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7-5: Electromagnetic Boundary Conditions

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7-5: Electromagnetic Boundary Conditions E1t=E2t, always. B1n=B2n, always. For PEC, the conductor side H2=0, E2=0. (7.66a) (7.66b) (7.66c) (7.66d) (7.68) – PowerPoint PPT presentation

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Title: 7-5: Electromagnetic Boundary Conditions


1
  • 7-5 Electromagnetic Boundary Conditions
  • E1tE2t, always.
  • B1nB2n, always.
  • For PEC, the conductor side H20, E20.

(7.66a)
(7.66b)
(7.66c)
(7.66d)
(7.68)
2
  • 7-6 Wave Equations and Time-Domain Solutions
  • Retarded scalar and vector potentials are the
    solution
  • to the non-homogeneous wave equation (7-65) and
    (7-63),
  • respectively
  • where is the propagation velocity,
    and

(7.77)
(7.78)
3
  • In contrast to the static case of instantaneous
  • response of
  • The wave nature of (7.77) and (7.78) shows the
  • retarded response to the source.

(3-61)
(6-23)
4
  • 7-6.2 Source-Free Wave Equations
  • In a region, where ,
    Maxwells equations
  • becomes

(7.79a)
(7.79b)
(7.79c)
(7.79d)
5
  • Taking both sides on (7.79a),
  • Hence,
  • In the same fashion,

(7.80)
(7.82)
6
  • 7-7 Time-Harmonic Fields
  • 7-7.1 Phasors
  • Phasor (frequency domain) converts the ordinary
    differential equations (ODEs) into algebraic
    equations.
  • Let I(t)I(w)cos(wtj) where I is the magnitude,
    w2pf.
  • Circuit
  • where e(t) E cos wt is the electromotive force
    (emf).
  • In the phasor form (taking the Fourier
    transform),
  • or

(7.84)
(7.91)
7
  • Example 7-6 Convert a time domain expression
  • into the phasor form (complex exponential)
  • Solution
  • In comparison with (7.92a),
  • Therefore,

(7.92a)
8
  • The complex form
  • And the phasor form, after dropping the time
    conversion ejwt is

9
  • Rules
  • From phasor to time-domain
  • From time-domain to phasor
  • See the example
  • 3. Similar to the Laplace transform

10
  • 7-7.2 Time-Harmonic Electromagnetics
  • Using the rule
  • We have the Maxwells equations in phasor form
    as
  • The Lorentz gauge

(7.94)
(7.98)
11
  • The nonhomogeneous wave equations
  • where
  • The wavenumber
  • The phasor solutions

(7.95)
(7.96)
(7.97)
(7.99)
(7.100)
12
  • Note
  • Wavenumber

(7.102)
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