DEPARTMENT OF ELECTRONICS AND COMMUNICATION ENGG.
COURSE PLAN
Department : ELECTRONICS AND COMMUNICATION ENGG.Subject : Electromagnetic WavesSemester & branch : 4th E & CName of the faculty : HSM, MSK, VKP, PK
No of contact hours/week : 04 Hrs/week
Assignment portionAssignment no. Topics
1 L1 – L19
2 L20 – L38
3 L39 – L48
Test portionTest no. Topics
1 L1 – L19
2 L20– L38
Submitted by:
M. SATHISH KUMAR
(Signature of the coordinator)Date:
Approved by:
(Signature of HOD)Date:
MANIPAL INSTITUTE OF TECHNOLOGY(A constituent college of Manipal University, Manipal)
Manipal Karnataka 576 104
(Page 1 of 5)
Course Objectives
At the end of this course, student should be able to:
CO1. Describe the basic principles of Electrostatics and Magnetostatics.
CO2. Apply the governing laws such as Gauss’ law, Ampere’s Law, Biot-Savart law and
Faraday’s law for analyzing of electromagnetic systems.
CO3. Determine the characteristics of Electromagnetic fields at the interface between
two different media, by applying boundary conditions.
CO4. List various Maxwell's equations in both integral and differential forms and apply
them to time-varying fields.
CO5. Describe the principle of electromagnetic wave propagation in loss less and lossy
media.
CO6. Calculate transmission and reflection coefficients for normal and oblique incidence
of TEM waves.
CO7. Determine parameters associated with waves on lossless and lossy media.
MIT/GEN/F-05/
(Page 2 of 5)
Lecture no. Topic to be covered
L1 Review of Vector analysis, Cartesian co-ordinate systems
L2 Cylindrical co-ordinate systems & Conversion from one to other
L3 Spherical co-ordinate systems & Conversion from one to other
L4 Tutorial
L5 Coulomb's law and its applications, Electric field intensity
L6 Field due to point charges, Field due to point line charge
L7 Field due to surface charge and volume charge
L8 Tutorial
L9 Electric flux and electric flux density, Gauss's law, Gauss's law applications
L10 Maxwell’s Equation, Divergence, Gauss divergence theorem
L11 Energy, Force, PD, PD due to Point Charge, PD due to ring charge, Potential Gradient,
L12 Tutorial
L13 Dipole, Energy in E field
L14 Ohm's law, continuity equations, Boundary Conditions
L15 Dielectrics, Boundary Conditions, Relaxation time,
L16 Tutorial
L17 Capacitance, Capacitance of coaxial cable, Capacitance two-wire transmission lines
L18 Poisson's and Laplace's equations, solution to Laplace's equations
L19 Magnetic field intensity, Biot-Savart's law, Ampere's law
MIT/GEN/F-05/
(Page 3 of 5)
Lecture no. Topic to be covered
L20 Tutorial
L21 Stoke's theorem
L22 Flux, Flux Density, Scalar vector potentials
L23 Magnetic vector potentials, Boundary Conditions
L24 Tutorial
L25 Faraday's law, Displacement Current, Torque
L26 Inductance
L27 Energy Densities
L28 Tutorial
L29 Maxwell's equations in integral and point form for free space and material media,
L30 Maxwell's equations in Sinusoidal form
L31 Retarded Potentials, Problems
L32 Tutorial
L33 Wave Equations and its solutions
L34 Uniform Plane wave
L35 Wave Propagation in Free space
L36 Tutorial
L37 Wave Propagation in Dielectric
L38 Poyinting vector and complex Poyinting vector, Skin effect
MIT/GEN/F-05/
(Page 4 of 5)
Lecture no. Topic to be covered
L39 Wave Polarization, Normal Incidence
L40 Tutorial
L41 Dielectric-conductor medium,
L42 Transmission and reflection coefficients
L43 Standing Wave Ratio, Multiple Interfaces
L44 Tutorial
L45 Propagation of EM Waves
L46 Propagation in General Directions, Oblique Incidence
L47 Total Internal Reflection, Brewster Angle
L48 Tutorial
MIT/GEN/F-05/
(Page 5 of 5)
MIT/GEN/F-05/
Recommended
