Difference between revisions of "Digital Signal Transmission/Redundancy-Free Coding"

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{{Header
 
{{Header
|Untermenü=Codierte und mehrstufige Übertragung
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|Untermenü=Coded and Multilevel Transmission
 
|Vorherige Seite=Grundlagen der codierten Übertragung
 
|Vorherige Seite=Grundlagen der codierten Übertragung
 
|Nächste Seite=Blockweise Codierung mit 4B3T-Codes
 
|Nächste Seite=Blockweise Codierung mit 4B3T-Codes
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== Blockweise und symbolweise Codierung ==
+
== Symbolwise coding vs. blockwise coding ==
 
<br>
 
<br>
Bei der Übertragungscodierung unterscheidet man zwischen zwei Arten, der symbolweisen und der blockweisen Codierung. Bei symbolweiser Codierung, die im Kapitel 2.4 im Detail beschrieben ist, wird mit jedem ankommenden Quellensymbol <i>q<sub>&nu;</sub></i> ein Codesymbol <i>c<sub>&nu;</sub></i> erzeugt, das außer vom aktuellen Symbol <i>q<sub>&nu;</sub></i> auch von vorangegangenen Symbolen abhängen kann.<br>
+
In transmission coding,&nbsp; a distinction is made between two fundamentally different methods:
  
Typisch für alle Übertragungscodes zur symbolweisen Codierung ist, dass die Bitdauer <i>T<sub>q</sub></i> der als binär und redundanzfrei angenommenen Nachrichtenquelle mit der Symboldauer <i>T<sub>c</sub></i> des meist mehrstufigen und redundanten Codersignals <i>c</i>(<i>t</i>) übereinstimmt.<br>
+
'''Symbolwise coding'''
 +
*Here,&nbsp; an encoder symbol &nbsp;$c_\nu$&nbsp; is generated with each incoming source symbol &nbsp;$q_\nu$,&nbsp; which can depend not only on the current symbol but also on previous symbols &nbsp;$q_{\nu -1}$, &nbsp;$q_{\nu -2}$, ... <br>
  
Dagegen wird bei der blockweisen Codierung jeweils einem Block von <i>m<sub>q</sub></i> binären Quellensymbolen (<i>M<sub>q</sub></i> = 2) der Bitdauer <i>T<sub>q</sub></i> eine ein&ndash;eindeutige Sequenz von <i>m<sub>c</sub></i> Codesymbolen aus einem Alphabet mit dem Codesymbolumfang <i>M<sub>c</sub></i> &#8805; 2 zugeordnet. Für die Symboldauer eines Codesymbols gilt dann
+
*It is typical for all transmission codes for symbolwise coding that the symbol duration &nbsp;$T_c$&nbsp; of the usually multilevel and redundant encoded  signal &nbsp;$c(t)$&nbsp; corresponds to the bit duration &nbsp;$T_q$&nbsp; of the source signal,&nbsp; which is assumed to be binary and redundancy-free.<br>
  
:<math>T_c = \frac{m_q}{m_c} \cdot T_q \hspace{0.05cm},</math>
 
  
und die relative Redundanz eines Blockcodes beträgt allgemein<br>
+
Details can be found in the chapter &nbsp;[[Digital_Signal_Transmission/Symbolwise_Coding_with_Pseudo-Ternary_Codes|"Symbolwise Coding with Pseudo-Ternary Codes"]].
  
:<math>r_c = 1- \frac{R_q}{R_c} = 1- \frac{T_c}{T_q} \cdot \frac{{\rm log_2} (M_q)}{{\rm log_2} (M_c)} = 1- \frac{T_c}{T_q \cdot {\rm log_2} (M_c)}\hspace{0.05cm}.</math>
 
  
Genauere Angaben zu den Blockcodes finden Sie im Kapitel 2.3.<br>
+
'''Blockwise coding'''
 +
*Here,&nbsp; a block of &nbsp;$m_q$&nbsp; binary source symbols &nbsp;$(M_q = 2)$&nbsp; of bit duration &nbsp;$T_q$&nbsp; is assigned a one-to-one sequence of &nbsp;$m_c$&nbsp;  encoder symbols from an alphabet with  encoder symbol set size &nbsp;$M_c  \ge 2$.&nbsp;
 +
 +
*For the&nbsp; '''symbol duration of an encoder symbol'''&nbsp; then holds:
 +
:$$T_c = \frac{m_q}{m_c} \cdot T_q \hspace{0.05cm},$$
 +
*The&nbsp; '''relative redundancy of a block code'''&nbsp; is in general
 +
:$$r_c = 1- \frac{R_q}{R_c} = 1- \frac{T_c}{T_q} \cdot \frac{{\rm log_2}\hspace{0.05cm} (M_q)}{{\rm log_2} \hspace{0.05cm}(M_c)} = 1- \frac{T_c}{T_q \cdot {\rm log_2} \hspace{0.05cm}(M_c)}\hspace{0.05cm}.$$
  
{{Beispiel}}''':''' Bei den Pseudoternärcodes wird durch die Erhöhung der Stufenzahl von <i>M<sub>q</sub></i> = 2 auf  <i>M<sub>c</sub></i> = 3 bei gleicher Symboldauer (<i>T<sub>c</sub></i> = <i>T<sub>q</sub></i>) eine relative Redundanz von 1 &ndash; 1/log<sub>2</sub>(3) &asymp; 37% hinzugefügt. Im Gegensatz dazu arbeiten die so genannten 4B3T&ndash;Codes auf Blockebene mit den Codeparametern <nobr><i>m<sub>q</sub></i> = 4,</nobr> <i>M<sub>q</sub></i> = 2, <i>m<sub>c</sub></i> = 3, <i>M<sub>c</sub></i> = 3 und besitzen eine relative Redundanz von ca. 16%. Das Sendesignal ist hier wegen <i>T<sub>c</sub></i>/<i>T<sub>q</sub></i> = 4/3 niederfrequenter als bei uncodierter Übertragung, was die oft teuere Bandbreite verringert und zudem für viele Nachrichtenkanäle auch aus übertragungstechnischer Sicht von Vorteil ist.{{end}}<br>
+
More detailed information on the block codes can be found in the chapter&nbsp; [[Digital_Signal_Transmission/Block_Coding_with_4B3T_Codes|"Block Coding with 4B3T Codes"]].<br>
  
 +
{{GraueBox|TEXT= 
 +
$\text{Example 1:}$&nbsp; For the&nbsp; "pseudo-ternary codes"',&nbsp; increasing the number of levels from &nbsp;$M_q = 2$&nbsp; to &nbsp;$M_c = 3$&nbsp; for the same symbol duration &nbsp;$(T_c = T_q)$&nbsp; adds a relative redundancy of &nbsp;$r_c = 1 - 1/\log_2 \hspace{0.05cm} (3) \approx 37\%$.&nbsp;
  
== Redundanzfreies Ternär– und Quaternärsignal (1) ==
+
In contrast,&nbsp; the so-called&nbsp; "4B3T codes"&nbsp; operate at block level with the code parameters &nbsp;$m_q = 4$, &nbsp;$M_q = 2$, &nbsp;$m_c = 3$&nbsp; and &nbsp;$M_c = 3$&nbsp; and have a relative redundancy of approx. &nbsp;$16\%$.&nbsp; Because of &nbsp;${T_c}/{T_q} = 4/3$,&nbsp; the transmitted signal &nbsp;$s(t)$&nbsp; is lower in frequency here than in uncoded transmission, which reduces the expensive bandwidth and is also advantageous for many channels from a transmission point of view.}}<br>
 +
 
 +
 
 +
== Quaternary signal with&nbsp; $r_{\rm c} \equiv 0$&nbsp;  and ternary signal with&nbsp; $r_{\rm c} \approx 0$==
 
<br>
 
<br>
Ein Sonderfall eines Blockcodes ist die redundanzfreie Codierung. Ausgehend vom redundanzfreien binären Quellensignal <i>q</i>(<i>t</i>) mit Bitdauer <i>T<sub>q</sub></i> wird ein <i>M<sub>c</sub></i>&ndash;stufiges Codersignal <i>c</i>(<i>t</i>) generiert, wobei die Symboldauer <i>T<sub>c</sub></i> = <i>T<sub>q</sub></i> &middot; log<sub>2</sub>(<i>M<sub>c</sub></i>) beträgt. Somit ergibt sich für die relative Redundanz:
+
A special case of a block code is a&nbsp; '''redundancy-free multilevel code'''.&nbsp;
 +
 
 +
*Starting from the redundancy-free binary source signal &nbsp;$q(t)$&nbsp; with bit duration &nbsp;$T_q$,&nbsp;
 +
*a &nbsp;$M_c$&ndash;level encoded signal &nbsp;$c(t)$&nbsp; with symbol duration &nbsp;$T_c = T_q \cdot \log_2 \hspace{0.05cm} (M_c)$&nbsp; is generated.
  
:<math>r_c = 1- \frac{T_c}{T_q \cdot {\rm log_2} (M_c)} = 1- \frac{m_q}{m_c \cdot {\rm log_2} (M_c)}= 0 \hspace{0.05cm}.</math>
 
  
Dabei gilt:
+
Thus,&nbsp; the relative redundancy is given by:
*Ist <i>M<sub>c</sub></i> eine Potenz zur Basis 2, so werden <i>m<sub>q</sub></i> = log<sub>2</sub>(<i>M<sub>c</sub></i>) zu einem einzigen Codesymbol (<i>m<sub>c</sub></i> = 1) zusammengefasst.<br>
+
:$$r_c = 1- \frac{T_c}{T_q \cdot {\rm log_2}\hspace{0.05cm} (M_c)} = 1- \frac{m_q}{m_c \cdot {\rm log_2} \hspace{0.05cm}(M_c)}\to 0 \hspace{0.05cm}.$$
*Ist <i>M<sub>c</sub></i> keine Zweierpotenz, so ist eine hundertprozentig redundanzfreie Blockcodierung nicht möglich. Codiert man beispielweise <i>m<sub>q</sub></i> = 3 Binärsymbole durch <i>m<sub>c</sub></i> = 2 Ternärsymbole und setzt <i>T<sub>c</sub></i> = 1.5 &middot; <i>T<sub>q</sub></i>, so verbleibt eine relative Redundanz von 1 &ndash; 1.5/log<sub>2</sub>(3) &asymp; 5%.<br>
 
*Codiert man einen Block von 128 Binärsymbolen mit 81 Ternärsymbolen, so ergibt sich eine relative Coderedundanz von weniger als 0.3%.<br><br>
 
  
Zur Vereinfachung der Schreibweise und zur Nomenklaturanpassung an das Kapitel 1 verwenden wir im Folgenden die Bitdauer <i>T</i><sub>B</sub> = <i>T<sub>q</sub></i> des redundanzfreien binären Quellensignals, die Symboldauer <i>T</i> = <i>T<sub>c</sub></i> von Codersignal und Sendesignal sowie die Stufenzahl <i>M</i> = <i>M<sub>c</sub></i>.<br>
+
Thereby holds:
 +
#If &nbsp;$M_c$&nbsp; is a power to the base &nbsp;$2$,&nbsp; then &nbsp;$m_q = \log_2 \hspace{0.05cm} (M_c)$&nbsp; are combined into a single  encoder symbol &nbsp;$(m_c = 1)$.&nbsp; In this case, the relative redundancy is actually &nbsp;$r_c = 0$.<br>
 +
#If &nbsp;$M_c$&nbsp; is not a power of two,&nbsp; a hundred percent redundancy-free block coding is not possible.&nbsp; For example, if &nbsp;$m_q = 3$&nbsp; binary symbols are encoded by &nbsp;$m_c = 2$&nbsp; ternary symbols and &nbsp;$T_c = 1.5 \cdot T_q$&nbsp; is set,&nbsp; a relative redundancy of &nbsp;$r_c = 1-1.5/ \log_2 \hspace{0.05cm} (3) \approx 5\%$&nbsp; remains.<br>
 +
#Encoding a block of &nbsp;$128$&nbsp; binary symbols with &nbsp;$81$&nbsp; ternary symbols results in a relative code redundancy of less than &nbsp;$r_c = 0.3\%$.<br><br>
  
Damit ergibt sich für das Sendesignal die identische Form wie bei der Binärübertragung, jedoch mit anderen Amplitudenkoeffizienten:
+
{{BlueBox|TEXT=
 +
To simplify the notation and to align the nomenclature with the [[Digital_Signal_Transmission| "first main chapter"]],&nbsp; we use in the following
 +
*the bit duration &nbsp;$T_{\rm B} = T_q$&nbsp; of the redundancy-free binary source signal,
 +
*the symbol duration &nbsp;$T = T_c$&nbsp; of the encoded signal and the transmitted signal, and
 +
*the number &nbsp;$M = M_c$&nbsp; of levels.<br>}}
  
:<math>s(t) = \sum_{\nu = -\infty}^{+\infty} a_\nu \cdot g_s ( t - \nu \cdot T)\hspace{0.3cm}{\rm mit}\hspace{0.3cm} a_\nu \in \{ a_1, ... , a_\mu , ... , a_{ M}\}\hspace{0.05cm}.</math>
 
  
Die Amplitudenkoeffizienten <i>a<sub>&nu;</sub></i> können prinzipiell beliebig &ndash; aber eindeutig &ndash; den Codersymbolen <i>c<sub>&nu;</sub></i> zugeordnet werden. Es ist zweckmäßig, die Abstände zwischen benachbarten Amplituden gleich groß zu wählen. Bei bipolarer Signalisierung (&ndash;1 &#8804; <i>a<sub>&mu;</sub></i> &#8804; +1) gilt somit für die möglichen Amplitudenkoeffizienten mit dem Laufindex <i>&mu;</i> = 1, ... , <i>M</i>:
+
This results in the identical form for the transmitted signal as for the binary transmission,&nbsp; but with different amplitude coefficients:
 +
:$$s(t) = \sum_{\nu = -\infty}^{+\infty} a_\nu \cdot g_s ( t - \nu \cdot T)\hspace{0.3cm}{\rm with}\hspace{0.3cm} a_\nu \in \{ a_1, \text{...} , a_\mu , \text{...} , a_{ M}\}\hspace{0.05cm}.$$
  
:<math>a_\mu = \frac{2\mu - M - 1}{M-1} \hspace{0.05cm}.</math>
+
*In principle,&nbsp; the amplitude coefficients &nbsp;$a_\nu$&nbsp; can be assigned arbitrarily&nbsp; &ndash; but uniquely &ndash;&nbsp; to the encoder symbols &nbsp;$c_\nu$.&nbsp; It is convenient to choose equal distances between adjacent amplitude coefficients.
 +
 +
*Thus,&nbsp; for bipolar signaling &nbsp;$(-1 \le a_\nu \le +1)$,&nbsp; the following applies to the possible amplitude coefficients with index &nbsp;$\mu = 1$, ... , $M$:
 +
:$$a_\mu = \frac{2\mu - M - 1}{M-1} \hspace{0.05cm}.$$
 +
*Independently of the level number &nbsp;$M$&nbsp; one obtains from this for the outer amplitude coefficients &nbsp;$a_1 = -1$&nbsp; and &nbsp;$a_M = +1$.
 +
 +
*For a ternary signal &nbsp;$(M = 3)$,&nbsp; the possible amplitude coefficients are &nbsp;$-1$, &nbsp;$0$&nbsp; and &nbsp;$+1$.
 +
 +
*For a quaternary signal &nbsp;$(M = 4)$,&nbsp; the coefficients are &nbsp;$-1$, &nbsp;$-1/3$, &nbsp;$+1/3$&nbsp; and &nbsp;$+1$.<br>
  
Unabhängig von der Stufenzahl <i>M</i> erhält man hieraus für die äußeren Amplitudenkoeffizienten <i>a</i><sub>1</sub> = &ndash;1 und <i>a<sub>M</sub></i> = +1. Bei einem ternären Signal (<i>M</i> = 3) sind die möglichen Amplitudenkoeffizienten &ndash;1, 0 und +1, während bei einem Quaternärsignal (<i>M</i> = 4) folgende Koeffizienten auftreten: &ndash;1, &ndash;1/3, +1/3, +1.<br>
 
  
 +
{{GraueBox|TEXT= 
 +
$\text{Example 2:}$&nbsp; The graphic above shows the quaternary redundancy-free transmitted signal &nbsp;$s_4(t)$&nbsp; with the possible amplitude coefficients &nbsp;$\pm 1$&nbsp; and &nbsp;$\pm 1/3$,&nbsp; which results from the binary source signal &nbsp;$q(t)$&nbsp; shown in the center.
 +
[[File:EN_Dig_T_2_2_S2.png|right|frame|Redundancy-free ternary and quaternary signal|class=fit]]
 +
 +
*Two binary symbols each are combined to a quaternary coefficient according to the table with red background. The symbol duration &nbsp;$T$&nbsp; of the signal &nbsp;$s_4(t)$&nbsp; is twice the bit duration &nbsp;$T_{\rm B}$&nbsp; $($previously: &nbsp;$T_q)$&nbsp; of the source signal.
 +
 +
*If &nbsp;$q(t)$&nbsp; is redundancy-free, it also results in a redundancy-free quaternary signal, i.e., the possible amplitude coefficients &nbsp;$\pm 1$&nbsp; and &nbsp;$\pm 1/3$&nbsp; are equally probable and there are no statistical ties within the sequence &nbsp;$⟨a_ν⟩$.&nbsp;
 +
  
== Redundanzfreies Ternär– und Quaternärsignal (2) ==
 
<br>
 
{{Beispiel}}''':''' Die Grafik zeigt oben das quaternäre redundanzfreie Sendesignal
 
<i>s</i><sub>4</sub>(<i>t</i>) mit den möglichen Amplitudenkoeffizienten &plusmn;1 und &plusmn;1/3, das sich aus dem in der Mitte dargestellten binären Quellensignal <i>q</i>(<i>t</i>) ergibt. Jeweils zwei Binärsymbole werden nach der rot hinterlegten Tabelle zu einem quaternären Amplitudenkoeffizienten zusammengefasst. Die Symboldauer <i>T</i> des Signals <i>s</i><sub>4</sub>(<i>t</i>) ist doppelt so groß wie die Bitdauer <i>T</i><sub>B</sub> (vorher: <i>T<sub>q</sub></i>) des Quellensignals. Ist <i>q</i>(<i>t</i>) redundanzfrei, so ergibt sich auch ein redundanzfreies Quaternärsignal, das heißt, die möglichen Amplitudenkoeffizienten &plusmn;1 und &plusmn;1/3 sind gleichwahrscheinlich und innerhalb der Folge &#9001;<i>a<sub>&nu;</sub></i>&#9002; gibt es keine statistischen Bindungen.
 
  
<br>[[File:P_ID1313__Dig_T_2_2_S2_v1.png|Redundanzfreies Ternär- und Quaternärsignal|class=fit]]<br><br>
+
The lower plot shows the $($almost$)$ redundancy-free ternary signal &nbsp;$s_3(t)$&nbsp; and the mapping of three binary symbols each to two ternary symbols.
 +
*The possible amplitude coefficients are &nbsp;$-1$, &nbsp;$0$&nbsp; and &nbsp;$+1$&nbsp; and the symbol duration of the encoded  signal &nbsp;$T = 3/2 \cdot T_{\rm B}$.
  
Die untere Darstellung zeigt das (nahezu) redundanzfreie Ternärsignal <i>s</i><sub>3</sub>(<i>t</i>) und die Zuordnung von jeweils drei Binärsymbolen zu zwei Ternärsymbolen. Die möglichen Amplitudenkoeffizienten sind &ndash;1, 0 und +1 und es gilt <i>T</i>/<i>T</i><sub>B</sub> = 3/2. Man erkennt aus der angegebenen Zuordnungstabelle, dass die Amplitudenkoeffizienten +1 und &ndash;1 etwas häufiger auftreten als der Amplitudenkoeffizent <i>a<sub>&nu;</sub></i> = 0. Hieraus ergibt sich die Redundanz von 5% (siehe letzte Seite). Aus dem sehr kurzen Signalausschnitt &ndash; nur acht Ternärsymbole entsprechend zwölf Bit &ndash; ist diese Eigenschaft allerdings nicht zu erkennen.{{end}}<br>
+
*It can be seen from the green mapping table that the coefficients &nbsp;$+1$&nbsp; and &nbsp;$-1$&nbsp; occur somewhat more frequently than the coefficient &nbsp;$a_\nu = 0$.&nbsp; This results in the above mentioned relative redundancy of&nbsp; $5\%$.
 +
 +
*However,&nbsp; from the very short signal section&nbsp; &ndash; only eight ternary symbols corresponding to twelve binary symbols &ndash;&nbsp; this property is not apparent.}}<br>
  
  
== AKF und LDS eines Mehrstufensignals ==
+
== ACF and PSD of a multilevel signal ==
 
<br>
 
<br>
Bei einem redundanzfrei codierten <i>M</i>&ndash;stufigen bipolaren Digitalsignal <i>s</i>(<i>t</i>) gilt für die diskrete AKF der Amplitudenkoeffizienten sowie für die entsprechende spektrale Leistungsdichte:
+
For a redundancy-free coded&nbsp; $M$&ndash;level bipolar digital signal &nbsp;$s(t)$,&nbsp;  the following holds for the &nbsp;[[Digital_Signal_Transmission/Basics_of_Coded_Transmission#ACF_calculation_of_a_digital_signal|"discrete auto-correlation function"]]&nbsp; $\rm (ACF)$&nbsp; of the amplitude coefficients and for the corresponding &nbsp;[[Digital_Signal_Transmission/Basics_of_Coded_Transmission#PSD_calculation_of_a_digital_signal|"power-spectral density"]]&nbsp; $\rm (PSD)$:
 
+
:$$\varphi_a(\lambda)  =  \left\{ \begin{array}{c} \frac{M+ 1}{3 \cdot (M-1)}    \\
:<math>\varphi_a(\lambda)  =  \left\{ \begin{array}{c} \frac{M+ 1}{3 \cdot (M-1)}    \\
 
 
  \\ 0  \\  \end{array} \right.\quad
 
  \\ 0  \\  \end{array} \right.\quad
\begin{array}{*{1}c} {\rm{f\ddot{u}r}}\\  \\ {\rm{f\ddot{u}r}} \\ \end{array}
+
\begin{array}{*{1}c} {\rm{for}}\\  \\ {\rm{for}} \\ \end{array}
 
\begin{array}{*{20}c}\lambda = 0, \\ \\  \lambda \ne 0 \\
 
\begin{array}{*{20}c}\lambda = 0, \\ \\  \lambda \ne 0 \\
 
\end{array}
 
\end{array}
\hspace{0.3cm}\Rightarrow \hspace{0.3cm}{\it \Phi_a(f)}  =
+
\hspace{0.9cm}\Rightarrow \hspace{0.9cm}{\it \Phi_a(f)}  =
\frac{M+ 1}{3  \cdot (M-1)}= {\rm const.}</math>
+
\frac{M+ 1}{3  \cdot (M-1)}= {\rm const.}$$
  
Unter Berücksichtigung der spektralen Formung durch den Sendegrundimpuls <i>g<sub>s</sub></i>(<i>t</i>) erhält man:
+
Considering the spectral shaping by the basic transmission pulse &nbsp;$g_s(t)$&nbsp; with spectrum &nbsp;$G_s(f)$,&nbsp; we obtain:
 
+
:$$\varphi_{s}(\tau) = \frac{M+ 1}{3 \cdot (M-1)} \cdot \varphi^{^{\bullet}}_{gs}(\tau) \hspace{0.4cm}\circ\!\!-\!\!\!-\!\!\!-\!\!\bullet
:<math>\varphi_{s}(\tau) = \frac{M+ 1}{3 \cdot (M-1)} \cdot \varphi^{^{\bullet}}_{gs}(\tau) \hspace{0.4cm}\circ\!\!-\!\!\!-\!\!\!-\!\!\bullet
 
 
\hspace{0.4cm}
 
\hspace{0.4cm}
 
   {\it \Phi}_{s}(f)  = \frac{M+ 1}{3 \cdot (M-1)}\cdot |G_s(f)|^2
 
   {\it \Phi}_{s}(f)  = \frac{M+ 1}{3 \cdot (M-1)}\cdot |G_s(f)|^2
   \hspace{0.05cm}.</math>
+
   \hspace{0.05cm}.$$
 +
 
 +
One can see from these equations:
 +
*In the case of redundancy-free multilevel coding,&nbsp; the shape of ACF and PSD is determined solely by the basic transmission pulse &nbsp;$g_s(t)$.&nbsp;<br>
 +
 
 +
*The magnitude of the ACF is lower than the redundancy-free binary signal by a factor &nbsp;$\varphi_a(\lambda = 0) = {\rm E}\big[a_\nu^2\big] = (M + 1)/(3M-3)$&nbsp; for the same shape.<br>
 +
 
 +
*This factor describes the lower signal power of the multilevel signal due to the &nbsp;$M-2$&nbsp; inner amplitude coefficients.&nbsp; For &nbsp;$M = 3$&nbsp; this factor is equal to &nbsp;$2/3$, for &nbsp;$M = 4$&nbsp; it is equal to &nbsp;$5/9$.<br>
  
Man erkennt aus diesen Gleichungen:
+
*However,&nbsp; a fair comparison between binary and multilevel signal with the same information flow&nbsp; (same equivalent bit rate)&nbsp; should also take into account the different symbol durations.&nbsp; This shows that a multilevel signal requires less bandwidth than the binary signal due to the narrower PSD when the same information is transmitted.<br><br>
*Bei redundanzfreier mehrstufiger Codierung wird die Form von AKF und LDS allein durch den Sendegrundimpuls  <i>g<sub>s</sub></i>(<i>t</i>) bestimmt.<br>
 
*Die Höhe von AKF und LDS ist bei gleicher Form gegenüber dem redundanzfreien Binärsignal um den Faktor <i>&phi;<sub>a</sub></i>(<i>&lambda;</i> = 0) = E[<i>a<sub>&nu;</sub></i><sup>2</sup>] = (<i>M</i> + 1)/(3<i>M</i> &ndash; 3) geringer.<br>
 
*Dieser Faktor beschreibt die geringere Signalleistung des Mehrstufensignals aufgrund der <i>M</i> &ndash; 2 inneren Amplitudenkoeffizienten. Bei <i>M</i> = 3 ist dieser Faktor gleich 2/3, bei <i>M</i> = 4 gleich 5/9.<br>
 
*Ein fairer Vergleich zwischen Binärsignal und Mehrstufensignal bei gleichem Informationsfluss (äquivalente Bitrate) sollte aber auch die unterschiedlichen Symboldauern berücksichtigen.<br>
 
*Dabei zeigt sich, dass ein Mehrstufensignal aufgrund des schmaleren LDS weniger Bandbreite benötigt als das Binärsignal, wenn die gleiche Information übertragen wird.<br><br>
 
  
{{Beispiel}}''':''' Wir gehen von einer binären Quelle mit der Bitrate <i>R</i><sub>B</sub> = 1 Mbit/s aus, so dass die Bitdauer <i>T</i><sub>B</sub> = 1 &mu;s beträgt. Bei Binärübertragung (<i>M</i> = 2) ist die Symboldauer <i>T</i> des Sendesignals gleich <i>T</i><sub>B</sub> und es ergibt sich bei NRZ&ndash;Rechteckimpulsen die blau eingezeichnete AKF in der linken Grafik (vorausgesetzt ist <i>s</i><sub>0</sub><sup>2</sup> = 10 mW). Beim Quaternärsystem (<i>M</i> = 4) ist die AKF ebenfalls dreieckförmig, aber um den Faktor 5/9 niedriger und wegen <i>T</i> = 2 <i>T</i><sub>B</sub> doppelt so breit.
+
{{GraueBox|TEXT= 
 +
$\text{Example 3:}$&nbsp; We assume a binary source with bit rate &nbsp;$R_{\rm B} = 1 \ \rm Mbit/s$,&nbsp; so that the bit duration &nbsp;$T_{\rm B} = 1 \ \rm &micro; s$.&nbsp;
 +
[[File:Dig_T_1_5_S3_version2.png|right|frame|Auto-correlation function and power-spectral density of binary and quaternary signal|class=fit]]
  
<br>[[File:P_ID1332__Dig_T_2_2_S3_v1.png|AKF und LDS von Binär- und Quaternärsignal|class=fit]]<br><br>
+
*For binary transmission &nbsp;$(M = 2)$,&nbsp; the symbol duration of the transmitted signal is &nbsp;$T =T_{\rm B}$&nbsp; and the auto-correlation function shown in blue in the left graph results for NRZ rectangular pulses (assuming &nbsp;$s_0^2 = 10 \ \rm mW$).  
 +
*For the quaternary system &nbsp;$(M = 4)$,&nbsp; the ACF is also triangular, but lower by a factor of &nbsp;$5/9$&nbsp; and twice as wide because of &nbsp;$T = 2 \cdot T_{\rm B}$.&nbsp;
  
Das si<sup>2</sup>&ndash;förmige Leistungsdichtespektrum hat im binären Fall bei den hier gewählten Signalparametern den Maximalwert 10<sup>&ndash;8</sup> W/Hz und die erste Nullstelle liegt bei <i>f</i> = 1 MHz. Demgegenüber ist das LDS des Quaternärsignals nur halb so breit und auch nur geringfügig höher (Faktor 2 &middot; 5/9 &asymp; 1.11).{{end}}<br>
 
  
 +
The &nbsp;$\rm sinc^2$&ndash;shaped power-spectral density in the binary case&nbsp;  (blue curve)&nbsp; has the maximum value &nbsp;${\it \Phi}_{s}(f = 0) = 10^{-8} \ \rm  W/Hz$&nbsp; (area of the blue triangle)&nbsp; for the signal parameters selected here.&nbsp; The first zero point is at &nbsp;$f = 1 \ \rm MHz$.
 +
*The PSD of the quaternary signal&nbsp; (red curve)&nbsp; is only half as wide and slightly higher.&nbsp; Here:  &nbsp;${\it \Phi}_{s}(f = 0) \approx 1.1 \cdot 10^{-8} \ \rm  W/Hz$. 
 +
*The value results from the area of the red triangle.&nbsp; <br>This is lower &nbsp;$($factor &nbsp;$0.55)$&nbsp; and wider (factor $2$).}}<br>
  
== Fehlerwahrscheinlichkeit eines Mehrstufensystems (1) ==
+
 
 +
== Error probability of a multilevel system ==
 
<br>
 
<br>
Nachfolgend sehen Sie die Augendiagramme eines binären (<i>M</i> = 2), eines ternären
+
[[File:P_ID1315__Dig_T_2_2_S4_v1.png|right|frame|Eye diagrams for redundancy&ndash;free binary, ternary and quaternary signals|class=fit]]
<nobr>(<i>M</i> = 3)</nobr> und eines quaternären (<i>M</i> = 4) Übertragungssystems. Hierbei ist für das Gesamtsystem <i>H</i><sub>S</sub>(<i>f</i>) &middot; <i>H</i><sub>E</sub>(<i>f</i>) von Sender und Empfänger eine Cosinus&ndash;Rolloff&ndash;Charakteristik mit dem Rolloff&ndash;Faktor <i>r</i> = 0.5 vorausgesetzt, so dass Impulsinteferenzen keine Rolle spielen. Das Rauschen wird als vernachlässigbar klein angenommen.
+
The diagram on the right shows the eye diagrams
 +
*of a binary transmission system &nbsp;$(M = 2)$,  
 +
*a ternary transmission system &nbsp;$(M = 3)$ and
 +
*a quaternary transmission system &nbsp;$(M = 4)$.  
 +
 +
 
 +
Here,&nbsp; a cosine rolloff characteristic is assumed for the overall system &nbsp;$H_{\rm S}(f) \cdot H_{\rm K}(f) \cdot H_{\rm E}(f)$&nbsp;  of transmitter, channel and receiver,&nbsp; so that intersymbol interference does not play a role.&nbsp; The rolloff factor is &nbsp;$r= 0.5$.&nbsp; The noise is assumed to be negligible.
 +
 
 +
The eye diagram is used to estimate intersymbol interference.&nbsp; A detailed description follows in the section &nbsp;[[Digital_Signal_Transmission/Error_Probability_with_Intersymbol_Interference#Definition_and_statements_of_the_eye_diagram|"Definition and statements of the eye diagram"]].&nbsp; However,&nbsp; the following text should be understandable even without detailed knowledge.<br>
  
<br>[[File:P_ID1315__Dig_T_2_2_S4_v1.png|Augendiagramme bei redundanzfreien Binär-, Ternär- und Quaternärsignalen|class=fit]]<br><br>
+
It can be seen from the above diagrams:
 +
<br clear = all>
 +
*In the&nbsp; '''binary system'''&nbsp; &nbsp;$(M = 2)$,&nbsp; there is only one decision threshold: &nbsp; $E_1 = 0$.&nbsp; A transmission error occurs if the noise component &nbsp;$d_{\rm N}(T_{\rm D})$&nbsp; at the detection time is greater than &nbsp;$+s_0$ &nbsp; $\big ($if &nbsp;$d_{\rm S}(T_{\rm D}) = -s_0$  $\big )$ &nbsp;or&nbsp; if &nbsp;$d_{\rm N}(T_{\rm D})$&nbsp; is less than &nbsp;$-s_0$ &nbsp;  $\big ($if &nbsp;$d_{\rm S}(T_{\rm D}) = +s_0$ $\big )$.<br>
  
Das Augendiagramm wird vorwiegend zur Abschätzung von Impulsinterferenzen genutzt. Eine genaue Beschreibung folgt in Kapitel 3.2 Der folgende Text ist aber auch ohne Detailkenntnisse verständlich.<br>
+
*In the case of the&nbsp; '''ternary system''' &nbsp;$(M = 3)$,&nbsp; two eye openings and two decision thresholds &nbsp;$E_1 = -s_0/2$&nbsp; and &nbsp;$E_2 = +s_0/2$&nbsp; can be recognized.&nbsp; The distance of the possible useful detection signal values &nbsp;$d_{\rm S}(T_{\rm D})$&nbsp; to the nearest threshold is &nbsp;$-s_0/2$ in each case.&nbsp; The outer amplitude values &nbsp;$(d_{\rm S}(T_{\rm D}) = \pm s_0)$&nbsp; can only be falsified in one direction in each case,&nbsp; while &nbsp;$d_{\rm S}(T_{\rm D}) = 0$&nbsp; is limited by two thresholds.<br>
  
Man erkennt aus obigen Darstellungen:
+
*Accordingly,&nbsp; an amplitude coefficient &nbsp;$a_\nu = 0$&nbsp; is falsified twice as often compared to &nbsp;$a_\nu = +1$&nbsp; or &nbsp;$a_\nu = -1$.&nbsp; For AWGN noise with rms value &nbsp;$\sigma_d$&nbsp; as well as equal probability amplitude coefficients,&nbsp; according to the section &nbsp;[[Digital_Signal_Transmission/Error_Probability_for_Baseband_Transmission#Definition_of_the_bit_error_probability|"Definition of the bit error probability"]]&nbsp; for the&nbsp; "symbol error probability":
*Beim Binärsystem (<i>M</i> = 2) gibt es nur eine einzige Entscheiderschwelle: <i>E</i><sub>1</sub> = 0. Zu einem Übertragungsfehler kommt es, wenn die Rauschkomponente <i>d</i><sub>N</sub>(<i>T</i><sub>D</sub>) zum Detektionszeitpunkt größer ist als +<i>s</i><sub>0</sub> (falls <i>d</i><sub>S</sub>(<i>T</i><sub>D</sub>) = &ndash;<i>s</i><sub>0</sub>) bzw. wenn <i>d</i><sub>N</sub></i>(<i>T</i><sub>D</sub>) kleiner ist als &ndash;<i>s</i><sub>0</sub>, falls <i>d</i><sub>S</sub>(<i>T</i><sub>D</sub>) = +<i>s</i><sub>0</sub> gilt.<br>
 
*Beim Ternärsystem (<i>M</i> = 3) erkennt man zwei Augenöffnungen und zwei Entscheiderschwellen <nobr><i>E</i><sub>1</sub> = &ndash;<i>s</i><sub>0</sub>/2</nobr> und <i>E</i><sub>2</sub> = +<i>s</i><sub>0</sub>/2. Der Abstand der möglichen Detektionsnutzsignalwerte <i>d</i><sub>S</sub>(<i>T</i><sub>D</sub>) zu der nächstgelegenen Schwelle beträgt jeweils  <i>s</i><sub>0</sub>/2. Die äußeren Amplitudenwerte (&plusmn;<i>s</i><sub>0</sub>) können nur in jeweils eine Richtung verfälscht werden, während <i>d</i><sub>S</sub>(<i>T</i><sub>D</sub>) = 0 von zwei Schwellen begrenzt wird.<br>
 
*Dementsprechend wird ein Amplitudenkoeffizient <i>a<sub>&nu;</sub></i> = 0 gegenüber <i>a<sub>&nu;</sub></i> = +1 bzw. <i>a<sub>&nu;</sub></i> = &ndash;1 doppelt so oft verfälscht. Bei gleichwahrscheinlichen Amplitudenkoeffizienten sowie AWGN&ndash;Rauschen mit dem Effektivwert <i>&sigma;<sub>d</sub></i> ergibt sich gemäß Kapitel 1.2 für die Symbolfehlerwahrscheinlichkeit:
 
  
::<math>p_{\rm S} = { 1}/{3} \cdot \left[{\rm Q} \left( \frac{s_0/2}{\sigma_d}\right)+
+
:$$p_{\rm S} = { 1}/{3} \cdot \left[{\rm Q} \left( \frac{s_0/2}{\sigma_d}\right)+
 
  2 \cdot {\rm Q} \left( \frac{s_0/2}{\sigma_d}\right)+ {\rm Q} \left(
 
  2 \cdot {\rm Q} \left( \frac{s_0/2}{\sigma_d}\right)+ {\rm Q} \left(
 
  \frac{s_0/2}{\sigma_d}\right)\right]=
 
  \frac{s_0/2}{\sigma_d}\right)\right]=
  \frac{ 4}{3} \cdot {\rm Q} \left( \frac{s_0/2}{\sigma_d}\right)\hspace{0.05cm}.</math>
+
  \frac{ 4}{3} \cdot {\rm Q} \left( \frac{s_0/2}{\sigma_d}\right)\hspace{0.05cm}.$$
 +
 
 +
*Please note that this equation no longer specifies the bit error probability &nbsp;$p_{\rm B}$, but the&nbsp;  "symbol error probability" &nbsp;$p_{\rm S}$.&nbsp; The corresponding a-posteriori parameters are&nbsp; "bit error rate"&nbsp; $\rm (BER)$&nbsp; and&nbsp; "symbol error rate"&nbsp; $\rm (SER)$.&nbsp; More details are given in the &nbsp;[[Digital_Signal_Transmission/Redundancy-Free_Coding#Symbol_and_bit_error_probability|"last section"]]&nbsp; of this chapter.<br>
 +
 
 +
 
 +
For the '''quaternary system''' &nbsp;$(M = 4)$&nbsp; with the possible amplitude values &nbsp;$\pm s_0$&nbsp; and &nbsp;$\pm s_0/3$,&nbsp;
 +
*there are three eye-openings,&nbsp; and
 +
*thus also three decision thresholds at &nbsp;$E_1 = -2s_0/3$, &nbsp;$E_2 = 0$&nbsp; and &nbsp;$E_3 = +2s_0/3$.
 +
 
 +
 
 +
Taking into account the occurrence probabilities&nbsp;  $(1/4$&nbsp; for equally probable symbols$)$&nbsp; and the six possibilities of falsification (see arrows in the graph),&nbsp; we obtain:
 +
:$$p_{\rm S} =
 +
{ 6}/{4} \cdot {\rm Q} \left( \frac{s_0/3}{\sigma_d}\right)\hspace{0.05cm}.$$
 +
 
 +
{{BlaueBox|TEXT= 
 +
$\text{Conclusion:}$&nbsp; In general, the&nbsp; '''symbol error probability'''&nbsp; for &nbsp;$M$&ndash;level digital signal transmission is:
 +
:$$p_{\rm S}  =
 +
\frac{ 2 + 2 \cdot (M-2)}{M} \cdot {\rm Q} \left( \frac{s_0/(M-1)}{\sigma_d(M)}\right) = \frac{ 2  \cdot (M-1)}{M} \cdot {\rm Q} \left( \frac{s_0}{\sigma_d (M)\cdot (M-1)}\right)\hspace{0.05cm}.$$
 +
 
 +
*The notation &nbsp;$\sigma_d(M)$&nbsp; is intended to make clear that the rms value of the noise component &nbsp;$d_{\rm N}(t)$&nbsp; depends significantly on the  level number &nbsp;$M$.&nbsp;}}<br>
 +
 
 +
 
 +
== Comparison between binary system and multilevel system==
 +
<br>
 +
For this system comparison under fair conditions,&nbsp; the following are assumed:
 +
*Let the equivalent bit rate &nbsp;$R_{\rm B} = 1/T_{\rm B}$&nbsp; be constant.&nbsp; Depending on the  level number &nbsp;$M$,&nbsp; the symbol duration of the encoded  signal and the transmitted signal is thus:
 +
:$$T = T_{\rm B} \cdot {\rm log_2} (M)  \hspace{0.05cm}.$$
 +
*The Nyquist condition is satisfied by a &nbsp;[[Digital_Signal_Transmission/Optimization_of_Baseband_Transmission_Systems#Root_Nyquist_systems|"root&ndash;root characteristic"]]&nbsp; with rolloff factor &nbsp;$r$.&nbsp; Furthermore,&nbsp; no intersymbol interference occurs.&nbsp; The detection noise power is:
 +
::$$\sigma_d^2 = \frac{N_0}{2T}  \hspace{0.05cm}.$$
 +
*The comparison of the symbol error probabilities &nbsp;$p_{\rm S}$&nbsp; is performed for &nbsp;[[Digital_Signal_Transmission/Optimization_of_Baseband_Transmission_Systems#System_optimization_with_power_limitation|"power limitation"]]. The energy per bit for &nbsp;$M$&ndash;level transmission is:
 +
:$$E_{\rm B} = \frac{M+ 1}{3 \cdot (M-1)} \cdot s_0^2 \cdot T_{\rm B}
 +
  \hspace{0.05cm}.$$
 +
 
 +
Substituting these equations into the general result on the &nbsp;[[Digital_Signal_Transmission/Redundancy-Free_Coding#Error_probability_of_a_multilevel_system|"last section"]],&nbsp; we obtain for the symbol error probability:
 +
:$$p_{\rm S}  =
 +
\frac{ 2  \cdot (M-1)}{M} \cdot {\rm Q} \left( \sqrt{\frac{s_0^2 /(M-1)^2}{\sigma_d^2}}\right) =
 +
\frac{ 2  \cdot (M-1)}{M} \cdot {\rm Q} \left( \sqrt{\frac{3 \cdot {\rm log_2}\hspace{0.05cm} (M)}{M^2 -1}\cdot
 +
\frac{2 \cdot E_{\rm B}}{N_0}}\right)$$
 +
[[File:EN_Dig_T_2_3_S3b_v2.png|right|frame|Symbol error probability curves for different level numbers &nbsp;$M$]]
 +
:$$\Rightarrow \hspace{0.3cm} p_{\rm S}  =
 +
  K_1 \cdot {\rm Q} \left( \sqrt{K_2\cdot
 +
\frac{2 \cdot E_{\rm B}}{N_0}}\right)\hspace{0.05cm}.$$
 +
 
 +
For &nbsp;$M = 2$,&nbsp; set &nbsp;$K_1 = K_2 = 1$.&nbsp; For larger level numbers,&nbsp; one obtains  for the symbol error probability that can be achieved with &nbsp;$M$&ndash;level redundancy-free coding:
 +
:$$M = 3\text{:} \ \ K_1 = 1.333, \ K_2 = 0.594;\hspace{0.5cm}M = 4\text{:} \ \ K_1 = 1.500, \ K_2 = 0.400;$$
 +
:$$M = 5\text{:} \ \ K_1 = 1.600, \ K_2 = 0.290;\hspace{0.5cm}M = 6\text{:} \ \ K_1 = 1.666, \ K_2 = 0.221;$$
 +
:$$M = 7\text{:} \ \ K_1 = 1.714, \ K_2 = 0.175;\hspace{0.5cm}M = 8\text{:} \ \ K_1 = 1.750, \ K_2 = 0.143.$$
 +
 
 +
The graph summarizes the results for &nbsp;$M$&ndash;level redundancy-free coding.
 +
*Plotted are the symbol error probabilities &nbsp;$p_{\rm S}$&nbsp; over the abscissa &nbsp;$10 \cdot \lg \hspace{0.05cm}(E_{\rm B}/N_0)$.
 +
 +
*All systems are optimal for the respective &nbsp;$M$,&nbsp; assuming the AWGN channel and power limitation.
 +
 
 +
*Due to the double logarithmic representation chosen here, a &nbsp;$K_2$ value smaller than &nbsp;$1$&nbsp; leads to a parallel shift of the error probability curve to the right.
 +
 
 +
*If &nbsp;$K_1 > 1$ applies, the curve shifts upwards compared to the binary system &nbsp;$(K_1= 1)$.&nbsp;<br>
 +
 
 +
 
 +
{{BlaueBox|TEXT= 
 +
$\text{System comparison under the constraint of power limitation:}$&nbsp; The above curves can be interpreted as follows:
 +
#Regarding symbol error probability,&nbsp; the binary system &nbsp;$(M = 2)$&nbsp; is superior to the multilevel systems.&nbsp; Already with &nbsp;$10 \cdot \lg \hspace{0.05cm}(E_{\rm B}/N_0) = 12 \ \rm dB$&nbsp; one reaches  &nbsp;$p_{\rm S} <10^{-8}$.&nbsp; For the quaternary system &nbsp;$(M = 4)$,&nbsp; &nbsp;$10 \cdot \lg \hspace{0.05cm}(E_{\rm B}/N_0) > 16 \ \rm dB$&nbsp; must be spent to reach the same symbol error probability &nbsp;$p_{\rm S} =10^{-8}$.&nbsp;
 +
#However,&nbsp; this statement is valid only for distortion-free channel,&nbsp; i.e., for &nbsp;$H_{\rm K}(f)= 1$.&nbsp; On the other hand,&nbsp; for distorting transmission channels,&nbsp; a higher-level system can provide a significant improvement because of the significantly smaller noise component of the detection signal&nbsp; (after the equalizer).<br>
 +
#For the AWGN channel,&nbsp; the only advantage of a higher-level transmission is the lower bandwidth requirement due to the smaller equivalent bit rate,&nbsp; which plays only a minor role in baseband transmission in contrast to digital carrier frequency systems,&nbsp; e.g. &nbsp;[[Modulation_Methods/Quadrature_Amplitude_Modulation#Quadratic_QAM_signal_space_constellations|"quadrature amplitude modulation"]]&nbsp; $\rm (QAM)$.}}
 +
 
 +
 
 +
{{BlaueBox|TEXT= 
 +
$\text{System comparison under the peak limitation constraint:}$&nbsp;
 +
*With the constraint&nbsp; "peak limitation",&nbsp; the combination of rectangular &nbsp;$g_s(t)$&nbsp; and rectangular &nbsp;$h_{\rm E}(t)$&nbsp; leads to the optimum regardless of the level number  &nbsp;$M$.&nbsp; <br>
 +
 
 +
*The loss of the multilevel system compared to the binary system is here even greater than with power limitation.
 +
 
 +
*This can be seen from the factor &nbsp;$K_2$&nbsp; decreasing with &nbsp;$M$,&nbsp; for which then applies:
 +
:$$p_{\rm S} = K_1 \cdot {\rm Q} \left( \sqrt{K_2\cdot
 +
\frac{2 \cdot s_{\rm 0}^2 \cdot T}{N_0} }\right)\hspace{0.3cm}{\rm with}\hspace{0.3cm}
 +
K_2 = \frac{ {\rm log_2}\,(M)}{(M-1)^2}
 +
\hspace{0.05cm}.$$
 +
*The constant &nbsp;$K_1$&nbsp; is unchanged from the above specification for power limitation,&nbsp; while &nbsp;$K_2$&nbsp; is smaller by a factor of &nbsp;$3$:&nbsp;
 +
:$$M = 3\text{:} \ \ K_1 = 1.333, \ K_2 = 0.198;\hspace{1cm}M = 4\text{:} \ \ K_1 = 1.500, \ K_2 = 0.133;$$
 +
:$$M = 5\text{:} \ \ K_1 = 1.600, \ K_2 = 0.097;\hspace{1cm}M = 6\text{:} \ \ K_1 = 1.666, \ K_2 = 0.074;$$
 +
:$$M = 7\text{:} \ \ K_1 = 1.714, \ K_2 = 0.058;\hspace{1cm}M = 8\text{:} \ \ K_1 = 1.750, \ K_2 = 0.048.$$}}
 +
 
 +
 
 +
== Symbol and bit error probability==
 +
<br>
 +
In a multilevel transmission system,&nbsp; one must distinguish between the &nbsp;"symbol error probability"&nbsp; and the &nbsp;"bit error probability",&nbsp; which are given here both as ensemble averages and as time averages:
 +
[[File:EN_Dig_T_2_2_S6a.png|right|frame|Symbol error probability and bit error probability|class=fit]]
 +
 
 +
*The&nbsp; '''symbol error probability'''&nbsp; refers to the &nbsp;$M$&ndash;level and possibly redundant sequences &nbsp;$\langle c_\nu \rangle$&nbsp; and &nbsp;$\langle w_\nu \rangle$:
 +
:$$p_{\rm S}  = \overline{{\rm Pr} (w_\nu \ne c_\nu)} =
 +
\lim_{N \to \infty} \frac{1}{N} \cdot \sum \limits^{N} _{\nu = 1} {\rm Pr} (w_\nu \ne c_\nu) \hspace{0.05cm}.$$
 +
*The&nbsp; '''bit error probability'''&nbsp; describes the falsifications with respect to the binary sequences  &nbsp;$\langle q_\nu \rangle$&nbsp; and &nbsp;$\langle v_\nu \rangle$&nbsp; of source and sink:
 +
:$$p_{\rm B}  = \overline{{\rm Pr} (v_\nu \ne q_\nu)} =
 +
\lim_{N \to \infty} \frac{1}{N} \cdot \sum \limits^{N} _{\nu = 1} {\rm Pr} (v_\nu \ne q_\nu) \hspace{0.05cm}.$$
 +
 
 +
The diagram illustrates these two definitions and is also valid for the next chapters.&nbsp; The block&nbsp; "encoder"&nbsp; causes
 +
*in the present chapter a redundancy-free coding,
 +
*in the &nbsp;[[Digital_Signal_Transmission/Block_Coding_with_4B3T_Codes|"following chapter"]]&nbsp; a blockwise transmission coding,&nbsp; and finally
 +
* in the &nbsp;[[Digital_Signal_Transmission/Symbolwise_Coding_with_Pseudo-Ternary_Codes|"last chapter"]]&nbsp; symbolwise coding with pseudo-ternary codes.
 +
 
 +
 
 +
{{BlaueBox|TEXT= 
 +
$\text{Conclusion:}$&nbsp;
 +
*For multilevel and/or coded transmission,&nbsp; a distinction must be made between the bit error probability &nbsp;$p_{\rm B}$&nbsp; and the symbol error probability &nbsp;$p_{\rm S}$.&nbsp; Only in the case of the redundancy-free binary system does &nbsp;$p_{\rm B} = p_{\rm S}$ apply.
  
Die Bildbeschreibung wird auf der nächsten Seite fortgesetzt. Beachten Sie aber bereits hier, dass mit dieser Gleichung nicht mehr die Bitfehlerwahrscheinlichkeit <i>p</i><sub>B</sub>, sondern die Symbolfehlerwahrschein-
+
*In general,&nbsp; the symbol error probability &nbsp;$p_{\rm S}$&nbsp; can be calculated somewhat more easily than the bit error probability &nbsp;$p_{\rm B}$&nbsp; for redundancy-containing multilevel systems.
lichkeit <i>p</i><sub>S</sub> angegeben wird. Die entsprechenden Aposteriori&ndash;Kenngrößen sind <i>Bit Error Rate</i> (BER) bzw. <i>Symbol Error Rate</i> (SER). Näheres hierzu auf der letzten Seite dieses Kapitels.<br>
 
  
 +
* However,&nbsp; a comparison of systems with different level numbers&nbsp; $M$&nbsp; or different types of coding should always be based on the bit error probability &nbsp;$p_{\rm B}$&nbsp; for reasons of fairness.&nbsp; The mapping between the source and encoder symbols must also be taken into account,&nbsp; as shown in the following example.}}<br>
 +
 +
{{GraueBox|TEXT= 
 +
$\text{Example 4:}$&nbsp; We consider a quaternary transmission system whose transmission behavior can be characterized as follows&nbsp; (see left sketch in the graphic):
 +
 +
*The falsification probability to a neighboring symbol is &nbsp;
 +
:$$p={\rm Q}\big [s_0/(3\sigma_d)\big ].$$
 +
*A falsification to a non-adjacent symbol is excluded.<br>
 +
*The model considers the dual falsification possibilities of inner symbols.<br>
  
<math></math><br>
 
 
<br>
 
<br>
<br><br>
+
For equally probable binary source symbols &nbsp;$q_\nu$&nbsp; the quaternary encoder symbols &nbsp;$c_\nu$&nbsp; also occur with equal probability.&nbsp; Thus,&nbsp; we obtain for the symbol error probability:
[[File:||class=fit]]<br><br>
+
:$$p_{\rm S}  ={1}/{4}\cdot (2 \cdot p + 2 \cdot 2 \cdot  p) =  {3}/{2} \cdot p\hspace{0.05cm}.$$
 +
 
 +
[[File:EN_Dig_T_2_2_S6b.png|right|frame|Comparison of  dual code and Gray code|class=fit]]
 +
To calculate the bit error probability,&nbsp; one must also consider the mapping between the binary and the quaternary symbols:
 +
*In &nbsp;"dual coding"&nbsp; according to the table with yellow background,&nbsp; one symbol error &nbsp;$(w_\nu \ne c_\nu)$&nbsp; can result in one or two bit errors &nbsp;$(v_\nu \ne q_\nu)$.&nbsp; Of the six falsification possibilities at the quaternary symbol level,&nbsp; four result in one bit error each and only the two inner ones result in two bit errors.&nbsp; It follows:
 +
:$$p_{\rm B}  = {1}/{4}\cdot (4 \cdot 1 \cdot p + 2 \cdot 2 \cdot p ) \cdot {1}/{2} = p\hspace{0.05cm}.$$
 +
 
 +
:The factor &nbsp;$1/2$&nbsp; takes into account that a quaternary symbol contains two binary symbols.
 +
 
 +
*In contrast,&nbsp; in the so-called &nbsp;"Gray coding"&nbsp; according to the table with green background,&nbsp; the mapping between the binary symbols and the quaternary symbols is chosen in such a way that each symbol error results in exactly one bit error. From this follows:
 +
 
 +
:$$p_{\rm B}  = {1}/{4}\cdot  (4 \cdot 1 \cdot p + 2 \cdot 1 \cdot p ) \cdot {1}/{2} =  {3}/{4} \cdot p\hspace{0.05cm}.$$
 +
}}<br>
 +
 
 +
 
 +
==Exercises for the chapter==
 +
<br>
 +
[[Aufgaben:Exercise_2.3:_Binary_Signal_and_Quaternary_Signal|Exercise 2.3: Binary Signal and Quaternary Signal]]
 +
 
 +
[[Aufgaben:Exercise_2.4:_Dualcode_and_Graycode|Exercise 2.4: Dual Code and Gray Code]]
  
 +
[[Aufgaben:Exercise_2.4Z:_Error_Probabilities_for_the_Octal_System|Exercise 2.4Z: Error Probabilities for the Octal System]]
  
 +
[[Aufgaben:Exercise_2.5:_Ternary_Signal_Transmission|Exercise 2.5: Ternary Signal Transmission]]
  
  
  
 
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Latest revision as of 15:01, 23 January 2023


Symbolwise coding vs. blockwise coding


In transmission coding,  a distinction is made between two fundamentally different methods:

Symbolwise coding

  • Here,  an encoder symbol  $c_\nu$  is generated with each incoming source symbol  $q_\nu$,  which can depend not only on the current symbol but also on previous symbols  $q_{\nu -1}$,  $q_{\nu -2}$, ...
  • It is typical for all transmission codes for symbolwise coding that the symbol duration  $T_c$  of the usually multilevel and redundant encoded signal  $c(t)$  corresponds to the bit duration  $T_q$  of the source signal,  which is assumed to be binary and redundancy-free.


Details can be found in the chapter  "Symbolwise Coding with Pseudo-Ternary Codes".


Blockwise coding

  • Here,  a block of  $m_q$  binary source symbols  $(M_q = 2)$  of bit duration  $T_q$  is assigned a one-to-one sequence of  $m_c$  encoder symbols from an alphabet with encoder symbol set size  $M_c \ge 2$. 
  • For the  symbol duration of an encoder symbol  then holds:
$$T_c = \frac{m_q}{m_c} \cdot T_q \hspace{0.05cm},$$
  • The  relative redundancy of a block code  is in general
$$r_c = 1- \frac{R_q}{R_c} = 1- \frac{T_c}{T_q} \cdot \frac{{\rm log_2}\hspace{0.05cm} (M_q)}{{\rm log_2} \hspace{0.05cm}(M_c)} = 1- \frac{T_c}{T_q \cdot {\rm log_2} \hspace{0.05cm}(M_c)}\hspace{0.05cm}.$$

More detailed information on the block codes can be found in the chapter  "Block Coding with 4B3T Codes".

$\text{Example 1:}$  For the  "pseudo-ternary codes"',  increasing the number of levels from  $M_q = 2$  to  $M_c = 3$  for the same symbol duration  $(T_c = T_q)$  adds a relative redundancy of  $r_c = 1 - 1/\log_2 \hspace{0.05cm} (3) \approx 37\%$. 

In contrast,  the so-called  "4B3T codes"  operate at block level with the code parameters  $m_q = 4$,  $M_q = 2$,  $m_c = 3$  and  $M_c = 3$  and have a relative redundancy of approx.  $16\%$.  Because of  ${T_c}/{T_q} = 4/3$,  the transmitted signal  $s(t)$  is lower in frequency here than in uncoded transmission, which reduces the expensive bandwidth and is also advantageous for many channels from a transmission point of view.



Quaternary signal with  $r_{\rm c} \equiv 0$  and ternary signal with  $r_{\rm c} \approx 0$


A special case of a block code is a  redundancy-free multilevel code

  • Starting from the redundancy-free binary source signal  $q(t)$  with bit duration  $T_q$, 
  • a  $M_c$–level encoded signal  $c(t)$  with symbol duration  $T_c = T_q \cdot \log_2 \hspace{0.05cm} (M_c)$  is generated.


Thus,  the relative redundancy is given by:

$$r_c = 1- \frac{T_c}{T_q \cdot {\rm log_2}\hspace{0.05cm} (M_c)} = 1- \frac{m_q}{m_c \cdot {\rm log_2} \hspace{0.05cm}(M_c)}\to 0 \hspace{0.05cm}.$$

Thereby holds:

  1. If  $M_c$  is a power to the base  $2$,  then  $m_q = \log_2 \hspace{0.05cm} (M_c)$  are combined into a single encoder symbol  $(m_c = 1)$.  In this case, the relative redundancy is actually  $r_c = 0$.
  2. If  $M_c$  is not a power of two,  a hundred percent redundancy-free block coding is not possible.  For example, if  $m_q = 3$  binary symbols are encoded by  $m_c = 2$  ternary symbols and  $T_c = 1.5 \cdot T_q$  is set,  a relative redundancy of  $r_c = 1-1.5/ \log_2 \hspace{0.05cm} (3) \approx 5\%$  remains.
  3. Encoding a block of  $128$  binary symbols with  $81$  ternary symbols results in a relative code redundancy of less than  $r_c = 0.3\%$.

To simplify the notation and to align the nomenclature with the "first main chapter",  we use in the following

  • the bit duration  $T_{\rm B} = T_q$  of the redundancy-free binary source signal,
  • the symbol duration  $T = T_c$  of the encoded signal and the transmitted signal, and
  • the number  $M = M_c$  of levels.


This results in the identical form for the transmitted signal as for the binary transmission,  but with different amplitude coefficients:

$$s(t) = \sum_{\nu = -\infty}^{+\infty} a_\nu \cdot g_s ( t - \nu \cdot T)\hspace{0.3cm}{\rm with}\hspace{0.3cm} a_\nu \in \{ a_1, \text{...} , a_\mu , \text{...} , a_{ M}\}\hspace{0.05cm}.$$
  • In principle,  the amplitude coefficients  $a_\nu$  can be assigned arbitrarily  – but uniquely –  to the encoder symbols  $c_\nu$.  It is convenient to choose equal distances between adjacent amplitude coefficients.
  • Thus,  for bipolar signaling  $(-1 \le a_\nu \le +1)$,  the following applies to the possible amplitude coefficients with index  $\mu = 1$, ... , $M$:
$$a_\mu = \frac{2\mu - M - 1}{M-1} \hspace{0.05cm}.$$
  • Independently of the level number  $M$  one obtains from this for the outer amplitude coefficients  $a_1 = -1$  and  $a_M = +1$.
  • For a ternary signal  $(M = 3)$,  the possible amplitude coefficients are  $-1$,  $0$  and  $+1$.
  • For a quaternary signal  $(M = 4)$,  the coefficients are  $-1$,  $-1/3$,  $+1/3$  and  $+1$.


$\text{Example 2:}$  The graphic above shows the quaternary redundancy-free transmitted signal  $s_4(t)$  with the possible amplitude coefficients  $\pm 1$  and  $\pm 1/3$,  which results from the binary source signal  $q(t)$  shown in the center.

Redundancy-free ternary and quaternary signal
  • Two binary symbols each are combined to a quaternary coefficient according to the table with red background. The symbol duration  $T$  of the signal  $s_4(t)$  is twice the bit duration  $T_{\rm B}$  $($previously:  $T_q)$  of the source signal.
  • If  $q(t)$  is redundancy-free, it also results in a redundancy-free quaternary signal, i.e., the possible amplitude coefficients  $\pm 1$  and  $\pm 1/3$  are equally probable and there are no statistical ties within the sequence  $⟨a_ν⟩$. 


The lower plot shows the $($almost$)$ redundancy-free ternary signal  $s_3(t)$  and the mapping of three binary symbols each to two ternary symbols.

  • The possible amplitude coefficients are  $-1$,  $0$  and  $+1$  and the symbol duration of the encoded signal  $T = 3/2 \cdot T_{\rm B}$.
  • It can be seen from the green mapping table that the coefficients  $+1$  and  $-1$  occur somewhat more frequently than the coefficient  $a_\nu = 0$.  This results in the above mentioned relative redundancy of  $5\%$.
  • However,  from the very short signal section  – only eight ternary symbols corresponding to twelve binary symbols –  this property is not apparent.



ACF and PSD of a multilevel signal


For a redundancy-free coded  $M$–level bipolar digital signal  $s(t)$,  the following holds for the  "discrete auto-correlation function"  $\rm (ACF)$  of the amplitude coefficients and for the corresponding  "power-spectral density"  $\rm (PSD)$:

$$\varphi_a(\lambda) = \left\{ \begin{array}{c} \frac{M+ 1}{3 \cdot (M-1)} \\ \\ 0 \\ \end{array} \right.\quad \begin{array}{*{1}c} {\rm{for}}\\ \\ {\rm{for}} \\ \end{array} \begin{array}{*{20}c}\lambda = 0, \\ \\ \lambda \ne 0 \\ \end{array} \hspace{0.9cm}\Rightarrow \hspace{0.9cm}{\it \Phi_a(f)} = \frac{M+ 1}{3 \cdot (M-1)}= {\rm const.}$$

Considering the spectral shaping by the basic transmission pulse  $g_s(t)$  with spectrum  $G_s(f)$,  we obtain:

$$\varphi_{s}(\tau) = \frac{M+ 1}{3 \cdot (M-1)} \cdot \varphi^{^{\bullet}}_{gs}(\tau) \hspace{0.4cm}\circ\!\!-\!\!\!-\!\!\!-\!\!\bullet \hspace{0.4cm} {\it \Phi}_{s}(f) = \frac{M+ 1}{3 \cdot (M-1)}\cdot |G_s(f)|^2 \hspace{0.05cm}.$$

One can see from these equations:

  • In the case of redundancy-free multilevel coding,  the shape of ACF and PSD is determined solely by the basic transmission pulse  $g_s(t)$. 
  • The magnitude of the ACF is lower than the redundancy-free binary signal by a factor  $\varphi_a(\lambda = 0) = {\rm E}\big[a_\nu^2\big] = (M + 1)/(3M-3)$  for the same shape.
  • This factor describes the lower signal power of the multilevel signal due to the  $M-2$  inner amplitude coefficients.  For  $M = 3$  this factor is equal to  $2/3$, for  $M = 4$  it is equal to  $5/9$.
  • However,  a fair comparison between binary and multilevel signal with the same information flow  (same equivalent bit rate)  should also take into account the different symbol durations.  This shows that a multilevel signal requires less bandwidth than the binary signal due to the narrower PSD when the same information is transmitted.

$\text{Example 3:}$  We assume a binary source with bit rate  $R_{\rm B} = 1 \ \rm Mbit/s$,  so that the bit duration  $T_{\rm B} = 1 \ \rm µ s$. 

Auto-correlation function and power-spectral density of binary and quaternary signal
  • For binary transmission  $(M = 2)$,  the symbol duration of the transmitted signal is  $T =T_{\rm B}$  and the auto-correlation function shown in blue in the left graph results for NRZ rectangular pulses (assuming  $s_0^2 = 10 \ \rm mW$).
  • For the quaternary system  $(M = 4)$,  the ACF is also triangular, but lower by a factor of  $5/9$  and twice as wide because of  $T = 2 \cdot T_{\rm B}$. 


The  $\rm sinc^2$–shaped power-spectral density in the binary case  (blue curve)  has the maximum value  ${\it \Phi}_{s}(f = 0) = 10^{-8} \ \rm W/Hz$  (area of the blue triangle)  for the signal parameters selected here.  The first zero point is at  $f = 1 \ \rm MHz$.

  • The PSD of the quaternary signal  (red curve)  is only half as wide and slightly higher.  Here:  ${\it \Phi}_{s}(f = 0) \approx 1.1 \cdot 10^{-8} \ \rm W/Hz$.
  • The value results from the area of the red triangle. 
    This is lower  $($factor  $0.55)$  and wider (factor $2$).



Error probability of a multilevel system


Eye diagrams for redundancy–free binary, ternary and quaternary signals

The diagram on the right shows the eye diagrams

  • of a binary transmission system  $(M = 2)$,
  • a ternary transmission system  $(M = 3)$ and
  • a quaternary transmission system  $(M = 4)$.


Here,  a cosine rolloff characteristic is assumed for the overall system  $H_{\rm S}(f) \cdot H_{\rm K}(f) \cdot H_{\rm E}(f)$  of transmitter, channel and receiver,  so that intersymbol interference does not play a role.  The rolloff factor is  $r= 0.5$.  The noise is assumed to be negligible.

The eye diagram is used to estimate intersymbol interference.  A detailed description follows in the section  "Definition and statements of the eye diagram".  However,  the following text should be understandable even without detailed knowledge.

It can be seen from the above diagrams:

  • In the  binary system   $(M = 2)$,  there is only one decision threshold:   $E_1 = 0$.  A transmission error occurs if the noise component  $d_{\rm N}(T_{\rm D})$  at the detection time is greater than  $+s_0$   $\big ($if  $d_{\rm S}(T_{\rm D}) = -s_0$ $\big )$  or  if  $d_{\rm N}(T_{\rm D})$  is less than  $-s_0$   $\big ($if  $d_{\rm S}(T_{\rm D}) = +s_0$ $\big )$.
  • In the case of the  ternary system  $(M = 3)$,  two eye openings and two decision thresholds  $E_1 = -s_0/2$  and  $E_2 = +s_0/2$  can be recognized.  The distance of the possible useful detection signal values  $d_{\rm S}(T_{\rm D})$  to the nearest threshold is  $-s_0/2$ in each case.  The outer amplitude values  $(d_{\rm S}(T_{\rm D}) = \pm s_0)$  can only be falsified in one direction in each case,  while  $d_{\rm S}(T_{\rm D}) = 0$  is limited by two thresholds.
  • Accordingly,  an amplitude coefficient  $a_\nu = 0$  is falsified twice as often compared to  $a_\nu = +1$  or  $a_\nu = -1$.  For AWGN noise with rms value  $\sigma_d$  as well as equal probability amplitude coefficients,  according to the section  "Definition of the bit error probability"  for the  "symbol error probability":
$$p_{\rm S} = { 1}/{3} \cdot \left[{\rm Q} \left( \frac{s_0/2}{\sigma_d}\right)+ 2 \cdot {\rm Q} \left( \frac{s_0/2}{\sigma_d}\right)+ {\rm Q} \left( \frac{s_0/2}{\sigma_d}\right)\right]= \frac{ 4}{3} \cdot {\rm Q} \left( \frac{s_0/2}{\sigma_d}\right)\hspace{0.05cm}.$$
  • Please note that this equation no longer specifies the bit error probability  $p_{\rm B}$, but the  "symbol error probability"  $p_{\rm S}$.  The corresponding a-posteriori parameters are  "bit error rate"  $\rm (BER)$  and  "symbol error rate"  $\rm (SER)$.  More details are given in the  "last section"  of this chapter.


For the quaternary system  $(M = 4)$  with the possible amplitude values  $\pm s_0$  and  $\pm s_0/3$, 

  • there are three eye-openings,  and
  • thus also three decision thresholds at  $E_1 = -2s_0/3$,  $E_2 = 0$  and  $E_3 = +2s_0/3$.


Taking into account the occurrence probabilities  $(1/4$  for equally probable symbols$)$  and the six possibilities of falsification (see arrows in the graph),  we obtain:

$$p_{\rm S} = { 6}/{4} \cdot {\rm Q} \left( \frac{s_0/3}{\sigma_d}\right)\hspace{0.05cm}.$$

$\text{Conclusion:}$  In general, the  symbol error probability  for  $M$–level digital signal transmission is:

$$p_{\rm S} = \frac{ 2 + 2 \cdot (M-2)}{M} \cdot {\rm Q} \left( \frac{s_0/(M-1)}{\sigma_d(M)}\right) = \frac{ 2 \cdot (M-1)}{M} \cdot {\rm Q} \left( \frac{s_0}{\sigma_d (M)\cdot (M-1)}\right)\hspace{0.05cm}.$$
  • The notation  $\sigma_d(M)$  is intended to make clear that the rms value of the noise component  $d_{\rm N}(t)$  depends significantly on the level number  $M$. 



Comparison between binary system and multilevel system


For this system comparison under fair conditions,  the following are assumed:

  • Let the equivalent bit rate  $R_{\rm B} = 1/T_{\rm B}$  be constant.  Depending on the level number  $M$,  the symbol duration of the encoded signal and the transmitted signal is thus:
$$T = T_{\rm B} \cdot {\rm log_2} (M) \hspace{0.05cm}.$$
  • The Nyquist condition is satisfied by a  "root–root characteristic"  with rolloff factor  $r$.  Furthermore,  no intersymbol interference occurs.  The detection noise power is:
$$\sigma_d^2 = \frac{N_0}{2T} \hspace{0.05cm}.$$
  • The comparison of the symbol error probabilities  $p_{\rm S}$  is performed for  "power limitation". The energy per bit for  $M$–level transmission is:
$$E_{\rm B} = \frac{M+ 1}{3 \cdot (M-1)} \cdot s_0^2 \cdot T_{\rm B} \hspace{0.05cm}.$$

Substituting these equations into the general result on the  "last section",  we obtain for the symbol error probability:

$$p_{\rm S} = \frac{ 2 \cdot (M-1)}{M} \cdot {\rm Q} \left( \sqrt{\frac{s_0^2 /(M-1)^2}{\sigma_d^2}}\right) = \frac{ 2 \cdot (M-1)}{M} \cdot {\rm Q} \left( \sqrt{\frac{3 \cdot {\rm log_2}\hspace{0.05cm} (M)}{M^2 -1}\cdot \frac{2 \cdot E_{\rm B}}{N_0}}\right)$$
Symbol error probability curves for different level numbers  $M$
$$\Rightarrow \hspace{0.3cm} p_{\rm S} = K_1 \cdot {\rm Q} \left( \sqrt{K_2\cdot \frac{2 \cdot E_{\rm B}}{N_0}}\right)\hspace{0.05cm}.$$

For  $M = 2$,  set  $K_1 = K_2 = 1$.  For larger level numbers,  one obtains for the symbol error probability that can be achieved with  $M$–level redundancy-free coding:

$$M = 3\text{:} \ \ K_1 = 1.333, \ K_2 = 0.594;\hspace{0.5cm}M = 4\text{:} \ \ K_1 = 1.500, \ K_2 = 0.400;$$
$$M = 5\text{:} \ \ K_1 = 1.600, \ K_2 = 0.290;\hspace{0.5cm}M = 6\text{:} \ \ K_1 = 1.666, \ K_2 = 0.221;$$
$$M = 7\text{:} \ \ K_1 = 1.714, \ K_2 = 0.175;\hspace{0.5cm}M = 8\text{:} \ \ K_1 = 1.750, \ K_2 = 0.143.$$

The graph summarizes the results for  $M$–level redundancy-free coding.

  • Plotted are the symbol error probabilities  $p_{\rm S}$  over the abscissa  $10 \cdot \lg \hspace{0.05cm}(E_{\rm B}/N_0)$.
  • All systems are optimal for the respective  $M$,  assuming the AWGN channel and power limitation.
  • Due to the double logarithmic representation chosen here, a  $K_2$ value smaller than  $1$  leads to a parallel shift of the error probability curve to the right.
  • If  $K_1 > 1$ applies, the curve shifts upwards compared to the binary system  $(K_1= 1)$. 


$\text{System comparison under the constraint of power limitation:}$  The above curves can be interpreted as follows:

  1. Regarding symbol error probability,  the binary system  $(M = 2)$  is superior to the multilevel systems.  Already with  $10 \cdot \lg \hspace{0.05cm}(E_{\rm B}/N_0) = 12 \ \rm dB$  one reaches  $p_{\rm S} <10^{-8}$.  For the quaternary system  $(M = 4)$,   $10 \cdot \lg \hspace{0.05cm}(E_{\rm B}/N_0) > 16 \ \rm dB$  must be spent to reach the same symbol error probability  $p_{\rm S} =10^{-8}$. 
  2. However,  this statement is valid only for distortion-free channel,  i.e., for  $H_{\rm K}(f)= 1$.  On the other hand,  for distorting transmission channels,  a higher-level system can provide a significant improvement because of the significantly smaller noise component of the detection signal  (after the equalizer).
  3. For the AWGN channel,  the only advantage of a higher-level transmission is the lower bandwidth requirement due to the smaller equivalent bit rate,  which plays only a minor role in baseband transmission in contrast to digital carrier frequency systems,  e.g.  "quadrature amplitude modulation"  $\rm (QAM)$.


$\text{System comparison under the peak limitation constraint:}$ 

  • With the constraint  "peak limitation",  the combination of rectangular  $g_s(t)$  and rectangular  $h_{\rm E}(t)$  leads to the optimum regardless of the level number  $M$. 
  • The loss of the multilevel system compared to the binary system is here even greater than with power limitation.
  • This can be seen from the factor  $K_2$  decreasing with  $M$,  for which then applies:
$$p_{\rm S} = K_1 \cdot {\rm Q} \left( \sqrt{K_2\cdot \frac{2 \cdot s_{\rm 0}^2 \cdot T}{N_0} }\right)\hspace{0.3cm}{\rm with}\hspace{0.3cm} K_2 = \frac{ {\rm log_2}\,(M)}{(M-1)^2} \hspace{0.05cm}.$$
  • The constant  $K_1$  is unchanged from the above specification for power limitation,  while  $K_2$  is smaller by a factor of  $3$: 
$$M = 3\text{:} \ \ K_1 = 1.333, \ K_2 = 0.198;\hspace{1cm}M = 4\text{:} \ \ K_1 = 1.500, \ K_2 = 0.133;$$
$$M = 5\text{:} \ \ K_1 = 1.600, \ K_2 = 0.097;\hspace{1cm}M = 6\text{:} \ \ K_1 = 1.666, \ K_2 = 0.074;$$
$$M = 7\text{:} \ \ K_1 = 1.714, \ K_2 = 0.058;\hspace{1cm}M = 8\text{:} \ \ K_1 = 1.750, \ K_2 = 0.048.$$


Symbol and bit error probability


In a multilevel transmission system,  one must distinguish between the  "symbol error probability"  and the  "bit error probability",  which are given here both as ensemble averages and as time averages:

Symbol error probability and bit error probability
  • The  symbol error probability  refers to the  $M$–level and possibly redundant sequences  $\langle c_\nu \rangle$  and  $\langle w_\nu \rangle$:
$$p_{\rm S} = \overline{{\rm Pr} (w_\nu \ne c_\nu)} = \lim_{N \to \infty} \frac{1}{N} \cdot \sum \limits^{N} _{\nu = 1} {\rm Pr} (w_\nu \ne c_\nu) \hspace{0.05cm}.$$
  • The  bit error probability  describes the falsifications with respect to the binary sequences  $\langle q_\nu \rangle$  and  $\langle v_\nu \rangle$  of source and sink:
$$p_{\rm B} = \overline{{\rm Pr} (v_\nu \ne q_\nu)} = \lim_{N \to \infty} \frac{1}{N} \cdot \sum \limits^{N} _{\nu = 1} {\rm Pr} (v_\nu \ne q_\nu) \hspace{0.05cm}.$$

The diagram illustrates these two definitions and is also valid for the next chapters.  The block  "encoder"  causes

  • in the present chapter a redundancy-free coding,
  • in the  "following chapter"  a blockwise transmission coding,  and finally
  • in the  "last chapter"  symbolwise coding with pseudo-ternary codes.


$\text{Conclusion:}$ 

  • For multilevel and/or coded transmission,  a distinction must be made between the bit error probability  $p_{\rm B}$  and the symbol error probability  $p_{\rm S}$.  Only in the case of the redundancy-free binary system does  $p_{\rm B} = p_{\rm S}$ apply.
  • In general,  the symbol error probability  $p_{\rm S}$  can be calculated somewhat more easily than the bit error probability  $p_{\rm B}$  for redundancy-containing multilevel systems.
  • However,  a comparison of systems with different level numbers  $M$  or different types of coding should always be based on the bit error probability  $p_{\rm B}$  for reasons of fairness.  The mapping between the source and encoder symbols must also be taken into account,  as shown in the following example.


$\text{Example 4:}$  We consider a quaternary transmission system whose transmission behavior can be characterized as follows  (see left sketch in the graphic):

  • The falsification probability to a neighboring symbol is  
$$p={\rm Q}\big [s_0/(3\sigma_d)\big ].$$
  • A falsification to a non-adjacent symbol is excluded.
  • The model considers the dual falsification possibilities of inner symbols.


For equally probable binary source symbols  $q_\nu$  the quaternary encoder symbols  $c_\nu$  also occur with equal probability.  Thus,  we obtain for the symbol error probability:

$$p_{\rm S} ={1}/{4}\cdot (2 \cdot p + 2 \cdot 2 \cdot p) = {3}/{2} \cdot p\hspace{0.05cm}.$$
Comparison of dual code and Gray code

To calculate the bit error probability,  one must also consider the mapping between the binary and the quaternary symbols:

  • In  "dual coding"  according to the table with yellow background,  one symbol error  $(w_\nu \ne c_\nu)$  can result in one or two bit errors  $(v_\nu \ne q_\nu)$.  Of the six falsification possibilities at the quaternary symbol level,  four result in one bit error each and only the two inner ones result in two bit errors.  It follows:
$$p_{\rm B} = {1}/{4}\cdot (4 \cdot 1 \cdot p + 2 \cdot 2 \cdot p ) \cdot {1}/{2} = p\hspace{0.05cm}.$$
The factor  $1/2$  takes into account that a quaternary symbol contains two binary symbols.
  • In contrast,  in the so-called  "Gray coding"  according to the table with green background,  the mapping between the binary symbols and the quaternary symbols is chosen in such a way that each symbol error results in exactly one bit error. From this follows:
$$p_{\rm B} = {1}/{4}\cdot (4 \cdot 1 \cdot p + 2 \cdot 1 \cdot p ) \cdot {1}/{2} = {3}/{4} \cdot p\hspace{0.05cm}.$$



Exercises for the chapter


Exercise 2.3: Binary Signal and Quaternary Signal

Exercise 2.4: Dual Code and Gray Code

Exercise 2.4Z: Error Probabilities for the Octal System

Exercise 2.5: Ternary Signal Transmission