The SWR is determined with the expression:
#Smith chart program generator
If the load is matched to the line and generator impedance, the load will absorb all of the power there will be no reflections back to the generator. When working with transmission lines, a main concern is the SWR. At the bottom of the chart are scales for determining the standing wave ratio (SWR), dB loss, and reflection coefficient-all common characteristics of a transmission line. The outer scale is a measure of wavelength toward the generator, the next is wavelength toward the load, and the inner scale is the reflection coefficient that’s the ratio of the reflected voltage to the incident voltage. Referring again to Figure 1, you will see some scales around the perimeter of the chart. And Z 4 is the normalized value of 25 – j10. For example, the value of Z 1 is the normalized value of 100 + j35. To do this, you just divide the R and X values by the assigned impedance of 50 Ω, and then plot the normalized value. To plot a specific impedance, you must adjust it to the main impedance. This value is assigned to the center of the chart where R = 1. That impedance is usually the characteristic impedance of a transmission line you’re using or the input and output impedance of a filter or impedance-matching circuit to be created. To use the chart for your own work, you must first set the chart to represent values associated with a specific impedance related to your application. Plotting Values on the Chartįigure 1 shows four examples of impedance plots:Įxamine these examples to be sure you understand them. The Smith chart, as shown, is normalized, thereby permitting you to customize it to your application. The curves above the horizontal line represent inductive-reactance values and the curves below the line represent capacitive reactance. These curves all come together at the R = infinity point at the far right. The remaining curves are parts of circles representing reactance. The R = 1 circle passes through the center of the R line. Resistance values are plotted on the resistance circles, all of which are tangent to one another at the far right of the resistance line. A horizontal line through the center of the main circle represents the resistance with R = 0 at the far left of the line and infinite resistance at the far right. The Smith chart is made up of multiple circles, and segments of circles arranged in a way to plot impedance values in the form of R ± jX (Fig.
#Smith chart program how to
If you have avoided the Smith chart in the past, here’s a primer on how to take advantage of it. And as you will find out, it’s useful for working out transmission-line problems and in designing impedance-matching circuits. How he came up with this is an untold story, but he provided a solution to the complex calculations on transmission lines. The intimidating graph, developed by Philip Smith in 1939, is just about as bad as it looks. Most of you have probably heard of the Smith chart. Identify impedance-matching component values from the Smith chart.Determine the impedance of a load at the end of a transmission line.Plot complex impedances on a Smith chart.
#Smith chart program pdf
Members can download this article in PDF format. This article is part of the Analog Series: Back to Basics: Impedance Matching
0 kommentar(er)
