ene 429 antenna and transmission lines theory
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DATE: 28/08/06 01/09/06. ENE 429 Antenna and Transmission lines Theory. Lecture 8 Rectangular waveguides and cavity resonator. TE waves in rectangular waveguides (1). E z = 0. From Expanding for z-propagating field gets where. TE waves in rectangular waveguides (2). - PowerPoint PPT PresentationTRANSCRIPT
ENE 429Antenna and Transmission lines Theory
Lecture 8 Rectangular waveguides and cavity resonator
DATE: 28/08/06 01/09/06
TE waves in rectangular waveguides (1)
Ez = 0
From
Expanding for z-propagating field gets
where
2 2 2( ) 0xy z u zH H
2 22
2 2 ( , ) 0z zz
H Hh H x y
x y
( , ) zz zH H x y e
TE waves in rectangular waveguides (2)
In the x-direction
Since Ey = 0, then from
we have
2 2 2 2z z
yu u
H Ej jE
x y
0zHx
at x = a and x = b
TE waves in rectangular waveguides (3)
In the y-direction
Since Ex = 0, then from
we have
0zHy
at y = a and y = b
2 2 2 2z z
xu u
H Ej jE
y x
Method of separation of variables (1)
Assume
then we have
( , )zH x y XY
1 2
3 4
( ) cos sin
( ) cos sin
x x
y y
X x c x c x
Y y c y c y
Properties of TE wave in x-direction of rectangular WGs (1)1. in the x-direction
at x = 0,
at x = a,
0zHx
1 2
( )sin cos 0x x x x
dX xc x c x
dx
2 0.c
0zHx
1
( )sin 0x x
dX xc x
dx
Properties of TE wave in x-direction of rectangular WGs (2)
( 0,1,2,3,...) xa m m
. xma
Properties of TE wave in y-direction of rectangular WGs (1)
2. in the y-direction
at y = 0,
at y = b,
0zHy
4 0c
0zHy
3 4
( )sin cos 0y y y y
dY yc y c y
dy
3
( )sin 0y y
dY yc y
dy
Properties of TE wave in y-direction of rectangular WGs (2)
( 0,1,2,3,...)yb n n
.y
nb
For lossless TE rectangular waveguides,
0 cos cos /j zz
m x n yH H e A m
a b
Cutoff frequency and wavelength of TE mode
2 2
,
1
2 2
c mn
h m nf Hz
a b
, 2 2
2
c mn mm na b
A dominant mode for TE waves
For TE mode, either m or n can be zero, if a > b, is a smallest eigne value and fc is lowest when m = 1 and n = 0 (dominant mode for a > b)
ha
10
1( )
22p
c TE
uf Hz
aa
10( ) 2c TE a m
A dominant mode for TM waves
For TM mode, neither m nor n can be zero, if a > b, fc is lowest when m = 1 and n = 1
11
2 21 1 1
( )2
c TMf Hza b
11 2 2
2( )
1 1c TM m
a b
Ex1 a) What is the dominant mode of an axb rectangular WG if a < b and what is its cutoff frequency?
b) What are the cutoff frequencies in a square WG (a = b) for TM11, TE20, and TE01 modes?
Ex2 Which TM and TE modes can propagate in the polyethylene-filled rectangular WG (r = 2.25, r = 1) if the operating frequency is 19 GHz given a = 1.5 cm and b = 0.6 cm?
Rectangular cavity resonators (1) At microwave frequencies, circuits with the dimension comparable to the operating wavelength become efficient radiators An enclose cavity is preferred to confine EM field, providelarge areas for current flow. These enclosures are called ‘cavity resonators’.
There are both TE and TM modesbut not unique.
a
b
d
Rectangular cavity resonators (2) z-axis is chosen as the reference.
“mnp” subscript is needed to designate a TM or TE standingwave pattern in a cavity resonator.
Electric field representation in TMmnp modes (1) The presence of the reflection at z = d results in a standingwave with sinz or cozz terms.
Consider transverse components Ey(x,y,z), from B.C. Ey = 0 at z = 0 and z = d
1) its z dependence must be the sinz type
2)
similar to Ex(x,y,z).
( 0,1, 2,...)p
pd
Electric field representation in TMmnp modes (2)
From
Hz vanishes for TM mode, therefore
2 2 2 2
2 2 2 2
z zx
u u
z zy
u u
H Ej jE
y x
H Ej jE
x y
2
2
zx
zy
EjE
xhEj
Eyh
Electric field representation in TMmnp modes (3)
If Ex and Ey depend on sinz then Ez must vary according to cosz, therefore
0 sin sin cos /m x n y p z
E V ma b d
( , , ) ( , ) cos /z z
p zE x y z E x y V m
d
2 2 2
2p
mnp
u m n pf resonant frequency Hz
a b d
Magnetic field representation in TEmnp modes (1) Apply similar approaches, namely
1) transverse components of E vanish at z = 0 and z = d
- require a factor in Ex and Ey as well as Hz.
2) factor indicates a negative partial derivative with z.
- require a factor for Hx and Hy
fmnp is similar to TMmnp.
sinp zd
cosp zd
( , , ) ( , )sin /z z
p zH x y z H x y A m
d
0 cos cos sin /m x n y p z
H A ma b d
Dominant mode The mode with a lowest resonant frequency is called
‘dominant mode’.
Different modes having the same fmnp are called degenerate modes.
Resonator excitation (1)For a particular mode, we need to
1) place an inner conductor of the coaxial cable where the electric field is maximum.
2) introduce a small loop at a location where the flux of the desired mode linking the loop is maximum.
source frequency = resonant frequency
Resonator excitation (2)For example, TE101 mode, only 3 non-zero components are Ey, Hx, and Hz.
insert a probe in the center region of the top or bottom face where Ey is maximum or place a loop to couple Hx maximum inside a front or back face.
Best location is affected by impedance matching requirements of the microwave circuit of which the resonator is a part.
Coupling energy method
place a hole or iris at the appropriate location
field in the waveguide at the hole must have a component that is favorable in exciting the desired mode in the resonator.
Ex3 Determine the dominant modes and their frequencies in an air-filled rectangular cavity resonator for
a) a > b > d
b) a > d > b
c) a = b = d