Presentation is loading. Please wait.

Presentation is loading. Please wait.

Prof. David R. Jackson Dept. of ECE Notes 2 ECE 5317-6351 Microwave Engineering Fall 2011 Smith Charts 1.

Published byCecil Wood Modified over 8 years ago

Similar presentations

Presentation on theme: "Prof. David R. Jackson Dept. of ECE Notes 2 ECE 5317-6351 Microwave Engineering Fall 2011 Smith Charts 1."— Presentation transcript:

1 Prof. David R. Jackson Dept. of ECE Notes 2 ECE 5317-6351 Microwave Engineering Fall 2011 Smith Charts 1

2 Recall, Generalized reflection Coefficient: Generalized Reflection Coefficient 2

3 Lossless transmission line (  = 0 ) Generalized Reflection Coefficient (cont.) For Proof: 3

4 Complex  Plane Increasing l ( toward generator) l Decreasing l ( toward load) Lossless line 4

5 Define Substitute into above expression for Z n (- l ): Impedance ( Z ) Chart Next, multiply both sides by the RHS denominator term and equate real and imaginary parts. Then solve the resulting equations for  R and  I in terms of R n and X n. This gives two equations. 5

6 1) Equation #1: Equation for a circle in the  plane Impedance ( Z ) Chart (cont.) 6 RR II

7 Equation for a circle in the  plane: Impedance ( Z ) Chart (cont.) 2) Equation #2: 7 RR II

8 Impedance ( Z ) Chart (cont.) Short-hand version R n = 1 X n = 1 X n = -1 8

9 Impedance ( Z ) Chart (cont.)  plane R n = 1 X n = 1 X n = -1 9

10 Note: Admittance ( Y ) Calculations Define: Same mathematical form as for Z n : Conclusion: The same Smith chart can be used as an admittance calculator. 10

11 Admittance ( Y ) Calculations (cont.)  plane B n = 1 B n = -1 G n = 1 11

12 Impedance or Admittance ( Z or Y ) Calculations The Smith chart can be used for either impedance or admittance calculations, as long as we are consistent. 12

13 As an alternative, we can continue to use the original  plane, and add admittance curves to the chart. Admittance ( Y ) Chart Compare with previous Smith chart derivation, which started with this equation: If ( R n X n ) = (a, b ) is some point on the Smith chart corresponding to  =  0, Then ( G n B n ) = (a, b ) corresponds to a point located at  = -  0 (180 o rotation). Side note: A 180 o rotation on a Smith chart makes a normalized impedance become its reciprocal. 13  R n = a circle, rotated 180 o, becomes G n = a circle. and X n = b circle, rotated 180 o, becomes B n = b circle.

14 Admittance ( Y ) Chart (cont.)  plane 14

15 Short-hand version G n = 1 B n = -1 B n = 1  plane 15 Admittance ( Y ) Chart (cont.)

16 Impedance and Admittance (ZY) Chart Short-hand version G n = 1 R n = 1 X n = 1 X n = -1 B n = -1 B n = 1  plane 16

17 The SWR is given by the value of R n on the positive real axis of the Smith chart. Standing Wave Ratio Proof: 17

18 At this link http://www.sss-mag.com/topten5.html Download the following.zip file smith_v191.zip Extract the following files smith.exesmith.hlpsmith.pdf This is the application file Electronic Smith Chart 18

Download ppt "Prof. David R. Jackson Dept. of ECE Notes 2 ECE 5317-6351 Microwave Engineering Fall 2011 Smith Charts 1."

Similar presentations

Notes 18 ECE Microwave Engineering Multistage Transformers

Notes 18 ECE Microwave Engineering Multistage Transformers
Waves and Transmission Lines Wang C. Ng. Traveling Waves.

Waves and Transmission Lines Wang C. Ng. Traveling Waves.
Waves and Transmission Lines TechForce + Spring 2002 Externship Wang C. Ng.

Waves and Transmission Lines TechForce + Spring 2002 Externship Wang C. Ng.
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.
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
Derivation and Use of Reflection Coefficient

Derivation and Use of Reflection Coefficient
UNIVERSITI MALAYSIA PERLIS

UNIVERSITI MALAYSIA PERLIS
ELEC 412Lecture 51 ELEC 412 RF & Microwave Engineering Fall 2004 Lecture 5.

ELEC 412Lecture 51 ELEC 412 RF & Microwave Engineering Fall 2004 Lecture 5.
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.
Prof. David R. Jackson Dept. of ECE Fall 2013 Notes 29 ECE 6340 Intermediate EM Waves 1.

Prof. David R. Jackson Dept. of ECE Fall 2013 Notes 29 ECE 6340 Intermediate EM Waves 1.
Microwave Engineering

Microwave Engineering
Prof. David R. Jackson ECE Dept. Spring 2014 Notes 13 ECE 6341 1.

Prof. David R. Jackson ECE Dept. Spring 2014 Notes 13 ECE
Prof. David R. Jackson Notes 19 Waveguiding Structures Waveguiding Structures ECE 3317 1 Spring 2013.

Prof. David R. Jackson Notes 19 Waveguiding Structures Waveguiding Structures ECE Spring 2013.
Prof. Ji Chen Notes 13 Transmission Lines (Impedance Matching) ECE 3317 1 Spring 2014.

Prof. Ji Chen Notes 13 Transmission Lines (Impedance Matching) ECE Spring 2014.
Warm-Up Exercises 1. 52 ANSWER 13 2 2. 15 3 ANSWER 5 15 3x 2 8 23 + =

Warm-Up Exercises ANSWER ANSWER x =

Similar presentations

Ads by Google