course plan
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MIT/GEN/F-01/R1
COURSE PLAN
Department : Electronics and
Communications
Course Name & code : Electromagnetic Waves & ECE
2012
Semester & branch : Third Semester & E and C
Name of the faculty : TGSC, KS and VKJ
No of contact hours/week : 4
ASSESSMENT PLAN:
1. In Semester Assessments - 50 %
Written tests : 2 tests of 1-Hr duration( Max Marks 15
each)
Surprise quizzes : 5 Surprise Tests(Max Marks 4 Mark Each)
2. End Semester Examination - 50 %
Written examination of 3 hours duration (Max. Marks: 50 )
Portions for Assignment
Assignment no. Topics
1 L0-L9
2 L10-l17
3 L18-L27
4 L28-L36
5 L37-L47
Portions for Sessional Test
Test no. Topics
1 L1 – L19
MANIPAL INSTITUTE OF TECHNOLOGY Manipal University, Manipal
Karnataka -576104
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MIT/GEN/F-01/R1
2 L20– L38
Course Plan
L. No. Topics
L0 Review of Vector analysis, Cartesian co-ordinate systems
L1 Cylindrical co-ordinate systems & Conversion from one to other
L2 Spherical co-ordinate systems & Conversion from one to other
L3 Tutorial
L4 Coulomb's law and its applications, Electric field intensity
L5 Field due to point charges, Field due to line charge
L6 Field due to surface charge and volume charge
L7 Tutorial
L8 Electric flux and electric flux density, Gauss's law, Gauss's law applications
L9 Divergence, Gauss divergence theorem
L 10 Energy, Force, PD, PD due to Point Charge, PD due to ring charge, Potential Gradient,
L11 Tutorial
L12 Dipole, Energy in E field
L 13 Ohm's law, continuity equations, Boundary Conditions
L 14 Dielectrics, Boundary Conditions, Relaxation time,
L 15 Tutorial
L16 Capacitance, Capacitance of coaxial cable, Capacitance two-wire transmission lines
L 17 Poisson's and Laplace's equations, solution to Laplace's equations
L18 Magnetic field intensity, Biot-Savart's law, Ampere's law
L19 Tutorial
L 20 Stoke's theorem
L 21 Flux, Flux Density, Scalar vector potentials
L 22 Magnetic vector potentials, Boundary Conditions
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MIT/GEN/F-01/R1
L23 Tutorial
L 24 Faraday's law, Displacement Current, Torque
L25 Inductance
L 26 Magnetic Energy Density
L27 Tutorial
L 28 Maxwell's equations in integral and point form for free space and material media,
L29 Maxwell's equations in Sinusoidal form
L 30 Problems, Wave equation.
L31 Tutorial
L32 Wave Equations and its solutions
L33 Uniform Plane wave
L 34 Wave Propagation in Free space
L 35 Tutorial
L 36 Wave Propagation in Dielectric, lossy dielectric and perfect conducting media
L 37 Poyinting vector and complex Poyinting vector, Skin effect
L 38 Wave Polarization, Normal Incidence
L 39 Tutorial
L 40 Transmission coefficient calculations
L41 Reflection coefficients calculations
L42 Standing Wave Ratio, Multiple Interfaces
L43 Tutorial
L 44 Propagation in General Directions, Oblique Incidence
L 45 Total Internal Reflection,
L 46 Brewster Angle, Critical angle
L 47 Tutorial
References:1. Jr.Hayt and Bucker, “Engineering Electromagnetics” 7th Edition , McGraw Hill.
2. Martin A Plonus “Applied Electromagnetics” McGraw Hill
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MIT/GEN/F-01/R1
3. John D Kraus, “ Electromagnetics” 4th Edition, McGraw Hill
4. Cheng, “Fields, Waves and Electromagnetics” 2nd Edition, Addison Wesley.
Submitted by: Dr. TGSC
(Signature of the faculty)
Date: 01/08/2015
Approved by:
(Signature of HOD)
Date:
*********
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