Linear Distortions

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Zusammenstellung wichtiger Beschreibungsgrößen


Linear system description

Now nonlinear distortions are excluded so that the system is fully described by the frequency response  $H(f)$ .

The generally complex frequency response can also be formulated as follows:

$$H(f) = |H(f)| \cdot {\rm e}^{-{\rm j} \hspace{0.05cm} \cdot \hspace{0.05cm} b(f)} = {\rm e}^{-a(f)}\cdot {\rm e}^{-{\rm j} \hspace{0.05cm} \cdot \hspace{0.05cm} b(f)}.$$

This yields the following descriptive quantities:

  • The magnitude  $|H(f)|$  is referred to as  amplitude response  and in logarithmic form as attenuation curve :
$$a(f) = - \ln |H(f)|\hspace{0.2cm}{\rm in \hspace{0.1cm}Neper \hspace{0.1cm}(Np) } = - 20 \cdot \lg |H(f)|\hspace{0.2cm}{\rm in \hspace{0.1cm}Dezibel \hspace{0.1cm}(dB) }.$$
  • The  phase response  $b(f)$  specifies the negative angle of  $H(f)$  dependent on  $f$  in the complex plane and with respect to the real axis:
$$b(f) = - {\rm arc} \hspace{0.1cm}H(f) \hspace{0.2cm}{\rm in \hspace{0.1cm}Radian \hspace{0.1cm}(rad)}.$$

Voraussetzungen für verzerrungsfreie Systeme


According to the explanations in the chapter Classification of the Distortions  there is a distortion-free system at hand if and only if all frequency components are uniformly damped and delayed:

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

According to the laws of system theory, the following must thus hold for the frequency response

$$H(f) = \alpha \cdot {\rm e}^{-{\rm j}\hspace{0.04cm}2 \pi f \tau}$$

or expressed with functions  $a(f)$  and  $b(f)$:

  • The attenuation curve must be constant for all frequencies contained in the input signal:
$$a(f) = - \ln |H(f)| = - \ln \ \alpha = {\rm const.}$$
  • The phase response must either be zero in the region of interest (system with no transit time) or increase linearly with frequency  $(τ$  indicats the transit time of the system):
$$b(f) = 2 \pi f \tau = {\rm const.} \cdot f.$$

$\text{Definitionen:}$  For a distortion-free system, both requirements must be satisfied simultaneously. Violation of even one of these two conditions results in linear distortions which are distinguished according to their cause.

  • It comes to  attenuation distortions if in the frequency range of interest the attenuation curve is not constant:
$$a(f) \ne {\rm const.}$$
  • In contrast to this, there are  phase distortions  if the phase function is not linear with respect to $f$ :
$$b(f) \ne {\rm const.} \cdot f.$$


It should be noted that in all realisable systems – in particular, in the "minimum-phase systems" described in  Chapter 3  – both forms of distortion usually occur simultaneously.

$\text{Definition:}$  In the time domain, the condition for a  distortion-free system is:

$$h(t) = \alpha \cdot \delta(t - \tau),\hspace{0.4cm}\alpha \ne 0.$$

Moreover, if  $α = 1$  and  $τ = 0$ hold,then there is an  ideal transmission system . In contrast, there are linear distortions whenever

  • $h(t)$  is a continuous-time function or
  • $h(t)$  is composed of more than one Dirac function.


$\text{Example 1:}$  The following sketch shows the attenuation curve $a(f)$  and the phase response $b(f)$  of a distortion-free system.

Requirement for a non-distorting channel
  • In a range from  $f_{\rm U}$  to  $f_{\rm O}$  around the carrier frequency  $f_{\rm T}$, in which the signal $x(t)$  has components,  $a(f)$  is constant.
  • From the given constant attenuation value  $6 \ \rm dB$  it follows for the amplitude response:  $\vert H(f)\vert = 0.5$.
  • The output spectrum $Y(f)$  is thus half as large in magnitude as the spectral components $X(f)$  of the input signal.
  • The phase response $b(f)$  increases linearly with frequency between $f_{\rm U}$ und $f_{\rm O}$.
  • This results in all frequency components being delayed by the same phase delay time $τ$  where  $τ$  is fixed by the slope of  $b(f)$ .
  • With $b(f) = 0$  a transit time-free system would arise as a result   ⇒   $τ = 0$.


Furthermore, the following generally valid properties can be identified from the graph:

  • The attenuation curve $a(f) = a(\hspace{-0.01cm}-\hspace{-0.08cm} f)$  is an even function in  $f$.
  • The phase curve $b(f) = \hspace{-0.01cm}–\hspace{-0.01cm} b(\hspace{-0.01cm}-\hspace{-0.01cm}f)$  is an odd function in $f$.


Outside the frequency band occupied by $x(t)$  the "constant attenuation" and "linear phase" conditions do not need to be satisfied. It can be seen from the dashed curve of $a(f)$ that even a much higher attenuation is purposeful here because as a consequence the always-existing noise components outside the useful bandwidth – which are not considered in this section – are suppressed better.

Dämpfungsverzerrungen


In the following, we consider the sum of two harmonic oscillations as input signal:

$$x(t) = A_1 \cdot \cos(2 \pi f_1 \cdot t - \varphi_1) + A_2 \cdot \cos(2 \pi f_2 \cdot t - \varphi_2).$$

If the output signal can be represented in the form

$$y(t) = \alpha_1 \cdot A_1 \cdot \cos(2 \pi f_1 \cdot t - \varphi_1) + \alpha_2 \cdot A_2 \cdot \cos(2 \pi f_2 \cdot t - \varphi_2).$$

and at the same time $α_1 ≠ α_2$ is valid, then  exclusively attenuation distortions  are existent since the phase values $\varphi_1$  and  $\varphi_2$  are not changed by the system.

The attenuation constants $α_1$  and  $α_2$  can be determined from the amplitude response $|H(f)|$ :

$$\alpha_1 = |H(f_1)|,\hspace{0.4cm}\alpha_2 = |H(f_2)|.$$

If the attenuation curve $a(f)$  is given in Neper, then likewise the following holds  $(1 \ \rm dB$ corresponds to $0.1151 \ \rm Np)$:

$$ \alpha_1 = {\rm e}^{-{\rm a}(f_1)},\hspace{0.4cm}\alpha_2 = {\rm e}^{-{\rm a}(f_2)}.$$

Please note:   In some character fonts, "$a$" and "$α$" (alpha) are difficult to distinguish.

Effects of attenuation distortions

$\text{Example 2:}$  The graph shows the input signal (blue curve)

$$x(t) = {1\, \rm V} \cdot \cos(2 \pi \cdot {1\, \rm kHz}\cdot t) + {1\, \rm V} \cdot \sin(2 \pi \cdot {2\, \rm kHz}\cdot t)$$

which is periodic with $T_0 = 1\ \rm ms$  and the signal $y(t)$ which is attenuation-distorted with  $α_1 = 0.2$,  $α_2 = 0.5$ .

Significant effects of these attenuation distortions can be perceived:

  • $y(t)$  bears little resemblance to $x(t)$.
  • In contrast, considering  $α_1 = α_2 = α$  the distortion-free signal $y(t) = α · x(t)$  would be obtained from which the original signal $x(t)$  could be reconstructed by amplifying it by $1/α$ .


We refer here explicitly to the interactive applet  Linear distortions of periodic signals.


Phasenlaufzeit


On the definition of the phase delay time

We consider a system with $|H(f)| = 1$ such that the following holds for the frequency response:

$$H(f) = {\rm e}^{-{\rm j} \hspace{0.05cm} \cdot \hspace{0.05cm} b(f)}.$$
  • The left graph shows an exemplary phase response $b(f)$. Such a phase response is always an odd function with respect to the frequency $f$:   $b(\hspace{-0.01cm}-\hspace{-0.08cm}f) = \hspace{0.08cm}-b(f)$.
  • On the right, the function $b(ω)$  is sketched which is dilated by a factor of $2π$ with respect to $b(f)$  in the abscissa.


If the harmonic oscillation at the input is

$$x(t) = C \cdot \cos(2 \pi f_0 t - \varphi) \circ\!\!-\!\!\!-\!\!\!-\!\!\bullet\, X(f ) = {C}/{2}\cdot {\rm e}^{{\rm j}\hspace{0.05cm} \cdot \hspace{0.05cm} \varphi} \cdot \delta(f + f_0) \hspace{0.01cm} + \hspace{0.01cm}{C}/{2}\cdot {\rm e}^{-{\rm j}\hspace{0.05cm} \cdot \hspace{0.05cm} \varphi} \cdot \delta(f - f_0),$$

then the following arises as a result for the spectral function at the output:

$$Y(f ) = {C}/{2}\cdot {\rm e}^{{\rm j}\hspace{0.05cm} \cdot \hspace{0.05cm} \varphi} \cdot {\rm e}^{\hspace{0.05cm}{\rm j}\hspace{0.05cm} \cdot \hspace{0.05cm} b(f_0)} \cdot \delta(f + f_0) \hspace{0.05cm} + \hspace{0.05cm}{C}/{2}\cdot {\rm e}^{-{\rm j}\hspace{0.05cm} \cdot \hspace{0.05cm} \varphi}\cdot {\rm e}^{-{\rm j}\hspace{0.05cm} \cdot \hspace{0.05cm} b(f_0)} \cdot \delta(f - f_0).$$

Thus, the output signal is:

$$y(t) = C \cdot \cos(2 \pi f_0 t - b(f_0) - \varphi).$$

This signal can also be represented in the following form:

$$y(t) = C \cdot \cos(2 \pi f_0 ( t - \tau_{\rm P}(f_0)) - \varphi).$$

$\text{Definition:}$  The  phase delay time  indicates the delay experienced by a harmonic oscillation of frequency $f_0$  through the system. For phase-distorting systems, the phase delay time is frequency-dependent:

$$\tau_{\rm P}(f_0) = \frac{b(f_0)}{2\pi f_0} \hspace{0.4cm}{\rm bzw.} \hspace{0.4cm} \tau_{\rm P}(\omega_0) = \frac{b(\omega_0)}{\omega_0}.$$


The following should be noted regarding this definition:

  • In the $b(ω)$–representation, the phase delay time $τ_{\rm P}$  can also be determined graphically as the slope of the straight line drawn in green in the above graph.
  • In general, an oscillation with a different frequency will also result in a different phase delay time. This is the physical background for phase distortions.
  • If for a system $b(ω) = τ_{\rm P} · ω$   or   $b(f) = 2π · τ_{\rm P} · f$ is true, then all frequencies have the same phase delay time $τ_{\rm P}$. Such a system does not cause phase distortions.


We refer here again to the interactive applet Linear distortions of periodic signals.

Unterschied zwischen Phasen- und Gruppenlaufzeit


Another important system description quantity is the group delay time which must not be confused with the phase delay time.

$\text{Definition:}$  The  group delay time  is defined as follows:

$$\tau_{\rm G}(\omega_0) = \left[ \frac{ {\rm d}b(\omega)}{ {\rm d}\omega}\right ]_{\omega = \omega_0}.$$
  • This quantity is mainly used to describe narrow-band systems.
  • It indicates the delay experienced by the envelope of a band-pass system.


On the definition of the group delay time

$\text{Example 3:}$  The graph shows the examplary phase function:

$$b(ω) = \arctan (ω/ω_0).$$
  • This increases monotonically from zero  $($at  $ω = 0)$  to  $π/2$  $($for  $ω → ∞)$.
  • The function value at $ω = ω_0$  is $π/4$.


If we set $ω_0 = 2π · 1 \ \rm kHz$, we obtain for the phase delay time:

$$\tau_{\rm P}(\omega_0) = \frac{b(\omega_0)}{\omega_0}= \frac{\pi / 4}{2 \pi \cdot{1\, \rm kHz} } = {125\, \rm µ s}.$$

This quantity corresponds to the slope of the straight line drawn in green in the above graph.

In contrast, the lesser slope of the tangent line shown in red denotes the group delay time:

$$\tau_{\rm G}(\omega_0) = \left[ \frac{ {\rm d}b(\omega)}{ {\rm d}\omega}\right ]_{\omega = \omega_0} = \left[ \frac{1}{\omega_0} \cdot \frac{1}{1 + \left(\omega / \omega_0\right]^2} \right ]_{\omega = \omega_0} = \frac{1}{2\omega_0}= \frac{1}{4 \pi \cdot{1\, \rm kHz} } \approx {80\, \rm µ s}.$$

Phasenverzerrungen


Zur Verdeutlichung dieses Sachverhaltes betrachten wir als Eingangssignal wieder die Summe zweier harmonischer Schwingungen:

$$x(t) = A_1 \cdot \cos(2 \pi f_1 \cdot t - \varphi_1) + A_2 \cdot \cos(2 \pi f_2 \cdot t - \varphi_2).$$

Ist bei diesem Eingangssignal das Ausgangssignal in der Form

$$y(t) = A_1 \cdot \cos(2 \pi f_1 \cdot (t - \tau_1) - \varphi_1) + A_2 \cdot \cos(2 \pi f_2 \cdot (t - \tau_2) - \varphi_2)$$

darstellbar und gilt gleichzeitig  $τ_1 ≠ τ_2$, so liegen  ausschließlich Phasenverzerrungen  vor.

Die beiden Phasenlaufzeiten  $τ_1 ≠ τ_2$  können aus dem Phasenverlauf (in Radian) ermittelt werden:

$$\tau_1 = \frac{b(f_1)}{2\pi f_1} , \hspace{0.4cm}\tau_2 = \frac{b(f_2)}{2\pi f_2}.$$
Auswirkungen von Phasenverzerrungen

$\text{Beispiel 4:}$  Die Grafik zeigt als blauen Kurvenverlauf das mit der Periodendauer  $T_0$  periodische Signal

$$x(t) = {1\, \rm V} \cdot \cos(2 \pi \cdot {1\, \rm kHz}\cdot t) + {1\, \rm V} \cdot \sin(2 \pi \cdot {2\, \rm kHz}\cdot t)$$

sowie das mit den Laufzeiten  $τ_1 = 0.7 \ \rm ms$  und  $τ_2 = 0.3 \ \rm ms$  phasenverzerrte Signal  $y(t)$  ⇒   rote Kurve.

  • Man erkennt deutlich die Auswirkungen der Phasenverzerrungen.
  • Mit  $τ_1 = τ_2 = τ$  ergäbe sich das verzerrungsfreie Signal
$$y(t) = x(t - τ).$$


Wir weisen nochmals auf das interaktive Applet  Lineare Verzerrungen periodischer Signale  hin.


Entzerrungsverfahren


Entzerrung von Signalen

Dieses für die Nachrichtentechnik sehr wichtige Verfahren soll hier nur kurz angerissen werden. Nähere Informationen hierzu finden Sie in den Büchern  Modulationsverfahren  und  Digitalsignalübertragung.

Wir gehen für diese Kurzbeschreibung von der skizzierten Konstellation aus:

  • $S_{\rm V}$  bezeichnet ein verzerrendes System,
  • während  $S_{\rm E}$  der Entzerrung dient.


Zu dieser Konstellation ist anzumerken:

  • Ist die Verzerrung nichtlinear, so muss auch die Entzerrung nichtlinear erfolgen.
  • Aber auch bei linearen Verzerrungen werden nichtlineare Entzerrungsverfahren eingesetzt, zum Beispiel Decision Feedback Equalization bei Digitalsystemen. Der Vorteil gegenüber linearer Entzerrung ist, dass es nicht zu einer Erhöhung der Rauschleistung kommt.
  • Ist  $S_{\rm V}$  ein lineares System mit Frequenzgang  $H_{\rm V}(f)$, so können mit dem inversen Frequenzgang  $H_{\rm E}(f) = 1/H_{\rm V}(f)$  die Verzerrungen vollständig eliminiert werden, und es gilt  $z(t) = x(t)$.
  • Voraussetzung hierfür ist allerdings, dass der Frequenzgang  $H_{\rm V}(f)$  im interessierenden Spektralbereich keine Nullstellen  besitzt, da sonst bei  $H_{\rm E}(f)$  Unendlichkeitsstellen erforderlich wären.
  • Bei Analogsystemen  bedeutet eine vollständige Entzerrung, dass sich  $z(t)$  von  $x(t)$  nur durch die unvermeidbaren Rauschanteile unterscheidet, und eventuell durch eine Laufzeit.
  • Bei Digitalsystemen  ist das Kriterium für eine vollständige Entzerrung weniger streng. Es muss dann nur sichergestellt werden, dass die Signale  $x(t)$  und  $z(t)$  zu den Detektionszeitpunkten übereinstimmen. Man spricht in diesem Zusammenhang von  Nyquistsystemen.

Aufgaben zum Kapitel


Aufgabe 2.5: Verzerrung und Entzerrung

Aufgabe 2.5Z: Nyquistentzerrung

Aufgabe 2.6: Zweiwegekanal

Aufgabe 2.6Z: Synchrondemodulator

Aufgabe 2.7: Nochmals Zweiwegekanal