Electricity and MagnetismA text for the standard electro-magnetism course for students in physics and engineering. Treats requisite theory with extensive examples of real-world applications. Offers coverage of topics neglected in most texts at this level, such as macroscopic vs. microscopic properties of matter. Also features a shorter, more student-oriented presentaton of the material, larger problem sets, and thorough discussion of alternative solution methods. |
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Page 372
... wires are located at x = ± a and are parallel to the y axis . The wires carry constant currents +1 , respectively . Another infinitely long parallel wire is moving with its instantaneous position at distances r1 and r2 from the wires at ...
... wires are located at x = ± a and are parallel to the y axis . The wires carry constant currents +1 , respectively . Another infinitely long parallel wire is moving with its instantaneous position at distances r1 and r2 from the wires at ...
Page 385
... wire carrying a current 12 is in the plane of the loop and at a distance d > R from the center of the loop . R I , 1 Figure 12.6 Force between 12 a current- carrying wire and a current - carrying loop placed in the same plane . 1 Since ...
... wire carrying a current 12 is in the plane of the loop and at a distance d > R from the center of the loop . R I , 1 Figure 12.6 Force between 12 a current- carrying wire and a current - carrying loop placed in the same plane . 1 Since ...
Page 514
... wire . Determine the vector potential of two infinitely long , parallel wires , 1 and 2 , at distances p1 and p2 from an observation point P in the plane of the wires . The distance between the wires is d . The current Io in wire 1 is ...
... wire . Determine the vector potential of two infinitely long , parallel wires , 1 and 2 , at distances p1 and p2 from an observation point P in the plane of the wires . The distance between the wires is d . The current Io in wire 1 is ...
Contents
VECTOR ANALYSIS | 1 |
ELECTROSTATICS | 28 |
ELECTROSTATIC BOUNDARY VALUE | 73 |
Copyright | |
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4περ A₁ Ampere's law angle atoms axis B₁ B₂ boundary conditions C₁ calculated capacitance capacitor charge density charge distribution charge q circuit coefficients components conducting conductor Consider constant coordinates current density cylinder dependence Determine dielectric displacement distance E₁ E₂ electric dipole electric field electromagnetic electron electrostatic element energy Example external ferromagnetic Figure flux force frequency function Gauss given by Eq gives H₂ hence inductance inside integral interface k₁ Laplace's equation linear loop Lorentz Lorentz transformation macroscopic magnetic field magnetic moment material Maxwell's equations medium molecules n₂ normal P₁ plane plates point charge polarization Poynting vector problem R₁ radiation radius region relation result RLC circuit scalar potential shown in Fig solenoid solution space sphere spherical surface charge transformation unit vector vector potential velocity voltage wire zero Απ Απερ μο