Advanced Electromagnetic Fields Detailed Syllabus for High Voltage Engineering/ Power Systems With Emphasis On H.V. Engineering M.Tech first year second sem is covered here. This gives the details about credits, number of hours and other details along with reference books for the course.
The detailed syllabus for Advanced Electromagnetic Fields M.Tech 2017-2018 (R17) first year second sem is as follows.
M.Tech. I Year II Sem.
Prerequisite: Electromagnetic Fields
Course Objectives:
- To understand the basic skills required to understand, develop, and design various engineering applications involving electromagnetic fields.
- To understand the foundations of electromagnetism and its Practice in modern communications.
- To understand Behavior of Conductors and Insulators in electric field
Course Outcomes: After the completion of this course, student will be able to:
- Apply vector calculus to static electric-magnetic fields in different engineering situations.
- Analyze Maxwell’s equation in different forms (differential and integral) and apply them to diverse engineering problems.
- Examine the phenomena of wave propagation in different media and its interfaces and in applications of microwave engineering.
- Analyze the nature of electromagnetic wave propagation in guided medium which are used in microwave applications.
UNIT– I: Electrostatics
Electrostatic Fields – Coulomb’s Law – Electric Field Intensity (EFI) – EFI due to a line and a surface charge – Work done in moving a point charge in an electrostatic field – Electric Potential – Properties of potential function – Potential gradient – Gauss’s law – Application of Gauss’s Law – Maxwell’s first law, div( D )=v – Laplace’s and Poisson’s equations – Solution of Laplace’s equation in one variable.
UNIT– II: Electric Fields – I
Introduction, Analytical calculation of space-charge-free fields, simple geometries, transmission conductors to ground, fields in multi-dielectric media, experimental analogs for space – space-charge free fields, electrolytic tank, semi conducting paper analog, resistive-mesh analog. Numerical computation of space-charge – free fields, successive imaging technique, the dipole method, charges imulation technique, finite-difference technique, combined charge-simulation and finite-difference technique, finite-element technique, combined charge-simulation and finite-element technique, boundary-element method, integral-equations technique, monte-cario technique.
UNIT– III: Electric Fields – II
Analytical Calculations Of Fields With Space Charges, Numerical Computation Of Fields With Space Charges, Finite Element Technique, Finite Element Technique Combined With The Method Of Characteristics, Charge-Simulation Technique Combined With The Method Of Residues, Electric Stress Control And Optimization, Electric Stress Control, Electric Stress Optimization.
UNIT– IV: Conductors, Dielectrics, Dipole and Capacitance
Behavior of conductors in an electric field – Conductors and Insulators – Electric field inside a dielectric material – polarization – Dielectric – Conductor and Dielectric – Dielectric boundary conditions – Energy stored and energy density in a static electric field – Current density – conduction and Convection current densities – Ohm’s law in point form – Equation of Electric dipole – Dipole
moment – potential and EFI due to an electric dipole – Torque on an Electric dipole in an electric field – Capacitance – Capacitance of parallel plate and spherical capacitors.
UNIT–V: Magneto Statics Time Varying Fields
Biot-Savart’s law – Magnetic field intensity (MFI), magnetic flux density and MFI, Ampere’s circuital law and its applications Point form of Ampere’s circuital law. Scalar Magnetic potential and its limitations – vector magnetic potential and its properties, vector Poisson’s equations. Energy stored and density in a magnetic field. Magnetic force – Moving charges in a Magnetic field – Lorentz force equation –– a differential current loop as a magnetic dipole, Time varying fields – Faraday’s laws of electromagnetic induction – Its integral and point forms, Statically and Dynamically induced EMFs – Modification of Maxwell’s equations for time varying fields – Displacement current.
TEXT BOOKS:
- “Engineering Electromagnetics” by William H. Hayt & John. A. Buck McGraw Hill Companies, 7th Editon.2005.
- “Electromagnetics” by J. D Kraus McGraw Hill Inc. 4th edition 1992.
REFERENCES:
- “Field Theory”, by Gangadhar, Khanna Publishers.
- “Elements of Electromagnetic field theory “, by Sadiku, Oxford Publ.
- “Electromagnetics” by J P Tewari.
- “Introduction to E-Magnetics” by CR Paul and S.A. Nasar, McGraw Hill Publications
- “Introduction to Electro Dynamics” by D J Griffiths, Prentice Hall of India Pvt. Ltd, 2nd editon
- “Electromagnetics” by Plonsy and Collin
- “Engineering Electro magnetics” by Nathan Ida, Springer(India) Pvt. Ltd. 2nd Edition.
For all other M.Tech 1st Year 2nd Sem syllabus go to JNTUH M.Tech High Voltage Engineering/ Power Systems With Emphasis On H.V. Engineering 1st Year 2nd Sem Course Structure for (R17) Batch.
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