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5.6 Bounce diagrams

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Transmission line engineers came up with bounce diagrams to keep track of all the waves bouncing back and forth on the line.

Now this new V 2 + will head back towards the load and ...Hmmm... things are going to get kind of messy and complicated. Fortunately for us,transmission line engineers came up with a scheme for keeping track of all of the waves bouncing back and forth on theline. The scheme is called a bounce diagram . A bounce diagram consists of a horizontal distance line, whichrepresents distance along the transmission line, and a vertical time axis, which represents time since the battery was firstconnected to the line. Just to keep things conceptually clear, we usually first start out by showing the line, the battery, theload and a switch, S, which is used to connect the source to the line. It doesnt hurt to make a little sketch like , and write down the length of the line, Z 0 and v p , along with the source and load resistances. Now we draw thebounce diagram, which is shown in

Transient problem

A "bounce diagram"

Normally, you would not put the formula for Γ v S and Γ v L by 0 and L in the diagram, but rather their values. This will become clear when we do anexample. The next thing we do is calculate V 1 + and draw a straight line on the bounce diagram (nominally at a slope of 1 v p ) which will represent the initial signal going down the line. Wemark a τ L v p on the vertical axis to show how long it takes for the wave to reach the end of the line .

Diagram with first wave

Once the initial wave hits the load, a second, reflected wave V 1 - Γ v L V 1 + is sent back the other way. So we add it to the bounce diagram. This is shown in . Since all of the waves move with the same phase velocity, we should becareful to draw all of the lines with the same slope. Note that the time when the reflected wave hits the generator end is atotal round trip time of 2 τ . (This simple concept is one which students often forget come test time, so be forewarned!)

Adding the first reflected wave

We saw that the next thing that happens is that another wave is reflected from the generator, so we add that to the bouncediagram as well. This is shown in .

The third wave

Finally, one last wave, as we are almost bounced right off the diagram, as shown in !

And the fourth

OK, so we've got a bounce diagram, so what? Having the diagram is only part of the solution. We still have to see what goodthey are. Let's do a numerical example, as it is maybe a little more illustrative, and certainly will be easier to write outthan all these ratios all the time. We will just pick some typical numbers, and then work out the answers. Let's let V S 40 V , R S 150 Ω , Z 0 50 Ω and R L 16.7 Ω . The line will be 100m long, and v p 2 10 8 m s .

A numerical example

First we calculate the reflection coefficients
Γ v L R L Z 0 R L Z 0 16.7 50 16.7 50 -0.50
and
Γ v S R S Z 0 R S Z 0 150 50 150 50 0.50
The initial voltage signal V 1 + is
V 1 + 50 50 150 40 10 V
and the propagation time is
τ L v p 100 m 2 10 8 m s 0.5 μ s
So we draw the bounce diagrams seen in .

The bounce diagram

Now, here's how we use a bounce diagram, once we have it. Suppose we want to know what V t , the voltage as a function of time, would look like half-way down the line. We draw a vertical line at the place weare interested in (the dotted line in ) and then just go up along the line, adding voltage to whatever wehad before whenever we cross one of the "bouncing" signal lines. Thus for the line as shown we would have for V t what we see in .

V(t) at 50m down the line

For the first 0.25μs we have no voltage, because V 1 + has not reached the half-way point yet. The voltage then jumps to +10V when V 1 + comes by. It stays like that until the -5V V 1 - comes by 0.5μs later. The voltage then remains constant at 5V until the -2.5V V 2 + comes along to drop the total voltage down to only 2.5 volts. When V 2 - comes along, it has been switched back to a positive voltage wave by the negative load reflection coefficient, and so now thevoltage jumps back up to 3.75V. It will keep oscillating back and forth until it finally settles down to some asymptoticvalue.
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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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