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Microwave EngineeringMicrowave Filters
Tamer Abuelfadl
Electronics and Electrical Communications Department
Faculty of Engineering
Cairo University
Tamer Abuelfadl (EEC, Cairo University) Topic 4 ELC305B 1 / 16
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Topics Discussed
Richard Transformation.
Kuroda's Identities.
Low Pass Filter Design using Stubs.
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Low Pass Filter Design Using StubsPrototype Implementation with Parallel and Series Stubs
Ω = 1 ⇒ stub lengths ` = λg/8.
A unity lter impedance is assumed.
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Low Pass Filter Design Using StubsConverting Series Stubs into Parallel Stubs Using Kuroda's Identities
Odd number of UE's are added before the series stub, while even
number of UE's are added before parallel stub.
Total Number of UE's used on both sides is N−1, where N is the
number of stubs used in the circuit.
Finally we end up with parallel open circuits cascaded alternatively
with UE's.
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Example 8.5 (Pozar)
Design a low-pass lter for fabrication using microstrip lines. The
specication are; cuto frequency of 4 GHz, third order, impedance of 50
Ω, and a 3 dB equal-ripple characteristic.
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To convert series stubs into parallel stubs we use the rst two Kuroda's
identities, where n2 = 1+Z2/Z1.
Z2
Z2n2
Z1n2
Z2
Z1
n2Z2
n2Z1
Z1
n2 = 1+Z2
Z1= 1+
1
3.3487= 1.299
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.
Making Impedance scaling with
Z0 = 50Ω (gure (e)).
Figure (f) show the realization
using microstrip transmission
lines.
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Amplitude responses of lumped-element anddistributed-element low-pas lter of Example 8.5.
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Stepped Impedance LPFApproximate Equivalent Circuits for short circuits Transmission line section
The ABCD matrix for a TL with length `,[A BC D
]=
[cos(β`) jZ0 sin(β`)
j sin(β`)/Z0 cos(β`)
]Transforming into Z matrix,[Z11 Z12
Z21 Z22
]=
[−jZ0 cot(β`) −jZ0 csc(β`)−jZ0 csc(β`) −jZ0 cot(β`)
]
Series elemnets of the Z11−Z12 =−jZ0
[cos(β`)−1
sin(β`)
]= jZ0 tan
(β`
2
)
If β` < π/2 the series arms act as inductors, while shunt arm Z12 acts
as capacitor.
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X
2= Z0 tan
(β`
2
), B = sin(β`)/Z0
For short line length (β` < π/4) and large characteristic impedance,
X ' Z0β`B ' 0
=⇒
For short line length (β` < π/4) and small characteristic impedance,
X ' 0
B ' Y0β`
=⇒
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To realize series inductance, a high impedance line Zh is used.
To realize shunt capacitance , a low impedance line Z` is used.
Zh/Z` should be as high as possible. Zh and Z` are usually set the
highest and lowest characteristic impedance that can be fabricated.
After impedance scaling with reference impedance R0, the electrical
lengths at the desired cuto frequency ωc ,
β` =LR0
Zh(inductor)
β` =CZ`
R0(capacitor)
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(Example 8.6 Pozar) Stepped-Impedance Filter Design
Design a stepped-impedance low-pass lter having a maximally at
response and a cuto frequency of 2.5 GHz. It is necessary to have more
than 20 dB insertion loss at 4 GHz. The lter Impedance is 50 Ω; the
highest practical line impedance is 120 Ω, and the lowest is 20 Ω.
ω
ωc−1=
4
2.5−1= 0.6 ⇒ N = 6 gives the required attenuation at 4 GHz.
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C1 = g1 = 0.5176L2 = g2 = 1.4142C3 = g3 = 1.9318L4 = g4 = 1.9318C5 = g5 = 1.4142L6 = g6 = 0.5176
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C1 = g1 = 0.5176L2 = g2 = 1.4142C3 = g3 = 1.9318L4 = g4 = 1.9318C5 = g5 = 1.4142L6 = g6 = 0.5176
section Zi = Z`, or Zh β`i section Zi = Z`, or Zh β`i
1 20 Ω 11.8 4 120 Ω 46.1
2 120 Ω 33.8 5 20 Ω 32.4
3 20 Ω 44.3 6 120 Ω 12.3
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Amplitude response of the stepped-impedance low-pass lter of Example
8.6, with (dotted line) and without (solid line) losses. The response of the
corresponding lumped-element lter is also shown.