Difference between revisions of "Linear and Time Invariant Systems/Some Results from Line Transmission Theory"

# OVERVIEW  OF  THE  FOURTH  MAIN  CHAPTER #

A special case of causal and time-invariant systems are  »electrical cables«.  Here,  due to the Hilbert transformation must always be assumed:

• a  »complex-valued frequency response«  $H(f)$  and

• strongly  »unbalanced impulse responses«  $h(t)$.

The fourth chapter presents a summary of  »conducted transmission channels«,  specifically

• important  »results and descriptive quantities of Line Transmission Theory«,  in particular

1. primary line parameters, 
2. complex propagation function  $($per unit length$)$, 
3. attenuation function  $($per unit length$)$, 
4. phase function  $($per unit length$)$, 
5. wave impedance,  and
6. the operational attenuation to take account of mismatches and reflections;

• the  »frequency responses and impulse responses of coaxial cables«,  in which,  due to good shielding,  all other interferences are negligible compared to thermal noise  $($Gaussian distributed and white$)$,  and

• the  »description of symmetrical copper cables«,  which are the main transmission medium in the  »access network of telecommunication systems«.  Since many pairs run in parallel in a cable,  »crosstalk«  occurs due to capacitive and inductive couplings.

Equivalent circuit diagram of a short transmission line section

To derive the line equations,  first a very short line section of length  ${\rm d}x$  is considered,  so that the values for voltage and current

• at the beginning of the line  $(U$  resp.   $I$  at  $x)$  and

• the end of the line  $(U + {\rm d}U$  and  $I + {\rm d}I$  at  $x + {\rm d}x)$ 

differ only slightly.  The diagram below shows the underlying model.

All  »infinitesimal components«  in the equivalent circuit sketched on the right are location-independent for homogeneous lines:

Equivalent circuit diagram of a short line section

1. The inductance of the considered line section is  $L\hspace{0.05cm}' \cdot {\rm d}x$, where  $L'$  is called  »serial inductance«  per unit length.
2. Similarly,  the  »parallel capacitance«  per unit length  $(C\hspace{0.05cm}')$  is an infinitesimally small quantity which,  similar to  $L'$,  depends only slightly on frequency.
3. The  »parallel conductance«  per unit length  $(G\hspace{0.05cm}')$  takes into account the losses of the dielectric between the wires.  It increases approximately proportionally with frequency.
4. By far the largest  $($negative$)$  influence on signal transmission is the  »serial resistance«  per unit length  $(R\hspace{0.05cm}')$,  which increases almost proportionally with the root of the frequency for high frequencies due to the so-called  »skin effect«.

From the mesh and node equations of the line section,  $ω = 2πf$  results in the two difference equations:

$$ U = I \cdot (R\hspace{0.05cm}' + {\rm j} \cdot \omega L\hspace{0.05cm}') \cdot {\rm d}x + (U + {\rm d}U)\hspace{0.05cm},$$

$$ I = (U + {\rm d}U) \cdot (G\hspace{0.05cm}' + {\rm j} \cdot \omega C\hspace{0.05cm}') \cdot {\rm d}x + (I + {\rm d}I)\hspace{0.05cm}. $$

For very short line sections  $($infinitesimally small  ${\rm d}x)$  and neglecting the small second order quantities  $($for example  ${\rm d}U \cdot {\rm d}x)$,  one can now form two differential quotients whose joint consideration leads to a second order linear differential equation:

$$\frac{ {\rm d}U}{ {\rm d}x} = - (R\hspace{0.05cm}' + {\rm j} \cdot \omega L\hspace{0.05cm}') \cdot I,\hspace{0.5cm} \frac{ {\rm d}I}{ {\rm d}x} = - (G\hspace{0.05cm}' + {\rm j} \cdot \omega C\hspace{0.05cm}') \cdot U\hspace{0.3cm} \Rightarrow \hspace{0.3cm}\frac{{\rm d}^2U}{{\rm d}x^2} = (R\hspace{0.05cm}' + {\rm j} \cdot \omega L\hspace{0.05cm}') \cdot (G\hspace{0.05cm}' + {\rm j} \cdot \omega C\hspace{0.05cm}') \cdot U\hspace{0.05cm}.$$

The solution of this differential equation is:

$$U(x) = U_{\rightarrow}(x=0) \cdot {\rm e}^{-\hspace{0.02cm}\gamma \hspace{0.03cm} \cdot \hspace{0.05cm}x} + U_{\leftarrow}(x=0) \cdot {\rm e}^{\gamma \hspace{0.03cm} \cdot \hspace{0.05cm}x} \hspace{0.05cm}.$$

The voltage curve depends not only on the location  $x$  but also on the frequency  $f$  which is not explicitly noted in the equation given here.

Formula-wise, this frequency dependence is captured by the  »complex propagation function«  per unit length:

$$\gamma(f) = \sqrt{(R\hspace{0.05cm}' + {\rm j} \cdot 2\pi f \cdot L\hspace{0.05cm}') \cdot (G\hspace{0.05cm}' + {\rm j} \cdot 2\pi f \cdot C\hspace{0.05cm}')} = \alpha (f) + {\rm j} \cdot \beta (f)\hspace{0.05cm}.$$

The last two equations together describe the voltage curve along the line,  which results from the superposition of a wave  $U_→(x)$  running in the positive  $x$ direction and the wave  $U_←(x)$  in the opposite direction.

• The real part  $α(f)$  of the complex propagation function  $γ(f)$  attenuates the propagating wave and is therefore called  »attenuation function«  per unit length.  This always even function   ⇒   $α(-f) = α(f)$  results from the above  $γ(f)$ equation as follows:

$$\alpha(f) = \sqrt{{1}/{2}\cdot \left (R\hspace{0.05cm}' \cdot G\hspace{0.05cm}' - \omega^2 \cdot L\hspace{0.05cm}' \cdot C\hspace{0.05cm}'\right)+ {1}/{2} \cdot \sqrt{(R\hspace{0.05cm}'\hspace{0.05cm}^2 + \omega^2 \cdot L\hspace{0.05cm}'\hspace{0.05cm}^2) \cdot (G\hspace{0.05cm}'\hspace{0.05cm}^2 + \omega^2 \cdot C\hspace{0.05cm}'\hspace{0.05cm}^2)}} \bigg |_{\hspace{0.05cm}\omega \hspace{0.05cm}= \hspace{0.05cm}2\pi f}.$$

• The odd imaginary part   ⇒   $β(- f) = - β(f)$  is called  »phase function«  per unit length and describes the phase rotation of the wave along the line:

$$\beta(f) = \sqrt{ {1}/{2}\cdot \left (-R\hspace{0.05cm}' \cdot G\hspace{0.05cm}' + \omega^2 \cdot L\hspace{0.05cm}' \cdot C\hspace{0.05cm}'\right)+ {1}/{2} \cdot \sqrt{(R\hspace{0.05cm}'\hspace{0.05cm}^2 + \omega^2 \cdot L\hspace{0.05cm}'\hspace{0.05cm}^2) \cdot (G\hspace{0.05cm}'\hspace{0.05cm}^2 + \omega^2 \cdot C\hspace{0.05cm}'\hspace{0.05cm}^2)}} \bigg |_{\hspace{0.05cm}\omega \hspace{0.05cm}= \hspace{0.05cm}2\pi f}.$$

Wave impedance and reflections

We consider a homogeneous line of length  $l$  with a harmonic oscillation  $U_0(f)$  of frequency $f$  applied to its input.

Line of length  $l$  with wiring

1. The transmitter has internal resistance  $Z_1$.
2. The receiver has the input impedance  $Z_2$.
3. This is also the terminating resistor of the line.
4. We assume for simplicity that  $Z_1$  and  $Z_2$  are real resistors.

Current and voltage of the outgoing wave and of the return wave are linked via the  »wave impedance«  $Z_{\rm W}(f)$:

$$I_{\rightarrow}(x, f) = \frac{U_{\rightarrow}(x, f)}{Z_{\rm W}(f)}\hspace{0.05cm}, \hspace{1cm} I_{\leftarrow}(x, f) = \frac{U_{\leftarrow}(x, f)}{Z_{\rm W}(f)}\hspace{0.05cm}.$$

The following applies to the  »wave impedance«:

$$Z_{\rm W}(f) = \sqrt{\frac {R\hspace{0.05cm}' + {\rm j} \cdot \omega L\hspace{0.05cm}'}{G\hspace{0.05cm}' + {\rm j} \cdot \omega C\hspace{0.05cm}'}} \hspace{0.1cm}\bigg |_{\hspace{0.05cm}\omega \hspace{0.05cm}= \hspace{0.05cm}2\pi f}.$$

• The wave traveling in the positive  $x$–direction is generated by the  »AC voltage source«  at the beginning of the line  $($at  $x = 0)$.

• The backward wave is only generated by the  »reflection of the forward wave«  at the end of the line  $($at  $x = l)$:

$$U_{\leftarrow}(x = l) = {U_{\rightarrow}(x = l)}\cdot \frac{Z_2 -Z_{\rm W}(f)}{Z_2 + Z_{\rm W}(f)}\hspace{0.05cm}.$$

• At this point,  the terminating resistor  $Z_2$  forces a fixed relationship between voltage and current:

$$U_2(f) = Z_2 · I_2(f).$$

In the following,  these equations are explained with an example.

Model to describe the wave reflection

$\text{Example 1:}$  We consider the case shown on the right:

1. The terminating resistor  $Z_2$  of the line  $($at the same time the input impedance of the following receiver$)$  differs from the wave impedance  $Z_{\rm W}(f)$.
2. We disregard the mismatch at the beginning of the line.

The diagram below from [Han17]^[1] is intended to make clear how the resulting wave  $U(x)$  - shown as a solid curve -  differs from the outgoing wave  $U_→(x)$.

Incoming, returning and resulting wave

To clarify:

• Marked in red is the outgoing wave  $U_→(x)$  which starting from the transmitter   ⇒   $U_→(x = 0)$ , attenuates along the line.  $U_→(x = l)$  denotes the wave at the end of the line.

• Due to the mismatch there is the returning wave  $U_←(x)$  from the end of the line to the transmitter, marked in green ⇒   »reflection« .  For this the following applies at  $x = l$:

$$U_{\leftarrow}(x = l) = {U_{\rightarrow}(x = l)}\cdot \frac{Z_2 -Z_{\rm W}(f)}{Z_2 + Z_{\rm W}(f)}\hspace{0.05cm}.$$

• The blue wave  $U(x)$  results from the in–phase addition of these two parts which are not visible by themselves.  As  $x$  increases,  $U(x)$  becomes smaller,  as does  $U_→(x)$  due to line attenuation.  Also the returning wave  $U_←(x)$  is attenuated with increasing length  $($here from right to left$)$.

Lossless and low-loss lines

If  $L\hspace{0.05cm}'$  and  $C\hspace{0.08cm}'$  are constant in the considered frequency range,  the  $($real$)$  wave impedance  $Z_{\rm W}(f)=Z_{\rm W}$  is also frequency–independent and the phase function per unit length   ⇒   $β(f)$  is proportional to the frequency.

1. This means that a lossless line is always distortion–free.
2. The output signal can only have a  »delay time«  compared to the input signal.
3. Common wave impedances are  $Z_{\rm W} = 50 \ \rm Ω$,  $Z_{\rm W} = 75 \ \rm Ω$ and  $Z_{\rm W} = 150 \ \rm Ω$.
4. One speaks of a  »low-loss line«  when the line is somewhat longer,  but cannot yet be called  "long".

$\text{Example 2:}$  The given formula for the  »attenuation function per unit length«   ⇒   $\alpha(f)$  is now to be evaluated for the case of constant primary line parameters,  which does not quite correspond to reality.

Attenuation function  $α(f)$  ( per unit length) and upper bounds

• Above a  »characteristic frequency«  $f_∗$ that depends on  $R\hspace{0.05cm}', \ L\hspace{0.05cm}', \ G\hspace{0.08cm}'$  and  $C\hspace{0.08cm}'$, 

1. the serial resistance per unit length  $(R\hspace{0.05cm}')$  can be assumed to be very small compared to  $ωL\hspace{0.05cm}'$,  and
2. the parallel conductance per unit length  $(G\hspace{0.05cm}')$  can be assumed to be very small compared to  $ωC\hspace{0.08cm}'$.

⇒   This gives the approximate formula often referred to as  »weak attenuation«,  valid for  $(f \gg f_∗)$:

$$\alpha_{_{ {\rm I} } }(f) = {1}/{2} \cdot \left [R\hspace{0.05cm}' \cdot \sqrt{ {C\hspace{0.05cm}'}/{ L\hspace{0.05cm}'} } + G\hspace{0.08cm}' \cdot \sqrt{ {L\hspace{0.05cm}'}/{ C\hspace{0.08cm}'} }\right ] \hspace{0.05cm}.$$

• On the other hand,  for small frequencies  $(f < f_∗)$ 

1. the serial resistance per unit length  $(R\hspace{0.05cm}')$  is much larger than  $ωL\hspace{0.05cm}'$,  and
2. the parallel conductance per unit length  $(G\hspace{0.05cm}')$  is much larger than  $ ωC\hspace{0.08cm}'$. 

⇒   A second upper bound is obtained,  often referred to in literature as  »strong attenuation«,  valid for  $(f \ll f_∗)$:

$$\alpha_{_{ {\rm II} } }(f) = \sqrt{ 1/2 \cdot \omega \cdot {R\hspace{0.05cm}' \cdot C\hspace{0.08cm}'} }\hspace{0.1cm} \bigg \vert_{\omega \hspace{0.05cm}= \hspace{0.05cm}2\pi f}\hspace{0.05cm}.$$

The diagram shows the attenuation function  $α(f)$  at constant primary line parameters according to the exact  $($but more complicated$)$  formula and the two bounds  $α_{\rm I}(f)$  and  $α_{\rm II}(f)$.  One recognizes from this representation:

1. Both  $α_{\rm I}(f)$  and  $α_{\rm II}(f)$  are upper bounds for  $α(f)$.
2. The characteristic frequency  $f_∗$  is the intersection of  $α_{\rm I}(f)$  and  $α_{\rm II}(f)$.
3. For  $f \gg f_∗$  holds  $α(f) ≈ α_{\rm I}(f)$,  whereas for  $f \ll f_∗$   $α(f) ≈ α_{\rm II}(f)$.

Influence of reflections - operational attenuation

The choice of the terminating resistor  $Z_2(f) = Z_{\rm W}(f)$  prevents the generation of a reflected wave at the end of the line.  In practice,  however,  an exact matching of these resistors is usually possible only in a very limited frequency range,  for example

Line of length  $l$  with ohmic terminations

1. due to the complicated frequency dependence of the wave impedance,
2. with cables of different designs along a connection,
3. when taking into account manufacturing tolerances.

Therefore,  in real systems the internal resistance  $R_1$  of the source and the terminating resistance  $R_2$  are usually chosen to be real and constant.  For example,  in the communication system  »Integrated Services Digital Network«  $\rm (ISDN)$  $R_1 = R_2 = 150 \ \rm Ω$  has been set.

This circuit simplification has the following effects:

• The input impedance  $Z_{\rm E}(f)$  of the line as seen from the source depends

1. on the complex propagation function per unit length   ⇒   $γ(f)$,
2. on the line length  $l$,
3. on the wave impedance  $Z_{\rm W}(f)$,  and
4. on the terminating resistance  $R_2$:

$$Z_{\rm E}(f) = Z_{\rm W}(f)\cdot \frac {R_2 + Z_{\rm W}(f) \cdot {\rm tanh}(\gamma(f) \cdot l)} {Z_{\rm W}(f)+ R_2 \cdot {\rm tanh}(\gamma(f) \cdot l)} \hspace{0.05cm}, \hspace{0.5cm} {\rm with}\hspace{0.5cm}{\rm tanh}(x) = \frac {{\rm sinh}(x)}{{\rm cosh}(x)} = \frac {{\rm e}^{x}-{\rm e}^{-x}}{{\rm e}^{x}+{\rm e}^{-x}}\hspace{0.05cm}, \hspace{0.3cm}x \in {\cal C} \hspace{0.05cm}.$$

• This circuit-related simplification   ⇒   $Z_{\rm 2}(f) = R_2$  results in reflections at the end of the line.

• These reduce the power available at the receiver and thus increase the line attenuation.

• For the evaluation of such a mismatched system, the  »operational attenuation«  has been defined as follows:

$${ a}_{\rm B}(f) \hspace{0.15cm}{\rm in} \hspace{0.15cm}{\rm Neper}\hspace{0.15cm}{\rm (Np)} = {\rm ln}\hspace{0.1cm}\frac {|U_0(f)|}{2 \cdot |U_2(f)|} \cdot \sqrt{{R_2}/{R_1}} = \alpha (f ) \cdot l + {\rm ln}\hspace{0.1cm}|q_1(f)| + {\rm ln}\hspace{0.1cm}|q_2(f)| + {\rm ln}\hspace{0.1cm}|1 - r_1(f) \cdot r_2(f) \cdot {\rm e}^{-\gamma(f) \hspace{0.05cm} \cdot \hspace{0.05cm}l}| \hspace{0.05cm}.$$

Exercises for the chapter

Exercise 4.1: Attenuation Function

Exercise 4.1Z: Transmission Behavior of Short Cables

Exercise 4.2: Mismatched Line

Exercise 4.3: Operational Attenuation

References