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Page 129
Given that Eu" (Z = 63) has a quadrupole moment Q = 2.5 × 10−9 cm” and a
mean radius R = (a + b)/2 = 7 x 10-13 cm, determine the fractional difference in
radius (a — b)/R. 4.3 A localized distribution of charge has a charge density p(r) =
...
Given that Eu" (Z = 63) has a quadrupole moment Q = 2.5 × 10−9 cm” and a
mean radius R = (a + b)/2 = 7 x 10-13 cm, determine the fractional difference in
radius (a — b)/R. 4.3 A localized distribution of charge has a charge density p(r) =
...
Page 267
8.5 8.6 (a) Assuming infinite conductivity for the walls, determine the possible
modes of propagation and their cutoff frequencies. (b) For the lowest modes of
each type calculate the attenuation constant, assuming that the walls have large,
but ...
8.5 8.6 (a) Assuming infinite conductivity for the walls, determine the possible
modes of propagation and their cutoff frequencies. (b) For the lowest modes of
each type calculate the attenuation constant, assuming that the walls have large,
but ...
Page 306
(b) Determine the total power radiated and find a numerical value for the
radiation resistance. Treat the linear antenna of Problem 9.4 by the long-
wavelength multipole expansion method. - (a) Calculate the multipole moments (
electric dipole, ...
(b) Determine the total power radiated and find a numerical value for the
radiation resistance. Treat the linear antenna of Problem 9.4 by the long-
wavelength multipole expansion method. - (a) Calculate the multipole moments (
electric dipole, ...
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Contents
Introduction to Electrostatics | 1 |
BoundaryValue Problems in Electrostatics I | 26 |
References and suggested reading | 50 |
Copyright | |
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