Add to ORKGCoulomb forces; electric fields and potentials; Lapace equation; boundary value problems and dielectrics; multipole distributions; magnetic induction; introduction to Maxwell\u27s equations
A basic introduction to electromagnetism, supplying the fundamentals of electrostatics and magnetost...
∂t = −∇ × E (Faraday) ∇ ·D = ρ (Poisson) ∇ · B = 0 (Gauss) E = Electric field vector H = Magnetic f...
This classic 1953 text for advanced undergraduates has been used by generations of physics majors. R...
Coulomb forces; electric fields and potentials; Lapace equation; boundary value problems and dielect...
Goals: To develop an understanding of the classical theory of electric and magnetic fields. Content...
Goals: To develop an understanding of the classical theory of electric and magnetic fields. Content...
Goals: To develop an understanding of the classical theory of electric and magnetic fields. Content...
Continuation of PHY440. Electric Induction; Maxwell\u27s equations; momentum and energy of electroma...
Goals: To develop an understanding of the classical theory of electric and magnetic fields. Content...
Unit 1: ELECTROSTATICS-The Electric field-Point charge and continuous charge distributions-Divergenc...
Goals: To develop an understanding of the classical theory of electric and magnetic fields. Content...
Goals: To develop an understanding of the classical theory of electric and magnetic fields. Content...
Maxwells̀ equations; electromagnetic waves; propagation of electromagnetic waves in bounded region; ...
Electric and magnetic quasistatic forms of Maxwell's equations applied to dielectric, conduction, an...
This book is a self contained course in electromagnetic theory suitable for senior physics and elect...
A basic introduction to electromagnetism, supplying the fundamentals of electrostatics and magnetost...
∂t = −∇ × E (Faraday) ∇ ·D = ρ (Poisson) ∇ · B = 0 (Gauss) E = Electric field vector H = Magnetic f...
This classic 1953 text for advanced undergraduates has been used by generations of physics majors. R...
Coulomb forces; electric fields and potentials; Lapace equation; boundary value problems and dielect...
Goals: To develop an understanding of the classical theory of electric and magnetic fields. Content...
Goals: To develop an understanding of the classical theory of electric and magnetic fields. Content...
Goals: To develop an understanding of the classical theory of electric and magnetic fields. Content...
Continuation of PHY440. Electric Induction; Maxwell\u27s equations; momentum and energy of electroma...
Goals: To develop an understanding of the classical theory of electric and magnetic fields. Content...
Unit 1: ELECTROSTATICS-The Electric field-Point charge and continuous charge distributions-Divergenc...
Goals: To develop an understanding of the classical theory of electric and magnetic fields. Content...
Goals: To develop an understanding of the classical theory of electric and magnetic fields. Content...
Maxwells̀ equations; electromagnetic waves; propagation of electromagnetic waves in bounded region; ...
Electric and magnetic quasistatic forms of Maxwell's equations applied to dielectric, conduction, an...
This book is a self contained course in electromagnetic theory suitable for senior physics and elect...
A basic introduction to electromagnetism, supplying the fundamentals of electrostatics and magnetost...
∂t = −∇ × E (Faraday) ∇ ·D = ρ (Poisson) ∇ · B = 0 (Gauss) E = Electric field vector H = Magnetic f...
This classic 1953 text for advanced undergraduates has been used by generations of physics majors. R...