Lecture 4f- Impedance Matching Using Smith Charts pdf · Lecture Outline •Why use impedance...
Transcript of Lecture 4f- Impedance Matching Using Smith Charts pdf · Lecture Outline •Why use impedance...
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Electromagnetics:
Microwave Engineering
Impedance MatchingUsing Smith Charts
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Lecture Outline
•Why use impedance matching?
• Two element impedance matching
• Example 1
• Single stub impedance matching
• Example 2
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Why use impedance matching?
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Why use impedance matching?
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• Maximum power delivered• Improved SNR• Reduce amplitude and phase errors in power distribution networks• Consider factors such as complexity, frequencies of operation, ease of
implementation, and behavior with variable loads.
𝑍𝐿Matching Network
LoadTransmission Line
𝑍0
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Two Element Impedance Matching
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Two-Element MatchingL Network
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The most common impedance matching circuit is the L network.
1. 𝑧𝐿 inside 1 + 𝑗𝑥
𝑍𝐿𝑗𝐵
𝑗𝑋
2. 𝑧𝐿 outside 1 + 𝑗𝑥
𝑍𝐿𝑗𝐵
𝑗𝑋
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Example 1
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Example 1 – L Network Impedance Matching
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𝑓 = 500 MHz𝑍𝐿 = 200 − 𝑗100 Ω𝑍0 = 100 Ω
Solution1. Normalize load impedance
𝑧𝐿 =𝑍𝐿𝑍0
= 2 − 𝑗1 Ω
𝑧𝐿 is located inside the 1 + 𝑗𝑥 circle, so option 1 is chosen.
𝑍𝐿𝑗𝐵
𝑗𝑋
1 + 𝑗𝑥 circle
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Example 1 – L Network Impedance Matching
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Solution3. The admittance of 𝑧𝐿 is
𝑦𝐿 = 0.4 − 𝑗0.2 Ωsince the first element is in parallel, we move alongthe ADMITTANCE circle to intersect the 1 + 𝑗𝑥 circle.The element will be a shunt capacitor of value 𝑗𝑏 = 𝑗0.29
+𝑗0.20
+𝑗0.49
+𝑗0.29
𝑍𝐿
𝑗𝑋
𝑗𝑏 = 0.29 𝑗𝐵
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Example 1 – L Network Impedance Matching
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Solution4. Now we move along the IMPEDANCE circle to the center of the chart.The element will be a series inductor of value 𝑗𝑥 = +𝑗1.23
+𝑗1.23
−𝑗1.23
𝑗0.00
𝑍𝐿𝑗𝑏 = 0.29
𝑗𝑥 = 1.23
𝑗𝑋
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Example 1 – L Network Impedance Matching
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Solution5. Now we obtain the values for the circuit elements:
𝐶 =𝑏
2𝜋𝑓𝑍0= 0.923 pF
𝐿 =𝑥𝑍𝑜
2𝜋𝑓= 39.15 nH
𝑍𝐿0.923 pF
38.8 nH
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Example 1 – Another Solution
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Another Solution1. We can also walk along the ADMITTANCE circles in the other direction to intersect the 1 + 𝑗𝑥 circle. This will yield a shunt inductor with 𝑗𝑏 = −𝑗0.69
+𝑗0.20
−𝑗0.49
−𝑗0.69
𝑍𝐿
𝑗𝑋
𝑗𝑏 = −𝑗0.69
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Example 1 – Another Solution
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Another Solution2. Now we walk along the IMPEDANCE circle to the center of the chart. This will yield a series capacitor with 𝑗𝑥 = −1.22
−𝑗1.22
+𝑗1.22
+𝑗0.0
𝑍𝐿𝑗𝑏 = −𝑗0.69
𝑗x = −𝑗1.22
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Example 1 – Another Solution
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Another Solution3. Now we obtain the values for the circuit elements:
𝐶 =−1
2𝜋𝑓𝑥𝑍0= 2.609 pF
𝐿 = −𝑍𝑜
2𝜋𝑓𝑏= 46.13 nH
𝑍𝐿0.461 nH
2.61 pF
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Single StubImpedance Matching
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What is Stub Tuning? (1 of 6)
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0 ,Z
L 0
L 0
Z Z
Z Z
− =
+
Power is reflected due to an impedance mismatch.
LZ
srcZ
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What is Stub Tuning? (2 of 6)
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0 ,Z
Ad
A
0 =
It is desired to add a short circuit stub to match the impedance.
LZ
srcZ
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Stub Tuning Concept (3 of 6)
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LZ0 ,Z
srcZ
Ad
Back off from the load until the real part of the input admittance is 1/𝑍0.
At this point, the real part of admittance is matched to the transmission line.
1 1
A A 0 AY Z Z jB− −= = +
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Stub Tuning Concept (4 of 6)
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Lz0 ,Z
srcz
Ad
It is possible to perfectly match to this admittance by introducing a shunt element with the conjugate susceptance.
1
in 0Y Z −=
SA AY jB= −
SAY
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Stub Tuning Concept (5 of 6)
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0 ,Z
A
To realize this shunt susceptance with a short-circuit stub, back off some distance ℓAfrom a short circuit load until the input admittance is −𝑗𝐵A.
This is the stub.
SA AY jB= −
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Stub Tuning Concept (6 of 6)
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Lz0 ,Z
srcz
Ad
Last, add the stub at position dA from the load to cancel the susceptance of the load. 1
in 0Y Z −=
A
The load is matched and there will be zero reflection!
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Single-Stub TuningExample – Step 1
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Problem:A 50 W transmission line with an air-core operates at 100 MHz and is connected to a load impedance of ZL = 27.5 + j35 W. Design a single-stub tuner.
Step 1 – Normalize impedance and calculate l.
( )( )
0
8
0
6
27.5 35 0.55 0.7
50
3 10 m s3 m
1.0 100 10 Hz
LL
Z jz j
Z
c
nfl
+ W= = = +
W
= =
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Single-Stub TuningExample – Step 2
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Plot impedance and find admittance.
We read
𝑧𝐿 = 0.55 + 𝑗0.7 Ω𝑦𝐿 ≅ 0.70 − 𝑗0.88 Ω−1
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Single-Stub TuningExample – Step 3
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Walk CW around the constant VSWR circle until the 1 + 𝑗𝑏 circle intersects it.
We read
A
B
𝑦𝐴 ≅ 1 + 𝑗1.1𝑦𝐵 ≅ 1 − 𝑗1.1
1 + 𝑗𝑏 circle
We will pick A because it leads to the shortest stub.
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Single-Stub TuningExample – Step 3
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A
B
How far CW did we traverse to get to A?
0.416𝜆 − 0.113𝜆 = 0.303𝜆
𝑑𝐴 ≈ 0.303𝜆𝑑𝐴 ≈ 90.9 cm
0.416𝜆
0.113𝜆
0.303𝜆
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Single-Stub TuningExample – Step 4
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yA is the admittance where the stub is about to be placed. We chose point A.
We need to cancel the reactive component cA
of this.
𝛾𝐴 ≅ 1 + 𝑗1.1
𝑦𝑆𝐴 = −𝑗1.1
A
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Single-Stub TuningExample – Step 5
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Find the –jcA circle on the chart and follow it to the outside of the chart.
𝑦𝑆𝐴 = −𝑗1.1
We are setting up to do an admittance transformation in the stub to realize a –j1.1
input admittance.
−𝑗1.1
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Single-Stub TuningExample – Step 6
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Start at the far left side of the chart and move CW to the point above (move away from short).
Here we are doing an admittance transformation to realize –j1.1.
ℓ𝐴
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Single-Stub TuningExample – Step 7
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Determine the distance (in wavelengths) this represents. This is lA.
ℓ𝐴 = 0.118𝜆ℓ𝐴 = 0.118 3 m
= 0.354 m = 35.4 cm
0.118𝜆
0.0