Classification of the Distortions

From LNTwww

# OVERVIEW OF THE SECOND MAIN CHAPTER #


$\text{Definition:}$  Generally, undesirable deterministic changes of a message signal by a transmission system are considered as  distortions .


In addition to stochastic interferences (noise, crosstalk, etc.), such deterministic distortions are a critical limitation on transmission quality and rate for many messaging systems.

This chapter presents these distortions in a summarising way, in particular:

  • the quantitative detection of such signal falsifications via the distortion power,
  • the distinguishing features between nonlinear and linear distortions,
  • the meaning and computation of the distortion factor in nonlinear systems and
  • the effects of linear distortions of damping and phase distortions.


Further information on the topic of "distortions" as well as tasks, simulations and programming exercises can be found in

  • Chapter 6: Linear Time-Invariant Systems (Programme lzi)


of the practical course "Simulation Methods in Communications Engineering". This (former) LNT course at TU Munich is based on

  • the educational software package  LNTsim   ⇒   Link refers to the ZIP-version of the programme, and
  • this practical course guide  Praktikumsanleitung   ⇒   Link refers to the PDF-version; Chapter 6: pages 99-118.


Prerequisites for the Entire Second Main Chapter


In the following, we consider a system whose input is the signal  $x(t)$  with the corresponding spectrum  $X(f)$ . The output signal is denoted by  $y(t)$  and its spectrum by  $Y(f).$

Description of a linear system

The block labelled "system" can be a part of an electrical circuit or a complete transmission system consisting of transmitter, channel and receiver.


For the whole main chapter ”Signal Distortions and Equalisation” the following shall apply:

  • The system be time-invariant. If the input signal  $x(t)$  results in the output signal  $y(t)$, then a later input signal of the same form – in particular  $x(t - t_0)$  – will result in the signal  $y(t - t_0)$ .
  •  No noise  is considered, which is always present in real systems.  For the description of these phenomena we refer to the  $\rm LNTwww$–book  Stochastische Signaltheorie.
  •  No detailed knowledge  about the system is assumed.  In the following, all system properties are derived from the signals  $x(t)$  and  $y(t)$  or their spectra alone.
  • In particular, no specifications are given with regards to  linearity for the time being.  The "system" can be linear (prerequisite for the application of the superposition principle) or non-linear.
  • Not all system properties are discernible from a single test signal  $x(t)$  and its response  $y(t)$ . Therefore,  sufficiently many test signals  must be used for evaluation.


In the following, we will classify transmission systems in more detail in this respect.

Ideal and Distortion-free System


$\text{Definition:}$  One deals with an  ideal system if the output signal  $y(t)$  is exactly equal to the input signal  $x(t)$ :

$$y(t) \equiv x(t).$$


It should be noted that such an ideal system does not exist in reality even if statistical disturbances and noise processes, that always exist but are not considered in this book, are disregarded. Every transmission medium exhibits losses (damping) and transit times. Even if these physical phenomena are very small, they are never zero. It is therefore necessary to introduce a somewhat less strict quality characteristic.

$\text{Definition:}$  A  distortion-free system  exists if the following condition is fulfilled:

$$y(t) = \alpha \cdot x(t - \tau).$$

Here,  $α$  describes the damping factor and  $τ$  the transit time.


If this condition is not met, the system is said to be distortive.

$\text{Example 1:}$  The following graph shows the input signal  $x(t)$  and the output signal  $y(t)$  of a nonideal but distortion-free system.  The system parameters are  $α = 0.8$  and  $τ = 0.25 \ \rm ms$.

Exemplary signals of a distortion-free system

Note:

  • The damping factor  $α$  can be completely reversed by a receiver-side gain of  $1/α = 1.25$, but it must be taken into account that this also increases any noise.
  • However, the transit time  $τ$  cannot be compensated due to  Kausalitätsgründen .  It now depends on the application whether such a transit time is subjectively perceived as disturbing or not.


For example, even with a transit time of one second the (unidirectional) TV broadcast of an event is still described as "live".  In contrast to this, transit times of  $\text{300 ms}$  are already perceived as very disturbing in bidirectional communication – for example, a telephone call. You either wait for the other person to react or both participants interrupt each other.

Quantitative Measure of Signal Distortion


We now consider a distortive system on the basis of the input and output signal.  In doing so, we assume that apart from the signal distortions there is no additional damping factor   $α$  which is constant for all frequencies and no additional transit time  $τ$  that is constant for all frequencies. These conditions are fulfilled for the signal sections sketched below.

Input and output of a distortive system and error signal (below)

In addition to the signals  $x(t)$  and  $y(t)$ , the difference signal is also shown in the graph:

$$\varepsilon(t) = y(t) - x(t).$$

As a quantitative measure of the strength of distortions, for example, the  squared mean of this difference signal is applicable:

$$\overline{\varepsilon^2(t)} = \frac{1}{T_{\rm M}} \cdot \int_{ 0 }^{ T_{\rm M}} {\varepsilon^2(t) }\hspace{0.1cm}{\rm d}t\hspace{0.4cm} \left( = P_{\rm V} \right).$$


The following should be noted about this equation:

  • The measurement time  $T_{\rm M}$  must be chosen sufficiently large.  Actually, this equation should be formulated as a limit process.
  • The squared mean mentioned above is often also called mean squared error  $\rm (MSE)$  or   distortion power  $P_{\rm D}$ .
  • If  $x(t)$  and  $y(t)$  are voltage signals, then  $P_{\rm D}$  has the unit of  ${\rm V}^2$, meaning the power is related to the resistance  $R = 1 \ Ω$  according to the above definition.


$\text{Definition:}$  Making use of the power  (based on  $R = 1 \ Ω$ )   $P_x$  of the input signal  $x(t)$  the  signal–to–distortion (power) ratio  can be given as:

$$\rho_{\rm D} = \frac{ P_{x} }{P_{\rm D} } \hspace{0.3cm} \Rightarrow \hspace{0.3cm} 10 \cdot \lg \hspace{0.1cm}\rho_{\rm D} = 10 \cdot \lg \hspace{0.1cm}\frac{ P_{x} }{P_{\rm D} }\hspace{0.3cm} \left( {\rm in \hspace{0.15cm} dB} \right).$$

For the signals shown in the graph above  $P_x = 4 \ {\rm V}^2$,  $P_{\rm D} = 0.04 \ {\rm V}^2$  and thus  $10 \cdot {\rm lg} \ ρ_{\rm D} = 20 \ \rm dB$ hold.


We reference the interactive applet  Lineare Verzerrungen periodischer Signale.

Significance of Damping and Transit Time


The equations given on the last page do not result in applicable statements if the system is additionanlly affected by an attenuation  $α$  and/or transit time  $τ$  . The graph shows the attenuated, delayed and distorted signal

Significance of damping and transit time
$$y(t) = \alpha \cdot x(t - \tau) + \varepsilon_1(t).$$

The term  $ε_1(t)$  summarises all distortions.  It can be seen from the green area that the error signal  $ε_1(t)$  is relatively small.

In contrast to this, if the attenuation  $α$  and transit time  $τ$  are unknwon, the following should be noted:

  • The error signal  $ε_2(t) = y(t) - x(t)$  determined in this way is relatively large despite small distortions  $ε_1(t)$ .
  • Here, instead of the distortion power the distortion energy must be considered because  $x(t)$  and  $y(t)$  are energy-limited signals.
  • The distortion energy is obtained by varying the unknown quantities  $α$  and  $τ$  and thus finding the minimum of the mean squared error:
$$E_{\rm V} = \min_{\alpha, \ \tau} \int_{ - \infty }^{ + \infty} {\big[y(t) - \left(\alpha \cdot x(t - \tau) \right) \big]^2}\hspace{0.1cm}{\rm d}t.$$
  • Die Energie des gedämpften und verzögerten Signals  $α · x(t - τ)$  ist unabhängig von der Laufzeit  $τ$  gleich  $α^2 · E_x$. Für das Signal–zu–Verzerrungs–Leistungsverhältnis gilt somit:
$$\rho_{\rm V} = \frac{ \alpha^2 \cdot E_{x}}{E_{\rm V}}\hspace{0.3cm}{\rm bzw.}\hspace{0.3cm}\rho_{\rm V}= \frac{ \alpha^2 \cdot P_{x}}{P_{\rm V}} .$$
  • Die erste dieser beiden Gleichungen gilt für zeitlich begrenzte und damit energiebegrenzte Signale, die zweite für zeitlich unbegrenzte, also leistungsbegrenzte Signale entsprechend der Seite  Energiebegrenzte und leistungsbegrenzte Signale  im Buch „Signaldarstellung”.

Linear and Nonlinear Distortions


Man unterscheidet zwischen linearen und nichtlinearen Verzerrungen:

Ist das System linear und zeitinvariant  $(\rm LZI)$, so wird es vollständig durch seinen  Frequenzgang  $H(f)$ charakterisiert, und es lässt sich Folgendes feststellen:

  • Entspechend der  $H(f)$–Definition gilt für das Ausgangsspektrum:   $Y(f)=X(f) · H(f)$.   Daraus folgt nach den Rechenregeln der Multiplkation, dass  $Y(f)$  keine Frequenzanteile beinhalten kann, die nicht schon in  $X(f)$  enthalten sind.
  • Die Umkehrung besagt:   Das Ausgangssignal  $y(t)$  kann jede Frequenz  $f_0$  beinhalten, die bereits im Eingangssignal  $x(t)$  enthalten ist. Voraussetzung ist also, dass  $X(f_0) ≠ 0$  gilt.
  • Bei einem LZI–System ist die absolute Bandbreite  $(B_y)$  des Ausgangssignals nie größer als die Bandbreite  $(B_x)$  des Eingangssignals:   $B_y \le B_x .$


$\text{Fazit:}$  Die Unterschiede zwischen linearen und nichtlinearen Verzerrungen sollen anhand einses Schaubildes verdeutlicht werden:

Lineare und nichtlineare Verzerrungen
  • In der oberen Grafik gilt  $B_y = B_x$.  Es liegen  lineare Verzerrungen  vor, da sich in diesem Frequenzband  $X(f)$  und  $Y(f)$  unterscheiden.
  • Eine Bandbegrenzung  $(B_y < B_x)$  ist eine Sonderform linearer Verzerrungen, die im  übernächsten Kapitel  behandelt werden.



  • Die untere Grafik zeigt ein Beispiel für  nichtlineare Verzerrungen  $(B_y > B_x)$.  Für ein solches System kann kein Frequenzgang  $H(f)$  angegeben werden.
  • Welche Beschreibungsgrößen für nichtlineare Systeme geeignet sind, wird im nächsten Kapitel  Nichtlineare Verzerrungen  dargelegt.


Bei den meisten realen Übertragungskanälen treten sowohl lineare als auch nichtlineare Verzerrungen auf.  Für eine ganze Reihe von Problemstellungen ist jedoch die klare Trennung der beiden Verzerrungsarten essentiell.  In  [Kam04][1]  wird ein entsprechendes Ersatzmodell angegeben.


Wir verweisen hier auf das Lernvideo  Lineare und nichtlineare Verzerrungen .

Exercises for the Chapter

Aufgabe 2.1: Linear? - Nichtlinear?

Aufgabe 2.1Z: Verzerrung und Entzerrung

Aufgabe 2.2: Verzerrungsleistung

Aufgabe 2.2Z: Nochmals Verzerrungsleistung



Quellenverzeichnis

  1. Kammeyer, K.D.: Nachrichtenübertragung. Stuttgart: B.G. Teubner, 4. Auflage, 2004.