6.2 Wireline channels (Page 2/3)

Fundamentals of electrical Page 2 / 3

The voltage between the two conductors and the current flowing through them will depend on distance $x$ along the transmission line as well as time. We express this dependence as $v x t$ and $i x t$ . When we place a sinusoidal source at one end of the transmissionline, these voltages and currents will also be sinusoidal because the transmission line model consists of linear circuit elements. Asis customary in analyzing linear circuits, we express voltages and currents as the real part of complex exponential signals,and write circuit variables as a complex amplitude—here dependent on distance—times a complex exponential: $v x t V x 2 f t$ and $i x t I x 2 f t$ . Using the transmission line circuit model, we find from KCL,KVL, and v-i relations the equations governing the complex amplitudes.

Kcl at center node

I x I x Δ x V x \tilde{G} 2 f \tilde{C} Δ x

V-i relation for rl series

V x V x Δ x I x \tilde{R} 2 f \tilde{L} Δ x

Rearranging and taking the limit

Δ x 0

yields the so-called transmission line equations .

x I x \tilde{G} 2 f \tilde{C} V x

x V x \tilde{R} 2 f \tilde{L} I x

By combining these equations, we can obtain a single equation that governs how the voltage's or the current's complexamplitude changes with position along the transmission line. Taking the derivative of the second equation and plugging thefirst equation into the result yields the equation governing the voltage.

x 2 V x \tilde{G} 2 f \tilde{C} \tilde{R} 2 f \tilde{L} V x

This equation's solution is

V x V_{+} γ x V_{-} γ x

Calculating its second derivative and comparing the result with our equation for the voltage can check this solution.

x 2 V x γ 2 V_{+} γ x V_{-} γ x γ 2 V x

Our solution works so long as the quantity

γ

satisfies

γ \pm \tilde{G} 2 f \tilde{C} \tilde{R} 2 f \tilde{L} \pm a f b f

Thus,

γ

depends on frequency, and we express it in terms of real and imaginaryparts as indicated. The quantities

V_{+}

and

V_{-}

are constants determined by the source and physical considerations. For example, let the spatial origin be themiddle of the transmission line model [link] . Because the circuit model contains simple circuit elements,physically possible solutions for voltage amplitude cannot increase with distance along the transmission line. Expressing

γ

in terms of its real and imaginary parts in our solution shows that such increases are a(mathematical) possibility.

V x V_{+} a b x V_{-} a b x

The voltage cannot increase without limit; because

a f

is always positive, we must segregate the solution for negative and positive

x

. The first term will increase exponentially for

x 0

unless

V_{+} 0

in this region; a similar result applies to

V_{-}

for

x 0

. These physical constraints give us a cleaner solution.

V x V_{+} a b x x 0 V_{-} a b x x 0

This solution suggests that voltages (and currents too) will decrease exponentially along a transmission line. The space constant , also known as the attenuation constant , is the distance over which the voltage decreases by a factor of

1

. It equals the reciprocal of

a f

, which depends on frequency, and is expressed by manufacturers inunits of dB/m.

The presence of the imaginary part of $γ$ , $b f$ , also provides insight into how transmission lines work. Becausethe solution for $x 0$ is proportional to $b x$ , we know that the voltage's complex amplitude will vary sinusoidally in space . The complete solution for the voltage has the form

v x t V_{+} a x 2 f t b x

The complex exponential portion has the form of a propagating wave . If we could take a snapshot of the voltage (take its picture at

t t_{1}

), we would see a sinusoidally varying waveform along thetransmission line. One period of this variation, known as the wavelength , equals

λ 2 b

. If we were to take a second picture at some later time

t t_{2}

, we would also see a sinusoidal voltage. Because

2 f t_{2} b x 2 f t_{1} t_{2} t_{1} b x 2 f t_{1} b x 2 f b t_{2} t_{1}

the second waveform appears to be the first one, but delayed—shifted to the right—in space. Thus, thevoltage appeared to move to the right with a speed equal to

2 f b

(assuming

b 0

). We denote this propagation speed by

c

, and it equals

c 2 f \tilde{G} 2 f \tilde{C} \tilde{R} 2 f \tilde{L}

In the high-frequency region where

≫ 2 f \tilde{L} \tilde{R}

and

≫ 2 f \tilde{C} \tilde{G}

, the quantity under the radical simplifies to

-4 2 f 2 \tilde{L} \tilde{C}

, and we find the propagation speed to be

f

∞ c 1 L ∼ C ∼

For typical coaxial cable, this propagation speed is a fraction (one-third to two-thirds)of the speed of light.

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Source: OpenStax, Fundamentals of electrical engineering i. OpenStax CNX. Aug 06, 2008 Download for free at http://legacy.cnx.org/content/col10040/1.9

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