5.2 Transmission line equation

Introduction to physical Page 1 / 1

This module continues derivation of Transmission Line equations. It also introduces characteristic impedance.

We need to solve the telegrapher's equations ,

x V x t L t I x t

x I x t C t V x t

The way we will proceed to a solution, and the way you always proceed when confronted with a pair of equations such as these,is to take a spatial derivative of one equation, and then substitute the second equation in for the spatial derivative inthe first and you end up with...well, let's try it and see.

Taking a derivative with respect to $x$ of

x 2 2 V x t L t x I x t

Now we substitute in for

x I x t

from

x 2 2 V x t L C t 2 2 V x t

It should be very easy for you to derive

x 2 2 I x t L C t 2 2 I x t

Oh, I know you all love differential equations! Well, let's take a look at these and just think for a minute. For either

V x t

I x t

, we need to find a function that has some rather stringent requirements. First of all, the function must be ofthe form such that no matter whether we take its second derivative in space (

x

) or in time (

t

), it must end up differing in the way it behaves in

x

t

by no more than just a constant (

L C

In fact, we can be more specific than that. First $V x t$ must have the same functional form for both its $x$ and $t$ variation. At most, the two derivatives must differ only by a constant. Let's try a "lucky"guess and let:

V x t V_{0} f x v t

where

V_{0}

is the amplitude of the voltage, and

f

is some function, of a form yet undetermined. Well

t f x v t v f

and

t 2 f x v t v 2 2 f

Note also, that

x 2 2 f x v t 2 f

Now, let's take , , and and substitute them into :

V_{0} 2 f L C V_{0} v 2 2 f

Our "lucky" guess works as a solution as long as

v \pm 1 L C

So, what is this

f x v t

? We don't know yet what its actual functional form will be, but suppose at some point in time,

t_{1}

, the function looks like .

F(x) at some point in time

f x

at time

t_{1}

At point

x_{1}

, the function takes on the value

V_{1}

. Now, let's advance to time

t_{2}

. We look at the function and we see .

F(x) at a later point in time

f x

at a later

t_{2}

t

increases from

t_{1}

t_{2}

then

x

will have to increase from

x_{1}

x_{2}

in order for the argument of

f

to have the same value,

V_{1}

. Thus we find

x_{1} v t_{1} x_{2} v t_{2}

which can be re-written as

x_{2} x_{1} t_{2} t_{1} Δ x Δ t v_{p} 1 L C

where

v_{p}

is the velocity with which the function is moving alongthe x-axis! (We use the subscript "p" to indicated that what we have here is what is called the phase velocity . We will encounter another velocity called the group velocity a little later in the course.)

If we had "guessed" an $f x v t$ for our function, it should be pretty easy to see that this would have given us a signal moving in the minus $x$ direction, instead of the plus $x$ direction. Thus we shall denote

V_{plus} V^{+} f x 1 L C t

the positive going voltage function and

V_{minus} V^{-} f x 1 L C t

which is the negative going voltage function. Notice that since we are taking the second derivative of

f

with respect to

t

, we are free to choose either a

1 L C

or a

1 L C

in front of the time argument inside

f

. Also note that these are our only choices for a solution. As we know from Differential Equations, a second order equation has, atmost, two independent solutions.

Since $I x t$ has the same differential equation describing its behavior, the solutions for $I$ must also be of the exact same form. Thus we can let

I_{plus} I^{+} f x 1 L C t

represent the current function which goes in the positive

x

direction, and

I_{minus} I^{-} f x 1 L C t

represent the negative going current function.

Now, let's take and and substitute them into :

V^{+} L C f x 1 L C t L I^{+} f x 1 L C t

This can be solved for

V^{+}

in terms of

I^{+}

V^{+} L C I^{+} Z_{0} I^{+}

where

Z_{0} L C

is called the characteristic impedance of the transmission line. We will leave it as an exercise to the reader to ensure that indeed

L C

has units of Ohms. For practice, and understanding about just how these equations work, the reader should ensurehim/her self that

V^{-} L C I^{-} Z_{0} I^{-}

Note the "subtle" difference here, with a "-" sign in front of the RHS of the equation!

We've been through lots of equations recently, so it is probably worth our while to summarize what we know so far.

The telegrapher's equations allow two solutions for the voltage and current on a transmission line. One moves in the $x$ direction and the other moves in the $x$ direction.
Both signals move at a constant velocity $v_{p}$ given by .
The voltage and current signals are related to one another by the characteristic impedance $Z_{0}$ , with

v_{p} 1 L C

Z_{0} L C

V^{+} I^{+} Z_{0}

V^{-} I^{-} Z_{0}

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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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