EX 4th sem Electromagnetic Theory syllabus EMT syllabus EX 401

Related: Electromagnetic Theory syllabus, EMT syllabus, EE EMT syllabus, 4th semester EMT syllabus, BE 4th semester EMT Syllabus, Electrical and Electronics Engineering
 

EX-401 Electromagnetic Theory (EMT) Syllabus

 RGTU/RGPV Electromagnetic Theory (EMT) SYLLABUS

Electrical and Electronics Engineering EX 4th Semester Syllabus,

Unit I Cartesian, cylindrical & spherical co-ordinate systems, scalar & vector fields, gradient, divergence & curl of a vector field, Divergence theorem & Stokes’s theorem, concept of vectors. Electrostatic Fields – Coulomb’s law, electric field intensity due to different charge distribution viz. line charge, sheet charge, Field due to continuous volume – electric potential, properties of potential function, potential gradient equipotential surfaces, line of force, Gauss law, applications of Gauss law, Gauss law in point form, method of images.

Unit II Laplace’s & Poisson’s equations, solution of Laplace’s equation, Electric dipole, dipole moment, potential & electric field intensity due to dipole, Behavior of conductors in an electric field. Conductor & insulator, electric field inside a dielectric, polarization, Boundary value conditions for electric Field, Capacitance & Capacitances of various types of capacitors, Energy stored and energy density in static electric field, Current density, conduction & convection current density ohms law in point form, equation of continuity.

Unit III Static Magnetic Field, Biot-Savart’s law, Magnetic Field intensity due to straight current carrying filament, circular, square and solenoidal current carrying wire, Relationship between magnetic flux, flux density & magnetic Field intensity; Ampere’s circuital law and its applications, magnetic Field intensity due to infinite sheet and various other configurations, Ampere’s circuital law in point form, Magnetic force, moving charge in a magnetic field, Lorentz Force on straight and long current carrying conductors in magnetic field, force between two long & parallel current carrying conductors. Magnetic dipole & dipole moment, a differential current loop as dipole, torque on a current carrying loop in magnetic field, Magnetic Boundary conditions.

Unit IV Scalar magnetic potential and its limitations, Vector magnetic potential and its properties, vector magnetic potential due to different simple configurations; Self and Mutual inductances, determination of self & mutual inductances, self inductance of solenoid, toroid coils, mutual inductance between a straight long wire & a square loop. Energy stored in magnetic Field & energy density, Faraday’s Law, transformer & motional EMFs, Displacement current, Maxwell’s equations as Generalization of circuit equations, Maxwell’s equation in free space, Maxwell’s equation for harmonically varying Field, static and steady fields, Maxwell’s equations in differential & integral form.

Unit V Electro Magnetic Waves : Uniform plane wave in time domain in free space, Sinusoidally time varying uniform plane wave in free space, Wave equation and solution for material medium, Uniform plane wave in dielectrics and conductors, Pointing  Vector theorem, instantaneous, average and complex poynting vector, power loss in a plane conductor, energy storage, Polarization of waves, Reflection by conductors and dielectric – Normal &  Oblique incidence, Reflection at surface of a conducting medium, surface impedance, transmission line analogy. 
 

Electromagnetic Theory syllabus EMT References:
1. Mathew N.O Sadiku; Elements of Electromagnetic; Oxford.
2. P.V. Gupta; Electromagnetic Fields; Dhanpat Rai.
3. N.N. Rao; Element of Engineering Electromagnetic; PHI.
4. William H. Hayt; Engineering Electromagnetic; TMH.
5. John D. Kraus; Electromagnetic; TMH.
6. Jordan Balmian; Electromagnetic wave & Radiating System; PHI.
7. David K. Cheng; Fields and Wave Electromagnetic; Addison Wesley.
8. S.P. Seth; Electromagnetic Field ;Dhanpat Rai & Sons

Note: Field plotting of electromagnetic systems on a PC using standard softwares. Application for low and high frequency devices. Suggested softwares, GEMINI(Infolytica), ANSYS, ANSOFT, NISA

EE 4th sem Electromagnetic Theory syllabus EMT syllabus EE 401

Related: Electromagnetic Theory syllabus, EMT syllabus, EE EMT syllabus, 4th semester EMT syllabus, BE 4th semester EMT Syllabus
 

EE-401 Electromagnetic Theory (EMT) Syllabus

 RGTU/RGPV Electromagnetic Theory (EMT) SYLLABUS

Electrical Engineering EE 4th Semester Syllabus,

Unit I Cartesian, cylindrical & spherical co-ordinate systems, scalar & vector fields, gradient, divergence & curl of a vector field, Divergence theorem & Stokes’s theorem, concept of vectors. Electrostatic Fields – Coulomb’s law, electric field intensity due to different charge distribution viz. line charge, sheet charge, Field due to continuous volume – electric potential, properties of potential function, potential gradient equipotential surfaces, line of force, Gauss law, applications of Gauss law, Gauss law in point form, method of images.

Unit II Laplace’s & Poisson’s equations, solution of Laplace’s equation, Electric dipole, dipole moment, potential & electric field intensity due to dipole, Behavior of conductors in an electric field. Conductor & insulator, electric field inside a dielectric, polarization, Boundary value conditions for electric Field, Capacitance & Capacitances of various types of capacitors, Energy stored and energy density in static electric field, Current density, conduction & convection current density ohms law in point form, equation of continuity.

Unit III Static Magnetic Field, Biot-Savart’s law, Magnetic Field intensity due to straight current carrying filament, circular, square and solenoidal current carrying wire, Relationship between magnetic flux, flux density & magnetic Field intensity; Ampere’s circuital law and its applications, magnetic Field intensity due to infinite sheet and various other configurations, Ampere’s circuital law in point form, Magnetic force, moving charge in a magnetic field, Lorentz Force on straight and long current carrying conductors in magnetic field, force between two long & parallel current carrying conductors. Magnetic dipole & dipole moment, a differential current loop as dipole, torque on a current carrying loop in magnetic field, Magnetic Boundary conditions.

Unit IV Scalar magnetic potential and its limitations, Vector magnetic potential and its properties, vector magnetic potential due to different simple configurations; Self and Mutual inductances, determination of self & mutual inductances, self inductance of solenoid, toroid coils, mutual inductance between a straight long wire & a square loop. Energy stored in magnetic Field & energy density, Faraday’s Law, transformer & motional EMFs, Displacement current, Maxwell’s equations as Generalization of circuit equations, Maxwell’s equation in free space, Maxwell’s equation for harmonically varying Field, static and steady fields, Maxwell’s equations in differential & integral form.

Unit V Electro Magnetic Waves : Uniform plane wave in time domain in free space, Sinusoidally time varying uniform plane wave in free space, Wave equation and solution for material medium, Uniform plane wave in dielectrics and conductors, Pointing  Vector theorem, instantaneous, average and complex poynting vector, power loss in a plane conductor, energy storage, Polarization of waves, Reflection by conductors and dielectric – Normal &  Oblique incidence, Reflection at surface of a conducting medium, surface impedance, transmission line analogy. 

Electromagnetic Theory syllabus EMT References:
1. Mathew N.O Sadiku; Elements of Electromagnetic; Oxford.
2. P.V. Gupta; Electromagnetic Fields; Dhanpat Rai.
3. N.N. Rao; Element of Engineering Electromagnetic; PHI.
4. William H. Hayt; Engineering Electromagnetic; TMH.
5. John D. Kraus; Electromagnetic; TMH.
6. Jordan Balmian; Electromagnetic wave & Radiating System; PHI.
7. David K. Cheng; Fields and Wave Electromagnetic; Addison Wesley.
8. S.P. Seth; Electromagnetic Field ;Dhanpat Rai & Sons

Note: Field plotting of electromagnetic systems on a PC using standard softwares. Application for low and high frequency devices. Suggested softwares, GEMINI(Infolytica), ANSYS, ANSOFT, NISA

RGPV / RGTU B.E. EC, 5th (V) Semester syllabus EC 502 Electromagnetic Theory Revised syllabus Electronics and Communication Engineering (EC)

Tags: RGPV, BE, EC 502 syllabus, Electromagnetic Theory syllabus, B.E. Electronics and Communication Engineering, EC V Semester syllabus, EC 5th Semester syllabus, RGPV EC 502 syllabus

Rajiv Gandhi Technological University, Bhopal (MP)
B.E. (EC) Electronics and Communication Engineering FOURTH IV SEMESTER
EC 502 Electromagnetic Theory
Revised Syllabus and Scheme of Examination Effective from July 2007

Unit I Cartesian, cylindrical and spherical co-ordinate systems, scalar and vector fields, gradient, divergence and curl of a vector field, Divergence theorem and Stokes’s theorem, concept of vectors. Electrostatic Fields – Coulomb’s law, electric field intensity due to different charge distribution viz. line charge, sheet charge, Field due to continuous volume – electric potential, properties of potential function, potential gradient equipotential surfaces, line of force, Gauss law, applications of Gauss law, Gauss law in point form method of images.

Unit II Laplace’s and Poisson’s equations, solution of Laplace’s equation. Electric dipole, dipole moment, potential and electric field intensity due to dipole. Behavior of conductors in an electric field. Conductor and insulator, electric field inside a dielectric, polarization. Boundary value conditions for electric Field. Capacitance and Capacitances of various types of capacitors. Energy stored and energy density in static electric field. Current density, conduction and convection current density, Ohms law in point form, equation of continuity.

Unit III Static Magnetic Field, Biot-Savart’s law, Magnetic Field intensity due to straight current carrying filament, circular, square and solenoidal current carrying wire. Relationship between magnetic flux, flux density and magnetic field intensity. Ampere’s circuital law and its applications, magnetic field intensity due to infinite sheet and various other configurations, Ampere’s circuital law in point form. Magnetic force, moving charge in a magnetic field, Lorentz force on straight and long current carrying conductors in magnetic field, force between two long and parallel current carrying conductors. Magnetic dipole and dipole moment, a differential current loop as dipole, torque on a current carrying loop in magnetic field, magnetic boundary conditions.

Unit IV Scalar magnetic potential and its limitations, Vector magnetic potential and its properties, vector magnetic potential due to different simple configurations; Self and Mutual inductances, determination of self and mutual inductances, self inductance of solenoid, toroid coils, mutual inductance between a straight long wire and a square loop. Energy stored in magnetic Field and energy density. Faraday’s Law, transformer and motional EMF equations. Displacement current, Maxwell’s equations as generalization of circuit equations, Maxwell’s equation in free space, Maxwell’s equation for harmonically varying field, static and steady fields. Maxwell’s equations in differential and integral form.

Unit V Electro Magnetic Waves: Uniform plane wave in time domain in free space, Sinusoidally time varying uniform plane wave in free space, Wave equation and solution for various medium, Uniform plane wave in dielectrics and conductors. Poynting Vector theorem, instantaneous, average and complex poynting vector, power loss in a plane conductor, energy storage. Polarisation of waves. Reflection by conductors and dielectric – Normal and Oblique incidence. Reflection at surface of a conducting medium, surface impedance, transmission line analogy.

References:
1. Mathew N.O Sadiku: Elements of Electromagnetic, Oxford.
2. N.N. Rao: Element of Engineering Electromagnetic, Pearson Education.
3. William H. Hayt: Engineering Electromagnetic, TMH.
4. John D. Kraus: Electromagnetics, Mc. Graw Hill.
5. Jordan Balmian: Electromagnetic wave and Radiating System, PHI.
6. David K. Cheng: Electromagnetic Fields and Wave, Addison Wesley.
7. Ramo, Whinnerry and VanDuzzer “ Fields and waves in communication electronics “, Wiley 1984
8. Harrington RF, “Electromagnetic fields” Mc Graw Hill