Presentation is loading. Please wait.

Presentation is loading. Please wait.

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

Published by Modified over 8 years ago

Similar presentations

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

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

Similar presentations

Microwave Engineering, 3rd Edition by David M. Pozar

Microwave Engineering, 3rd Edition by David M. Pozar
ELCT564 Spring 2012 4/13/20151ELCT564 Chapter 5: Impedance Matching and Tuning.

ELCT564 Spring /13/20151ELCT564 Chapter 5: Impedance Matching and Tuning.
Waves and Transmission Lines Wang C. Ng. Traveling Waves.

Waves and Transmission Lines Wang C. Ng. Traveling Waves.
ENE 428 Microwave Engineering

ENE 428 Microwave Engineering
Smith Chart Impedance measured at a point along a transmission line depends not only on what is connected to the line, but also on the properties of the.

Smith Chart Impedance measured at a point along a transmission line depends not only on what is connected to the line, but also on the properties of the.
EKT241 – ELECTROMAGNETICS THEORY

EKT241 – ELECTROMAGNETICS THEORY
Derivation and Use of Reflection Coefficient

Derivation and Use of Reflection Coefficient
UNIVERSITI MALAYSIA PERLIS

UNIVERSITI MALAYSIA PERLIS
UNIVERSITI MALAYSIA PERLIS

UNIVERSITI MALAYSIA PERLIS
Design and Analysis of RF and Microwave Systems IMPEDANCE TRANSFORMERS AND TAPERS Lecturers: Lluís Pradell Francesc.

Design and Analysis of RF and Microwave Systems IMPEDANCE TRANSFORMERS AND TAPERS Lecturers: Lluís Pradell Francesc.
Chebyshev Multi-section Matching

Chebyshev Multi-section Matching
ELCT564 Spring 2012 6/9/20151ELCT564 Chapter 2: Transmission Line Theory.

ELCT564 Spring /9/20151ELCT564 Chapter 2: Transmission Line Theory.
Chapter 2: Transmission Line Theory

Chapter 2: Transmission Line Theory
Solid State Amplifier At microwave frequencies, the scattering parameters are used In the design of microwave amplifiers. Design Goals: 1.Maximum power.

Solid State Amplifier At microwave frequencies, the scattering parameters are used In the design of microwave amplifiers. Design Goals: 1.Maximum power.
16.360 Lecture 6 Last lecture: Wave propagation on a Transmission line Characteristic impedance Standing wave and traveling wave Lossless transmission.

Lecture 6 Last lecture: Wave propagation on a Transmission line Characteristic impedance Standing wave and traveling wave Lossless transmission.
16.360 Lecture 9 Last lecture Parameter equations input impedance.

Lecture 9 Last lecture Parameter equations input impedance.
Smith Chart Graphically solves the following bi-linear formulas Note: works for admittance too. Just switch sign of 

Smith Chart Graphically solves the following bi-linear formulas Note: works for admittance too. Just switch sign of 
Instructor: Engr. Zuneera Aziz Course: Microwave Engineering

Instructor: Engr. Zuneera Aziz Course: Microwave Engineering
16.360 Lecture 9 Last lecture Power flow on transmission line.

Lecture 9 Last lecture Power flow on transmission line.
ALL POLE FILTERS SYNTHESIS AND REALIZATION TECHNIQUES.

ALL POLE FILTERS SYNTHESIS AND REALIZATION TECHNIQUES.

Similar presentations

Ads by Google