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ENEE482-Dr. Zaki1 Impedance Matching with Lumped Elements YLYL jX 1 jB 2.

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Presentation on theme: "ENEE482-Dr. Zaki1 Impedance Matching with Lumped Elements YLYL jX 1 jB 2."— Presentation transcript:

1 ENEE482-Dr. Zaki1 Impedance Matching with Lumped Elements YLYL jX 1 jB 2

2 ENEE482-Dr. Zaki2 jB 2 jX 1 ZLZL

3 ENEE482-Dr. Zaki3 Single-Stub Matching Load impedance Input admittance=S

4 ENEE482-Dr. Zaki4 Series Stub Input impedance=1/S Voltage minimum

5 ENEE482-Dr. Zaki5 Double Stub Matching Network jB 1 jB 2 YLYL a b ba

6 ENEE482-Dr. Zaki6 0 r=1 x=1 x=-1 Real part of Refl. Coeff. P short circuit P open circuit r=0.5 Smith Chart YLYL

7 ENEE482-Dr. Zaki7 0 r=1 x=1 x=-1 Real part of Refl. Coeff. P short circuit P open circuit r=0.5 Smith Chart YLYL Rotate the the G=1 circle through an angle -  The intersection of G=1 and the G L circle determine The point P 2 P2P2 P3P3 G 1 =1

8 ENEE482-Dr. Zaki8 0 r=1 x=1 x=-1 Real part of Refl. Coeff. P short circuit P open circuit r=0.5 Smith Chart YLYL The shaded range is for the load impedance which cannot be matched when d=1/8 wavelength

9 ENEE482-Dr. Zaki9 Quarter-Wave Transformers ZLZL  4 Z C =Z 0 Z C =Z 1

10 ENEE482-Dr. Zaki10

11 ENEE482-Dr. Zaki11   mm  2   mm  Bandwidth characteristic for a single Section quarter wave transformer

12 ENEE482-Dr. Zaki12 Theory of Small Reflection  LL 11 22     1    

13 ENEE482-Dr. Zaki13

14 ENEE482-Dr. Zaki14 1  21  Multiple reflection of waves for a circuit with two reflection junctions

15 ENEE482-Dr. Zaki15 Approximate Theory for Multi-Section Quarter Wave Transformers LL  00 22 11 NN A multi-section quarter-wave transformer   

16 ENEE482-Dr. Zaki16

17 ENEE482-Dr. Zaki17 Binomial Transformer

18 ENEE482-Dr. Zaki18

19 ENEE482-Dr. Zaki19

20 ENEE482-Dr. Zaki20

21 ENEE482-Dr. Zaki21 Example ZLZL Z2Z2 Z1Z1 Z0Z0 Z3Z3 Design a three section binomial transformer to match a 50 Ohms load to a 100 Ohms line. Calculate the bandwidth For max reflection =.05 over the passband.

22 ENEE482-Dr. Zaki22

23 ENEE482-Dr. Zaki23 Chebyshev Transformer  mm  mm mm 

24 ENEE482-Dr. Zaki24

25 ENEE482-Dr. Zaki25

26 ENEE482-Dr. Zaki26 Example Design a two section Chebyshev transformer (two sections) to Match a line of load impedance =2. The maximum tolerance Value of  is 0.05.

27 ENEE482-Dr. Zaki27

28 ENEE482-Dr. Zaki28 Design of Complex Impedance Termination AmplifierZcZc ZcZc Input Matching network Output Matching network ZsZs ZLZL Microwave amplifier circuit

29 ENEE482-Dr. Zaki29

30 ENEE482-Dr. Zaki30 jB 1 Stub ZLZL ZcZc ZLZL ll G=1 jB 1 ZLZL G=1 jB 2 ZLZL G=1 jX 1 jX 2 = Transmission Line Matching Network Alternative Matching Networks

31 ENEE482-Dr. Zaki31 Generator Load l/ = 0.4375 l/ = 0.0626 j1 -j1 YLYL Z L = 0.4-j0.2 Y’ in 1 2 G=1 G=2 Y” in Design Procedure for the Matching Network with Shunt Stub

32 ENEE482-Dr. Zaki32 Impedance Mismatch Factor

33 ENEE482-Dr. Zaki33 Z 11 -Z 12 Z 22 -Z 12 Z 12 ZLZL ZSZS VSVS Z in ZTZT V oc ZLZL MLML A T matching networkThevenin equivalent network

34 ENEE482-Dr. Zaki34 Impedance Transformation and Matching Review of Transmission Lines and Smith Chart ZgZg ZLZL Z0Z0 VgVg Finite Transmission Line terminated with load impedance Z =L Z=0 L

35 ENEE482-Dr. Zaki35

36 ENEE482-Dr. Zaki36 Standing wave ration (SWR) S: Smith Chart:

37 ENEE482-Dr. Zaki37

38 ENEE482-Dr. Zaki38 Imaginary part of Refl. Coeff. 0 r=1 x=1 x=-1 Real part of Refl. Coeff. P short circuit P open circuit r=0.5 Smith Chart

39 ENEE482-Dr. Zaki39 Review of Transmission Lines and Smith Chart ZgZg ZLZL Z0Z0 VgVg Finite Transmission Line terminated with load impedance Z =L Z=0 L

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