Presentation is loading. Please wait.

Presentation is loading. Please wait.

Prof. David R. Jackson Notes 13 Transmission Lines (Impedance Matching) ECE 3317 [Chapter 6]

Published byClarissa Berry Modified over 9 years ago

Similar presentations

Presentation on theme: "Prof. David R. Jackson Notes 13 Transmission Lines (Impedance Matching) ECE 3317 [Chapter 6]"— Presentation transcript:

1 Prof. David R. Jackson Notes 13 Transmission Lines (Impedance Matching) ECE 3317 [Chapter 6]

2 Smith Chart Impedance matching is very important to avoid reflected power, which causes a loss of efficiency and interference. ZgZg z sinusoidal source ZLZL z = 0 Z0Z0 S We will discuss two methods:  Quarter-wave transformer  Single-stub matching

3 Quarter-Wave Transformer Quarter-Wave Transformer: First consider a real load. Z L = R L Z0Z0 Z 0T Z in Hence

4 Z L = R L Z0Z0 Z 0T Z in Set This gives us Hence Quarter-Wave Transformer (cont.)

5 Next, consider a general (complex) load impedance Z L. shunt (parallel) susceptance Y L = 1 / Z L Z0Z0 Z 0T Y L = G L Z0Z0 Z 0T New model: Z L = R L = 1 / G L

6 Quarter-Wave Transformer (cont.) Summary of quarter-wave transformer matching method Y L = G L + j B L Z0Z0 Z 0T Y s = jB s

7 Quarter-Wave Transformer (cont.) Realization using a shorted stub Y L = G L + j B L Z0Z0 Z 0T B s = - B L lsls Z0sZ0s (An open-circuited stub could also be used.)

8 Single-Stub Matching A susceptance is added at a distance d from the load. ZLZL Y 0 = 1 / Z 0 d 1) We choose the distance d so that at this distance from the load 2) We then choose the shunt susceptance so that (i.e., G in = Y 0 )

9 Single-Stub Matching (cont.) ZLZL Y 0 = 1 / Z 0 d The feeding transmission line on the left sees a perfect match.

10 Realization using a shorted stub ZLZL Z0Z0 lsls Z0sZ0s d (An open-circuited stub could also be used.) Single-Stub Matching (cont.)

11 ZLZL Z0Z0 lsls Z0sZ0s d We use the Smith chart as an admittance calculator to determine the distance d. 1)Convert the load impedance to a load admittance Y L. 2)Determine the distance d to make the normalized input conductance equal to 1.0. 3)If desired, we can also use the Smith chart to find the stub length. Single-Stub Matching (cont.)

12 ZLZL Z0Z0 lsls Z0sZ0s d Example Single-Stub Matching (cont.)

13 X X X X wavelengths toward load wavelengths toward generator Smith chart scale: use this one Single-Stub Matching (cont.)

14 ZLZL z UNMATCHED z 1.62 1.55 0.38 1.0 0.78 X Crank diagram Single-Stub Matching (cont.)

15 ZLZL z ZLZL z jB s MATCHED UNMATCHED z 1.62 1.55 0.78 SWR = 1.0 z 1.62 1.55 0.38 1.0 0.78 Single-Stub Matching (cont.) SWR = 4.26

16 0-j0.5 0-j1 0+j0.5 0+j1 0+j0 0+j2 0-j2 Next, we find the length of the short-circuited stub: Rotate clockwise from S/C to desired B s value. Assume Z 0s = Z 0 Otherwise, we have to be careful with the normalization! admittance chart Single-Stub Matching (cont.)

17 X admittance chart From the Smith chart: Analytically: Single-Stub Matching (cont.)

Download ppt "Prof. David R. Jackson Notes 13 Transmission Lines (Impedance Matching) ECE 3317 [Chapter 6]"

Similar presentations

ELCT564 Spring 2012 4/13/20151ELCT564 Chapter 5: Impedance Matching and Tuning.

ELCT564 Spring /13/20151ELCT564 Chapter 5: Impedance Matching and Tuning.
ENE 428 Microwave Engineering

ENE 428 Microwave Engineering
3 February 2004K. A. Connor RPI ECSE Department 1 Smith Chart Supplemental Information Fields and Waves I ECSE 2100.

3 February 2004K. A. Connor RPI ECSE Department 1 Smith Chart Supplemental Information Fields and Waves I ECSE 2100.
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.
Lecture 4 Antenna Impedance Matching

Lecture 4 Antenna Impedance Matching
Prof. Ji Chen Notes 12 Transmission Lines (Smith Chart) ECE 3317 1 Spring 2014.

Prof. Ji Chen Notes 12 Transmission Lines (Smith Chart) ECE Spring 2014.
EKT241 – ELECTROMAGNETICS THEORY

EKT241 – ELECTROMAGNETICS THEORY
Chapter Fourteen: Transmission Lines

Chapter Fourteen: Transmission Lines
Derivation and Use of Reflection Coefficient

Derivation and Use of Reflection Coefficient
UNIVERSITI MALAYSIA PERLIS

UNIVERSITI MALAYSIA PERLIS
UNIVERSITI MALAYSIA PERLIS

UNIVERSITI MALAYSIA PERLIS
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
16.360 Lecture 12 Last lecture: impedance matching Vg(t) A’ A Tarnsmission line ZLZL Z0Z0 Z in Zg IiIi Matching network Z in = Z 0.

Lecture 12 Last lecture: impedance matching Vg(t) A’ A Tarnsmission line ZLZL Z0Z0 Z in Zg IiIi Matching network Z in = Z 0.
ELEC 412Lecture 51 ELEC 412 RF & Microwave Engineering Fall 2004 Lecture 5.

ELEC 412Lecture 51 ELEC 412 RF & Microwave Engineering Fall 2004 Lecture 5.
ENEE482-Dr. Zaki1 Impedance Matching with Lumped Elements YLYL jX 1 jB 2.

ENEE482-Dr. Zaki1 Impedance Matching with Lumped Elements YLYL jX 1 jB 2.
16.360 Lecture 9 Last lecture Parameter equations input impedance.

Lecture 9 Last lecture Parameter equations input impedance.
Electromagnetics (ENGR 367) The Smith Chart: A Graphical Method for T-lines.

Electromagnetics (ENGR 367) The Smith Chart: A Graphical Method for T-lines.
16.360 Lecture 11 Today: impedance matcing Vg(t) A’ A Tarnsmission line ZLZL Z0Z0 Z in Zg IiIi Matching network Z in = Z 0.

Lecture 11 Today: impedance matcing Vg(t) A’ A Tarnsmission line ZLZL Z0Z0 Z in Zg IiIi Matching network Z in = Z 0.
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 

Similar presentations

Ads by Google