EEC404: Electromagnetic Field & Wave Theory Syllabus for EE 4th Sem 2017 Pattern Mumbai University

Electromagnetic Field & Wave Theory detailed syllabus scheme for Electrical Engineering (EE), 2017 regulation has been taken from the University of Mumbai official website and presented for the Bachelor of Engineering students. For Course Code, Course Title, Test 1, Test 2, Avg, End Sem Exam, Team Work, Practical, Oral, Total, and other information, do visit full semester subjects post given below.

For all other Mumbai University Electrical Engineering 4th Sem Syllabus 2017 Pattern, do visit EE 4th Sem 2017 Pattern Scheme. The detailed syllabus scheme for electromagnetic field & wave theory is as follows.

Electromagnetic Field & Wave Theory Syllabus for Electrical Engineering SE 4th Sem 2017 Pattern Mumbai University

Course Objectives:

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Course Outcomes:

Students will be able

• To apply knowledge of mathematics and physics in electrical engineering field.
• To analyse electrostatic and static magnetic fields.
• To analyse the effect of material medium on electric and magnetic fields.
• To analyse and formulate time varying electric and magnetic fields.
• To analyse wave generation and its propagation in different media.
• To analyse static magnetic field and electrostatic field distribution using software tool.

Module 1

Vector Basics: Concept of Scalar and Vector, Co-ordinate System: Rectangular, Cylindrical and Spherical Co-ordinate System, Co-ordinate and vector transformation, (Numerical on line, Surface and Volume Integrals. 04

Module 2

Static Electric Fields: Coulombs Law in Vector Form, Electric Field Intensity, Definition, Principle of Superposition, Electric Field due to point charges, Electric Field due to line charge (one and two conductor transmission lines), Electric Field due to an infinite uniformly charged sheet, Definition and physical interpretation of gradient, Electric scalar potential, Relationship between potential and electric field and its application on Surface voltage gradient on conductor, Potential due to electrical dipole and flux lines, Electric Flux Density, Gauss Law, Definition and physical Significance of Divergence, Divergence theorem

Module 3

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Module 4

Electric and Magnetic Fields in Materials: Poissons and Laplaces equation and its application on Estimation and control of electric stress, control of stress at an electrode edge, Electric Polarization, Definition of Capacitance, Capacitance of two parallel plate, Co-axial, Spherical and Capacitance of two conductor of a single phase line, Electrostatic energy and energy density, Boundary conditions for electric and magnetic field, Electric current, Current density, Point form of ohms law, Continuity equation for current, Definition of Inductance, Inductance of loops and solenoids, Flux linkage within and outside the conductor producing the flux, Energy density in magnetic fields. 08

Module 5

Time varying Electric and Magnetic Fields: Faradays law, Maxwells Second Equation in integral form from Faradays Law, Equation expressed in point form, Displacement current, Amperes circuital law in integral form, Modified form of Amperes circuital law as Maxwells first equation in integral form, Equation expressed in point form, Maxwells four equations in integral form and differential form. 04

Module 6

Wave theory: Derivation of Wave Equation, Uniform Plane Waves, Maxwells equation in phasor form, Wave equation in phasor form, Plane waves in free space and in a homogenous material, Wave equation for a conducting medium, Plane waves in lossy dielectrics, Propagation in good conductors, Skin effect. 04

Text Books:

For the complete Syllabus, results, class timetable, and many other features kindly download the iStudy App
It is a lightweight, easy to use, no images, and no pdf platform to make students’s lives easier.
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Reference Books:

1. Fenmann, Lectures on physics, Vol – 2, Addition Wesley, 1965
2. S. seely, Introduction to electromagnetic fields, McGraw Hill, 1958.
3. David K. cheng, Field and electromagnetic, Addison Wesley, 2nd edition, 1999.
4. Corson and lerrain, Electromagnetic, CBS publications, 2nd edition, 1986.
5. Ramo, Whinnery and Van Duzer: Fields and Waves in Communications Electronics John Wiley & Sons (3rd edition 2003)
6. M.N.O.Sadiku: Elements of Engineering Electromagnetics Oxford University Press, Third edition.
7. David K.Cherp: Field and Wave Electromagnetics – Second Edition-Pearson Edition.
8. David J.Grithiths: Introduction to Electrodynamics- III Edition-PHI
9. John Reitz, Frederick Milford, Robert Christy, Foundations of Electromagnetic Theory Pearson publications, fourth impression,2013.

Assessment:

Internal Assessment consists of two tests out of which; one should be compulsory class test (on minimum 02 Modules) and the other is either a class test or assignment on live problems or course project. Term work Term work consists of minimum eight tutorials (at least one on each module) and assignments (min. 2). The distribution of the term work shall be as follows: Tutorials :15 marks Assignments :05 marks Attendance (Theory and Tutorial) :05 marks The final certification and acceptance of term-work ensures the minimum passing in the termwork.

Theory Examination:

1. Question paper will comprise of 6 questions, each carrying 20 marks.
2. Total four questions need to be solved.
3. Q.1 will be compulsory, based on entire syllabus wherein sub questions of 2 to 5 marks will be asked.
4. Remaining question will be randomly selected from all the modules.

For detail syllabus of all other subjects of Electrical Engineering (EE) 4th Sem 2017 regulation, visit EE 4th Sem Subjects syllabus for 2017 regulation.