notes 19 3317
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Transcript notes 19 3317
ECE 3317
Prof. D. R. Wilton
Notes 19
Waveguiding Structures
[Chapter 5]
Waveguiding Structures
A waveguiding structure is one that carries a
signal (or power) from one point to another.
There are three common types:
Transmission lines
Fiber-optic guides
Waveguides
Transmission lines
Properties
Has two conductors running parallel
Can propagate a signal at any frequency (in theory)
Becomes lossy at high frequency
Can handle low or moderate amounts of power
Does not have signal distortion, unless there is loss
May or may not be immune to interference
Does not have Ez or Hz components of the fields (TEMz)
R j L G jC
k z j j
R j L G jC
j
Lossless: kz LC
k
(always real: = 0)
Fiber-Optic Guide
Properties
Has a single dielectric rod
Can propagate a signal only at high frequencies
Can be made very low loss
Has minimal signal distortion
Very immune to interference
Not suitable for high power
Has both Ez and Hz components of the fields
Fiber-Optic Guide (cont.)
Two types of fiber-optic guides:
1) Single-mode fiber
Carries a single mode, as with the mode on a
waveguide. Requires the fiber diameter to be small
relative to a wavelength.
2) Multi-mode fiber
Has a fiber diameter that is large relative to a
wavelength. It operates on the principle of total
internal reflection (critical angle effect).
Multi-Mode Fiber
Higher index core region
http://en.wikipedia.org/wiki/Optical_fiber
Waveguide
Properties
Has a single hollow metal pipe
Can propagate a signal only at high frequency: > c
The width must be at least one-half of a wavelength
Has signal distortion, even in the lossless case
Immune to interference
Can handle large amounts of power
Has low loss (compared with a transmission line)
Has either Ez or Hz component of the fields (TMz or TEz)
http://en.wikipedia.org/wiki/Waveguide_(electromagnetism)
Waveguides (cont.)
Cutoff frequency property (derived later)
In a waveguide:
k
We can write
kc c
kz k k
2
2 1/2
c
kc
constant determined
by guide geometry
(wavenumber of material inside waveguide)
(wavenumber of material at cutoff frequency c )
c : k z k 2 kc2 real
(propagation)
c : k z j kc2 k 2 imaginary
(evanescent decay)
Field Expressions of a Guided Wave
Statement:
All six field components of a wave guided along the z-axis
can be expressed in terms of the two fundamental field
components Ez and Hz.
"Guided-wave theorem"
Assumption:
E x, y, z E 0 x, y e jkz z
H x, y , z H 0 x, y e
jk z z
(This is the definition of a guided wave.
Note for such fields, = jk z )
z
A proof of the “statement” above is given next.
Field Expressions (cont.)
Proof (illustrated for Ey)
H j E
or
1 H z H x
Ey
j x
z
1 H z
Ey
jk
H
z
x
j x
Now solve for Hx :
E j H
Field Expressions (cont.)
E j H
1 E z E y
Hx
j y
z
1 E z
jk z E y
j y
Substituting this into the equation for Ey yields the result
1 E z
1 H z
Ey
jk z
jk z E y
j x
j y
Next, multiply by
j j k 2
Field Expressions (cont.)
This gives us
H z
E z
k E y j
jk z
k z2 E y
x
y
2
Solving for Ey, we have:
j H z jk z E z
Ey 2
2
2
2
k k z x k k z y
The other three components Ex, Hx, Hy may be found similarly.
Field Expressions (cont.)
Summary of Fields
j H z jk z E z
Ex 2
2
2
2
k k z y k k z x
j H z jk z E z
Ey 2
2
2
2
k
k
x
k
k
z
z y
j E z jk z H z
Hx 2
2
2
2
k
k
y
k
k
z
z x
j E z jk z H z
Hy 2
2
2
2
k
k
x
k
k
z
z y
Field Expressions (cont.)
TMz Fields
TEz Fields
jk z E z
Ex 2
2
k k z x
j H z
Ex 2
2
k
k
z y
jk z E z
Ey 2
2
k
k
z y
j H z
Ey 2
2
k
k
z x
j E z
Hx 2
2
k
k
z y
jk z H z
Hx 2
2
k
k
z x
j E z
Hy 2
2
k
k
z x
jk z H z
Hy 2
2
k
k
z y
TEMz Wave
Assume a TEMz wave:
Ez 0
Hz 0
To avoid having a completely zero field,
k 2 kz2 0
Hence,
TEMz
kz k
TEMz Wave (cont.)
Examples of TEMz waves:
A wave in a transmission line
A plane wave
In each case the fields do not have a z component!
z
S
E
H
H
x
coax
E
plane wave
y
TEMz Wave (cont.)
Wave Impedance Property of TEMz Mode
Faraday's Law:
E j H
Take the x component of both sides:
The field varies as
E z E y
j H x
y
z
E y x, y, z E y 0 x, y e jkz
Hence,
jk E y jHx
Therefore, we have
Hx
k
Ey
TEMz Wave (cont.)
E j H
Now take the y component of both sides:
Hence,
jk Ex jHy
Therefore, we have
Hence,
E z E x
j H y
x
z
Ex
Hy
E x
Hy
k
TEMz Wave (cont.)
Summary:
Ey
Hx
Ex
Hy
These two equations may be written as a single vector equation:
E zˆ H
The electric and magnetic fields of a TEMz wave are perpendicular to one
another, and their amplitudes are related by .
The electric and magnetic fields of a TEMz wave are transverse to z, and
their transverse variation as the same as electro- and magneto-static
fields, rsp.
TEMz Wave (cont.)
Examples
z
E = ˆ
V0
e jkz
ln b a
S
V0
H = ˆ
e jkz
ln b a
coax
plane wave
y
H
x
E
z
The fields look like a plane
wave in the central region.
d
V0 jkz x
V0 jkz microstrip
H yˆ
e
E xˆ
e
d
d
y
Waveguide
In a waveguide, the fields cannot be TEMz.
y
PEC boundary
A
Proof:
C
E
Assume a TEMz field
x
B
waveguide
B
E dr 0
(property of flux line)
C
A
E dr
C
S
E dr 0
B
B
nˆ dS z dS 0
t
t
S
contradiction!
(Faraday's law in integral form)
Waveguide (cont.)
In a waveguide, there are two types of fields:
TMz: Hz = 0, Ez 0
TEz: Ez = 0,
Hz 0