hand book


2K6 SYLLABUS

44

III SEMESTER B.E (ELECTRICAL & ELECTRONICS)2K6EE304 Electrical & Electronics Measurements



PART-A1. Units, Dimensions & Caliberation of Measurements : S-I system of units. Dimensional analysis

using S-I system of units, Primary, Secondary and working Intrinsic and Prototype calibration.6 hrs

2. Measurement Principles : Systematic errors, Random errors, Cumulative errors, Resolution, accuracy, Precision, Stability of Instruments, Graphing data, Best Fit, Interpolation, Extrapolation.

4 hrs3. Ammeters, Voltmeters, Wattmeter, Energy meter and Instrument Transformers : Review of

Permanent magnet moving coil, moving iron, Ammeter, Voltmeter, Electrostatic Voltmeter - theory, construction, errors and limitations. Methods of range extension. Dynamometer type wattmeter-errors and compensating devices. LPF watt meters. Three phase wattmeter and reactive power meter. Induction type energy meters -single phase and three phases. Errors, adjustments and calibration. Theory and construction of current transformers-ratio and phase angle error. Theory and construction of potential transformers, errors. Effect of variation of burden, power factor and frequency on the performance of CT and PT. Silsbee’s method of CT testing. 14 hrs

4. Measurement Of Resistance, Inductance And Capacitance : Wheatstone bridge and its limitations, Kelvin’s double bridge. Loss of charge method, Megohm Bridge method, Measurement of Earth Resistance, Factors affecting Earth Resistance, Cable fault location by Murray loop test, Megger, Maxwell’s bridge. Anderson’s bridge. Desauty’s Bridge and Schering Bridge. AC and DC detectors. Sources of errors in A.C. bridges-remedial measures. 10 hrs

5. Potentiometers : Principle, Crompton’s DC potentiometer, Polar and co-ordinate type AC potentiometers. Applications. 6 hrs

PART-B

6. Electronic Meters : Block schematic description of Electronic Voltmeter, True RMS Voltmeter, Digital Voltmeter (Ramp, Integrating, Continuous Balance and SAR), Source of Error in DVM, RF power and voltage measurements, Q meter. 6 hrs

7. Signal Sources : Function generators, Frequency synthesized signal generator, Standard signal generators (RF), Sweep frequency generators (Direct and Indirect). 3 hrs

8. Signal Analyzing Instruments : Spectrum Analyzers – Fourier Transform Spectrum Analyzer, Application of Spectrum Analyzer, Sensitivity of spectrum Analyzers, Distortion Analyzer, Network Analyzer and Wave Analyzer and their applications. 4 hrs

9. Digital Analyzing Instruments : Electronic Counters, Errors in counters, Extending frequency range of counters, Logic Analyzers. 3 hrs

10. Input Transducers for instrumentation systems : Classification, Selection, Static gauge, Displacement, LVDT, Piezoelectric, Proximity, Thermocouple, Thermistors, Photosensitive their characteristics and applications. 4 hrs

REFERENCES :1. Electrical & Electronic Measurements & Instrumentation - A K Sawhney.2. Modern Electronic Instrumentation and Measuring Techniques - Cooper & Helfrick.3. Electrical Measurements & Measuring Instruments - Golding & Widdies, Pitman.4. Electrical Measurements - Harris.5. Principles of Measurement Systems - John P Beately.6. Electrical Measurements - Stout.7. Applied Electronics Instrumentation and Measurement – David Buchala and Wayne.8. Electronics Measurement, New York, McGraw Hill – Terman and Petit.9. Electronic Instrumentation – K S Kalsi.


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45

III SEMESTER B.E (ELECTRICAL & ELECTRONICS)2K6EE305 Electronics laboratory I



1. Characteristics of semiconductor & Zener diodes.

2. Characteristics of transistors (CE & CB modes) determination of static h - parameters.

3. Characteristics of MOSFET.

4. Clipping & Clamping ckts, using diodes.

5. Attennuators.

6. Single stage RC coupled amplifier.

7. Two - stage Direct Coupled amplifier.

8. Transformer coupled amplifier.

9. Emitter follower & Darlington pair Emitter follower.

10. Boots trapped emitter follower.

11. Differential amplifier.

12. Tuned amplifiers.

13. Class A, Class B and Class AB push pull amplifier.

III SEMESTER B.E (ELECTRICAL & ELECTRONICS)2K6EE306 Electrical Machines laboratory I



1. Open circuit characteristic of a D.C. generator.

2. Load characteristics of shunt and compound generators.

3. Load test on shunt and compound motors.

4. Hopkinson’s test.

5. Swinburne’s test

6. Speed control of D.C. shunt motor by field control and armature control.

7. O.C. and S.C. tests on single phase transformer, predetermination of efficiency regulation, equivalent circuit.

8. Parallel operation of two single phase and 3 phase transformers.

9. Sumpner’s test.

10. Separation of losses in a single phase transformer.

11. Polyphase connections : Voltage relation and harmonic analysis, Υ- Υ, Υ- Υ with grounding on both sides, Υ- Δ, grounded Υ- Δ, Δ – Δ.

12. Scott connection.

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46

III SEMESTER B.E (ELECTRICAL & ELECTRONICS)2K6EE307 Electrical Circuits & Measurements laboratory



1. Measurement of Inductance by three Voltmeter, Ammeter method and A,V,W method.

2. Measurement of Capacitance by three Voltmeter, Ammeter method and A,V,W method.

3. Verification of theorems (D.C. Circuits only) Superposition, Reciprocity.

4. Verification of theorems (D.C. Circuits only) Thevenin’s theorem, Maximum power transfer theorem.

5. Measurement of Resistance by

(i) Wheatstone’s Bridge (ii) Kelvin’s Double Bridge

6. Adjustment and Calibration of Single phase Energy meter.

7. Measurement of Resistance by DC Potentiometer ; Calibration of Ammeter, Voltmeter & Wattmeter by D.C. Potentiometer.

8. Measurement of 3 phase active & reactive power by One Wattmeter method & Two Wattmeter method.

9. Measurement of L and C by A.C. Bridges

a) Maxwell Bridge b) Desauty Bridge c] Anderson Bridge

10. Calibration of current - transformer by Silsbee’s Test.

11. Calibration of Dynamometer type Wattmeter by Phantom Loading Method.

12. Measurement of displacement using LVDT.

13. Temperature measurement by Thermocouple.

14. Integrated type DVM (voltage to frequency conversion).

15. Frequency counter.

2K6 SYLLABUS

47

IV SEMESTER B.E (ELECTRICAL & ELECTRONICS)2K6SM401 Engineering Mathematics – IV



PART-A

UNIT-ISets in the Complex plane-Functions of a complex variable-limit, continuity and differentiability-Analytic functions-Cauchy-Riemann equations in Cartesian and polar forms. Harmonic functionsUNIT-IIComplex integration-Line integral, Cauchy theorem (Proof by Green’s theorem), Cauchy integral formula for complex functions and for derivatives, problems.UNIT-IIIPower series-Convegrence, Radius of convergence, Taylor’s theorem and Laurent’s theorem (statement only), problems.UNIT-IVSingularities, Poles, Classification of singularities, Cauchy residue theorem-Evaluation of definite integrals

of the types

PART–B

UNIT-VAlgebraic and transcendental equations – solution by bisection regular-falsi, Secant’s linear-iteration and Newton-Raphson’s methods, Aitken’s Δ2 – method.UNIT-VISolution of system of linear equations, Gauss-elimination, Gaus-Jordan methods, LU-decomposition, Choleky’s methods, Jacobi and Gauss-Seidle iteration methods.UNIT-VIIFinite differences-Forward, Backward and Central differences – Shift operator (No derivations of relations between operators)Interpolation-Newton’s divided difference, Lagrange’s Interpolation formula (problems only) Numerical differentiation based on Newton’s forward and backward difference formula.

UNIT-VIIINumerical Integration-Trapezoidal, Simposon’s 1/3rd, Simpson’s 3/8th rule, solution of ordinary differential equations : Euler’s, Modified Euler’s, Picard’s, Runge-Kutta II and IV order methods.

PATTERN OF QUESTION PAPER :The question paper contains two Parts namely PART-A and PART-B each containing 4 questions.

Five questions in all out of 8 questions are to be answered choosing atleast two from each PART.

References :1. Complex Analysis : Schaum series2. Numerical methods for Physicus and Engineers, Iyengar, Jain and Iyengar, New Age Inte. 4th Edition.3. Sastry : Introductory methods of Numerical analysis, PHI

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48

IV SEMESTER B.E (ELECTRICAL & ELECTRONICS)2K6EE401 Analog Electronic Circuits-II



PART-A

1. Feedback Amplifiers : Classification, Concept of feedback, Topologies of feedback amplifier, Effect of feedback on different characteristics of feedback amplifier, Analysis of voltage series, current series, current shunt & voltage shunt feedback amplifiers. 12 hrs.

2. Sinusoidal Oscillators : Introduction, Types of oscillators, Barkhausen criteria for sustained oscillations, Generalized Analysis of oscillators using BJT and MOSFET. Analysis of LF oscillators - RC phase shift (both phase lag & phase lead) & Wein bridge oscillator. Analysis of LC tuned oscillators - Hartley, Colpitt’s & Clapp’s oscillator, Tuned collector oscillator. Crystal oscillators, Frequency stability & amplitude stability. 12 hrs.

3. Negative resistance devices & Circuits : Negative resistance, characteristics - voltage controllable & current controllable, Tunnel diode, UJT-VI characteristics Negative resistance phenomenon Tunnel diode & UJT relaxation oscillator. 10 hrs.

PART-B

4. Voltage Time Base Generators : Features of time base signal, Methods of generation Bootstrap time base generator - working & waveforms. 6 hrs.

5. DC Power Supplies : Half wave, Full wave & Bridge rectifiers - comparison, ripple factor, efficiency, regulation, transformer utilization factor. Full wave rectifier with filters - Analysis of capacitor, inductor, LC & Pi section filters. Regulators - Working & analysis of Zener regulator, Series regulator with & without feedback, shunt regulator & current regulator. Short circuit protection Voltage multipliers - Half wave & Full wave. Principles of switching regulator, its merits over linear regulator. 20 hrs.

REFERENCES :1. Electronic Devices and Circuits - Millman & Halkias.2. Principles of Electronics - Kamal Choudhary.3. Taxas instrumentation Inc - Transistor Circuit Design.4. Pulse Digital & Switching wave forms - Millman & Taub.5. Foundation of Electronics - Chatopadhyay.


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49

IV SEMESTER B.E (ELECTRICAL & ELECTRONICS)2K6EE402 Micro Electronics


Exam marks: 100 Sess. marks 25.PART-A

1. LINEAR ICs: Introduction to Linear ICs, Operational Amplifiers : Ideal Op-amp, Electrical Parameters, Analysis of op-amp ckt, Characteristics & Ratings. Op-amp ckts - Inverting and Non-Inverting Amplifiers, Voltage Follower, Summer, Integrator, Differentiator, Comparators, Schmmitt Trigger, Instrumentation Amplifier, Precision Rectifier, Peak Detector, Sample & Hold ckt. Voltage to Frequency Converter, Square Wave, Pulse, Stair Case, Wave & Triangular Waveform Generator. Multivibrators : Monostable, Astable. Timer : Basics of Timer ckt - 555 Timer used as Astable & Mono-Stable Multi vibrators. 15 hrs.

2. Digital ICs: SSI, MSI, LSI & VLSI ckts. Boolean Algebra, Demorgans Laws, Logic Gates, Simplification of SOP & POS Expressions (Minterms & Maxterms), Canonical SOP and POS forms, Karnaugh Map, Tabular Method, VEM Technique Reduction upto SIX variables, LOGIC FAMILIES : TTL, CMOS, NMOS, PMOS, HMOS, VHMOS, I I L ( I2L ) & ECL Logic Families Parameters & Characteristics. 15 hrs.

PART-B

3. COMBINATIONAL CIRCUITS: Half adder, Full adder, Full subtractor, Parallel adders, Design of Ex-3 adder/subtractor, BCD adder, Carry Look Ahead adders, Digital Comparators, Multiplexers : Design of Combinational Circuits using MUX, MUX TREE and its design, Demultiplexers : Design of Combinational Circuits, Encoders, Decoders & Priority Encoders, Code Converters : Gray to Binary and Binary to Gray, BCD to Ex-3, Ex-3 to BCD, Decimal to BCD, Decimal to Hex-decimal and vice-versa, ASCII Code, EBCDIC Code, Weighted and Non-weighted Codes. ALU : Circuits Design using ALU. LED and LCD Display. 12 hrs.

4. SEQUENTIAL CIRCUITS: Flip flops, RS, JK, Master slave JK, D & T FFs. Counters : Asynchronous & Synchronous counters : Design of Ripple/Binary counter, Up-down counter, Binary Up-down counter, 2421, 5421, 4421, 2221 counters upto 4 bits, Study of 7490, 7493, 7492, 74192, 74193 and their applications, Shift Registers : Study of 7495, SISO, SIPO, PIPO,PISO, Right Shift, Left Shift. Bi-directional, Ring counter, Johnson counter (Twisted Ring counter), Counters and Generators : Design of Counters using Shift Registers, Universal State Diagrams, Sequence Generators. 10 hrs.

5. DATA CONVERTERS: D/A Converters : Binary Weighted and R-2R Ladder Network, A/D Converter : Flash/Simultaneous type, Successive Approximation, Single Slope, and Dual Slope, RAM/Stair Step, Parallel to Serial Conversion using A/D, Accuracy Resolution & Errors in D/A & A/D Converters. 6 hrs.

6. MEMORIES : RAM, ROM, PROM, EPROM, EEPROM, PLA : Design of Digital Circuits using PLA, PAL. 2 hrs.

REFERENCES :

1. OP - Amplifiers and Linear IC’s - Gayakwad.

2. OP - Amplifiers and Applications - Coughlin & Driscol.

3. Microelectronics - Jacob Millman.

4. Integrated Circuits - Taub & Schilling.

5. Digital Principles and Applications - Malvino & Leech.


2K6 SYLLABUS

50

IV SEMESTER B.E (ELECTRICAL & ELECTRONICS)2K6EE403 Signals and Systems



PART-A

1. Introduction : Continuous time & Discrete time signals. Transformation of independent variable, exponential & sinusoidal signals. Unit impulse & unit step functions. Discrete time systems & their basic system properties. Basic system properties. Conversion of continuous – time system to discrete time system. Modeling by discrete-time system. 10 hrs

2. Linear – Time – Invariant Systems (LTI) : Discrete time LTI systems, Convolution sum, Continuous-time LTI systems, the convolution integral. Properties of Linear time invariant systems, Causal LTI systems described by differential and difference equations. 10 hrs

3. Fourier series Representation of Periodic Signals : Response of LTI systems to complex exponentials. Fourier series representation of continuous time periodic signals. Fourier series representation of discrete time periodic signals. Fourier Series & LTI systems. Continuous time and discrete-time Filters. 10 hrs

PART-B

4. Fourier Transform : Definition of Fourier transform & its Inverse. Properties of Fourier transform. Fourier transform of periodic signals. Spectral density, Autocorrelation Functions, Cross-correlation functions, and its properties. Discrete time Fourier transform & its properties, frequency Response of discrete time systems. Hilbert Transform : Definition of Hilbert transform, Pre-envelope. Representation of Bandpass signals and band-pass systems. 14 hrs

5. Z-transform : Definition of Z-transform & its inverse, Properties of Z-transform, Region of convergence of Z-transform, Inverse Z-transform - inverse by long division & partial fraction expansion methods – by evaluation of residues. Analysis & characterization of LTI systems using Z-transforms. 10 hrs

6. Network Functions: Network functions of one port and two port Networks, poles and zeros. Time domain response from pole zero diagram. Restrictions on pole and zero locations for driving point and transfer functions. 6 hrs.

References Books :

1. Kamen, Heck : Fundamentals of Signals & Systems using MATLAB.

2. Oppenheim, Willsky & Nawab : Signals & Systems : PHI.

3. Carlson : Signals & Linear System Analysis : Wiley Engg.,

4. Haykins : Communication Systems : III Edition

5. Haykins : Signals & Systems : John Wiley International.

6. Nagarath et. Al, TMH, 2001.


2K6 SYLLABUS

51

IV SEMESTER B.E (ELECTRICAL & ELECTRONICS)

2K6EE404 Object Oriented Programming Using C++


Exam marks: 100 Sess. Marks 25.

1. Introduction: Characteristics of OOPs. 2 hrs.

2. C++ Programming Language : Program statements, declaration statements, constants variables data types, Operators, type conversion, assignment statements, cin and cout statements. 3 hrs.

3. Loops and Decisions : For, While and Do-while loops, If, If-else, Switch statements, Break, Continue and Goto statements. 4 hrs.

4. Functions : Defining a function, function arguments, default arguments, constant arguments, passing by value, passing by reference, inline functions, function overloading, functions and strings, functions and structures, arrays and pointers. 7 hrs.

5. Classes and Objects : Specifying a class, member function, private & public, static data members, static member function, array of object, function argument, friend function, returning objects. 10 hrs.

6. Constructor & Destructor : Definition, Constructor with default and multiple arguments, copy constructor, dynamic initialization of objects. 6 hrs.

7. Operator overloading : Definition, overloading unary and binary operator, usage of friend function, rules for overloading. 5 hrs

8. Inheritance : Introduction, single, multiple, multilevel, hierarchical hybrid, virtual base class, abstract base class, constructors in derived class, pointers to objects, virtual functions, polymorphism. 5 hrs

9. Files : Streams, opening & closing of files, File modes, File input and output using fundamental and abstract data types, character and string input/output, templates and exception handling. 10 hrs.

10. Data Structures : Linked list and its advantages, Single linked list, Doubly linked list, Circularly linked list, Stack and Queues, Searching, Sorting. 8 hrs.

Reference Books :

1. Object Oriented Programming in Turbo C++ Robert Lafore2. Object Oriented Programming in Turbo C++ Venugopal 3. Object Oriented Programming in Turbo C++ Balaguruswamy4. The C++ Programming language by B. Jarne Stronstrup, Person Education, 3rd edition.5. Data Structures using C++ by Padma Reddy.

Question paper pattern :The question paper consists of 8 questions. The students have to answer 5 full questions.

2K6 SYLLABUS

52

IV SEMESTER B.E (ELECTRICAL & ELECTRONICS)2K6EE405 Electrical Machines II

(Induction machines & Synchronous machines)



PART-A

1. Three-phase Induction Motors : Types, Construction, Rotating Magnetic Field, Principle of Operation, Equivalent circuit, Phasor diagram, Slip, Torque equation and Maximum Torque, Torque Slip Characteristic. Relation between Slip Rotor Copper Losses, Rotor input and Efficiency. Free Run and Blocked Rotor Tests, Circle Diagram. Methods of starting, Star-delta starting, Auto transformer starter, rotor resistance starter. Introduction to speed control of Induction motor. 18 hrs.

2. Induction Generators : Negative slip, Generator Vs Motor action. Characteristics & circle diagram.3 hrs.

3. Single Phase Motors : Construction, Double Revolving Field theory and Principle of operation. Starting torque and methods of starting - Split phase, Shaded pole, Capacitor start and Capacitor run, Universal motor. Applications. 6 hrs.

PART-B

4. Synchronous Generators : Construction, Salient and non-salient pole machines, EMF equation, different types of windings, winding factors. Fractional slot windings. Harmonics - reduction and elimination. Armature reaction - leakage reactance and synchronous reactance. Vector diagram of alternator (non-salient type). Transient, sub-transient and steady state reactances. 10 hrs.

5. Two Reaction Theory : Direct axis and quadrature axis synchronous reactance, vector diagram. Slip test and regulation. Equation for power in terms of power angle for salient and non-salient pole alternator.

4 hrs

6. Voltage Regulation : EMF, MMF, ZPF method. Short circuit ratio of alternators. 4 hrs.

7. Parallel Operation of Alternators : Effect of change of excitation and input. Conditions for parallel operation. Synchronisation and Synchronising power, operation of alternator on infinite bus. Division of load between two alternators, capability curves or operating chart of alternators. 7 hrs.

8. Synchronous Motor : Principle of operation, Rotating magnetic field, vector diagram for salient and non-salient pole motor. Torque and torque angle, Blondel diagram, Effect of change in load, Effect of change in excitation, V and inverted V curves. Synchronous condenser. Maximum power. Hunting and damping. Methods of starting synchronous motors. 8 hrs.

REFERENCES BOOKS :

1. Performance and Design of AC Machines - M G Say.2. Principles of AC Machinery - Lawrence & Richards.3. Electrical Technology - H Cotton.4. Theory of AC Machinery - Langsdorf.5. Theory of AC Machinery - J B Gupta.


2K6 SYLLABUS

53

IV SEMESTER B.E (ELECTRICAL & ELECTRONICS)2K6EE406 Electrical Machines laboratory II (Induction & Synchronous)



1. No-load and blocked-rotor tests on 3 phase induction motor-circle diagram-Predetermination of performance curves-Equivalent circuit.

2. Load Test on 3 phase induction motor.

3. Load Test on single phase induction motor.

4. Load test on induction generator.

5. Open circuit & short circuit tests on alternators-regulation by EMF & MMF methods.

6. Regulation of alternators by ZPF method.

7. Determination of Xd & Xq of a salient pole alternator & predetermination of regulation.

8. V & inverted V curves of synchronous motor.

9. Harmonic analysis of voltages.

10. Short circuit performance of Synchronous machines.

11. Analysis of Short circuit current wave shape by using Harmonic analyzer or by hand calculation.

IV SEMESTER B.E (ELECTRICAL & ELECTRONICS)2K6EE407 Electronics laboratory II



1. Diode Rectifier with and without capacitor filter.

2. Voltage series feedback amplifier.

3. Voltage multiplier circuits.

4. Transistor RC phase shift oscillator using BJT.

5. Transistor Hartley & Colpitt’s oscillators.

6. Pierce crystal oscillator.

7. Series Voltage regulator.

8. Op-amp applications (i) Inverting (ii) Non-inverting (iii) Voltage follower (iv) Integrator

(v) Differentiator (vi) Precision rectifier

9. ZCD and Schmitt trigger using OPAMP.

10. Op-amp / Timer as Astable and Monostable Multi vibrator.

11. Realization of 2’s compliment full adder / subtractor.

12. Realization of MUX and DEMUX using NAND gates.

13. Modulus-N counter using 7490, 7493 and 74193 i.e., chips up down counter.

14. Universal shift register and its application such as Ring counter, Johnson Ring counter, Maximum

sequence generator using feedback circuit for 4 bits, SISO, SIPO, PIPO, PISO.

15. D/A converter : R to 2R type.

16. Single digit display using 7 segment display device, counter and a decoder 7447/7446 IC.

2K6 SYLLABUS

54V SEMESTER B.E (ELECTRICAL & ELECTRONICS)

2K6EE501 CONTROL SYSTEMS ENGINEERING(Effective from the Academic year 2008-09)



1. Modeling of Systems : Definition of Control systems, open loop and closed loop systems, types of feedback, Modeling of Electrical, Mechanical and electromechanical systems, differential equations of physical system. F-I and F-V analogous circuits. Linear and non-linear, continuous, discrete data, time invariant, time variant control systems. 8 hrs

2. Block diagram and Signal flow graphs : Transfer function, block diagram representation and reduction, signal flow graph representation and reduction using Mason’s gain formula. 8 hrs

3. Time Response of Feed back control systems : Standard test signals, steady state error analysis, unit step response of first and second order systems, time domain specifications and transient response of a prototype second order system. 10 hrs

4. Stability analysis : Bounded input and bounded output stability, zero input and asymptotic stability, methods of determining stability, Routh-Hurwitz criterion. 8hrs

5. Root locus Techniques : Basic properties and construction. Procedure to construct root locus diagrams. Analysis of simple problems using root locus. 8 hrs

6. Frequency domain analysis : Polar plots, Bode plots, Gain and Phase cross over points, Frequency domain specifications – resonant peak, resonant frequency and bandwidth. Effect of adding a zero or pole to the forward path transfer function. Nyquist stability criterion, relative stability using polar plot and Bode plot. 12 hrs

7. Controllers : Design of P, PI and PID (Frequency domain approach). 6 hrs

REFERENCES :

1. Control Systems (Tata McGraw Hill, 2nd Edition, 2002) - Nagarath & Gopal.

2. Modern Control Systems, [Pearson Education, 8th Edition, 2002] – Richard C Darf and Robert H Bishop.

3. Modern Control theory [Pearson Education, 4th Edition, 2002] – Ogata.

4. Automatic control systems (Prentice Hall New Delhi) - B C Kuo.

5. Analysis of linear systems - David K Cheng.

6. Control Systems – Nagoor Kani.

8. Problems and Solutions in Control System – A. K. Jairath

2K6 SYLLABUS

55

V SEMESTER B.E (ELECTRICAL & ELECTRONICS)2K6EE502 ELECTRICAL MACHINE DESIGN

(Effective from the Academic year 2008-09)



1. Design Considerations : Specification of transformers and rotating machines. Factors to be considered in design and limitations. Temperature rise in Electrical machines, Methods of cooling & quantity of cooling medium. 6 hrs.

2. DC Machines : Main dimensions of the armature, design of armature winding and dimensions of the slots. Design of commutator and brushes. Design of magnetic circuit and estimation of the mmf, Design of shunt and series field windings, Design of interpoles. 15 hrs

3. Design of Transformers : Main dimensions of the core, details of winding, No load current, leakage reactance - estimation in case of simple winding configurations, Determination of the voltage regulation and efficiency. Design of tank, round and rectangular tubes. Design of Current transformers.

12 hrs.

4. Design of three phase induction motor : Main dimensions of the stator, details of stator winding, dimension of the slots. Design of cage and slipring rotor & rotor windings. No load current, leakage reactance and circle diagram. 15hrs.

5. Design of Synchronous machines : Main dimensions of the stator, details of stator windings, dimensions of the slots. Design of rotor & rotor windings of salient and non-salient pole type alternator. 12 hrs.

REFERENCES :

1. The performance & Design of Direct Current machines - Albert C Clayton & N N Hancock.2. Elements of Electrical Machine Design - Still & Siskind.3. The Performance & Design of Alternating Current Machines - M G Say.4. A Course in Electrical Machine Design - A K Sawhney.

Note : The students have to answer FOUR questions out of SIX questions.

2K6 SYLLABUS

56

V SEMESTER B.E (ELECTRICAL & ELECTRONICS)2K6EE503 TRANSMISSION & DISTRIBUTION




1.GENERATION: Introduction to generation of electrical energy, Sources of energy, Types of generating stations, Thermal, Hydroelectric, Nuclear, Selection of site. Load curves, Load duration Curves. Economics of Power generation. 10 Hrs

2. SUPPLY SYSTEMS: General layout of Power system, effect of transmission voltage on conductor weight, transmission efficiency and line drop. Effect of low Power factor and improvement of Power Factor. 4 Hrs

3. OVERHEAD SYSTEMS: Types of supporting structures, comparison of copper, aluminium and ACSR conductors. Sag calculation, Supports at same level and at different levels. Effect of wind, ice, temperature correction. Stringing charts and Sag templates, line vibrations, vibration dampers. 6 Hrs.

4. INSULATORS : Materials used, types of insulators, potential distribution over a string of insulators, methods of improving string efficiency, grading rings and arcing horns, Testing of insulators (with mention of relevant IS standards ) 5 Hrs

5. UNDERGROUND CABLES : Comparison with overhead lines, different types of Insulating materials used including XLPE and Gas insulation. Types of Cables, Insulation resistance, Electric stress and Capacitance of string core cables, Grading of cables, Intersheath and capacitance grading. Capacitance of Three core cables. 8 Hrs

6. CORONA : Phenomena of Corona, Disruptive and visual critical voltage, power loss, advantages and disadvantages of Corona. 3 Hrs

7. LINE PARAMETERS : Inductance of single phase, two wire line, composite conductor lines, self and mutual GMD. Inductance of three phase lines, equilateral spacing, unsymmetrical spacing, transposition, Inductance of transposed line with unsymmetrical spacing, Bundle conductors.Capacitance of single phase two wire lines, 3 phase lines with symmetrical spacing and unsymmetrical but transposed lines. Ferranti effect, power loss due to charging current. Skin effect and proximity effect.

10 Hrs.

8. LINE PERFORNAMCE : Short lines, medium lines, nominal T and PI methods, long lines, ABCD constants. 8 Hrs.

9. DISTRIBUTION : Feeders, distributors and service mains, AC distribution. 6 Hrs

REFERENCES: 1. Transmission and Distribution by H Cotton.2. Principles of Electrical Power Transmission by Waddicar.3. A Course in Electrical Power by Sony, Gupta and Bhatnagar.4. Electrical Power by S L Uppal.5. Electrical Power Systems by C L Wadhwa.

2K6 SYLLABUS


2K6EE504 POWER ELECTRONICS(Effective from the Academic year 2008-09)



1. Power Semiconductor Devices : Power diodes, SCR, GTO, Triac, Power transistors, Power MOSFET, IGBT - their junction structure, Switching characteristics, Rating & applications. 6 hrs.

2. Thyristor : Junction structure, Static characteristics, Diode and two transistor analogy, dynamic turn on and turn off characteristics, Triggering methods. R,RC,UJT triggering. Protection against OV,OC, Snubber circuit, Thyristor ratings and protection, series and parallel operation of thyristors. 8 hrs.

3. Power Converters : Controlled rectifiers, single phase and three phase half and fully controlled bridge feeding resistive, Inductive and DC motor loads, Free wheeling diode, effect of load and source inductance, Dual converters and their applications. 10 hrs.

4. AC voltage controllers : ON OFF control, phase angle control, single phase uni and bidirectional controllers with R, L, E loads, Cyclo converters. 8 hrs.

5. Turn off methods : Principle of commutation, Class A, B, C, D , Circuits and their design procedure.6 hrs.

6. Choppers : Principle, Classifications step down, step up, buck boost, buckboost regulators and their applications 8 hrs.

7. Inverters : 1 and 3 VSI, Series, Parallel, Bridge, Current source Inverters, Voltage control techniques, Harmonic reduction, Performance analysis. 10 hrs.

8. Industrial Applications : UPS, SMPS, Speed control of motors. 4 hrs.

REFERENCES :

1. Thyristor and their Applications - M Ramamurthy.2. Power Electronics - Circuits, Devices, Applications - Rashid.3. Power Electronics - Principles & Applications - Joseph Vithyathil.4. Power Electronics - P.C. Sen.5. Power Electronics – Dr. P. S. Bimbhra6. Power Electronics – M D Singh & Kanchandani

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58

V SEMESTER B.E (ELECTRICAL & ELECTRONICS)2K6EE505 ELECTRO MAGNETIC FIELD THEORY




PART A

1. Electrostatics : Coulomb’s law. Electric field intensity, electrostatic potential and potential difference. Field due to several point charges, principle of linear superposition. Concept of line charge, surface charge and volume charge. Scalar potential and its relation with electric field. Field maps and field cells. Gauss’s theorem and applications. Poisson’s and Laplace equations-solutions for simple cases. Dipole, polarization and r of dielectric, Capacitance calculations for different configurations. Energy and energy density in an Electrostatic field. Boundary conditions. Displacement current and density. Equation of continuity of currents. 16 hrs

PART B

2. Magnetostatics : Introduction. Magnetic flux and flux density. Magnetic field intensity. Biot-Savart’s law, Ampere’s law and applications. Forces and Torque Lorentz force equation. Force acting on a current carrying conductor. Examples on Force Calculation, Torque on a loop in magnetic field. Scalar and vector potentials-applications. Neuman’s formula for Inductance. Inductance calculations for simple configurations. Magnetic Dipole and r. Energy stored and energy density in a magnetic field. Boundary conditions. 16 hrs

3. Time varying Electric and Magnetic fields : Introduction. Faraday’s law of electromagnetic induction. Faraday’s law in integral and differential forms. Maxwell’s equations from different laws in differential and integral forms. Maxwell’s equations for free space and harmonic fields. 10 hrs

4. Relationship between field and circuit theory : Application of field and circuit theory for series circuit. Maxwell’s equations as generalization of circuit equations. 4 hrs

PART C

5. Electromagnetic Waves : Wave equations IN FREE SPACE. Rectangular plane waves in free space. Sinusoidal plane wave propagation in Free space, Good dielectrics, good conductors and in lossy dielectric media. Skin depth and Skin effect. Relaxation time. 8 hrs

6. Poynting Vector and flow of power : Poynting’s theorem and Poynting Vector. Instantaneous average and complex poynting vector. Power loss in a plane conductor. Application of P-vector.

4 hrs

7. Introduction to Computational Electromagnetics using Software packages. 2 hrs

REFERENCES :1. Electromagnetics (McGraw Hill) - John D. Kraus.2. Electromagnetic waves and radiating systems - Jordon.3. Engineering Electromagnetics - W. Hayt. Jr.4. Electromagnetic fields - S. Seely.5. Foundation of electromagnetic theory - Reitz & Milford.

2K6 SYLLABUS


2K6EE506 ELECTRICAL DRAWING(Effective from the Academic year 2008-09)



1. IEEE symbols used in Electrical Engineering and preparation of wiring diagrams using symbols.6 hrs.

2. DC windings : Double layer, simplex and multiplex lap and wave windings.8 hrs

3. Three Phase AC Windings : Double layer integral and fractional slot lap and wave windings. Single layer windings - unbifurcated, bifurcated and mush windings.

8 hrs.

4. Details of drawings : yoke and poles, armature and commutator of a DC machine, Details of stator and rotor of alternator and induction motor. (to be dealt separately) 28 hrs.

5. Detail drawing of Single & 3 phase Transformer of Core &Shell type Transformer.10 hrs.

REFERENCES:

1. Alternating Current Armature Windings - Siskind.

2. Electrical Drawing - K L Narang.

3. General Electrical Drawing - Surjit Singh.

2K6 SYLLABUS

60V SEMESTER B.E (ELECTRICAL & ELECTRONICS)2K6EE507 POWER ELECTRONICS LABORATORY




1. Static characteristics of SCR, Diac, Traic & MOSFET.2. SCR triggering circuits a. Resistance triggering

b. RC triggering c. UJT triggering

3. Phase controlled rectifiers. Single phase half and full Bridge rectifier with R, RL loads with and without freewheeling diode4. Forced commutation circuits

Self commutation using LC circuits Auxiliary commutation

Complimentary commutation.5. DC motor control using single phase converter.6. Jone’s Chopper7. DC motor control using choppers.8. Application of Triac a) Speed control of universal motors b) Induction motor 9. Cycloconverter10. Single-phase inverters half bridge and full bridge.

V SEMESTER B.E (ELECTRICAL & ELECTRONICS)2K6EE508 CIRCUITS AND CONTROL SIMULATION LABORATORY




1. Simulation of RLC circuit using Pspice.

2. Simulate the following theorems using Pspice

1) Thevinin’s Theorem (AC & DC)

2) Maximum Power Transfer (AC & DC) Theorem

3) Super position (AC & DC) Theorem

4) Reciprocity Theorem

3. Measurement of three phase active and reactive power of balanced and unbalanced loads.

4. Simulation of single phase and three phase AC – DC converters using Pspice.

5. Commutation circuits.

6. Design of chopper circuit & simulation using p-spice, Buck, boost and Buckboost.

7. Simulation of single phase, AC voltage controller circuits (ON OFF & phase angle control).

8. Design of single phase, 3 phase voltage source inverter and obtain the load voltage and load current

using p-spice.

9. Transient response of 1st order, 2nd order systems.

10. Root locus based on design using mat lab.

11. Bode plot based on design using mat lab.

12. Nyquist plot based on design using mat lab.

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61

VI SEMESTER B.E (ELECTRICAL & ELECTRONICS)2K6EE601 MICRO PROCESSOR & MICRO CONTROLLER




PART A : MICROPROCESSORS

INTRODUCTION : Microprocessors, Classification, Microprocessor families. 2 hrs

8085 Microprocessor : Architecture, Addressing modes, Timing diagram for memory read & memory write operations. 4 hrs

8086 Microprocessor : Architecture, Organization, Addressing modes, Instruction sets of 8086. 6 hrs

Instruction & Programming : Instruction format, Detailed instruction sets of 8086, Assembly language programming examples: Binary & BCD arithmetic operations, Software delay generation, Searching & Sorting, Code conversions: BCD to binary & binary to BCD code conversion. ASCII – Binary & Vice-Versa, Use of stack subroutines & interrupts. 10 hrs

PART B : INTERFACING

Interfacing & Programmable peripheral devices : Concept of interfacing, Memory & I/O mapping. Detailed study of interfacing devices. 8255-Programmable peripheral interface, Block diagram and Architecture – Key Board interfacing, A / D converter, DAC converter, 8253 Timer interfacing, Square wave generation, 8259 Programmable interrupt controller, 8257 DMA controller, 8251 Serial Communication, 8279 Keyboard Interface. 20 hrs

PART C : MICROCONTROLLERS

INTRODUCTION : Concept of Microcontrollers, comparison of Microcontrollers against Microprocessors. 2 hrs

8051 Microcontroller : Architecture, Addressing modes, Instruction set, Assembly Language Programming. 16 hrs

REFERENCES :1. Microprocessor Architecture, Programming and applications - Ramesh Gaonkar.2. Microprocessor Fundamentals - Douglas .V. Hall.3. Introduction to Microprocessor - A.P.Mathur.4. Microprocessor Peripherals - Bram.5. Design with Microcontrollers - John.B.Peatman.6. Programming and customizing using 8051 Microcontroller—Myke Predko7. 8051 Microcontroller—Kenneth Ayala

2K6 SYLLABUS

62VI SEMESTER B.E (ELECTRICAL & ELECTRONICS)

2K6EE602 H V ENGINEERING(Effective from the Academic year 2008-09)



PART A

1. Introduction: Advantages of high voltage for power transmission-prospective voltage levels. 2 hrs.

2. Generation of high voltages :

A C Voltages : Transformers in cascade. Resonant transformers – parallel and series resonant transformers. Tesla coil.

D C Voltages : voltage doubler circuit, cockroft - Walton cascaded D C generators – Voltage regulation, ripple, optimum number of stages. Electrostatic DC generators.

Impulse Voltages : Standard Lighting and switching voltages. Single stage impulse generators. Multistage impulse generators. Controlled tripping - three - electrode and trigatron gap methods. Impulse current generator. Generation of switching surge voltages. 14 hrs.

3. High Voltage & Current Measurements : R-dividers for AC and DC voltages. Generating voltmeter. Electrostatic voltmeter, sphere gaps - Method of measurement of AC, DC and impulse voltages. Effects of temperature, pressure, humidity and radiation. Potential dividers for impulse voltages-R, C and RC mixed dividers. Measurement of high DC, AC and Impulse currents. Diode peak voltmeter.

10 hrs.

4. Breakdown Theory : Ionisation phsenomena, Breakdown in Gases - Townsend’s theory, Paschen’s law, streamer’s theory of break down. Time lags of breakdown, Breakdown in Electronegative gases, Corana discharges and breakdown in non-uniform field. Breakdown in solid and liquid dielectrics.

8 hrs.

PART B

1. Over Voltage Phenomena on Transmission lines : Causes of over voltages including lightning, switching, faults etc. Origin of travelling waves. Partial differential equations for loss less lines and their solution. Behavior of rectangular travelling wave at transition points - open ended line, short circuit line, line terminated with a resistance, capacitance and inductance (R-L-C). Bewley - Lattice diagram. Protection of transmission lines against over voltages - Horn gap, surge absorber. Ground wires, Lightning arrestors - Silicon carbide and Zinc oxide arrestors - comparison between them with regard to construction and characteristics. Insulation co-ordination. 10 hrs.

2. High Voltage testing of electrical apparatus : Layout of HV Testing laboratory. Clearances, earthing and shielding. 4 hrs.

3. Non destructive HV tests on materials and apparatus: Introduction, Measurements of capacitance and loss factor using Scherings bridge at low and high frequencies. Partial discharge measurements. Straight and balanced methods of detection. Measurement of PD in cables and transformers. 6 hrs.

4. High voltage Testing of Electrical apparatus : HV testing of Bushings, testing of cables, transformers and surge diverters ( to be discussed with testing circuits and procedure for important tests as per Indian Standards). 6 hrs.

REFERENCES: 1. High Voltage Engineering (Pargamon Oxford) - Kuffel and Zangel.2. High Voltage Engineering (TMH New Delhi) - Naidu and Kamaraju.3. A Course in electrical Power - Soni, Gupta and Bhatnagar.4. T & D Hand Book - Westinghouse.5. An Introduction to HV experimental Techniques - Deterkind. (Wiley Eastern)6. Partial discharge Measurements - IEC Specification No 270(1968) SI 6209(1971).7. Methods of HV testing - IS 2071 - (1976).8. Methods impulse testing - IS 2070 - (1962). 9. Insulators testing - IS 2099 - (1986), IS-731.10. Impulse testing of transformers - IS 2026 - (1981).11. Testing of Circuit Brakers and Isolators - IS 2516 - (1980).12. Testing of Power cables (Part I and Part II) - IS 5959 - (1970).13. Lighting Arrestors - IS 4004 - (1967) and IS 4850 - (1968) and IS 3070 - (1982).14. RIV Measurements - B S 5049 (1973).

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63

VI SEMESTER B.E (ELECTRICAL & ELECTRONICS)2K6EE603 ADVANCED CONTROL SYSTEMS




1. State variable analysis and Design : Introduction, Concept of State, State variables and State model of Linear systems, Linearization of state equations. State space Representation using physical variables, phase variables and canonical variables. State space representation of simple Electrical circuits. 16 hrs

2. Derivation of Transfer function from state model, Diagonalisation, Eigen values and Eigen vectors, Generalized Eigen values. 6 hrs

3. Solution of state equation, State transition matrix and its properties, computation using Laplace transformation, Power series method, Caley-Hamilton method, concept of controllability and observability, methods of determining the same. 14 hrs

4. Introduction, Behavior of Non-linear systems, Common physical Non linearity-saturation, friction, backlash, dead zone, relay, multi variable non-linearity. 4 hrs

5. Phase plane method, Singular points, stability of non-linear systems, limit cycles, construction of phase trajectories. 8 hrs.

6. Pole placement Techniques : Stability improvements by State feed back, necessary and sufficient conditions for Arbitrary pole placement, State regular design, design state observers. 6 hrs

7. Liapunov stability criterion, Liapunov functions, Direct method of Liapunov and the non-linear system. Hurwitz criterion and Liapunov’s direct method. 6 hrs

References :

1. Advanced Control Systems - Nagoor Kani

2. State Space Analysis of Control Systems [ Prentice Hall Inc.] – Katsuhiko Ogata.

3. Control Engineering [ PHI, 2003] – M. N. Bandyopadhyay.

4. Digital Control and State variable methods [TMH, 2003] – M. Gopal.

2K6 SYLLABUS

64

VI SEMESTER B.E (ELECTRICAL & ELECTRONICS)2K6EE604 COMMUNICATION SYSTEMS(Effective from the Academic year 2008-09)



INTRODUCTION : Information, transmitter, Channel, Receiver, Block Diagram of communication systems, modulation-bandwidth requirements. Different types of noises. Noise figure and Noise Calculation. 6 hrs.

AMPLITUDE AND FREQUENCY MODULATION : Expression. Spectral analysis. Power and Bandwidth requirements. Generation and Demodulation circuits for AM, DSBSC, SSB,& FM. Comparison of AM & FM. AM transmitter/receiver. FM transmitter/receiver (Block diagram description).

16 hrs.

PULSE AND DIGITAL COMMUNICATION : Sampling theorem, PAM, PDM and PPM systems. Introduction to Digital Communications-PCM, DM/ADM systems. Broad band communications-Mixing. Theory and coding concepts. Hamming code. Carrier telephones. (Power line carrier communication systems). 16 hrs.

TV TRANSMITTER AND RECEIVER : Block-diagram: Transmitter & Receiver. 6 hrs.

COMPUTER COMMUNICATIONS : Need for communication network. Distributed processing principle of ASK, FSK & PSK. 5 hrs.

LAN NETWORK : Principles of working, Topology, Different standards. Protocols-CSMA/CD and token passing protocols. MAN & WAN Networks. 5 hrs.

MICROWAVE LINKS : Introduction to Microwave Communication, Satellite communication systems, Optical communication system, Mobile communication. 6 hrs

REFERENCES :

1. Electronics Communication Systems – John & Kennedy.

2. Electronics Communication – Roddy & Collen.

3. Communications – Ropbem Schoenbeck

4. Computer Communication Networks – Tannenbaum.

5. Analog & Digital Communications – Simon Haykin

2K6 SYLLABUS


2K6EE605 AC/DC DRIVES(Effective from the Academic year 2008-09)



1. Characteristics of Electric Motors 4 hrs.

2. Dynamics of Electric Drives : Classification, Basic elements of an electric drive. Dynamic conditions & Stability considerations. 6 hrs.

3. DC drives : Single phase drives, 3 phase drives, Chopper drives. 12 hrs.

4. AC drives : Induction motor drivers, synchronous motor : Cylindrical rotor motor, Salient-pole motors, reluctance motors, permanent magnet motors, switched reluctance motor, brushless DC & AC motor drives. 12 hrs.

5. Rating and Heating of Motors : Requirements of a drive motor, Power losses and heating of electric motors, Cooling of electric motors, Classes of duty and selection of motor. 6 hrs.

6. Closed loop control of AC & DC Drives : Open loop transfer function, closed loop transfer function, block diagram, signal flow graph method, PLL control 10 hrs.

7. Drives for Specific Applications : Drive Considerations for Textile mills, Steel rolling mills, Cranes and hoist drives, Cement mills, Sugar mills, Machine tools, Paper mills. 4 hrs.

8. Microprocessors and Control of Electrical Drives : Control of Electric drives using microprocessors, Some aspects of Control System design of microprocessor based variable speed drives, Stepper motor drives. 6 hrs.

REFERENCES :

1. Electric Drives - Vedam Subrahmanyam.2. Electric Drives – G. K. Dubey.3. Power Electronics & AC drives – B. K. Bose.

2K6 SYLLABUS


2K6EE606 COMPUTER ORGANIZATION & DESIGN(Effective from the Academic year 2008-09)



General Purpose Machines : The general purpose machine, the user’s view, the machine / assembly language programmer’s view. The computer architect’s view, the computer system logic designer’s view, historical perspective, Classification of computers and their instructions, Computer Instruction sets, informal description of simple RISC computer, SRC, formal description of SRC using register transform notation, RTN, description of addressing modes with RTN, register transfer and logic circuits: from behaviour to hardware 12 hrs.

Real Machines: Machine characteristics and performance, RISC v/s CISC, a CISC microprocessor, the Motorola MC 68000. 6 hrs

Processor design and microprogramming: The design process, a single bus micro architecture for the SRC, data part implementation, logic design for the 1 – bus SRC, the control unit, the 2 and 3 bus processor designs, the machine reset, machine exception. 10 hrs

Computer arithmetic unit: Number systems and radix conversion, fixed point arithmetic, floating point arithmetic. 6 hrs.

Control unit: Basic concepts, hard wired and microprogrammed control unit, micro instruction format, methods of control memory organization. 10 hrs.

Memory unit: Dynamic and static memories, memory hierarchy, virtual memory, associative memory, cache memory, memory management, input output organization. 8 hrs.

Introduction to parallel processing: Basic concepts, classifications, principle of pipelining, arithmetic pipelines, instruction pipelines, processor level parallelism. 8 hrs.

Reference Books:1. Vincent .P. Heuring & Harry. F. Jordan, Computer systems design & architecture, Addison-

Wesley, 1997.2. Computer Organization : V C Hamacher, Z G Vraneric & S. G. Zaly, 4th Edition, 1996.3. William Stallings, Computer Organization & Architecture, 4th Edition PHI.4. I P Hayer, Computer Architecture & Organization5. Hwang K & F A Briggs, Computer Architecture & Parallel Processing MGH 1988.6. M.Raffiquazzaman & Rajan Chandra, Modern Computer Architecture, Galgotia 1990.7. Computer Organization & Design, David A Patterion & John L Hennery, Morgan Karyman 1997.

2K6 SYLLABUS

67

VI SEMESTER B.E (ELECTRICAL & ELECTRONICS)

2K6EE607 INDUSTRIAL DRIVES LABORATORY(Effective from the Academic year 2008-09)



1. DC Drive – Closed loop or Open loop control.

2. Rotor voltage control of Induction motor.

3. Stator voltage control of Induction motor.

4. Static Kramer Drive.

5. Static Scherbius Drive.

6. Inverter fed Induction motor control.

7. V/F control of Induction motor and Synchronous motor.

8. DSP based control of DC motor and Induction motor.

9. Vector control method of Induction motor.

10. 3 phase Dual converter fed DC shunt motor control.

VI SEMESTER B.E (ELECTRICAL & ELECTRONICS)

2K6EE608 MICROPROCESSOR & MICROCONTROLLER LAB(Effective from the Academic year 2008-09)



1. PROBLEMS ON DATA TRANSFER GROUP : Memory to register and vice versa, Block Movement, Arranging data in ascending, descending order, Software Counter, Sorting-Selection and Bubble sort method, Searching-Linear Search Method.

2. PROBLEMS RELATED TO ARITHMETIC OPERATIONS : 8-bit and 16-bit Addition and Subtraction, 8-bit and 16-bit Multiplication and Division, BCD Addition and Subtraction.

3. PROBLEMS ON CODE CONVERSION AND CODING : BCD to Binary and Vice versa, Binary to ASCII and Vice versa, 2 out of 5 Code, Palindrome etc.

4. PROBLEMS ON STACKS : Delay loop as subroutine, Multiple delay using same subroutine, Use of monitor routines to display the information on Data and Address field.

5. PROBLEMS ON I/O OPERATIONS AND PERIPHERALS : 8255 interface and data transfer in modes 0 and 1, Logic gate simulation, Interfacing Seven-segment display units through 8255, Operation of 8253 in mode 3, Generation of Waveforms using DAC, Experiments on ADC-Counter type, ASCII Display using 8279, Interfacing a 4x4 keyboard using 8255, Stepper Motor control.

6. INTERRUPT USAGE : Simulation of a Die (Random number generator).

NOTE : Programs to be developed and tested on 8085 & 8051Kit.

2K6 SYLLABUS

68

VII SEMESTER B.E (ELECTRICAL & ELECTRONICS)

2K6EE701 POWER SYSTEM I(Effective from the Academic year 2009-10)

4 hrs/ week Max. Marks 125.


1. Representation of a Power systems: General background of an Electric Power system, standard symbols to represent different components of an electric power system, one line representation, circuit model of a synchronous machine, transformer, transmission line etc., impedance diagram of the system, advantages of per unit computations. 12 hrs.

2. Generalized circuit constants, Universal power circle diagrams, Series & Shunt compensation. 8 hrs.

3. Symmetrical components: Introduction, synthesis of unbalanced phases from their symmetrical components and resolution of unbalanced phases into their symmetrical components, power in terms of symmetrical components, phase shift of sequence components of voltages and currents on the two sides of star-delta bank of 3 phase transformers, measurement of sequence quantities of voltage, current and power, using segregating networks. 10 hrs.

4. Sequence impedances : General circuit involving mutual impedance, concept of sequence impedance, constant flux linkage theorem, constants of synchronous machine, measurement of sequence impedances of synchronous machine, constants of two winding & three winding transformers, +ve sequence, -ve sequence and zero sequence impedances of transmission lines.

10 hrs.

5. Symmetrical three phase faults: Analysis of three phase short circuits in a power system using Z-bus. 6 hrs.

6. Unsymmetrical faults: Analysis of different types of faults at the terminals of an unloaded generator, sequence networks of a power system, analysis of Unsymmetrical faults such as L-G, LL-G, LL faults on a system, open conductor faults, bus impedance matrix method of analysis of Unsymmetrical faults.

14 hrs.

REFERENCES:

1. Elements of Power System analysis - Stevenson.

2. Symmetrical components - Wagner Evans.

3. Modern Power System analysis - I.J. Nagrath & D.P. Kothari.

4. Symmetrical components & short circuit calculations - Dr. P.N. Reddy.

2K6 SYLLABUS

69


2K6EE702 NON-CONVENTIONAL ENERGY SOURCES(Effective from the Academic year 2009-10)



1. AN INTRODUCTION TO ENERGY SOURCES: Introduction, Energy Sources, Energy Sources and their availability, World Energy Futures, New Energy Technologies, Renewable energy sources, Prospects of renewable Energy Sources 6 hrs.

2. SOLAR ENERGY : Introduction, Solar radiation and measurement, Different Solar energy collectors, Energy Balance equation and Collector efficiency ( Problems on Efficiency equation ), Solar energy storage systems, Solar Pond, Extraction of Thermal Energy, Application of Solar energy – Solar water heating, Solar thermal Electric conversion, Solar electric power generation, Solar cooking. 10 hrs.

3. PHOTO VOLTAICS: Introduction to solar energy conversion, PV cells, characteristics, cell efficiency, stand alone and integrated operation. 6 hrs

4. WIND ENERGY: Introduction, Basic Principles of Wind energy conversion, Basic components of Wind energy conversion systems (WECS), Classification of WECS, Advantages and Disadvantages of WECS, Types of Wind machines (Wind Energy collection), Performance of Wind machines, Generating Systems, Applications of Wind Energy. 10 hrs.

5. ENERGY FROM BIO-MASS: Introduction, Bio-mass Conversion technology, Generation, Types of Bio-gas plants, Community bio-gas plant, Utilization of Bio-gas. 6 hrs.

6. HYDROGEN ENERGY: Introduction, Utilization of Hydrogen gas, Hydrogen as an Alternate fuel for motor vehicles, Hydrogen Technology development in India 6 hrs.

7. Fuel cells and Battery Technology 8 hrs

8. MAGNETO HYDRO DYNAMICS (MHD): Introduction, Principle of MHD Power Generation, MHD systems, Advantages of MHD systems. 6 hrs.

9. ENERGY FROM THE OCEANS: Introduction, Ocean Thermal Electric conversion, Energy from tides, Wave energy conversion devices. 8 hrs.

REFERENCES:

1. Non-Conventional Sources of Energy by G D RAI, Khanna

2. Solar Energy by Sukhatme

3. Solar Energy hand book - edited by William C Dikkinson, ASISES, Newyork.

2K6 SYLLABUS

70


2K6EE703 SWITCH GEAR & PROTECTION(Effective from the Academic year 2009-10)



PART A

1. Representation of Power System: Single line diagram of Generating Station, Substation & Distribution System. 3 hrs

2. Switches: Isolating switches, Load break switches, Earthing switches. HRC fuses and their applications. 3 hrs

3. Theory of Circuit interruption: Introduction. Physics of arc phenomenon. Essential properties of the arc. Maintenance of the arc. Arc interruption theories. 6 hrs

4. Circuit Breakers: DC Circuit breaking, AC circuit breaking. Methods of arc extinction. Restriking voltage, rate of rise of restriking voltage. Resistance switching, current chopping, capacitive and inductive current breaking. Principle’s of arc quenching. Arc controlled devices. Requirement of an ideal circuit breaker. Rating of circuit breakers. Types of circuit breakers, plain break, self generated pressure oil circuit breakers. Externally generated pressure oil circuit breakers. Air circuit breakers - low voltage air break type, arc chutes, axial blast and cross blast air circuit breakers. Advantages and disadvantages OCB and ACB, SF6 circuit breakers. Vacuum circuit breakers, HVDC Breakers. Testing of circuit breakers. 14 hrs

5. Switchgear: HT, LT, indoor, outdoor cubicle drawout, metal clad, SF6 switchgear. 4 hrs

PART B

6. Protective Relays: Purpose of protective relaying. Requirement of relays, sensitivity, selectivity, reliability and speed of operation. Glossary of terms used in protective relaying like pick-up level, reset level, zone of protection - over reach and under reach. Classification of relays. universal relay-torque equation. 6 hrs

7. Electromagnetic Relays: Operating principles of attracted armature, solenoid and induction type relays, over current relays, Directional over current relays. Differential relays. Distance relays. Negative sequence relays. 5 hrs

8. Protection of apparatus: Introduction. Transformer protection. Generator protection. Motor protection and Bus-zone protection. 5 hrs

9. Feeder Protection: Introduction – over current protection. Determination of TMS and PSM setting. Protection of radial feeders. Parallel feeders and ring main. Distance protection. Pilot protection. Carrier current protection. 5 hrs

10. Solid State Relays: Advantages. Application of semiconductor devices to power system protection. Comparators. Level detectors. Logic circuit for fault detection and protection. Static over current relays. IDMT relays. Distance relays. Two input and multi input relays. Relay with quadrilateral and elliptic characteristics. Microprocessor based Relays 5 hrs

11. Computer Based integrated protection system. 4 hrs

REFERENCE: 1. Power protection and switchgear - Ravindranath & Chander.2. Switchgear and protection - Despande.3. Electrical Power - Soni, Bhatnagar & Gupta.4. Switchgear & Protection - Sunil S Rao.

2K6 SYLLABUS

71

VII SEMESTER B.E (ELECTRICAL & ELECTRONICS)2K6EE704 DIGITAL SIGNAL PROCESSING




Discrete Fourier Transform: Introduction, definition of D.F.T & IDFT. Properties of D.F.T, Circular convolution, Linear convolution using D.F.T, Computation of D.F.T - Decimation-in-time F.F.T algorithm, Decimation in frequency F.F.T algorithm, Chirp Z-transform algorithm. 12 hrs

Digital Filter Structures: IIR filter structures: Direct form I & II, cascade, parallel & ladder type realization. FIR filter structures: Direct form & Linear phase FIR structures. 6 hrs

Analog Filter Design : Butterworth low pass filters, Chebyshev low pass filters. Frequency transformation. 8 hrs

IIR Filter Design: IIR filter design by approximation of derivatives, IIR filter design by impulse invariance, IIR filter design by Bilinear transformation, Transformation of basic low pass filter. 12 hrs

FIR Filter Design : Characteristics of FIR digital filters, Different types of windows : Rectangular, Bartlett, Hamming, Blackman & Kaiser windows, Design of FIR filters using windows, Design of FIR filters by Frequency sampling method, Design of Equiripple FIR filters, Design of FIR differentiators, Comparison of IIR & FIR digital filters. 12 hrs

Digital Signal Processors (DSPs): TMS320 & equivalent Motorola family overview, typical applications, General description, Key features of C5X DSP processor. 10 hrs

References:

1. Terrell & L K Kwan : Digital Signal Processing A Student guide

2. Oppenheim & R W Schafer : Discrete time signal processing, PHI

3. Sanjeev K Mitra : Digital Signal Processing : McGraw Hill

4. Proakis & Monolokis : Digital Signal Processing, PHI

5. Oppenheim & Schafer et.al : Application of DSP, PHI

6. TMS Manual : Texas Instruments

7. Padmanabhan et.al: Digital Signal Processing, New Age Publishers, 2001.

8. Ingle and Proakis : Digital Signal Processing using Matlab, 2001.

9. S. Salivahanan et.al: Digital Signal Processing, TMH, 2001.

2K6 SYLLABUS

72VII SEMESTER BE (ELECTRICAL & ELECTRONICS)

2K6EE706 POWER SYSTEMS LABORATORY – I(Effective from the Academic year 2009-10)



1. 1) Characteristics of a) overcurrent, b) overvoltage, c) undervoltage, d) directional over current,

e) Microprocessor based Relays, f) Differential relay, g) Static overcurrent relay.

2. Short circuit studies using DC calculating board.

3. Calculation of % regulation and % efficiency of AC transmission line model.

4. Reactive power compensation

5. Protection of 3 phase induction motor.

6. Measurement of negative & zero sequence impedances of synchronous machines.

7. Power angle characteristics of synchronous machine.

8. Operation of 3-phase induction motor

a) under unbalanced voltage conditions &

b) with one line open.

VII SEMESTER B.E (ELECTRICAL & ELECTRONICS)2K6EE707 DSP laboratory




1. Getting started with MATLAB.2. Discrete Time Signals & Systems : Find Impulse response, Step response, Ramp response & Frequency response of a given system.3. Time and Frequency domain responses.

a) Linear convolution.b) Circular convolution.c) Verification of Linear convolution using DFT.d) Finding DFT using FFT algorithms.e) Finding the Inverse FFT.

4. DSP Hardware experiments using TMS 320CXX/ADSP – 21xx Starter kits.a) Addition.b) Subtractionc) Multiplicationd) Divisione) Factorial.f) Study :

i) Generation of Different Waveforms.ii) Generation of Echo.iii) Voice storingiv) Voice retrieval.

5. DSP application for - Speed control of DC motor- Speed control of AC motor

6. DSP application for stepper motor

2K6 SYLLABUS

73VII SEMESTER B.E (ELECTRICAL & ELECTRONICS)

2K6EE708 ESTIMATION, ECONOMICS & MANAGEMENT(Effective from the Academic year 2009-10)



1. Estimation: Estimates of HT lines - 400KV, 11KV, LT Line - 400V/230V, 5 wire distribution including earthing. Transformer - Distribution transformer centre (11KV/400V) with earthing. Domestic wiring: Different types with earthing. Industrial wiring - HT, LT with earthing. 12 hrs.

2. Specification: Importance of specification, ISI specifications of Alternators, Power Transformers, AC Motors, Circuit Breakers, Overhead line Conductors, Insulated HT underground cables, porcelain insulators, Insulating wire, Power line carrier Communication (PLCC) equipment. 4 hrs.

3. Tariffs: Aims, Objectives, Classification of Cost, Requirements of good Tariff. 4 hrs

4. Depreciation & Valuation: Depreciation, Kinds of depreciation, Depletion as a form of depreciation, life, salvage value & other terms, depreciation cost & depreciation provision, requirements, problems.

6 hrs

5. Choice of plants & Economic selection: Factors to be considered in selecting an equipment, methods of selection, problems. 4 hrs

6. Principles of costing & cost Accounting: Objectives of costing, functions, elements of cost, components of cost, types of cost, breakeven analysis, breakeven chart, advantages of breakeven analysis. 8 hrs

7. Growth and concept of Industry : Basic and scientific factory systems, types of ownership, principles of management, principles of Taylor, Henny l. Gantt and Henry Fayol in modern Industry, functions and process of management. 4 hrs.

8. Organization: Types of organizations, Line type, Line and staff, Functional, Line-functional and Matrix types. Authorities and responsibilities, managerial controls 4 hrs.

9. Production Management : Plant location, layout of plants, production planning and control, routine, scheduling, inspection, Line balancing, automation characteristics, impact of automation - advantages and disadvantages of automation, quality control - scope, organization, standards and specifications (Tolerances). Statistical quality control, control charts, techniques of Time and Motion study.

6 hrs.

10. Personnel Management & Human Relations: Introduction, qualification of personnel recruitment and selection of personnel. Training of personnel - Craftsmen, supervisors (TWI scheme), managers. Employer and Employee relations, Employees morale, health and welfare of workers, effect of noise, lighting, ventilation on production. Fatigue and reduction of fatigue, accidents and their reduction, settlement of individual disputes, ILO, workers participation in management. 8 hrs.

REFERENCES:1. Industrial organization and management - Bethel.2. Introduction to Management - S.S. Chatterjee3. Engineering Economics and Management - N.Narasimhaswamy.4. Industrial Organization and Engineering Economics - T.R. Banga & S.C. Sharma.5. Industrial Engineering and Production control systems - Praveen Kumar Khorana.6. Managing Engineering & Technology, Babcock & Morse Pearson Education 2004.7. Essentials of Management by Koontz, 9th Edition, McGraw Hill, 1988.

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ELECTIVE I 2K6EE705.1 ILLUMINATION ENGINEERING(Effective from the Academic year 2009-10)



Light & Vision: Electromagnetic spectrum, visible spectrum, Photopic, Scotopic & Mesopic Visions – Visual functions, Accommodation, Adaptation & Convergence. 4 hrs Propagation of light: Light propagation, Reflection, Specular, diffuse, spread, compound, scattered & selective reflections, Absorption, Transmission, Refraction, Polarization. 4 hrsPhotometric quantities &Units: Basic quantities – Laws of illumination from point law, surface, photometry, spectrometry & photocells - Inter relation between the various photometric quantities, Luminous efficacy, Spectral eye sensitivity curve, Light watt, Brightness, Luminous exitance, Radiometric quantities & units, Point by point method of illuminance Calculations – Horizontal and Vertical illuminance calculations. 10 hrsArtificial light sources: Construction – principle of operation - Luminous efficacy, Lamp life & Colour characteristics of incandescent, Tungsten halogen, fluorescent, High pressure mercury vapour, High pressure sodium vapour and metal halide lamps – Electro luminescence &LED-LCD Displays. 8 hrs Luminaire: Definition – optical characteristics of light control elements – classification, Symmetrical and asymmetrical , diffuse and focussed & C.I.E. classification - Applications of various light control elements (Reflectors, Refractors, diffusers & screening devices), Luminous intensity distribution measurements using GONIO photometer, L.I.D. diagrams in rectangular & polar co-ordinates. 8 hrsArtificial illumination design techniques: Utilization factor – Maintenance factor – Light output ratio – D.L.O.R & U.L.O.R - L.D.L of various lamps – Glare – Direct & Indirect types - Designing for average uniform illumination – Room index – space to mounting height ratio – Lumen method of calculations – Numerical examples – IES glare index computation method – simple examples using ceiling mounted luminaires (Calculation of initial glare index only) – Evaluation of total luminous flux output from photometric test data. 10 hrsFlood lighting of buildings: design aspects – Location of the equipment – Flood lighting of monuments & sports grounds – Numerical examples. Flood light calculation. 8 hrsRoad lighting: Road lighting criteria – Luminance & Luminance ratio – Overall & Longitudinal uniformity ratio – Zebra effect – Convectional lighting schemes – Factors affecting cost & quality of road lighting – Lighting of curves. Energy conservation measures in illumination systems – Introduction to optical fibers & Lasers. 8 hrs

REFERENCES:1. Cayless M. A. & A.M. Marsden , Lamps and Lighting (3e), O & IBH Pub., 1983.2. Ronald N. Helms, Illumination Engg. for Energy efficient luminous Environment, PH, 19803. Cotton H., Principles of Illumination, Chapman & Hall Ltd, London 1960.4. Durrant D.W, Interior lighting design (5e), Lighting industry federation Ltd., 1977.5. W. J. M Van Bommel and J. B. Boer, Road lighting, Kluwer Technical Lib, 1981.6. Boer J. B. and D. Fischer, Interior lighting (5e), Kluwer Technical Lib, 1981.7. I. E. S. N. A New York, Lighting Handbook (8e), 1993.

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ELECTIVE I 2K6EE705.2 EMBEDDED SYSTEM DESIGN(Effective from the Academic year 2009-10)



1. Concept of Embedded System Design, Embedded microcontrollers cores, embedded memories, examples of embedded system. 12 hrs

2. Technological aspects of embedded systems: Interfacing between analog and digital blocks, signal conditioning digital signal processing. 12 hrs

3. Subsystem interfacing, interfacing with external systems, user interfacing. 10 hrs

4. Design trade offs due to process incompatibility, thermal considerations etc., 10 hrs

5. Software aspects of embedded systems, real time programming languages, operating systems for embedded systems. 16 hrs

Reference Books:

1. Valvano, J. W. Embedded Microcomputer system; Real time interfacing, Brooks/Cole, 20002. Ganssle, Jack, The art of Designing Embedded systems, Newness, 19993. Simon David, An embedded software primer, Addison Wesley, 2000.4. Ayala, K J.., The 8051 Microcontroller, Architecture, Programming and Application, Pernam Intl,

1996.

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ELECTIVE I 2K6EE705.3 OPERATING SYSTEMS(Effective from the Academic year 2009-10)



PART A

1. INTRODUCTION: Batch systems, Concepts of multi programming and time-sharing parallel, distributed and real-time systems. Operating system structures-operating system components and services. System calls and Systems programs. Virtual machines. 8 hrs

2. PROCESS MANAGEMENT: Process concept, process scheduling, co-operating processes, threads and interprocess communication. CPU scheduling-scheduling criteria, scheduling algorithms, multiple-processor scheduling and real-time scheduling. Algorithm evaluation.

8 hrs

3. PROCESS SYNCHRONIZATION AND DEAD LOCKS: The critical section problem, synchronization hardware, semaphores, classical problems of synchronization, critical regions and monitors. Dead locks-system model, characterization, Dead lock prevention, avoidance and detection. Recovery from dead lock. Combined approach. 14 hrs

PART B

4. STORAGE MANAGEMENT : Memory management – logical and physical address space, swapping, contiguous allocation, paging and segmentation. Segmentation with paging in MULTICS and Intel 386. Virtual Memory-Demanding paging and its performance. Page replacement algorithms. Allocation of frames. Thrashing. Page size and other considerations. Demand segmentation. File systems, Secondary Storage Structure, Protection and Security-File concept, access methods, directory structure, protection and consistency semantics. File system structure, allocation methods. Free space management. Directory implementation. Efficiency and performance. Recovery. Disk structure, disk scheduling methods. Disk management. Swap-space management. Disk reliability. 14 hrs

5. PROTECTION AND SECURITY: Protection-Goals of protection, domain of protection. Access matrix and its implementation. Revocation of access. Security-Authentication, passwords. Threats and threat monitoring. Encryption. Computer security classifications. 8 hrs

6. CASE STUDY: Windows NT, Design principles, System components, environmental subsystems, File system, networking and programmer interface. 8 hrs

Reference:1. Silbcrschalz and Galvin, Operating System Concepts, Fifth Edition, Addision-Wesely, 19982. Milan Milancovic, Operating Systems, Concepts and Design, Second Edition, McGrawHill, 1992.3. Harvey M Deital, Operating Systems, Second Edition, Addition-Wesely, 1990.4. Dhamdhere: Systems Programming & Operating Systems, TMH, 2000.5. Singhal & Shivaralti: Operating Systems, TMH, 2001.6. Godbole: Operating Systems, TMH, 2001.

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77


ELECTIVE I 2K6EE705.4 WEB TECHNOLOGIES(Effective from the Academic year 2009-10)



Introduction : Web Development Strategies, History of Web, Protocols governing Web, Creating Websites for individual and Corporate World, Cyber Laws, Web Applications, Writing Web Projects, Identification of Objects, Target Users, Web Team, Planning and Process Development. 7 hrs

HTML, XML and Scripting : List, Tables, Images, Forms, Frames, CSS, Document type definition, XML schemes, Object Models, Presenting XML, Using XML, Processors : DOM and SAX, Introduction to Java Script, Object in Java Script, Dynamic HTML with Java Script. 8 hrs

Java Beans and Web Servers: Introduction to Java Beans, Advantage, Properties, BDK, Introduction to EJB, Java Beans API. Introduction to Servelets, Lifecycle, JSDK, Servlet API, Servlet Packages: HTTP package, Working with Http request and response, Security Issues. 15 hrs

JSP : Introduction to JSP, JSP processing, JSP application design, Tomcat Server, Implicit JSP objects, Conditional Processing, Declaring variables and methods, Error Handling and Debugging, Sharing data between JSP pages – Sharing Session and Application Data. 15 hrs

Database Connectivity : Database Programming using JDBC, Studying Javax.sql.*package, accessing a database from a JSP page, Application-specific Database Action, Developing Java Beans in a JSP page, Introduction to Struts framework. 15 hrs

Reference:1. Burdman, “Collaborative Web Development” Addison Wesley.2. Chris Bates, “Web Programming Building Internet Applications”, 2nd Edition, Wiley, Dreamtech.3. Joel Sklar, “Principal of Web Design” Vikash and Thomas Learning.4. Horstmann, “CoreJava”, Addison Wesley.5. Herbert Schieldt, “The Complete Reference: Java”, TMH.6. Hans Bergsten, “Java Server Pages”, SPD O’ Reilly.

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ELECTIVE I 2K6EE705.5 DIGITAL CONTROL SYSTEMS(Effective from the Academic year 2009-10)



1. Z-Plane Analysis of Discrete-time control systems: Impulse Sampling and data hold, obtaining the z transform by the convolution integral method, reconstructing original signals from sampled signals, the pulse transfer function, realization of digital controllers and digital filters. 15 hrs

2. Design of Discrete Time Control Systems by Conventional Methods : Mapping between the s plane and the z plane, stability, analysis of closed loop systems in the z plane, transient and steady state response analysis, design based on the root locus method, design based on the frequency response method, analytical design method. 15 hrs

3. State Space Analysis: State space representation of discrete time systems, Solution of discrete time state space equations, pulse transfer function matrix, discretization of continuous time state space equations, Liapunov stability analysis. 15 hrs

4. Pole Placement and Observer Design: Controllability, Observability, useful transformations in state space analysis and design, design via pole placement, state observers, servo systems. 15 hrs

Reference Books:

1. M. Gopal, “Digital Control and State Variable Methods”, 2nd Edition, TMH 2003.2. Richard C Dorf, Robert H Bishop, “Modern Control System”, Pearson Education.3. John F Dorsey, “Continuous and Discrete Control Systems”, McGraw Hill 4. Katsuhiko Ogata, “Discrete-Time Control Systems”, 2nd Edition Pearson Education, 2002.

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79


ELECTIVE I 2K6EE705.6 LINEAR INDUCTION MOTORS(Effective from the Academic year 2009-10)



1. A review of the Governing equations : A basic difference between Linear Electric machines and rotating machines, Review of the governing equations & some simple examples, the concept of current sheet, the air gap field equation, A design criterion, the goodness factor. 12 hrs

2. Classification of LEMS: Linear motors & levitation machines, Linear Induction motors, Linear synchronous motors, DC linear motors, linear levitation machines. 8 hrs

3. Certain Applications of LEMS: High speed application, low speed and stand still application, Application of Energy machines. 8 hrs

4. High speed linear induction motors: Possible arrangements for high speed LIMS, certain phenomena in short primary LIMS, analysis of end Affects, Transverse edge effects, the exact model of an LIM: Numerical solutions, primary windings with half-filled end slots short primary SLIM, Design consideration: compensation of end effects. 14 hrs

5. Low Speed Linear induction motors: Flat LIM, the tabular LIM, an example. 6 hrs

6. Diverse Linear motors and oscillators: Transverse flux linear induction motors, DC linear motor, linear stepper motor. 12 hrs

Reference books:

1. Linear Motion Electric Machines, S. A. Nasar, I. Boldea.2. Induction Machines, B. V. Jaywant, McGraw Hill, 1968.3. E. R. Laithwaite, Induction Machines for special purposes, Chemical publishing company

Newyork, 1966.4. S. Yamamura, Theory of Linear Induction motors, Wiley Inter Science, 1972.

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80


ELECTIVE I 2K6EE705.7 ADVANCED ELECTRICAL MACHINERY(Effective from the Academic year 2009-10)



1. DC machines: Elements of Generalized Machine theory, Linear Transformation application to DC machines. 24 hrs2. Synchronous machine: Ideal synchronous Machine, Synchronous machines inductances, Transformation to dqo variable, basic relations in dqo variables, steady state analysis, steady state P-S characteristics and Voltage regulation studies. 24 hrs

3. Induction machines: Ideal induction machine, transformation to dqo variable, basic machine relations in dqo variables, steady state analysis. 12 hrs

Reference books:

1. Bhimbra: Generalized theory of electric machine, Khanna Publishers.2. Fitzgerald & Kingsley: Electric Machine, 2nd Edition, McGrawHill.

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81


ELECTIVE I 2K6EE705.8 PROGRAMMABLE LOGIC CONTROLLERS(Effective from the Academic year 2009-10)



Introduction to PLC : Programmable logic controller (PLC) basics, definition overview of PLC systems – ON–OFF control concept using relay logic– Input & Output modules– Power Supplies– Isolators– PLC installation – Trouble Shooting And Maintenance of PLC – General PLC Programming Procedures – Programming ON–OFF Outputs. 15 hrs

PLC – Auxiliary Commands and Functions: Creating ladder diagram from process descriptions – PLC basic functions – Register basics – Timer functions – Counter functions – Design of Interlocks & Alarms using PLC – PLC advanced functions – Alternate Programming Languages – Analog PLC operation.

15 hrs

Automation : Introduction & Historical background – Traditional & Computer based control system developments – Resulting System Architectures – Local Control Unit (LCU) Introduction – Basic Elements of A Microprocessor Based Controller – Function blocks – Example of continuous control, Logic control and Batch Reactor – Security design issues for LCU – manual back–up designs – Redundant controller designs. 15 hrs

Communication system requirements : Architectural issues – Channel structure – Operator interface requirements – Low Level Operator Interface – High Level Operator Interface, Introduction to Field Bus – Architecture Topology – Bus standards – Interoperability – Interchangeability. 15 hrs

Text Books

1. John. W. Webb and Ronald. A. Reis, “Programmable Logic Controllers Principles and Applications”,

Prentice Hall Inc, New Jersey, 3rd edition, 1995.

2. Lukas M. P, “Distributed Control Systems”, Van Nostrand Reinhold Co, New York, 1986

References

1. Deshpande .P .B & Ash .R .H, “Elements of Computer Process Control”, Instrument Society of

America, 1981.

2. Hughes .T .A, “Programmable Controllers”, ISA, 1989.

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VIII SEMESTER B.E (ELECTRICAL & ELECTRONICS)

2K6EE801 POWER ELECTRONICS IN INDUSTRY(Effective from the Academic year 2009-10)



Chapter I: Introduction – Different types of converters and principles of operation, Testing of converters.8 hrs

Chapter II : Applications of Power Electronics converters in Battery charging, Welding power controls, induction heating, Electrochemical, Dielectric heating. 10 hrs

Chapter III : Stepper motor drives – Introduction – Variable reluctance step motor, Permanent magnet step motor, Hybrid motor, Modes of excitation in step motors, Drive circuits for step motors, Switch reluctance motor drives. 12 hrs

Chapter IV : Switching DC power supplies, Introduction – Overview of SMPS. DC-DC converters – Buck, Boost, Buck-Boost converters. 12 hrs

Chapter V : Power conditioners and U.P.S : Introduction – Power line disturbances, Power conditioners – UPS – different types – Principle of operation – Applications. 10 hrs

Chapter VI : Electric Utility Applications : Introduction – HVDC – Static variable control, Inter connection of Renewable Energy sources. 8 hrs

Reference Books :

1. Power Electronics : Converters, Applications and Design by Ned Mohan, John Wiley & Sons, 1989.2. Industrial and Power Electronics by Harish C Rai, Umesh Publication, 1994.3. Industrial Electronics and Control by Biswanath Paul, Prentice Hall of India Publications.

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83

VIII SEMESTER B.E (ELECTRICAL & ELECTRONICS)2K6EE802 POWER SYSTEM II




1. Load Flow Studies: Introduction, network model formulation for load flow studies, solution of load flow problem by Gauss seidel, Newton Raphson, Fast decoupled methods, Comparison of load flow methods. 18 hrs.

2. Optimal system operation: Introduction, Thermal Power station performance characteristics, loss coefficients, criteria for optimum loading of a generator connected to a bus, optimum loading of a system taking transmission losses into account. 10 hrs.

3. Automatic generation & voltage control : Introduction, load frequency control (single area case).8 hrs

4. Stability studies: Concept of stability - steady state, transient and dynamic stability, steady state stability limit of a round rotor and salient rotor synchronous machine connected to infinite bus, steady state stability limit of a two terminal pair network represented by ABCD constants, steady state stability of a two machine system interconnected through a reactance network maintaining constant generated voltages, steady state stability limits of two machine system interconnected through series reactance maintaining constant terminal voltages using Clarke’s diagram. 8 hrs.

5. Transient stability: Development of swing equation for a single machine connected to infinite bus, equal area criterion and its applications, solution of swing equation by step by step method, determination of critical clearing time, factors affecting the transient stability, methods of improving transient stability. 16 hrs.

REFERENCES:

1. Elements of Power system Analysis - Stevenson.

2. Power system stability vol. I - Kimbark .

3. Power system stability vol. I & II - Crary S B.

4. Modern Power system analysis - I J Nagrath, D P Kothari.

5. Computer Methods in Power system analysis - M A Pai.

Note : The students have to answer FOUR questions out of SIX questions.

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VIII SEMESTER B.E (ELECTRICAL & ELECTRONICS)2K6EE803 HVDC & FACTS




PART A

1. D.C. Power transmission technology : Comparison of A.C. and D.C transmission, application of D.C transmission, Description of D.C transmission systems, planning and modern trends in H.V.D.C transmission. Economic considerations 6 hrs.

2. Analysis of HVDC Converters : Thyristor valve, valve protection, tests and recent trends. Choice of Converter configuration. Analysis of 6 pulse bridge type converter (Graetz circuit), effect of source inductance, equivalent circuit (without filters) converter bridge characteristics. Valve voltage wave forms with and without overlap. Line commutated inverter with source inductance. 15 hrs.

3. Harmonics and Filters : Generation of Harmonics, types of filters, carrier frequency and RI noise.3 hrs.

PART B

1. Converter and HVDC System Control : Principles of D.C link control, converter control characteristics, Firing angle control current and extinction angle control, power control, higher level controllers. 6 hrs.

2. Converter faults and protection : Converter faults, protection against over currents and over voltages, over voltages in a Converter station. Static VAR systems, Reactive power control during transients. 6 hrs.

3. Multiterminal HVDC Systems : Types of MTDC Systems, Control and protection of MTDC Systems, applications of MTDC Systems. 4 hrs.

4. Stability of A.C. -D.C interconnected system. 2 hrs.

5. Simulation of HVDC Systems : Modelling of HVDC Systems for digital dynamic Simulation.4 hrs.

PART C

1. Principles of Reactive power compensation, Concepts of Flexible AC Transmission system (FACTS).4 hrs

2. Static variable compensations, Thyristor controlled reactor, Thyristor switched capacitor, Controllable series compensation. 10 hrs

References :

1. Miller T.J.E – Reactive Power control in Electric Systems

2. HVDC Power transmission systems - Wiley eastern ltd. - K.R.Padiyar.

3. Direct current transmission Vol I, Wiley Newyork 1960 - E.W.Kimbark.

4. Computer modelling of Electrical Power Systems - Wiley InterScience, Newyork 1983 - Arrillaga.T, Arnold, C.P. and Harker.B.J.

5. High voltage Direct current transmission - Garraway Limited, London 1960 - Hingorani, N.G and Adamson.C.

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VIII SEMESTER B.E (ELECTRICAL & ELECTRONICS)2K6EE804 UTILIZATION OF ELECTRIC POWER




1. Heating and Welding : Advantage and method of electric heating, resistance ovens, induction heating, dielectric heating, the arc furnace, electric welding, resistance and arc welding, control device and welding equipment. 12 hrs

2. Electrolytic process : Fundamental principles extraction refining of metals electroplating, Factors affecting electro deposition process. 6 hrs.

3. Illumination : Laws of illumination, distribution and control, lighting calculation, factory lighting, flood lighting, street lighting, different types of lamps, incandescent, fluorescent, vapour and CFL and their working. Glare and its remedy, Metal halide lamps. 12 hrs

4. Electric traction : System of traction, speed time curve, tractive effort at coefficient of adhensions selection of traction motors, method of speed control, energy saving by series parallel control, AC traction equipment. AC series motor, characteristics, regenerative braking, linear induction motor and their use. AC traction, diesel electric equipment, train lighting system. 20 hrs

5. Electric vehicles and systems : Road load characteristics, city drive cycle, Power estimation, Torque estimation, Acceleration profiling, Auxiliary loads. 2 hrsElectric propulsion : Electric vehicles, hybrid electric vehicles, series hybrid, parallel hybrid, combination hybrid, energy management, power flow strategies, regenerative breaking, gear train, differential gear. 3 hrsPrime movers : DC motor, PMDC motor, PMSM, Induction motor, drives for prime movers, PWM strategies, inverter design, speed control strategies v/f control, vector control, field weakening control. 3 hrsBatteries for electric vehicles : Power density, energy density, choice of batteries, DOD for EV batteries, Alternate energy storage mechanism. 2 hrs

Reference Books :1. Chakraborthy, Soni, Gupta & bhatnager, A course in Electrical power, Dhanpat Rai and Sons2. Openshaw taylor, Utilization of Electric energy (Chapter 1,2,3,6)

VIII SEMESTER B.E (ELECTRICAL & ELECTRONICS)2K6EE807 POWER SYSTEMS LABORATORY II




1. Formation of Y-Bus.

2. Formation of Z-Bus.

3. Load flow study using Newton-Raphson method.

4. Load flow study using Fast-decoupled load flow method.

5. Short circuit analysis using Z-Bus for 3 phase fault.

6. Solution of swing equation of a single machine connected to infinite bus.

7. Calculation of penalty factors and solution of co-ordination equation for economic operation of power systems.

8. Calculation of ABCD parameters and Reactive power compensation.

Note : Programs to be developed using C-language

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86


ELECTIVE II 2K6EE805.1 ARTIFICIAL INTELLIGENCE & EXPERT SYSTEMS(Effective from the Academic year 2009-10)



1. INTRODUCTION : Artificial Intelligence : Its scope, history and applications, AI as representation and search. The predicate calculus-inference rules. A logic based financial advisor. Structures and strategies for state space search-graph theory, strategies for space search, using state space to represent reasoning with the predicate calculus. 12 hrs

2. HEURISTIC SEARCH : Heuristic search-An algorithm for heuristic search. Admissibility, mono tonicity and informedness. Heuristics in games. Complexity issues. Control and implementation of state space search-Recursion based search, pattern directed search, production systems. Predicate calculus and planning, the black board architecture for problem solving. 8 hrs

3. KNOWLEDGE BASED SYSTEMS : Knowledge-intensive problem solving-Overview of expert system technology. Rule based expert systems. Model-based reasoning, Case-based reasoning. The knowledge representation problem. Reasoning with uncertain or incomplete information-The statistical approach to uncertainity. Non-monotonic systems. Reasoning with fuzzy sets. 8 hrs

4. KNOWLEDGE REPRESENTATION AND LISP : Knowledge representation-languages, Issues in knowledge representation. A survey of network representation. Conceptual graphs. A network representation language. Structured representations. Further issues in knowledge representation. Introduction to LISP-Search in LISP : A functional approach to the farmer, wolf, goat, and cabbage problem. Higher-order functions and procedural abstraction. Search strategies in LISP. A recursive Unification function. Interpreters and embedded languages. Logic programming in LISP. Streams and delayed evaluation. An expert system shell in LISP. 12 hrs

5. AUTOMATED REASONING : Automated reasoning-Weak methods in theorem proving. The general problem solver and difference labels. Resolution theorem proving, further issues in automated reasoning. Machine learning : Connectionist – Foundations for connectionist networks, perception learning, back propagation learning. Competitive learning, Hebbian coincidence learning. Attractor networks or memories. 12 hrs

6. EXPERT SYSTEM ARCHITECTURE : Basic components, rule based systems, forward and backward chaining, ES features, ES development, ES categories, ES tools and examples from electric power systems. 8 hrs

References :1. G.F Luger and W.A Stubblefield, Artificial Intelligence – Structures and Strategies for Complex

Problem Solving, Third Edition, Addison-Wesely, 1998.2. P.H. Winston, Artificial Intelligence, Third Edition, Addision-Wesely, 1992.3. E Rich and Knight, Artificial Intelligence, Second Edition, TMH, 1991.4. D W Patterson, “Introduction to Artificial Intelligence and Expert Systems”, PHI 1992.

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ELECTIVE II 2K6EE805.2 NEURAL NETWORK & FUZZY LOGIC (Effective from the Academic year 2009-10)



Introduction, Biological neuron, Artificial neuron, Activation, Functions, Defining a neural

network, Neurophsiological background, Modelling and Uninformation. Neural network as Dynamic

systems, Neural Network Models. General features, Set Selection Problem. Supervised learning, Linear

discriminant functions, Unsupervised learning, Perception learning algorithms, Multilayer perception,

Kohonen’s self organizing networks, Hopfield networks.

Fuzzy logic control. Basic concepts of fuzzy sets, operation of fuzzy sets Fuzzy logic, Fuzzy

relations, Fuzzy graphs, Fuzzy control, Applications to Engineering.

60 hrsReferences :

1. Kosko B, Neural Networks and Fuzzy systems, prentice hall, 1992.2. Beale R and Jackson T, Neural computing, An Introduction, Adam Hilger, 1990.3. Bose & Liang: Neural network fundamentals with graphs, Algorithms & application - McGraw4. Robert L Hannery: Neural network principles.


ELECTIVE II 2K6EE805.3 RESONANT CONVERTERS(Effective from the Academic year 2009-10)



Introduction, Basic Principles of Series and Parallel resonance, Classification of Resonant converters,

Series resonant DC-DC converter, Parallel Resonant DC-DC converter, Series-Parallel DC-DC converter,

Fixed frequency control of resonant converters-Quasi-resonant converters-ZVS DC-DC converters-ZVS

Quasi resonant forward converter, ZVS multi-Resonant DC-DC converter, ZCS Quasi Resonant DC-DC

converter, ZCS clamped voltage topology, Resonant DC link converter, High Frequency link half cycle

converters, Applications.

60 hrs

Reference:1. Ned Mohan, John Wiley & Sons – Power Electronics, Converters, Applications and Design.2. Currents Literature.

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ELECTIVE II 2K6EE805.4 COMPUTER GRAPHICS(Effective from the Academic year 2009-10)



PART A1. INTRODUCTION : Image Processing as picture analysis, Advantages of interactive graphics,

Representative users of computer graphics, Classification & applications, Development of hardware and software for computer graphics, Conceptual framework for interactive graphics, Drawing with SRGP, Basic interaction handling, Raster graphics features, Limitations of SRGP, Hardcopy technologies, Display technologies, Raster-scan display systems, The video controller, Random-scan display processor, Input devices for operator interaction, Image scanners. 6 hrs

2. RASTER GRAPHICS ALGORITHMS : Overview, Scan converting lines, Scan converting circle, Filling rectangle, Filling polygons, Filling Ellipse arcs, Pattern filling, Thick primitives, Line style and pen style, Clipping in a raster world, Clipping lines, Clipping circles and ellipse, Clipping polygons, Generating characters, SRGP copy pixel, Antialiasing. 8 hrs

3. GEOMETRICAL TRANSFORMATIONS: 2D transformations, Homogeneous coordinates and matrix representation of 2D transformations, Composition of 2D transformations, the window-to-view port transformation, Efficiency, Matrix representation of 3D transformations, Composition of 3D transformations, Transformations as a change in coordinate system. 8 hrs

4. VIEWING IN 3D : Projections, Specifying an arbitrary 3D view, Examples of 3D viewing, The mathematics of planar geometric projections, Implementing planar geometric projections, Coordinate systems. 8 hrs

PART B

5. INTERACTION TECHNIQUES, DIALOG DESIGN AND USER INTERFACE SOFTWARE : Interaction hardware, Basic interaction tasks, Composite interaction tasks, The form and content of user-computer dialogues, User-interface styles, Important design considerations, Modes and syntax, Visual design, the design methodologies. 8 hrs

6. REPRESENTING CURVES AND SURFACES : Polygon meshes, Parametric cubic curves, Parametric bicubic surfaces, Quadric surfaces. 8 hrs

7. SOLID MODELING : Representing solids, Regularized Boolean set operations, primitive instancing, Sweep representations, Boundary representations, Spatial-partitioning representations, Constructive solid geometry, Comparison of representations, user interfaces for solid modeling.

8 hrs

8. VISIBLE-SURFACE DETERMINATION : Functions of two variables, Techniques for efficient visible-surface algorithms, Algorithms for visible-line determination, the z-buffer algorithms, List-priority algorithms, Scan-line algorithms, Area-subdivision algorithms, Algorithms for octrees, Algorithms for curved surfaces, Visible-surface ray tracing. 6 hrs

References :1. James D Foley, Andries Van Dam, Steven K Feiner, John F Huges, Compute Graphics, Addison-

Wesley, 1997.2. Hearn and Baker, Computer Graphics, Second Edition, PHI.3. N. Krishnamurthy : Computer Graphics, TMH, 2002.

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89VIII SEMESTER B.E (ELECTRICAL & ELECTRONICS)

ELECTIVE II 2K6EE805.5 POWER SYSTEM OPERATION AND CONTROL(Effective from the Academic year 2009-10)



Load dispatching: Load dispatching facilities – operating restriction – installed capacity – cold reserve, operating reserve, spinning reserve – Contingencies – Scheduled overhaul – Load characteristics – capacity scheduling – Load duration and Load energy curves. 14 hrs

Objectives of power control: Real power balance and its effect on system frequency – Power frequency control – Reactive power balance and its effect on system voltage – Q-V control – Structure of control system. 8 hrs Power frequency control: Local control – power control mechanism of an individual generator. Mathematical model of speed governing system, speed load characteristic of governing mechanism – Regulation of two generators in parallel – System control – Division of power system into control areas – Tie line with frequency bias control – economic dispatch controller. 18 hrs Reactive power voltage control: Local control – fundamental characteristic of excitation system, generator representation, stabilizing circuit system, generation and absorption of reactive power method – method of voltage control – injection of reactive power – tap changing transformer – regulating transformer, voltage regulators, excitation systems 14 hrs

Recent trends: Introduction to energy control centers; Various states of a power system; SCADA systems and RTUs. Qualitative study of real time control of power system for maintaining security. 6 hrs

REFERENCES:

1. Elgerd O.I., Electric Energy System Theory, An Introduction (e2), TMH, 1982.2. Weedy B.M., Electric Power System (e3), Wiley, 1988.3. Nagrath & Kothari, Power System Engineering, TMH, 1994.

VIII SEMESTER B.E (ELECTRICAL & ELECTRONICS)ELECTIVE II 2K6EE805.6 TRANSDUCERS & SIGNAL CONDITIONING




1. Introduction, Classification, Active / Passive, Mechanical / Electrical, Basic requirements of Transducer, Electrical Transducers, Variable resistance transducers – Strain gauges, Variable Capacitance transducers, Variable Inductance transducers-LVDT, Hall-effect, Semiconductor, Opto-electric, piezo-electric transducers. 20 hrs

2. Instrumentation Amplifier : Basic characteristics, Three-amplifier configuration, Amplifiers for signal conditioning. 8 hrs

3. Signal Processing : Stair case generator comparator V/f – I/f comparator, filters, Data acquaintance and conversion, Multiplexer, Sample and hold click, ADC, DAC. 12 hrs Digital signal transmission and processing, Modulation and Demodulation digital data transmission, telemetry 8 hrs

Input devices and display, Analog devices & receivers, digital input output devices, semi signal, dot matrix display LED, LCD. 8 hrs

Digital fuzzy meter, time period and time interval 4 hrs

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ELECTIVE II 2K6EE805.7 ENERGY MANAGEMENT & AUDITING(Effective from the Academic year 2009-10)



INTRODUCTION : Consumption and demand patterns of different sources of Energy - both commercial and renewable sources. Sector wise energy consumption patterns - demand projections, Energy conservation-differential sectors (case study) 18 hrs

LOAD FORECASTING : Necessity and types of forecasting (both short term and long term).6 hrs

DEMAND SIDE MANAGEMENT : Concept of D S M Benefits. D S M Techniques - time of day pricing, load priority technique, peak clipping, peak shifting, valley filling. Conservation methods. Energy efficient equipment. Some typical case of conservation.Minimization of energy losses in transmission lines and distribution networks. 18 hrs

ENERGY AUDITING : Principles and practice, case studies. 18 hrs

References :

1. Robert L Sullivan : Power system planning. McGraw Hill International Book Company (1977).2. D P SenGupta, K R Padiyar, Indraned Sen, M A Pai (Ed) : Recent advances in Control & Management

of Energy Systems. Interline Publishers. Bangalore (1993).3. Ashok V Desai (Ed) : Energy Demand - Analysis, Management and Conservation Wiely Eastern

Ltd. New Delhi.

4. H U D S Hand Book of Industrial Energy conservation. Van Nostrand Reinhold Company. New York (1983).5. Paul O’Callanghan - Energy Management. McGraw Hill Book Company, London (1993).6. TERI Reports.7. Current Literature.

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ELECTIVE II 2K6EE805.8 POWER SUPPLY SYSTEM DESIGN(Effective from the Academic year 2009-10)



1. DC – DC converters : Fly back converters, topologies, forward converter, variation, push pull converter, limitations of push pull converter, topologies, half bridge and full bridge DC – DC converters, High frequency inductor / transformer design, magnetic cores. 14 hrs

2. Switch mode DC power supplies : Voltage fed forward PWM control, current mode control, digital PWM control, isolation techniques, Soft start, Current limit circuits, Over voltage protection circuit, popular monolithic PWM control circuit & their applications. 10 hrs.

3. EMI & RFI : EMI & RFI, conducted & radiated noise, EMI suppression, EMI reduction at source, EMI filters, EMI screening, EMI measurements & specifications. 10 hrs

4. Snubber circuits : Function & types of snubber circuits, Diode snubbers, Snubbers for thyristors, need for snubbers with transistors, Turn off snubber, Over voltage snubber, Turn on snubber, Snubber for bridge circuits. 8 hrs

5. Gate Drive : Preliminary Design consideration, DC coupled drive circuits, electrically isolated drive circuits, cascade connection of drive circuits, Thyristor drive circuits, Power devices protection in drive circuits. 8 hrs

6. Design of Magnetic components : Magnetic materials and cores, copper windings, thermal considerations, Inductor design analysis, transformer design analysis, procedure. 10 hrs

Reference Books :

1) Hart D W Introduction to Power Electronics2) P C Sen Modern Power Electronics3) Power Electronics Converters, Application and Design. Mohan, Undeland, Robbins John & Wiley & Sons Inc. 4) Pressman A I Switching Power System Design5) Whittington HW BW Power Supply System Design

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Elective II 2K6EE805.9 MICRO ELECTRONICS AND MECHANICAL SYSTEMS (MEMS)(Effective from the Academic year 2009-10)



MEMS and microsystems: MEMS and microsystem products – evaluation of microfabrication – Microsystems and microelectronics – applications of microsystems – working principles of microsystems – microsensors –microactuators – MEMS and microactuators – microaccelerometers. Scaling laws in miniaturization: Introduction – scaling in geometry – scaling in rigid body dynamics – the Trimmer force scaling vector – scaling in electrostatic forces, electromagnetic forces, scaling in electricity and fluidic dynamics, scaling in heat conducting and heat convection. 14 hrs

Materials for MEMS and microsystems: Substrates and wafers – Silicon as a substrate material, ideal substrates for MEMS – single crystal Silicon and wafers crystal structure – mechanical properties of Si – Silicon compounds – SiO2, SiC, Si3N4 and polycrystalline Silicon – Silicon piezoresistors – Gallium arsenside, quartz – piezoelectric crystals – polymers for MEMS – conductive polymers. Engineering mechanics for microsystems design: Introduction – static bending of thin plates – circular plates with edge fixed, rectangular plate with all edges fixed and square plates with all edges fixed. Mechanical vibration -resonant vibration – microaccelerometers – design theory and damping coefficients. Thermomechanics – thermal stresses. Fracture mechanics – stress intensity factors, fracture toughness and interfacial fracture mechanics. 14 hrs

Basics of fluid mechanics in macro and mesco scales: Viscosity of fluids – flow patterns Reynolds number. Basic equation in continuum fluid dynamics – laminar fluid flow in circular conduits – computational fluid dynamics –incompressible fluid flow in microconducts, surface tension, capillary effect and micropumping - Fluid flow in submicrometer and nanoscale – rarefield gas, Kundsen and Mach number and modelling of microgas flow – heat conduction in multilayered thin films – heat conduction in solids in submicrometer scale - Thermal conductivity of thin films - heat conduction equation for thin films. Microsystem fabrication process: Photolithography – photoresist and applications – light sources. Ion implanation – diffusion process – oxidation – thermal oxidation – silicon diode – thermal oxidation rates – oxide thickness by colour - Chemical vapour deposition - principle – reactants in CVD – enhanced CVD physical vapour deposion – sputtering – deposition by epitaxy – etching – chemcial and plasma etching. 18 hrs

Micromanufacturing and microsystem packaging: Bulk Micromachining - Isotropic And Danisotropic Etching, Wet etchants, etch stops, dry etching comparison of wet and dry etching - Surface micromachining, process in general – problems associated surface micromachining - The LIGA process – description – materials for substrates and photoresists – electroplating – The SLIGA process. Microsystem packaging – General considerations - The three levels of microsystem packaging – die level, device level and system level – essential packaging technologies – die preparation – surface bonding wire bonding and sealing - Three dimensional packaging, assembly of microsytems – selection of packaging materials.

14 hrsReference Books1. Mark Madou, Fundamentals of Microfabrication, CRC Press, 1997.2. J. W. Gardner, Microsensors: Principles and Applications3. S. M. Sze, Semiconductor Sensors, McGraw Hill, 19944. C. Y. Chang and S. M. Sze, VLSI Technology, 2000.5. Tai-Ran Hsu, MEMS and Microsystems Design and Manufacture, Tata McGraw Hill, New Delhi, 2002

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ELECTIVE II 2K6EE805.10 DATA COMMUNICATION(Effective from the Academic year 2009-10)



PART A

1. INTRODUCTION : Data communication, Networking, Protocols and Protocol architecture, standards, Data transmission concepts, Analog and digital transmission, Transmission impairments. 8 hrs

2. TRANSMISSION MEDIA : Guided transmission media and wireless transmission, Data encoding-Digital and analog data and signals, spread spectrum. Data communication interface-asynchronous and synchronous transmission, line configuration and interfacing. Data link control-flow control. Error detection and error control. HDLC and other data link protocols. Multiplexing Frequency division, synchronous time division, and statistical time-division multiplexing.

20 hrs

PART B

3. SWITCHING : Switched networks, Circuit-switched networks, Switching concepts. Routing in circuit-switched networks. Control signaling. Packet switching principles. Routing and congestion control, X.25 protocol standard. 16 hrs

4. LOCAL AREA NETWORKS : LAN Technology-LAN architecture, Bus/tree, ring, star, and wireless LANs. LAN systems-Ethernet and Fast Ethernet (CSMA/CD) Token ring and FDDI, 100 VG-Any LAN, ATM LANs, Fiber channel, wireless LANs. Bridges – Bridge operation and routing with bridges. 14 hrs

References :

1. W. Stallings, Data and Computer Communications, Fifth Edition, PHI, 1998.2. A.S. Tanenbaum, Computer Networks, Third Edition, PHI, 1996.3. S. Keshav, An Engineering Approach to Computer Networking, Addison Wesely, 1997.4. Michael A Miller : Data & Network Communication, Thomson Learning, 2001.5. Behrouz a Forouzn, Data Communications & Networks, 2nd Edition, TMH, 2000.6. James Martin : Telecommunication and the Computer, 2000.7. Mark Campa : Designing 7 Complementary, Thomson Learning, 2001.8. Shay : Data Communication & Networks, Thomson Learning, 2001.

2K6 SYLLABUS

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UVCE 2K6 EEE Syllabus