Explanation Given data: The frequency of the wave f is 0.5 MHz . The electric field amplitude of the wave E 0 i is 3000 V / m . The relative permittivity ε r of the medium is 72 . The relative permeability μ r of the medium is 1 . The conductivity of the medium σ is 4 S / m . The minimum signal amplitude required for communication is 0.01 μV / m Calculation: The standard relation for real and imaginary permittivity is, ε ″ ε ′ = σ ω ε r ε 0 (1) Here, ω is the angular velocity. ε 0 is the permittivity of air, which has standard value as 8.85 × 10 − 12 F / m . The angular velocity ω is given by, ω = 2 π f Substitute 0.5 MHz for f in above equation. ω = 2 π × 0.5 MHz = π Mrad / s The conversion from Mrad / s to rad / s is given as, 1 Mrad / s = 10 6 rad / s The conversion of π Mrad / s into rad / s is given as, π Mrad / s = π × 10 6 rad / s Hence, angular velocity, ω = π × 10 6 rad / s Substitute π × 10 6 rad / s for ω , 4 S / m for σ , 72 for ε r and 8.85 × 10 − 12 F / m for ε 0 in equation (1). ε ″ ε ′ = 4 S / m π × 10 6 rad / s × 72 × 8.85 × 10 − 12 F / m = 2000 Since, ε ″ ε ′ ≫ 0.01 Hence, the medium is a good conductor. For a good conductor, attenuation constant α 2 is given by, α 2 = π f μ 0 σ Substitute 0.5 × 10 6 Hz for f , 4 π × 10 − 7 H / m for μ 0 and 4 S / m for σ in above equation. α 2 = π × 0.5 × 10 6 Hz × 4 π × 10 − 7 H / m × 4 S / m = 2.81 Np / m Intrinsic impedance of medium 2 η c2 is given by, η c2 = ( 1 + j ) α 2 σ Substitute 2.81 Np / m for α 2 and 4 S / m for σ in above equation. η c2 = ( 1 + j ) 2.81 Np / m 4 S / m = 0.7 ( 1 + j ) Ω The intrinsic impedance of the medium 1 (air) is, η 1 = η 0 Here, η 0 is the intrinsic impedance of air. Intrinsic impedance of the air is given by, η 0 = μ 0 ε 0 (2) Here, μ 0 is the permeability of air, which has standard value as 4 π × 10 − 7 H / m and ε 0 is the permittivity of air, which has standard value as 8

Fundamentals of Applied Electromagnetics (7th Edition)

7th Edition

ISBN: 9780133356816

Author: Fawwaz T. Ulaby, Umberto Ravaioli

Publisher: PEARSON

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Chapter 8, Problem 16P

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The maximum depth d up to which the successful communication is possible.

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Chapter 8, Problem 15P

Chapter 8, Problem 17P

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Chapter 8 Solutions

Fundamentals of Applied Electromagnetics (7th Edition)

Ch. 8.1 - Prob. 1CQ Ch. 8.1 - In the radar radome design of Example 8-1, all the...Ch. 8.1 - Explain on the basis of boundary conditions why it...Ch. 8.1 - Prob. 1E Ch. 8.1 - Prob. 2E Ch. 8.1 - Obtain expressions for the average power densities...Ch. 8.2 - In the visible part of the electromagnetic...Ch. 8.2 - If the light source of Exercise 8-4 is situated at...Ch. 8.3 - If the index of refraction of the cladding...Ch. 8.4 - Prob. 4CQ

Ch. 8.4 - What is the difference between the boundary...Ch. 8.4 - Why is the Brewster angle also called the...Ch. 8.4 - At the boundary, the vector sum of the tangential...Ch. 8.4 - A wave in air is incident upon a soil surface at i...Ch. 8.4 - Determine the Brewster angle for the boundary of...Ch. 8.4 - Prob. 9E Ch. 8.8 - What are the primary limitations of coaxial cables...Ch. 8.8 - Can a TE mode have a zero magnetic field along the...Ch. 8.8 - What is the rationale for choosing a solution for...Ch. 8.8 - What is an evanescent wave?Ch. 8.8 - For TE waves, the dominant mode is TE10, but for...Ch. 8.8 - Prob. 10E Ch. 8.8 - Prob. 11E Ch. 8.8 - Prob. 12E Ch. 8.10 - Why is it acceptable for up to exceed the speed of...Ch. 8.10 - Prob. 13E Ch. 8.10 - Prob. 14E Ch. 8 - A plane wave in air with an electric field...Ch. 8 - A plane wave traveling in medium 1 with r1 = 2.25...Ch. 8 - A plane wave traveling in a medium with r1 = 9 is...Ch. 8 - A 200 MHz, left-hand circularly polarized plane...Ch. 8 - Prob. 5P Ch. 8 - A 50 MHz plane wave with electric field amplitude...Ch. 8 - What is the maximum amplitude of the total...Ch. 8 - Repeat Problem 8.6, but replace the dielectric...Ch. 8 - Prob. 9P Ch. 8 - Prob. 10P Ch. 8 - Repeat Problem 8.10, but interchange r1 and r3.Ch. 8 - Orange light of wavelength 0.61 m in air enters a...Ch. 8 - A plane wave of unknown frequency is normally...Ch. 8 - Consider a thin film of soap in air under...Ch. 8 - A 5 MHz plane wave with electric field amplitude...Ch. 8 - Prob. 16P Ch. 8 - Prob. 17P Ch. 8 - Prob. 18P Ch. 8 - Prob. 19P Ch. 8 - Prob. 20P Ch. 8 - Prob. 21P Ch. 8 - Prob. 22P Ch. 8 - Prob. 23P Ch. 8 - Prob. 24P Ch. 8 - Prob. 25P Ch. 8 - Prob. 26P Ch. 8 - A plane wave in air with E=y20ej(3x+4z) (V/m) is...Ch. 8 - Prob. 28P Ch. 8 - A plane wave in air with Ei=(x9y4z6)ej(2x+3z)(V/m)...Ch. 8 - Natural light is randomly polarized, which means...Ch. 8 - A parallel-polarized plane wave is incident from...Ch. 8 - A perpendicularly polarized wave in air is...Ch. 8 - Show that the reflection coefficient can be...Ch. 8 - Prob. 34P Ch. 8 - Prob. 35P Ch. 8 - A 50 MHz right-hand circularly polarized plane...Ch. 8 - Consider a flat 5 mm thick slab of glass with r =...Ch. 8 - Derive Eq. (8.89b).Ch. 8 - Prob. 39P Ch. 8 - A TE wave propagating in a dielectric-filled...Ch. 8 - Prob. 41P Ch. 8 - Prob. 42P Ch. 8 - Prob. 43P Ch. 8 - Prob. 44P Ch. 8 - Prob. 45P Ch. 8 - Prob. 46P Ch. 8 - Prob. 47P

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