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6.8 Introduction to using the smith chart

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Introducing the Smith Chart.

Using the Smith Chart , we will investigate some of the application and uses of the Smith Chart . For the text, we will use my new "mini Smith Chart" which is reproduced below. Clearly, there is notmuch detail here, and our answers will not be as accurate as they would be if we used a full size chart, but we want to get ideasacross here, not the best number possible, and with the small size, we won't run out of paper before everything is done.

The smith chart

Note that we have a couple of "extras" on the chart. The twoscales at the bottom of the chart can be used to either set or measure radial variables such as the magnitude of the reflectioncoefficient Γ , or the VSWR, as it turns out that in practice, what one can actually measure on a line is the VSWR. Remember, thereis a direct relationship between the VSWR and the magnitude of the reflection coefficient.
VSWR 1 Γ 1 Γ
Γ VSWR 1 VSWR 1
Since r s Γ , once we have the VSWR, we have r s and so we know how big a circle we need on the Smith Chart in order to go from one place to the next. Note also thatthere is a scale around the outside of the chart which is given in fractions of a wavelength. Since r s rotates around at a rate 2 β s and β 2 λ , we could either show distance in cm or something, and then change the scale whenever we change wavelength. Or, wecould just use a distance scale in λ , and measure all distances in units of the wavelength. This is what we shall do.Since the rate of rotation is 2 β s , one trip around the Smith Chart is the same as going one half of a wavelength down the line. Rotation in a clockwisedirection is the same as moving away from the load towards the generator, while motion along the line in the other direction(towards the load) calls for counterclockwise rotation. The scale is, of course, a relative one, and so we will have tore-set our zero, depending upon where the load etc. are really located. This will all become clearer as we do an example.

Let's start out with the simplest thing we can, with just a generator, line and load . Our task will be to find the input impedance, Z in , for the line, so that we can figure the input voltage.

Transmission line problem

For this first problem, we are going to start out with all the basics. In later examples, we probably will only give lengths inwavelengths, and impedances in terms of Z 0 , but let's do this the whole way through.
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Source:  OpenStax, Introduction to physical electronics. OpenStax CNX. Sep 17, 2007 Download for free at http://cnx.org/content/col10114/1.4
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