5.4 Exciting a line

Introduction to physical Page 1 / 1

This module looks at what happens when we excite a transmission line. The module examines this concept in the context of a cable TV co-axial transmission line.

We will now go on and look at what happens when we excite the line. Let's take a DC voltage source with a sourceinternal impedance $R_{s}$ and connect it to our semi-infinite line. The sketch in is sort of awkward looking, and will be hard to analyze, so let's make a more "schematic like"drawing , keeping in mind that it is a situation such as which we trying to represent.

Exciting a transmission line

Schematic representation

Why have we shown an

I^{+}

and a

V^{+}

but not

V^{-}

I^{-}

? The answer is, that if the line is semi-infinite, then the "other" end is at infinity, and we know thereare no sources at infinity. The current flowing through the source resistor is just

I_{1}^{+}

, so we can do a KVL around the loop

V_{s} I_{1}^{+} 0 t R_{s} V_{1}^{+} 0 t 0

Substituting for

I_{1}^{+}

in terms of

V_{1}^{+}

using this equation :

V_{s} V_{1}^{+} 0 t Z_{0} R_{s} V_{1}^{+} 0 t 0

Which we re-write as

V_{1}^{+} 0 t 1 R_{s} Z_{0} V_{s}

Or, on solving for

V_{1}^{+} 0 t

V_{1}^{+} 0 t Z_{0} Z_{0} R_{s} V_{s}

This should look both reasonable and familiar to you. The line and the source resistance are actingas a voltage divider . In fact, is just the usual voltage divider equation for two resistors in series. Thus, thegenerator can not tell the difference between a semi-infinite transmission line of characteristic impedance

Z_{0}

and a resistor with a resistance of the same value .

Line is initially a voltage divider!

Have you ever heard of "

300

twin-lead" or maybe "

75

co-ax" and wondered why people would want to use wires with such a high resistance value to bring a TV signal to theirset? Now you know. The

300

characterization is not a measure of the resistance of the wire, rather it is a specification of the transmissionline's impedance. Thus, if a TV signal coming from your antenna has a value of, say,

30 V

, and it is being brought down from the roof with

300

twin-lead, then the current flowing in the wires is

I 30 V 300 100 nA

, which is a very small current indeed!

Why then, did people decide on $300$ ? An antenna which is just a half-wavelength long (Which turns out to be both a convenient and efficient choicefor signals in the 100MHz ( $3 m$ ) range) acts like a voltage source with a source resistance of about $300$ . If you remember from ELEC 242, when we have a source with a source resistance $R_{s}$ and a load resistor with load resistance value $R_{L}$ , you calculate the power delivered to the load using the following method.

Power transfer to a load

P_{L}

, the power in the load, is just product of the voltage across the load times the current through the load. We can usethe voltage divider law to find the voltage across

R_{L}

and the resistor sum law to find the current through it.

P_{L} V_{L} I_{L} R_{L} R_{L} R_{s} V_{s} V_{s} R_{L} R_{s} R_{L} R_{L} R_{s} 2 V_{s} 2

If we take the derivative of with respect to

R_{L}

, the load resistor (which we assume we can pick, given some predetermined

R_{s}

) we have (ignoring the

V_{s} 2

R_{L} P_{L} 1 R_{L} R_{s} 2 2 R_{L} R_{L} R_{s} 3 0

Putting everything on

R_{L} R_{s} 3

and then just looking at the numerator:

R_{L} R_{s} 2 R_{L} 0

Which obviously says that for maximum power transfer, you wantyour load resistor

R_{L}

to have the same value as your source resistor

R_{s}

! Thus, people came up with

300

twin lead so that they could maximize the energy transfer between the TV antenna and the transmission linebringing the signal to the TV receiver set. It turns out that for a co-axial transmission line (such as your TV cable)

75

minimizes the signal loss, which is why that value was chosen for CATV.

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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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