Electromagnetic Fields Detailed Syllabus for B.Tech second year first sem is covered here. This gives the details about credits, number of hours and other details along with reference books for the course.<\/p>\n
The detailed syllabus for Electromagnetic Fields B.Tech 2016-2017 (R16) \u00a0second year first sem is as follows.<\/p>\n
B.Tech. II Year I Sem. \u00a0 \u00a0L\/T\/P\/C
\nCourse Code: EE302ES \u00a04\/1\/0\/4
\nPrerequisite: Mathematics II & Physics II<\/p>\n
Course Objectives: <\/strong><\/p>\n Course Outcomes:<\/strong> upon completion of course, student will be able to<\/p>\n UNIT \u2013 I\u00a0Electrostatics:<\/strong> Electrostatic Fields \u2013 Coulomb\u2019s Law \u2013 Electric Field Intensity (EFI) \u2013 EFI UNIT \u2013 II\u00a0Dielectrics & Capacitance:<\/strong> Behavior of conductors in an electric field \u2013 Conductors and UNIT \u2013 III\u00a0Magneto Statics<\/strong>: Static magnetic fields \u2013 Biot-Savart\u2019s law \u2013 Magnetic field intensity (MFI)\u00a0\u2013 MFI due to a straight current carrying filament \u2013 MFI due to circular, square and solenoid\n
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\ndue to a line and a surface charge \u2013 Work done in moving a point charge in an electrostatic\u00a0field \u2013 Electric Potential \u2013 Properties of potential function \u2013 Potential gradient \u2013 Guass\u2019s law\u00a0\u2013 Application of Guass\u2019s Law \u2013 Maxwell\u2019s first law, div ( D )=\uf072v \u2013 Laplace\u2019s and Poison\u2019s\u00a0equations \u2013 Solution of Laplace\u2019s equation in one variable. Electric dipole \u2013 Dipole moment\u00a0\u2013 potential and EFI due to an electric dipole \u2013 Torque on an Electric dipole in an electric field\u00a0\u2013 Behavior of conductors in an electric field \u2013 Conductors and Insulators<\/p>\n
\nInsulators \u2013 Electric field inside a dielectric material \u2013 polarization \u2013 Dielectric \u2013 Conductor\u00a0and Dielectric \u2013 Dielectric boundary conditions \u2013 Capacitance \u2013 Capacitance of parallel plots\u00a0\u2013 spherical co-axial capacitors \u2013 with composite dielectrics \u2013 Energy stored and energy\u00a0density in a static electric field \u2013 Current density \u2013 conduction and Convection current\u00a0densities \u2013 Ohm\u2019s law in point form \u2013 Equation of continuity<\/p>\n
\ncurrent \u2013 Carrying wire \u2013 Relation between magnetic flux, magnetic flux density and MFI \u2013
\nMaxwell\u2019s second Equation, div(B)=0,\u00a0Ampere\u2019s Law & Applications: Ampere\u2019s circuital law and its applications viz. MFI due to\u00a0an infinite sheet of current and a long current carrying filament \u2013 Point form of Ampere\u2019s\u00a0circuital law \u2013 Maxwell\u2019s third equation, Curl (H)=Jc<\/p>\n