Difference between revisions of "Channel Coding/Code Description with State and Trellis Diagram"

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{{Header
 
{{Header
|Untermenü=Faltungscodierung und geeignete Decoder
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|Untermenü=Convolutional Codes and Their Decoding
|Vorherige Seite=Algebraische und polynomische Beschreibung
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|Vorherige Seite=Algebraic and Polynomial Description
|Nächste Seite=Decodierung von Faltungscodes
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|Nächste Seite=Decoding of Convolutional Codes
 
}}
 
}}
  
== Zustandsdefinition für ein Speicherregister ==
+
== State definition for a memory register ==
 
<br>
 
<br>
Ein Faltungscodierer kann auch als Automat mit endlicher Anzahl von Zuständen aufgefasst werden. Die Zustandsanzahl ergibt sich aus der Zahl der Speicherelemente &nbsp; &#8658; &nbsp; Gedächtnis $m$ dabei zu $2^m$.<br>
+
A convolutional encoder can also be understood as an automaton with a finite number of states.&nbsp; This number results from the number&nbsp; $m$&nbsp; of memory elements to&nbsp; $2^m$.<br>
  
[[File:P ID2630 KC T 3 3 S1 v2.png|right|frame|Faltungscodierer mit $k = 1, n = 2, m = 2$|class=fit]]
+
In this chapter we mostly start from the drawn convolutional encoder,&nbsp; which is characterized by the following parameters:
 +
[[File:P ID2630 KC T 3 3 S1 v2.png|right|frame|Convolutional encoder with&nbsp; $k = 1, \ n = 2, \ m = 2$|class=fit]]
 +
*$k = 1, \ n = 2$ &nbsp; &#8658; &nbsp; code rate $R = 1/2$,<br>
  
In diesem Kapitel gehen wir meist vom gezeichneten Faltungscodierer aus, der durch folgende Kenngrößen charakterisiert wird:
+
*Memory&nbsp; $m = 2$ &nbsp; &#8658; &nbsp; influence length $\nu = m+1=3$,<br>
*$k = 1, \ n = 2$ &nbsp; &#8658; &nbsp; Coderate $R = 1/2$,<br>
 
  
*Gedächtnis $m = 2$ &nbsp; &#8658; &nbsp; Einflusslänge $\nu = 3$,<br>
+
*Transfer function matrix in octal form&nbsp; $(7, 5)$:
 
 
*Übertragungsfunktionsmatrix in Oktalform $(7, 5)$:
 
 
:$$\mathbf{G}(D) = (1 + D + D^2, \ 1 + D^2).$$
 
:$$\mathbf{G}(D) = (1 + D + D^2, \ 1 + D^2).$$
  
Die Codesequenz zum Zeitpunkt $i$ &nbsp; &#8658; &nbsp; $\underline{x}_i = (x_i^{(1)}, \ x_i^{(2)})$ hängt außer vom Informationsbit $u_i$ auch vom Inhalt $(u_{i-1}, \ u_{i-2})$ des Speichers ab.   
+
The encoded sequence&nbsp; $\underline{x}_i = (x_i^{(1)}, \ x_i^{(2)})$ &nbsp; at time&nbsp; $i$&nbsp; depends not only on the information bit&nbsp; $u_i$&nbsp; but also on the content&nbsp; $(u_{i-1}, \ u_{i-2})$&nbsp; of the memory.   
*Hierfür gibt es $2^m = 4$ Möglichkeiten, nämlich die Zustände $S_0, S_1, S_2$ und $S_3$.  
+
*There are &nbsp; $2^m = 4$ &nbsp; possibilities for this,&nbsp; namely the states&nbsp; $S_0, \ S_1, \ S_2,\ S_3$.
*Der Registerzustand $S_{\mu}$ sei dabei über den Index definiert:
+
 +
*Let the register state&nbsp; $S_{\mu}$&nbsp; be defined by the index
  
::<math>\mu =  u_{i-1} + 2 \cdot u_{i-2}\hspace{0.05cm}, \hspace{0.5cm}{\rm allgemein\hspace{-0.1cm}:}\hspace{0.15cm}
+
::<math>\mu =  u_{i-1} + 2 \cdot u_{i-2}\hspace{0.05cm}, \hspace{0.5cm}{\rm general\hspace{-0.1cm}:}\hspace{0.15cm}
 
\mu = \sum_{l = 1}^{m} \hspace{0.1cm}2\hspace{0.03cm}^{l-1} \cdot u_{i-l}
 
\mu = \sum_{l = 1}^{m} \hspace{0.1cm}2\hspace{0.03cm}^{l-1} \cdot u_{i-l}
 
\hspace{0.05cm}.</math>
 
\hspace{0.05cm}.</math>
  
Im Englischen verwendet man für &bdquo;Zustand&rdquo; den Begriff <i>State</i>. Deshalb ist auch im deutschen Text manchmal vom <i>Registerstatus</i> die Rede.<br>
+
To avoid confusion,&nbsp; we distinguish in the following by upper or lower case letters:
 
 
Um Verwechslungen zu vermeiden, unterscheiden wir im Weiteren durch Groß&ndash; bzw. Kleinbuchstaben:
 
*die möglichen Zustände $S_{\mu}$ mit den Indizes $0 &#8804; \mu &#8804; 2^m \,&ndash;1$,<br>
 
  
*die aktuellen Zustände $s_i$ zu den Zeitpunkten $i = 1, \ 2, \ 3, \ \text{...}$<br>
+
# &nbsp; the possible states&nbsp; $S_{\mu}$&nbsp; with the indices&nbsp; $0 &#8804; \mu &#8804; 2^m \,-1$,<br>
 +
# &nbsp; the current states&nbsp; $s_i$&nbsp; at the times&nbsp; $i = 1, \ 2, \ 3, \ \text{...}$<br>
  
  
 
{{GraueBox|TEXT=   
 
{{GraueBox|TEXT=   
$\text{Beispiel 1:}$&nbsp;  Die Grafik zeigt für den oben skizzierten  Faltungscodierer
+
$\text{Example 1:}$&nbsp;  The graph shows for the convolutional encoder sketched above
*die Informationssequenz $\underline{u} = (u_1,u_2, \text{...} \ ) $ &nbsp; &#8658; &nbsp; Informationsbits $u_i$,
+
[[File:EN_KC_T_3_3_S1b_v3.png|right|frame|To illustrate the states&nbsp; $S_{\mu}$ |class=fit]]
 +
<br>
 +
*the information sequence&nbsp; $\underline{u} = (u_1,u_2, \text{...} \ ) $ <br>&nbsp; &#8658; &nbsp; information bits&nbsp; $u_i$,
  
*die aktuellen Zustände zu den Zeitpunkten $i$ &nbsp; &#8658; &nbsp; $s_i &#8712; \{S_0, \ S_1, \ S_2, \ S_3\}$,<br>
+
*the current states at times&nbsp; $i$<br> &nbsp; &#8658; &nbsp; $s_i &#8712; \{S_0, \ S_1, \ S_2, \ S_3\}$,<br>
  
*die 2 Bit&ndash;Sequenzen $\underline{x}_i = (x_i^{(1)}, \ x_i^{(2)})$ &nbsp; &#8658; &nbsp; Codierung des Informationsbits $u_i$.<br>
+
*the 2&ndash;bit sequences&nbsp; $\underline{x}_i = (x_i^{(1)}, \ x_i^{(2)})$ <br>&nbsp; &#8658; &nbsp; encoding the information bit $u_i$.<br>
 
+
<br clear=all>
 
+
For example,&nbsp; you can see from this illustration&nbsp; $($the colors are to facilitate the transition to later graphics$)$:
[[File:P ID2631 KC T 3 3 S1b v1.png|center|frame|Zur Verdeutlichung der Registerzustände $S_{\mu}$|class=fit]]
 
 
 
Beispielsweise erkennt man aus dieser Darstellung (die Farben sollen den Übergang zu späteren Grafiken erleichtern):
 
 
 
*Zum Zeitpunkt $i = 5$ gilt $u_{i-1} = u_4 = 0$, $u_{i-2} = u_3 = 1$. Das heißt, der Automat befindet sich im Zustand $s_5 = S_2$. Mit dem Informationsbit $u_i = u_5 = 0$ erhält man die Codesequenz $\underline{x}_5 = (11)$.<br>
 
 
 
*Der Zustand für den Zeitpunkt $i = 6$ ergibt sich aus $u_{i-1} = u_5 = 0$ und $u_{i-2} = u_4 = 0$ zu $s_6 = S_0$. Wegen $u_6 = 0$ wird nun $\underline{x}_6 = (00)$ ausgegeben und der neue Zustand $s_7$ ist wiederum $S_0$.<br>
 
 
 
*Zum Zeitpunkt $i = 12$ wird wegen $u_{12} = 0$ wie zum Zeitpunkt $i = 5$ die Codesequenz $\underline{x}_{12} = (11)$ ausgegeben und man geht vom Zustand $s_{12} = S_2$ in den Zustand $s_{13} = S_0$ über.<br>
 
  
*Dagegen wird zum Zeitpunkt $i = 9$ die Codesequenz $\underline{x}_{9} = (00)$ ausgegeben und auf $s_9 = S_2$ folgt $s_{10} = S_1$. Gleiches gilt auch für $i = 15$.  In beiden Fällen lautet das aktuelle Informationsbit $u_i = 1$.}}<br>
+
# &nbsp; At time&nbsp; $i = 5$ &nbsp; &rArr; &nbsp; $u_{i-1} = u_4 = 0$,&nbsp; $u_{i-2} = u_3 = 1$&nbsp; holds.&nbsp; That is,&nbsp; the automat is in state&nbsp; $s_5 = S_2$.&nbsp;
 +
# &nbsp; With the information bit&nbsp; $u_i = u_5 = 0$,&nbsp; the encoded sequence&nbsp; $\underline{x}_5 = (11)$&nbsp; is obtained.<br>
 +
# &nbsp; The state for time&nbsp; $i = 6$&nbsp; results from&nbsp; $u_{i-1} = u_5 = 0$&nbsp; and&nbsp; $u_{i-2} = u_4 = 0$&nbsp; to&nbsp; $s_6 = S_0$.
 +
# &nbsp;  Because of&nbsp; $u_6 = 0$ &nbsp; &rArr; &nbsp; $\underline{x}_6 = (00)$&nbsp; is output and the new state&nbsp; $s_7$&nbsp; is again&nbsp; $S_0$.<br>
 +
# &nbsp; At time&nbsp; $i = 12$&nbsp; the encoded sequence&nbsp; $\underline{x}_{12} = (11)$&nbsp; is output because of&nbsp; $u_{12} = 0$&nbsp; as at time&nbsp; $i = 5$.&nbsp;
 +
# &nbsp; Here,&nbsp; one passes from state&nbsp; $s_{12} = S_2$&nbsp; to state&nbsp; $s_{13} = S_0$&nbsp;.<br>
 +
# &nbsp; In contrast,&nbsp; at time&nbsp; $i = 9$&nbsp; the encoded sequence&nbsp; $\underline{x}_{9} = (00)$&nbsp; is output and state&nbsp; $s_9 = S_2$&nbsp; is followed by&nbsp;  $s_{10} = S_1$.  
 +
# &nbsp; The same is true for&nbsp; $i = 15$.&nbsp; In both cases,&nbsp; the current information bit is&nbsp; $u_i = 1$.}}<br>
  
 
{{BlaueBox|TEXT=   
 
{{BlaueBox|TEXT=   
$\text{Fazit:}$&nbsp;  Aus diesem Beispiel ist zu erkennen, dass die Codesequenz $\underline{x}_i$ zum Zeitpunkt $i$ allein abhängt
+
$\text{Conclusion:}$&nbsp;  From this example it can be seen that the encoded sequence&nbsp; $\underline{x}_i$&nbsp; at time&nbsp; $i$&nbsp; depends solely on
*vom aktuellen Zustand $s_i = S_{\mu} \ \ (0 &#8804; \mu &#8804; 2^m \, &ndash;1)$, sowie<br>
+
# &nbsp; the current state&nbsp; $s_i = S_{\mu} \ (0 &#8804; \mu &#8804; 2^m -1)$, as well as<br>
*vom aktuellen Informationsbit $u_i$.<br><br>
+
# &nbsp; the current information bit&nbsp; $u_i$.<br><br>
  
Ebenso wird der Nachfolgezustand $s_{i+1}$ allein durch $s_i$ und $u_i$ bestimmt.  
+
*Similarly,&nbsp; the successor state&nbsp; $s_{i+1}$&nbsp; is determined by&nbsp; $s_i$&nbsp; and&nbsp; $u_i$&nbsp; alone.  
  
Diese Eigenschaften werden im so genannten  <i>Zustandsübergangsdiagramm</i> auf der nächsten Seite berücksichtigt.}}<br>
+
*These properties are considered in the so-called&nbsp; "state transition diagram"&nbsp; in the next section.}}<br>
  
== Darstellung im Zustandsübergangsdiagramm ==
+
== Representation in the state transition diagram ==
 
<br>
 
<br>
Die Grafik zeigt das <b>Zustandsübergangsdiagramm</b> (englisch: <i>State Transition Diagram</i>) für unseren '''&bdquo;Standard&ndash;Codierer&rdquo;'''.
+
The graph shows the state transition diagram for the&nbsp; $(n = 2, \ k = 1, \ m = 2)$&nbsp; convolutional encoder.
*Dieses liefert alle Informationen über den $(n = 2, \ k = 1, \ m = 2)$&ndash;Faltungscodierer in kompakter Form.  
+
[[File:EN_KC_T_3_3_S2_v3.png|right|frame|State transition diagram&nbsp; $\rm A$&nbsp; for the&nbsp; $(n = 2, \ k = 1, \ m = 2)$&nbsp; convolutional encoder; <br> &nbsp; &nbsp; &nbsp; in the following:&nbsp; "our standard convolutional encoder" |class=fit]]
*Die Farbgebung ist mit der [[Kanalcodierung/Codebeschreibung_mit_Zustands%E2%80%93_und_Trellisdiagramm#Zustandsdefinition_f.C3.BCr_ein_Speicherregister| sequenziellen Darstellung]] auf der vorherigen Seite abgestimmt.  
+
*Der Vollständigkeit halber ist auch die Herleitungstabelle nochmals angegeben.<br>
+
# &nbsp;This diagram  provides all information about this special convolutional encoder in compact form.  
 +
# &nbsp;The color scheme is aligned with the&nbsp; [[Channel_Coding/Code_Description_with_State_and_Trellis_Diagram#State_definition_for_a_memory_register|$\text{sequential representation}$]]&nbsp; in the previous section.  
 +
# &nbsp;For the sake of completeness,&nbsp; the derivation table is also given again.<br>
 +
# &nbsp;The&nbsp; $2^{m+k}$&nbsp; transitions are labeled&nbsp; "$u_i \ | \ \underline{x}_i$".
  
  
[[File:P ID3022 KC T 3 3 S2 v2.png|center|frame|Zustandsübertragungsdiagramm $\rm A$ für $n = 2, \ k = 1, \ m = 2$|class=fit]]
+
For example,&nbsp; it can be read:
 +
*The information bit &nbsp; $u_i = 0$ &nbsp; $($indicated by a red label$)$&nbsp; takes you from state &nbsp; $s_i = S_1$ &nbsp; to state &nbsp; $s_{i+1} = S_2$ &nbsp; and the two code bits are &nbsp; $x_i^{(1)} = 1, \ x_i^{(2)} = 0$.<br>
  
Die $2^{m+k}$ Übergänge sind mit &bdquo;$u_i \ | \ \underline{x}_i$&rdquo; beschriftet. Beispielsweise ist abzulesen:
+
*With the information bit &nbsp; $u_i = 1$ &nbsp; $($blue label$)$&nbsp; in the state &nbsp; $s_i = S_1$ &nbsp;  the code bits result in &nbsp; $x_i^{(1)} = 0, \ x_i^{(2)} = 1$,&nbsp; and one arrives at the new state&nbsp; $s_{i+1} = S_3$.<br><br>
*Durch das Informationsbit $u_i = 0$ (gekennzeichnet durch eine rote Beschriftung) gelangt man vom Zustand $s_i = S_1$ zum Zustand $s_{i+1} = S_2$ und die beiden Codebits lauten $x_i^{(1)} = 1, x_i^{(2)} = 0$.<br>
 
  
*Mit dem Informationsbit $u_i = 1$ (blaue Beschriftung) im Zustand $s_i = S_1$ ergeben sich dagegen die Codebits zu $x_i^{(1)} = 0, \ x_i^{(2)} = 1$, und man kommt zum neuen Zustand $s_{i+1} = S_3$.<br><br>
 
  
Betrachten wir nun einen weiteren systematischen Code, ebenfalls mit den Kenngrößen $n = 2, \ k = 1, \ m = 2$. Es handelt sich hierbei um die [[Kanalcodierung/Algebraische_und_polynomische_Beschreibung#.C3.84quivalenter_systematischer_Faltungscode|äquivalente systematische Repräsentation]] des oberen Codierers. Man bezeichnet diesen auch als '''RSC&ndash;Codierer''' (englisch: <i>Recursive Systematic Convolutional Encoder</i>).<br>
+
[[File:P ID2680 KC T 3 3 S2b v3.png|right|frame|State transition diagram&nbsp; $\rm B$&nbsp; for another&nbsp; $(n = 2, \ k = 1, \ m = 2)$&nbsp; convolutional encoder; <br> &nbsp; &nbsp; &nbsp; in the following:&nbsp; "equivalent systematic representation"|class=fit]]
 +
We now consider another systematic encoder with same parameters:
 +
::$$n = 2, \ k = 1, \ m = 2.$$
  
[[File:P ID2680 KC T 3 3 S2b v3.png|center|frame|Zustandsübertragungsdiagramm $\rm B$ für $n = 2, \ k = 1, \ m = 2$|class=fit]]
+
This is the&nbsp; [[Channel_Coding/Algebraic_and_Polynomial_Description#Equivalent_systematic_convolutional_code|$\text{equivalent systematic representation}$]]&nbsp; of our standard convolutional encoder,&nbsp; also referred to as&nbsp; "recursive systematic convolutional encoder".
  
Gegenüber dem oberen Zustandsübergangsdiagramm erkennt man folgende Unterschiede:
+
Compared to the upper state transition diagram&nbsp; $\rm A$,&nbsp; one can see the following differences:
*Da die früheren Informationsbits $u_{i-1}$ und $u_{i-2}$ nicht abgespeichert werden, beziehen sich hier die Zustände $s_i = S_{\mu}$ auf die verarbeiteten Größen $w_{i-1}$ und $w_{i-2}$, wobei $w_i = u_i + w_{i-1} + w_{i-2}$ gilt.<br>
+
*Since the earlier information bits&nbsp; $u_{i-1}$&nbsp; and&nbsp; $u_{i-2}$&nbsp; are not stored, here the states&nbsp; $s_i = S_{\mu}$&nbsp; are related to the processed quantities&nbsp; $w_{i-1}$&nbsp; and&nbsp; $w_{i-2}$, where&nbsp; $w_i = u_i + w_{i-1} + w_{i-2}$&nbsp; holds.<br>
 
 
*Da dieser Code ebenfalls systematisch ist, gilt wieder $x_i^{(1)} = u_i$. Die Herleitung der zweiten Codebits $x_i^{(2)}$ finden Sie in der [[Aufgaben:3.5_Rekursive_Filter_f%C3%BCr_GF(2)|Aufgabe 3.5]]. Es handelt sich um ein rekursives Filter, wie im Abschnitt [[Kanalcodierung/Algebraische_und_polynomische_Beschreibung#Filterstruktur_bei_gebrochen.E2.80.93rationaler_.C3.9Cbertragungsfunktion| Filterstruktur bei gebrochen&ndash;rationaler Übertragungsfunktion]] beschrieben.<br><br>
 
  
 +
*Since this code is also systematic &nbsp; &rArr; &nbsp; $x_i^{(1)} = u_i$.&nbsp; The derivation of the second code bits&nbsp; $x_i^{(2)}$&nbsp; can be found in&nbsp; [[Aufgaben:Exercise_3.5:_Recursive_Filters_for_GF(2)|"Exercise 3.5"]].&nbsp; It is a recursive filter,&nbsp; as described in the&nbsp; [[Channel_Coding/Algebraic_and_Polynomial_Description#Filter_structure_with_fractional.E2.80.93rational_transfer_function| "Filter structure with fractional&ndash;rational transfer function"]]&nbsp; section.<br><br>
 +
<br clear=all>
 
{{BlaueBox|TEXT=   
 
{{BlaueBox|TEXT=   
$\text{Fazit:}$&nbsp;  Der Bildervergleich zeigt, dass sich für beide Codierer ein ähnliches Zustandsübergangsdiagramm ergibt:
+
$\text{Conclusion:}$&nbsp;  The comparison of the graphics shows that a similar state transition diagram is obtained for both encoders:
 
 
*Die Struktur des Zustandsübergangsdiagramms ist allein durch die Parameter $m$ und $k$ festgelegt.
 
  
*Die Anzahl der Zustände ist $2^{m \hspace{0.05cm}\cdot \hspace{0.05cm}k}$.<br>
+
*The structure of the state transition diagram is determined solely by the parameters&nbsp; $m$&nbsp; and&nbsp; $k$&nbsp;.
  
*Von jedem Zustand gehen $2^k$ Pfeile ab.<br>
+
*The number of states is&nbsp; $2^{m \hspace{0.05cm}\cdot \hspace{0.05cm}k}$&nbsp; and&nbsp; $2^k$&nbsp; arrows go from each state.<br>
  
*Man gelangt auch von jedem Zustand $s_i &#8712; \{S_0, \ S_1, \ S_2, \ S_3\}$ zu den gleichen Nachfolgezuständen $s_{i+1}$.<br>
+
*You also get from each state&nbsp; $s_i &#8712; \{S_0, \ S_1, \ S_2, \ S_3\}$&nbsp; to the same successor states&nbsp; $s_{i+1}$.<br>
  
*Ein Unterschied besteht allein hinsichtlich der ausgegebenen Codesequenzen, wobei in beiden Fällen  $\underline{x}_i &#8712; \{00, 01, 10, 11\}$ gilt.}}<br><br>
+
*A difference exists solely with respect to the encoded sequences output,&nbsp; where in both cases&nbsp; $\underline{x}_i &#8712; \{00, \ 01, \ 10, \ 11\}$&nbsp; applies.}}<br><br>
  
==  Darstellung im Trellisdiagramm ==
+
==  Representation in the trellis diagram ==
 
<br>
 
<br>
Man kommt vom Zustandsübergangsdiagramm zum so genannten <i>Trellisdiagramm</i> (oder kurz: '''Trellis'''), indem man zusätzlich eine Zeitkomponente &nbsp; &#8658; &nbsp; Laufvariable $i$ berücksichtigt. Die folgende Grafik stellt beide Diagramme für unseren &bdquo;Standard&ndash;Codierer&rdquo; $(n = 2, \ k = 1, \ m = 2)$ gegenüber.<br>
+
One gets from the state transition diagram to the so-called&nbsp; "trellis diagram"&nbsp; $($short: &nbsp;$\text{trellis)}$&nbsp; by additionally considering a time component &nbsp; &#8658; &nbsp; control variable&nbsp; $i$.&nbsp; The following graph contrasts both diagrams for&nbsp; "our standard convolutional encoder".&nbsp; The bottom illustration has a resemblance to a&nbsp; "garden trellis" &ndash; assuming some imagination.  
 
 
[[File:P ID2635 KC T 3 3 S3 v2.png|center|frame|Zustandsübergangsdiagramm vs. Trellisdiagramm $(n = 2, \ k = 1, \ m = 2)$|class=fit]]
 
 
 
Die untere Darstellung hat Ähnlichkeit mit einem Gartenspalier &ndash; etwas Phantasie vorausgesetzt. Die englische Übersetzung hierfür ist &bdquo;Trellis&rdquo;. Weiter ist anhand dieser Grafik zu erkennen:
 
*Da alle Speicherregister mit Nullen vorbelegt sind, startet das Trellis stets vom Zustand $s_1 = S_0$. Zum nächsten Zeitpunkt $(i = 2)$ sind dann nur die beiden (Start&ndash;)Zustände $S_0$ und $S_1$ möglich.<br>
 
 
 
*Ab dem Zeitpunkt $i = m + 1 = 3$ hat das Trellis für jeden Übergang von $s_i$ nach $s_{i+1}$ genau das gleiche Aussehen. Jeder Zustand $S_{\mu}$ ist durch einen roten Pfeil $(u_i = 0)$ und einen blauen Pfeil $(u_i = 1)$ mit einem Nachfolgezustand verbunden.<br>
 
  
*Gegenüber einem <i>Codebaum</i>, der mit jedem Zeitschritt $i$ exponentiell anwächst &ndash; siehe zum Beispiel Abschnitt [[Digitalsignalübertragung/Viterbi–Empfänger#Fehlergr.C3.B6.C3.9Fen_und_Gesamtfehlergr.C3.B6.C3.9Fen| Fehlergrößen und Gesamtfehlergrößen]] im Buch &bdquo;Digitalsignalübertragung&rdquo; &ndash; ist hier die Zahl der Knoten (also der möglichen Zustände) auf $2^m$ begrenzt.<br>
+
[[File:P ID2635 KC T 3 3 S3 v2.png|right|frame|State transition diagram vs. trellis diagram for&nbsp;  "our standard convolutional encoder"|class=fit]]
  
*Diese erfreuliche Eigenschaft eines jeden Trellisdiagramms nutzt auch der [[Kanalcodierung/Decodierung_von_Faltungscodes| Viterbi&ndash;Algorithmus]] zur effizienten Maximum&ndash;Likelihood&ndash;Decodierung von Faltungscodes.<br><br>
+
Further is to be recognized on the basis of this diagram:
 +
# &nbsp; Since all memory registers are preallocated with zeros,&nbsp; the trellis always starts from the state&nbsp; $s_1 = S_0$.&nbsp; At the next time&nbsp; $(i = 2)$&nbsp; only the two states&nbsp; $S_0$&nbsp; and&nbsp; $S_1$&nbsp; are possible.<br>
 +
# &nbsp; From time&nbsp; $i = m + 1 = 3$&nbsp; the trellis has exactly the same appearance for each transition from&nbsp; $s_i$&nbsp; to&nbsp; $s_{i+1}$.&nbsp; Each state&nbsp; $S_{\mu}$&nbsp; is connected to a successor state by a red arrow&nbsp; $(u_i = 0)$&nbsp; and a blue arrow&nbsp; $(u_i = 1)$.<br>
 +
# &nbsp; Versus a&nbsp; "code tree"&nbsp;  that grows exponentially with each time step&nbsp; $i$ &nbsp; &ndash; see for example section&nbsp; [[Digital_Signal_Transmission/Viterbi_Receiver#Metric_and_accumulated_metric| "Error sizes and total error sizes"]] &nbsp; in the book&nbsp; "Digital Signal Transmission" &ndash;&nbsp; here the number of nodes&nbsp; $($i.e. possible states$)$&nbsp; is limited to&nbsp; $2^m$&nbsp;.<br>
 +
# &nbsp; This pleasing property of any trellis diagram is also used by the&nbsp; [[Channel_Coding/Decoding_of_Convolutional_Codes|$\text{Viterbi algorithm}$]]&nbsp; for efficient maximum likelihood decoding of convolutional codes.<br><br>
  
Das folgende Beispiel soll zeigen, dass zwischen der Aneinanderreihung der Codesequenzen $\underline{x}_i$ und den Pfaden durch das Trellisdiagramm eine $1\text{:}1$&ndash;Zuordnung besteht.  
+
The following example is to show that there is a&nbsp; "$1\text{:}1$"&nbsp;  mapping between the string of encoded sequences&nbsp; $\underline{x}_i$&nbsp; and the paths through the trellis diagram.  
*Auch die Informationssequenz $\underline{u}$ ist aus dem ausgewählten Trellispfad anhand der Farben der einzelnen Zweige ablesbar.  
+
*Also the information sequence&nbsp; $\underline{u}$&nbsp; can be read from the selected trellis path based on the colors of the individual branches.
*Ein roter Zweig steht für das Informationsbit $u_i = 0$, ein blauer für $u_i = 1$.<br>
+
 +
*A red branch stands for the information bit&nbsp; $u_i = 0$, &nbsp;  a blue one for&nbsp; $u_i = 1$.<br>
  
  
 
{{GraueBox|TEXT=   
 
{{GraueBox|TEXT=   
$\text{Beispiel 2:}$&nbsp;  Im [[Kanalcodierung/Codebeschreibung_mit_Zustands–_und_Trellisdiagramm#Zustandsdefinition_f.C3.BCr_ein_Speicherregister|$\text{Beispiel 1}$]] wurde für unseren Rate&ndash;$1/2$&ndash;Standardcodierer mit Gedächtnis $m = 2$ sowie die Informationssequenz $\underline{u} = (1, 1, 1, 0, 0, 0, 1, 0, 1, \ \text{...})$ die Codesequenz $\underline{x}$ hergeleitet, die hier für $i &#8804; 9$ nochmals angegeben wird.<br>
+
$\text{Example 2:}$&nbsp;  In the former&nbsp; [[Channel_Coding/Code_Description_with_State_and_Trellis_Diagram#State_definition_for_a_memory_register|$\text{Example 1}$]]&nbsp; the encoded sequence&nbsp; $\underline{x}$&nbsp; was derived
 
 
[[File:P ID2636 KC T 3 3 S3b v1.png|center|frame|Trellisdiagramm einer Beispielssequenz|class=fit]]
 
  
Darunter gezeichnet ist das Trellisdiagramm. Man erkennt:
+
*for our rate&nbsp; $1/2$&nbsp; standard convolutional encoder with memory&nbsp; $m = 2$&nbsp; and
*Der ausgewählte Pfad durch das Trellis ergibt sich durch die Aneinanderreihung roter und blauer Pfeile, die für die möglichen Informationsbits $u_i \in \{ 0, \ 1\}$ stehen. Diese Aussage gilt für jeden Rate&ndash;$1/n$&ndash;Faltungscode. Bei einem Code mit $k > 1$ gäbe es $2^k$ verschiedenfarbige Pfeile.<br>
+
 +
*the information sequence&nbsp; $\underline{u} = (1, 1, 1, 0, 0, 0, 1, 0, 1, \ \text{. ..})$
 +
[[File:EN_KC_T_3_3_S3b_v3.png|right|frame|Trellis diagram of a sample sequence|class=fit]]
  
*Bei einem Rate&ndash;$1/n$&ndash;Faltungscode sind die Pfeile mit den Codeworten $\underline{x}_i = (x_i^{(1)}, \ \text{...} \ , \ x_i^{(n)})$ beschriftet, die sich aus dem Informationsbit $u_i$ und den aktuellen Registerzuständen $s_i$ ergeben. Für $n = 2$ gibt es nur vier mögliche Codeworte, nämlich $00, 01, 10$ und $11$.<br>
 
  
*In vertikaler Richtung erkennt man aus dem Trellis die Registerzustände $S_{\mu}$. Bei einem Rate&ndash;$k/n$&ndash;Faltungscode mit der Gedächtnisordnung $m$ gibt es $2^{k \hspace{0.05cm}\cdot \hspace{0.05cm}m}$ verschiedene Zustände. Im vorliegenden Beispiel $(k = 1, \ m = 2)$ sind dies die Zustände $S_0, \ S_1, \ S_2$ und $S_3$.}}<br>
+
The table on the right shows the result for&nbsp; $i &#8804; 9$&nbsp; once again.&nbsp; The trellis diagram is drawn below.&nbsp; You can see:
 +
# &nbsp; The selected path through the trellis is obtained by lining up red and blue arrows representing the possible information bits&nbsp; $u_i \in \{ 0, \ 1\}$&nbsp;.
 +
# &nbsp; This statement is true for any rate&nbsp;  $1/n$&nbsp;  convolutional code. For a code with&nbsp; $k > 1$&nbsp; there would be&nbsp; $2^k$&nbsp; different colored arrows.<br>
 +
# &nbsp; For a rate&nbsp; $1/n$&nbsp; convolutional code,&nbsp; the arrows are labeled with the code words&nbsp; $\underline{x}_i = (x_i^{(1)}, \ \text{...} \ , \ x_i^{(n)})$&nbsp; which are derived from the information bit&nbsp; $u_i$&nbsp; and the current register states&nbsp; $s_i$.
 +
# &nbsp; For&nbsp; $n = 2$&nbsp; there are only four possible code words,&nbsp; namely&nbsp; $00, \ 01, \ 10$&nbsp; and&nbsp; $11$.<br>
 +
# &nbsp; In vertical direction,&nbsp; one recognizes from the trellis the register states&nbsp; $S_{\mu}$.&nbsp; Given a rate $k/n$ convolutional code with memory order&nbsp; $m$&nbsp; there are&nbsp; $2^{k \hspace{0.05cm}\cdot \hspace{0.05cm}m}$&nbsp; different states.  
 +
# &nbsp; In the present example&nbsp; $(k = 1, \ m = 2)$&nbsp; these are the states&nbsp; $S_0, \ S_1, \ S_2$ and $S_3$.}}<br>
  
== Definition der freien Distanz ==
+
== Definition of the free distance ==
 
<br>
 
<br>
Eine wichtige Kenngröße der linearen Blockcodes ist die [[Kanalcodierung/Zielsetzung_der_Kanalcodierung#Einige_wichtige_Definitionen_zur_Blockcodierung| ''minimale Hamming&ndash;Distanz'']] '''zwischen zwei beliebigen Codeworten''' $\underline{x}$ und $\underline{x}\hspace{0.05cm}'$:
+
An important parameter of linear block codes is the&nbsp; [[Channel_Coding/Objective_of_Channel_Coding#Important_definitions_for_block_coding|$\text{minimum Hamming distance}$]]&nbsp; '''between any two code words'''&nbsp; $\underline{x}$&nbsp; and&nbsp; $\underline{x}\hspace{0.05cm}'$:
  
 
::<math>d_{\rm min}(\mathcal{C}) =
 
::<math>d_{\rm min}(\mathcal{C}) =
 
\min_{\substack{\underline{x},\hspace{0.05cm}\underline{x}' \hspace{0.05cm}\in \hspace{0.05cm} \mathcal{C} \\ {\underline{x}} \hspace{0.05cm}\ne \hspace{0.05cm} \underline{x}\hspace{0.03cm}'}}\hspace{0.1cm}d_{\rm H}(\underline{x}, \hspace{0.05cm}\underline{x}\hspace{0.03cm}')\hspace{0.05cm}.</math>
 
\min_{\substack{\underline{x},\hspace{0.05cm}\underline{x}' \hspace{0.05cm}\in \hspace{0.05cm} \mathcal{C} \\ {\underline{x}} \hspace{0.05cm}\ne \hspace{0.05cm} \underline{x}\hspace{0.03cm}'}}\hspace{0.1cm}d_{\rm H}(\underline{x}, \hspace{0.05cm}\underline{x}\hspace{0.03cm}')\hspace{0.05cm}.</math>
  
*Aufgrund der Linearität gehört  zu jedem Blockcode auch das Nullwort $\underline{0}$. Damit ist $d_{\rm min}$ identisch mit dem minimalen [[Kanalcodierung/Zielsetzung_der_Kanalcodierung#Einige_wichtige_Definitionen_zur_Blockcodierung| Hamming&ndash;Gewicht]] $w_{\rm H}(\underline{x})$ eines Codewortes $\underline{x} &ne; \underline{0}$.<br>
+
*Due to linearity,&nbsp; the zero word &nbsp; $\underline{0}$ &nbsp; also belongs to each block code.&nbsp; Thus&nbsp; $d_{\rm min}$&nbsp; is identical to the minimum&nbsp; [[Channel_Coding/Objective_of_Channel_Coding#Important_definitions_for_block_coding|$\text{Hamming weight}$]]&nbsp; $w_{\rm H}(\underline{x})$&nbsp; of a code word&nbsp; $\underline{x} &ne; \underline{0}$.<br>
  
*Bei Faltungscodes erweist sich allerdings die Beschreibung der Distanzverhältnisse als wesentlich aufwändiger, da ein Faltungscode aus unendlich langen und unendlich vielen Codesequenzen besteht. Deshalb definieren wir hier anstelle der minimalen Hamming&ndash;Distanz:
+
*For convolutional codes,&nbsp; however,&nbsp; the description of the distance ratios proves to be much more complex,&nbsp; since a convolutional code consists of infinitely long and infinitely many encoded sequences.&nbsp; Therefore we define here instead of the minimum Hamming distance:
  
  
 
{{BlaueBox|TEXT=   
 
{{BlaueBox|TEXT=   
 
$\text{Definition:}$&nbsp;   
 
$\text{Definition:}$&nbsp;   
*Die <b>freie Distanz</b> $d_{\rm F}$ eines Faltungscodes ist gleich der Anzahl der Bits, in dem sich zwei beliebige Codesequenzen $\underline{x}$ und $\underline{x}\hspace{0.03cm}'$ (mindestens) unterscheiden.  
+
*The&nbsp; &raquo;<b>free distance</b>&laquo; &nbsp; $d_{\rm F}$&nbsp; of a convolutional code is equal to the number of bits in which any two encoded sequences &nbsp; $\underline{x}$ &nbsp; and &nbsp; $\underline{x}\hspace{0.03cm}' $&nbsp; differ&nbsp; $($at least$)$.
*Anders ausgedrückt: Die freie Distanz ist gleich der ''minimalen'' Hamming&ndash;Distanz '''zwischen zwei beliebigen Pfaden''' durch das Trellis.}}<br>
+
 +
*In other words: &nbsp; The free distance is equal to the minimum Hamming distance&nbsp; '''between any two paths'''&nbsp; through the trellis.}}
 +
 
  
Da Faltungscodes ebenfalls linear sind, kann man auch hier als Bezugssequenz die unendlich lange Nullsequenz heranziehen: &nbsp; $\underline{x}\hspace{0.03cm}' = \underline{0}$. Damit ist die freie Distanz $d_{\rm F}$ gleich dem minimalen Hamming&ndash;Gewicht (Anzahl der Einsen) einer Codesequenz $\underline{x} &ne; \underline{0}$.<br>
+
Since convolutional codes are linear,&nbsp; we can also use the infinite zero sequence as a reference sequence: &nbsp; $\underline{x}\hspace{0.03cm}' = \underline{0}$.&nbsp; Thus,&nbsp; the free distance&nbsp; $d_{\rm F}$&nbsp; is equal to the minimum Hamming weight&nbsp; $($number of&nbsp; "ones"$)$&nbsp; of a encoded sequence&nbsp; $\underline{x} &ne; \underline{0}$.<br>
  
 
{{GraueBox|TEXT=   
 
{{GraueBox|TEXT=   
$\text{Beispiel 3:}$&nbsp;   Wir betrachten die Nullsequenz $\underline{0}$ (mit weiß gefüllten Kreisen markiert) sowie zwei andere Codesequenzen $\underline{x}$ sowie $\underline{x}\hspace{0.03cm}'$ (mit gelber bzw. dunkler Hinterlegung) in unserem Standard&ndash;Trellis und charakterisieren diese Sequenzen anhand der Zustandsfolgen:
+
$\text{Example 3:}$&nbsp; We consider the null sequence&nbsp; $\underline{0}$&nbsp; (marked with white filled circles) as well as two other encoded sequences&nbsp; $\underline{x}$&nbsp; and&nbsp; $\underline{x}\hspace{0.03cm}'$&nbsp; (with yellow and dark background, respectively) in our standard trellis and characterize these sequences based on the state sequences:
 +
[[File:P ID2638 KC T 3 3 S4b v2.png|right|frame|On the definition of free distance|class=fit]]
 +
 
 +
:$$\underline{0} =\left ( S_0 \rightarrow S_0 \rightarrow S_0\rightarrow S_0\rightarrow S_0\rightarrow \hspace{0.05cm}\text{...} \hspace{0.05cm}\right)$$
 +
:$$\hspace{0.3cm} \Rightarrow \hspace{0.3cm} \underline{0} = \left ( 00, 00, 00, 00, 00,\hspace{0.05cm} \text{...} \hspace{0.05cm}\right) \hspace{0.05cm},$$
 +
 
 +
 
 +
:$$\ \underline{x} =\left ( S_0 \rightarrow S_1 \rightarrow S_2\rightarrow S_0\rightarrow S_0\rightarrow \hspace{0.05cm}\text{...} \hspace{0.05cm}\right)$$
 +
:$$\hspace{0.3cm} \Rightarrow \hspace{0.3cm}\underline{x} == \left ( 11, 10, 11, 00, 00,\hspace{0.05cm} \text{...} \hspace{0.05cm}\right) \hspace{0.05cm},$$
 +
 
 +
 
 +
:$$\underline{x}\hspace{0.03cm}' = \left ( S_0 \rightarrow S_1 \rightarrow S_3\rightarrow S_2\rightarrow S_0\rightarrow \hspace{0.05cm}\text{...} \hspace{0.05cm}\right)$$
 +
:$$\hspace{0.3cm} \Rightarrow \hspace{0.3cm}\underline{x}\hspace{0.03cm}' = \left ( 11, 01, 01, 11, 00,\hspace{0.05cm} \text{...} \hspace{0.05cm}\right) \hspace{0.05cm}.$$
  
:<math>\underline{0} =\left ( S_0 \rightarrow S_0 \rightarrow S_0\rightarrow S_0\rightarrow S_0\rightarrow \hspace{0.05cm}\text{...} \hspace{0.05cm}\right)= \left ( 00, 00, 00, 00, 00,\hspace{0.05cm} \text{...} \hspace{0.05cm}\right) \hspace{0.05cm},</math>
 
:<math>\underline{x} =\left ( S_0 \rightarrow S_1 \rightarrow S_2\rightarrow S_0\rightarrow S_0\rightarrow \hspace{0.05cm}\text{...} \hspace{0.05cm}\right)= \left ( 11, 10, 11, 00, 00,\hspace{0.05cm} \text{...} \hspace{0.05cm}\right) \hspace{0.05cm},</math>
 
:<math>\underline{x}\hspace{0.03cm}' = \left ( S_0 \rightarrow S_1 \rightarrow S_3\rightarrow S_2\rightarrow S_0\rightarrow \hspace{0.05cm}\text{...} \hspace{0.05cm}\right)= \left ( 11, 01, 01, 11, 00,\hspace{0.05cm} \text{...} \hspace{0.05cm}\right) \hspace{0.05cm}.</math>
 
  
[[File:P ID2638 KC T 3 3 S4b v2.png|center|frame|Zur Definition der freien Distanz|class=fit]]
 
  
Man erkennt aus diesen Darstellungen:
+
One can see from these plots:
*Die freie Distanz $d_{\rm F} = 5$ ist gleich dem Hamming&ndash;Gewicht $w_{\rm H}(\underline{x})$. Keine andere Sequenz als die gelb hinterlegte unterscheidet sich von $\underline{0}$ um weniger als fünf Bit. Beispielsweise ist $w_{\rm H}(\underline{x}') = 6$.<br>
+
# &nbsp; The free distance&nbsp; $d_{\rm F} = 5$&nbsp; is equal to the Hamming weight&nbsp; $w_{\rm H}(\underline{x})$.  
 +
# &nbsp; No sequence other than the one highlighted in yellow differs from &nbsp; $\underline{0}$ &nbsp; by less than five bits.&nbsp; For example&nbsp; $w_{\rm H}(\underline{x}') = 6$.<br>
 +
# &nbsp; In this example,&nbsp; the free distance &nbsp; $d_{\rm F} = 5$ &nbsp; also results as the Hamming distance between the sequences &nbsp; $\underline{x}$ &nbsp; and &nbsp; $\underline{x}\hspace{0.03cm}'$,&nbsp; which differ in exactly five bit positions.}}
  
*In diesem Beispiel ergibt sich die freie Distanz $d_{\rm F} = 5$ auch als die Hamming&ndash;Distanz zwischen den Sequenzen $\underline{x}$ und $\underline{x}\hspace{0.03cm}'$, die sich genau in fünf Bitpositionen unterscheiden.}}
 
  
 +
The larger the free distance&nbsp; $d_{\rm F}$,&nbsp; the better is the&nbsp; "asymptotic behavior"&nbsp; of the convolutional encoder.
 +
*For the exact error probability calculation,&nbsp; however,&nbsp; one needs the exact knowledge of the&nbsp; [[Channel_Coding/Bounds_for_Block_Error_Probability#Distance_spectrum_of_a_linear_code|$\text{weight enumerator function}$]]&nbsp; just as for the linear block codes.
  
Je größer die freie Distanz $d_{\rm F}$ ist, desto besser ist das &bdquo;asymptotische Verhalten&rdquo; des Faltungscoders.
+
*This is given for the convolutional codes in detail only in the chapter&nbsp; [[Channel_Coding/Distance_Characteristics_and_Error_Probability_Bounds|"Distance Characteristics and Error Probability Bounds"]].  
*Zur genauen Fehlerwahrscheinlichkeitsberechnung benötigt man allerdings ebenso wie bei den linearen Blockcodes die genaue Kenntnis der [[Kanalcodierung/Schranken_für_die_Blockfehlerwahrscheinlichkeit#Distanzspektrum_eines_linearen_Codes| Gewichtsfunktion]] (englisch: <i>Weight Enumerator Function</i>).
 
*Diese wird für die Faltungscodes  im Detail erst im Kapitel [[Kanalcodierung/Distanzeigenschaften_und_Fehlerwahrscheinlichkeitsschranken|Distanzeigenschaften und Fehlerwahrscheinlichkeitsschranken]] angegeben.  
 
 
<br clear=all>
 
<br clear=all>
[[File:P ID2639 KC T 3 3 S4c.png|right|frame|Optimale Faltungscodes der Rate $1/2$|class=fit]]
+
[[File:EN_KC_T_3_3_S4cd_v3.png|right|frame|Optimal convolutional codes of rate&nbsp; $1/2$ |class=fit]]
Vorneweg nur einige wenige Bemerkungen:
+
At the outset,&nbsp; just a few remarks:
*Die freie Distanz $d_{\rm F}$ nimmt mit wachsendem Gedächtnis $m$ zu, vorausgesetzt, dass man für die Übertragungsfunktionsmatrix $\mathbf{G}(D)$ geeignete Polynome  verwendet.  
+
# &nbsp; The free distance&nbsp; $d_{\rm F}$&nbsp; increases with increasing memory&nbsp; $m$&nbsp; provided that one uses appropriate polynomials for the transfer function matrix&nbsp; $\mathbf{G}(D)$&nbsp;.  
*In der Tabelle sind für Rate&ndash;$1/2$&ndash;Faltungscodes die $n = 2$ Polynome zusammen mit dem $d_{\rm F}$&ndash;Wert angegeben.
+
# &nbsp; In the table for rate&nbsp; $1/2$&nbsp; convolutional codes,&nbsp; the&nbsp; $n = 2$&nbsp; polynomials are given together with the&nbsp; $d_{\rm F}$&nbsp; value.
* Von größerer praktischer Bedeutung ist der  <i>Industrie&ndash;Standardcode</i> mit $m = 6$ &nbsp; &#8658; &nbsp; $64$ Zustände und der freien Distanz $d_{\rm F} = 10$.
+
# &nbsp; Of greater practical importance is the&nbsp; "industry standard code"&nbsp; with&nbsp; $m = 6$&nbsp; &#8658; &nbsp; $64$&nbsp; states and the free distance&nbsp; $d_{\rm F} = 10$&nbsp; $($in the table this is highlighted in red$)$.
 +
 
 +
 
 +
The following example shows the effects of using unfavorable polynomials.
 
<br clear=all>
 
<br clear=all>
Das folgende Beispiel zeigt, welche Auswirkungen es hat, wenn man ungünstige Polynome zugrundelegt.
 
 
 
{{GraueBox|TEXT=   
 
{{GraueBox|TEXT=   
$\text{Beispiel 4:}$&nbsp;   Im $\text{Beispiel 3}$ wurde gezeigt, dass unser Standard&ndash;Faltungscoder $(n = 2, \ k = 1, \ m = 2)$ die freie Distanz $d_{\rm F} = 5$ aufweist. Dieser basiert auf der Übertragungsfunktionsmatrix $\mathbf{G}(D) = (1 + D + D^2, \ 1 + D^2)$, wie aus dem gezeigten Modell (ohne rote Streichung) hervorgeht.
+
$\text{Example 4:}$&nbsp; In&nbsp; $\text{Example 3}$&nbsp; it was shown that our standard convolutional encoder&nbsp; $(n = 2, \ k = 1, \ m = 2)$&nbsp; has the free distance&nbsp; $d_{\rm F} = 5$.&nbsp; This is based on the transfer function matrix &nbsp; $\mathbf{G}(D) = (1 + D + D^2, \ 1 + D^2)$,&nbsp; as shown in the model&nbsp; $($without red deletion$)$.  
 
 
[[File:P ID2640 KC T 3 3 S4d v3.png|center|frame|Zustandsübergangsdiagramm $\rm C$ für $n = 2, \ k = 1, \ m = 2$|class=fit]]
 
 
 
Verwendet man $\mathbf{G}(D) = (1 + D, \ 1 + D^2)$ &nbsp; &rArr; &nbsp; rote Änderung, so ändert sich das Zustandsübergangsdiagramm gegenüber dem [[Kanalcodierung/Codebeschreibung_mit_Zustands–_und_Trellisdiagramm#Darstellung_im_Zustands.C3.BCbergangsdiagramm| Zustandsübergangsdiagramm $\rm A$]] auf den ersten Blick nur wenig. Die Auswirkungen sind aber gravierend:
 
*Die freie Distanz ist nun nicht mehr $d_{\rm F} = 5$, sondern nur noch $d_{\rm F} = 3$, wobei die Codesequenz $\underline{x} = (11, 01, 00, 00, \ \text{...})$ mit nur drei Einsen zur Informationssequenz $\underline{u} = \underline{1} = (1, 1, 1, 1, \ \text{...})$ gehört.<br>
 
  
*Das heißt: Durch nur drei Übertragungsfehler an den Positionen 1, 2, und 4 verfälscht man die Einssequenz $(\underline{1})$ in die Nullsequenz $(\underline{0})$ und produziert so unendlich viele Decodierfehler im Zustand $S_3$.<br>
+
[[File:EN_KC_T_3_3_S4d_v2.png|right|frame|State transition diagram&nbsp; $\rm C$&nbsp;  for the&nbsp; modified standard convolutional encoder|class=fit]]
  
*Einen Faltungscodierer mit diesen Eigenschaften bezeichnet man als &bdquo;katastrophal&rdquo;. Der Grund für dieses extrem ungünstige Verhalten ist, dass hier die beiden Polynome $1 + D$ und $1 + D^2$ nicht teilerfemd sind.}}<br>
+
Using&nbsp; $\mathbf{G}(D) = (1 + D, \ 1 + D^2)$ &nbsp; &rArr; &nbsp; red change,&nbsp; the state transition diagram changes from the&nbsp; [[Channel_Coding/Code_Description_with_State_and_Trellis_Diagram#Representation_in_the_state_transition_diagram|$\text{state transition diagram $\rm A$}$]]&nbsp; little at first glance.&nbsp; However, the&nbsp; effects are serious:
 +
# &nbsp; The free distance is no longer&nbsp; $d_{\rm F} = 5$,&nbsp; but&nbsp; $d_{\rm F} = 3$,&nbsp; where the encoded sequence &nbsp; $\underline{x} = (11, \ 01, \ 00, \ 00, \text{. ..})$ &nbsp; with only three&nbsp; '''ones'''&nbsp; belonging to the information sequence &nbsp; $\underline{u} = \underline{1} = (1, \ 1, \ 1, \ 1, \ \text{...})$.<br>
 +
# &nbsp; That is:&nbsp; By only three transmission errors at positions&nbsp; '''1''',&nbsp; '''2''',&nbsp; and&nbsp; '''4''',&nbsp; one falsifies the&nbsp; "one sequence"&nbsp; $(\underline{1})$&nbsp; into the&nbsp; "zero sequence"&nbsp; $(\underline{0})$&nbsp; and thus produces infinitely many decoding errors in state&nbsp; $S_3$.<br>
 +
# &nbsp; A convolutional encoder with these properties is called&nbsp; "catastrophic".&nbsp; The reason for this extremely unfavorable behavior is that here the two polynomials &nbsp; $1 + D$ &nbsp; and &nbsp; $1 + D^2$ &nbsp; are not divisor-remote.}}<br>
  
== Terminierte Faltungscodes ==
+
== Terminated convolutional codes ==
 
<br>
 
<br>
Bei der theoretischen Beschreibung der Faltungscodes geht man stets von Informationssequenzen $\underline{u}$ und Codesequenzen $\underline{x}$ aus, die per Definition unendlich lang sind.  
+
In the theoretical description of convolutional codes,&nbsp; one always assumes information sequences&nbsp; $\underline{u}$&nbsp; and encoded sequences&nbsp; $\underline{x}$&nbsp; that are  by definition infinite in length.
*In praktischen Anwendungen &ndash; siehe z.B. [[Beispiele_von_Nachrichtensystemen/Allgemeine_Beschreibung_von_GSM|GSM]] und [[Beispiele_von_Nachrichtensystemen/Allgemeine_Beschreibung_von_UMTS|UMTS]] &ndash; verwendet man dagegen stets eine Informationssequenz endlicher Länge $L$.  
+
*On the other hand,&nbsp;in practical applications e.g.&nbsp; [[Examples_of_Communication_Systems/General_Description_of_GSM|$\text{GSM}$]]&nbsp; and&nbsp; [[Examples_of_Communication_Systems/General_Description_of_UMTS|$\text{UMTS}$]],&nbsp;  one always uses an information sequence of finite length&nbsp; $L$.
*Bei einem Rate&ndash;$1/n$&ndash;Faltungscode hat dann die Codesequenz mindestens die Länge $n \cdot L$.<br>
+
 
 +
*For a rate $1/n$ convolutional code,&nbsp; the encoded sequence then has at least length&nbsp; $n \cdot L$.
  
  
[[File:P ID2641 KC T 3 3 S5 v2.png|center|frame|Terminierter Faltungscode der Rate $R = 128/260$|class=fit]]
+
The graph&nbsp; $($without the gray background$)$&nbsp; shows the trellis of our standard rate&nbsp; $1/2$&nbsp; convolutional code at binary input sequence &nbsp; $\underline{u}$&nbsp; of finite length&nbsp; $L = 128$.&nbsp;
 +
[[File:P ID2641 KC T 3 3 S5 v2.png|right|frame|Terminated convolutional code of rate&nbsp; $R = 128/260$|class=fit]]  
 +
*Thus the encoded sequence&nbsp; $\underline{x}$&nbsp; has length&nbsp; $2 \cdot L = 256$.
  
Die Grafik ohne die graue Hinterlegung rechts  zeigt das Trellis unseres Standard&ndash;Rate&ndash;$1/2$&ndash;Faltungscodes bei binärer Eingangsfolge $\underline{u}$ der endlichen Länge $L = 128$. Damit hat die Codefolge $\underline{x}$ die Länge $2 \cdot L = 256$.  
+
*However,&nbsp; due to the undefined final state,&nbsp; a complete maximum likelihood decoding of the transmitted sequence is not possible.  
  
Aufgrund des undefinierten Endzustands ist eine vollständige Maximum&ndash;Likelihood&ndash;Decodierung der gesendeten Folge allerdings nicht möglich. Da man nicht weiß, welcher der Zustände $S_0, \ \text{...} \ , \ S_3$ sich für $i > L$ einstellen würden, wird die Fehlerwahrscheinlichkeit (etwas) größer sein als im Grenzfall $L &#8594; &#8734;$.<br>
+
*Since it is not known which of the states &nbsp; $S_0, \ \text{...} \ , \ S_3$ &nbsp; would occur for&nbsp; $i > L$,&nbsp; the error probability will be&nbsp; $($somewhat$)$&nbsp; larger than in the limiting case&nbsp; $L &#8594; &#8734;$.<br>
  
Um dies zu verhindern, terminiert man den Faltungscode entsprechend der Hinterlegung in obiger Grafik:
+
*To prevent this,&nbsp; the convolutional code is terminated as shown in the diagram:&nbsp; You add&nbsp; $m = 2$&nbsp; zeros to the&nbsp; $L = 128$&nbsp; information bits &nbsp; &#8658; &nbsp; $L' = 130$.
*Man fügt an die $L = 128$ Informationsbits noch $m = 2$ Nullen an &nbsp;&#8658;&nbsp; $L' = 130$.
 
  
*Damit ergibt sich beispielsweise für den farblich hervorgehobenen Pfad durch das Trellis:
+
*This results,&nbsp; for example,&nbsp; for the color highlighted path through the trellis:
  
::<math>\underline{x}' = (11\hspace{0.05cm},\hspace{0.05cm} 01\hspace{0.05cm},\hspace{0.05cm} 01\hspace{0.05cm},\hspace{0.05cm} 00 \hspace{0.05cm},\hspace{0.05cm} \text{...}\hspace{0.1cm},\hspace{0.05cm} 10\hspace{0.05cm},\hspace{0.05cm}00\hspace{0.05cm},\hspace{0.05cm} 01\hspace{0.05cm},\hspace{0.05cm} 01\hspace{0.05cm},\hspace{0.05cm} 11 \hspace{0.05cm} ) \hspace{0.3cm}
+
:$$\underline{x}' = (11\hspace{0.05cm},\hspace{0.05cm} 01\hspace{0.05cm},\hspace{0.05cm} 01\hspace{0.05cm},\hspace{0.05cm} 00 \hspace{0.05cm},\hspace{0.05cm} \text{...}\hspace{0.1cm},\hspace{0.05cm} 10\hspace{0.05cm},\hspace{0.05cm}00\hspace{0.05cm},\hspace{0.05cm} 01\hspace{0.05cm},\hspace{0.05cm} 01\hspace{0.05cm},\hspace{0.05cm} 11 \hspace{0.05cm} ) $$
\Rightarrow \hspace{0.3cm}\underline{u}' = (1\hspace{0.05cm},\hspace{0.05cm} 1\hspace{0.05cm},\hspace{0.05cm} 0\hspace{0.05cm},\hspace{0.05cm} 1 \hspace{0.05cm},\hspace{0.05cm} \text{...}\hspace{0.1cm},\hspace{0.05cm} 0\hspace{0.05cm},\hspace{0.05cm}1\hspace{0.05cm},\hspace{0.05cm} 1\hspace{0.05cm},\hspace{0.05cm} 0\hspace{0.05cm},\hspace{0.05cm} 0 \hspace{0.05cm} ) \hspace{0.05cm}.</math>
+
:$$\Rightarrow \hspace{0.3cm}\underline{u}' = (1\hspace{0.05cm},\hspace{0.05cm} 1\hspace{0.05cm},\hspace{0.05cm} 0\hspace{0.05cm},\hspace{0.05cm} 1 \hspace{0.05cm},\hspace{0.05cm} \text{...}\hspace{0.1cm},\hspace{0.05cm} 0\hspace{0.05cm},\hspace{0.05cm}1\hspace{0.05cm},\hspace{0.05cm} 1\hspace{0.05cm},\hspace{0.05cm} 0\hspace{0.05cm},\hspace{0.05cm} 0 \hspace{0.05cm} ) \hspace{0.05cm}.$$
  
*Das Trellis endet nun stets (also unabhängig von den Daten) im definierten Endzustand $S_0$ und man erreicht so die bestmögliche Fehlerwahrscheinlichkeit entsprechend Maximum&ndash;Likelihood.<br>
+
The trellis now ends always&nbsp; $($independent of the data$)$&nbsp; in the defined final state&nbsp; $S_0$;&nbsp; one thus achieves the best possible error probability according to maximum likelihood.<br>
  
*Die Verbesserung hinsichtlich der Fehlerwahrscheinlichkeit erkauft man sich allerdings auf Kosten einer kleineren Coderate.  
+
*However,&nbsp; the improvement in error probability comes at the cost of a lower code rate.
*Bei $L \gg m$ ist dieser Verlust nur gering. Im betrachteten Beispiel ergibt sich  anstelle von $R = 0.5$ mit Terminierung die Coderate
+
 +
*For&nbsp; $L \gg m$&nbsp; this loss is only small.&nbsp; In the considered example,&nbsp; instead of&nbsp; $R = 0.5$&nbsp; with termination the code rate results in
 
:$$R\hspace{0.05cm}' = 0.5 \cdot L/(L + m) \approx 0.492.$$<br>
 
:$$R\hspace{0.05cm}' = 0.5 \cdot L/(L + m) \approx 0.492.$$<br>
  
== Punktierte Faltungscodes ==
+
== Punctured convolutional codes ==
 
<br>
 
<br>
 
{{BlaueBox|TEXT=   
 
{{BlaueBox|TEXT=   
 
$\text{Definition:}$&nbsp;   
 
$\text{Definition:}$&nbsp;   
*Wir gehen von einem Faltungscode der Rate $R_0 = 1/n_0$ aus, den wir <i>Muttercode</i> nennen.  
+
*We assume a convolutional code of rate&nbsp; $R_0 = 1/n_0$&nbsp; which we call&nbsp; "mother code".
*Streicht man von dessen Codesequenz einige Bits nach einem vorgegebenen Muster, so spricht man von einem <b>punktierten Faltungscode</b> (englisch: <i>Punctured Convolutional Code</i>) mit der Coderate $R > R_0$.}}<br>
+
 
+
*If one deletes some bits from its encoded sequence according to a given pattern,&nbsp; it is called a&nbsp; &raquo;<b>punctured convolutional code</b>&laquo;&nbsp; with code rate&nbsp; $R > R_0$.}}<br>
Die Punktierung geschieht mittels der Punktierungsmatrix $\mathbf{P}$ mit folgenden Eigenschaften:
 
*Die Zeilenzahl ist $n_0$, die Spaltenzahl gleich der Punktierungsperiode $p$, die durch die gewünschte Coderate bestimmt wird.<br>
 
 
 
*Die $n_0 \cdot p$ Matrixelemente $P_{ij}$ sind binär ($0$ oder $1$). Bei $P_{ij} = 1$ wird das entsprechende Codebit übernommen, bei $P_{ij} = 0$ punktiert.<br>
 
  
*Die Rate des punktierten Codes ist gleich dem Quotienten aus der Punktierungsperiode $p$ und der Anzahl $N_1$ der Einsen in der $\mathbf{P}$&ndash;Matrix.<br>
+
The puncturing is done using the puncturing matrix&nbsp; $\mathbf{P}$&nbsp; with the following properties:
 +
# &nbsp; The row number is&nbsp; $n_0$,&nbsp; the column number is equal to the puncturing period&nbsp; $p$,&nbsp; which is determined by the desired code rate.<br>
 +
# &nbsp; The&nbsp; $n_0 \cdot p$&nbsp; matrix elements&nbsp; $P_{ij}$&nbsp; are binary &nbsp;$(0$&nbsp; or&nbsp; $1)$.
 +
# &nbsp; If&nbsp; $P_{ij} = 1$&nbsp; the corresponding code bit&nbsp; $x_{ij}$&nbsp; is taken,&nbsp; if&nbsp; $P_{ij} = 0$&nbsp; not.<br>
 +
# &nbsp; The rate of the punctured code is equal to the quotient of the puncturing period&nbsp; $p$&nbsp; and the number&nbsp; $N_1$&nbsp; of&nbsp;  ones&nbsp; in the&nbsp; $\mathbf{P}$ matrix.<br>
  
  
Man findet günstig punktierte Faltungscodes üblicherweise nur mittels computergestützter Suche. Dabei bezeichnet man einen punktierten Faltungscode dann als günstig, wenn er
+
One can usually find favorably punctured convolutional codes only by means of computer-aided search.&nbsp; Here,&nbsp; a punctured convolutional code is said to be favorable if it has
*die gleiche Gedächtnisordnung $m$ aufweist wie der Muttercode (auch die Gesamteinflusslänge ist in beiden Fällen gleich: &nbsp; $\nu = m + 1$),<br>
+
*the same memory order&nbsp; $m$&nbsp; as the parent code,&nbsp; and also the total influence length is the same in both cases: &nbsp; $\nu = m + 1$,<br>
  
*eine möglichst große freie Distanz $d_{\rm F}$ besitzt, die natürlich kleiner ist als die des Muttercodes.<br><br>
+
* a free distance&nbsp; $d_{\rm F}$&nbsp; as large as possible which is of course smaller than that of the mother code.<br><br>
  
 
{{GraueBox|TEXT=   
 
{{GraueBox|TEXT=   
$\text{Beispiel 5:}$&nbsp;  Ausgehend von unserem [[Kanalcodierung/Codebeschreibung_mit_Zustands–_und_Trellisdiagramm#Zustandsdefinition_f.C3.BCr_ein_Speicherregister| Rate&ndash;1/2&ndash;Standardcode]] mit den Parametern $n_0 = 2$ und $m = 2$ erhält man mit der Punktierungsmatrix
+
$\text{Example 5:}$&nbsp;  Starting from our&nbsp; [[Channel_Coding/Code_Description_with_State_and_Trellis_Diagram#State_definition_for_a_memory_register|$\text{rate 1/2 standard code}$]]&nbsp; with parameters&nbsp; $n_0 = 2$&nbsp; and&nbsp; $m = 2$,&nbsp; we obtain with the puncturing matrix
  
 
::<math>{\boldsymbol{\rm P} } =  
 
::<math>{\boldsymbol{\rm P} } =  
Line 249: Line 265:
 
\end{pmatrix}\hspace{0.3cm}\Rightarrow \hspace{0.3cm} p = 3\hspace{0.05cm}, \hspace{0.2cm}N_1 = 4</math>
 
\end{pmatrix}\hspace{0.3cm}\Rightarrow \hspace{0.3cm} p = 3\hspace{0.05cm}, \hspace{0.2cm}N_1 = 4</math>
  
einen punktierten Faltungscode der Rate $R = p/N_1 = 3/4$. Wir betrachten hierzu folgende Konstellation:
+
a punctured convolutional code of rate&nbsp; $R = p/N_1 = 3/4$.  
*Informationssequenz: $\hspace{2.5cm} \underline{u} = (1, 0, 0, 1, 1, 0, \ \text{...}\hspace{0.03cm})$,<br>
 
 
 
*Codesequenz ohne Punktierung: $\hspace{0.7cm} \underline{x} = (11, 1 \color{grey}{0}, \color{gray}{1}1, 11, 0\color{gray}{1}, \color{gray}{0}1, \ \text{...}\hspace{0.03cm})$,<br>
 
 
 
*Codesequenz mit Punktierung: $\hspace{0.90cm} \underline{x}\hspace{0.05cm}' = (11, 1\_, \_1, 11, 0\_, \_1, \ \text{...}\hspace{0.03cm})$,<br>
 
  
*Empfangssequenz ohne Fehler: $\hspace{0.88cm} \underline{y} = (11, 1\_, \_1, 11, 0\_, \_1, \ \text{...}\hspace{0.03cm})$,<br>
+
We consider the following constellation for this purpose:
 +
# &nbsp; Information sequence: $\hspace{2.5cm} \underline{u} = (1, 0, 0, 1, 1, 0, \ \text{...}\hspace{0.03cm})$,<br>
 +
# &nbsp; encoded sequence without puncturing: $\hspace{0.35cm} \underline{x} = (11, 1 \color{grey}{0}, \color{gray}{1}1, 11, 0\color{gray}{1}, \color{gray}{0}1, \ \text{...}\hspace{0.03cm})$,<br>
 +
#  &nbsp; encoded sequence with puncturing: $\hspace{0.90cm} \underline{x}\hspace{0.05cm}' = (11, 1\_, \_1, 11, 0\_, \_1, \ \text{...}\hspace{0.03cm})$,<br>
 +
#  &nbsp; received sequence without errors: $\hspace{0.58cm} \underline{y} = (11, 1\_, \_1, 11, 0\_, \_1, \ \text{...}\hspace{0.03cm})$,<br>
 +
#  &nbsp; modified received sequence: $\hspace{1.4cm} \underline{y}\hspace{0.05cm}' = (11, 1\rm E, E1, 11, 0E, E1, \ \text{...}\hspace{0.03cm})$.<br>
  
*Modifizierte Empfangssequenz: $\hspace{0.8cm} \underline{y}\hspace{0.05cm}' = (11, 1\rm E, E1, 11, 0E, E1, \ \text{...}\hspace{0.03cm})$.<br>
+
<u>Note:</u>
 +
*So each punctured bit in the received sequence&nbsp; $\underline{y}$&nbsp; $($marked by an underscore$)$ &nbsp; is replaced by an&nbsp; "Erasure"&nbsp; $\rm (E)$,&nbsp; see&nbsp; [[Channel_Coding/Channel_Models_and_Decision_Structures#Binary_Erasure_Channel_.E2.80.93_BEC| "Binary Erasure Channel"]].  
  
 +
*Such an erasure created by the puncturing&nbsp;  is treated by the decoder in the same way as an erasure by the channel.
  
Jedes punktierte Bit in der Empfangssequenz $\underline{y}$ (markiert durch einen Unterstrich) wird also durch ein <i>Erasure</i> $\rm E$ ersetzt &ndash; siehe [[Kanalcodierung/Klassifizierung_von_Signalen#Binary_Erasure_Channel_.E2.80.93_BEC| Binary Erasure Channel]]. Ein solches durch die Punktierung entstandene <i>Erasure</i> wird vom Decoder genauso behandelt wie eine Auslöschung durch den Kanal.
+
*Of course,&nbsp; the puncturing increases the error probability.&nbsp; This can already be seen from the fact that the free distance decreases to&nbsp; $d_{\rm F} = 3$&nbsp; after the puncturing.  
  
Natürlich erhöht sich durch die Punktierung die Fehlerwahrscheinlichkeit. Dies kann man bereits daran erkennen, dass die freie Distanz nach der Punktierung auf $d_{\rm F} = 3$ sinkt. Demgegenüber besitzt der Muttercode die freie Distanz $d_{\rm F} = 5$.}}<br>
+
*In contrast,&nbsp; the mother code has the free distance&nbsp; $d_{\rm F} = 5$.}}<br>
  
Eine Anwendung findet die Punktierung zum Beispiel bei den so genannten RCPC&ndash;Codes (<i>Rate Compatible Punctered Convolutional Codes</i>). Näheres hierzu in der [[Aufgaben:3.8_RCPC%E2%80%93Codes| Aufgabe 3.8]].<br>
+
For example,&nbsp; puncturing is used in the so-called&nbsp; [https://ieeexplore.ieee.org/document/2763 $\text{RCPC codes}$]&nbsp; $($"rate compatible punctured convolutional codes"$)$.&nbsp; More about this in&nbsp;  [[Aufgaben:Aufgabe_3.8:_Rate_Compatible_Punctured_Convolutional_Codes| "Exercise 3.8"]].<br>
  
  
== Aufgaben zum Kapitel==
+
== Exercises for the chapter==
 
<br>
 
<br>
[[Aufgaben:Aufgabe_3.6:_Zustandsübergangsdiagramm|Aufgabe 3.6: Zustandsübergangsdiagramm]]
+
[[Aufgaben:Aufgabe_3.6:_Zustandsübergangsdiagramm|Exercise 3.6: State Transition Diagram]]
  
[[Aufgaben:Aufgabe_3.6Z:_Übergangsdiagramm_für_m_%3D_3|Aufgabe 3.6Z: Übergangsdiagramm für ''m'' = 3]]
+
[[Aufgaben:Aufgabe_3.6Z:_Übergangsdiagramm_bei_3_Zuständen|Exercise 3.6Z: Transition Diagram at 3 States]]
  
[[Aufgaben:Aufgabe_3.7:_Vergleich_zweier_Faltungscodierer|Aufgabe 3.7: Vergleich zweier Faltungscodierer]]
+
[[Aufgaben:Aufgabe_3.7:_Vergleich_zweier_Faltungscodierer|Exercise 3.7: Comparison of Two Convolutional Encoders]]
  
[[Aufgaben:Aufgabe_3.7Z:_Welcher_Code_ist_katastrophal%3F|Aufgabe 3.7Z: Welcher Code ist katastrophal?]]
+
[[Aufgaben:Aufgabe_3.7Z:_Welcher_Code_ist_katastrophal%3F|Exercise 3.7Z: Which Code is Catastrophic?]]
  
[[Aufgaben:Aufgabe_3.8:_Rate_Compatible_Punctured_Convolutional_Codes|Aufgabe 3.8: ''Rate Compatible Punctured Convolutional Codes'']]
+
[[Aufgaben:Aufgabe_3.8:_Rate_Compatible_Punctured_Convolutional_Codes|Exercise 3.8: Rate Compatible Punctured Convolutional Codes]]
  
 
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Latest revision as of 17:10, 7 December 2022

State definition for a memory register


A convolutional encoder can also be understood as an automaton with a finite number of states.  This number results from the number  $m$  of memory elements to  $2^m$.

In this chapter we mostly start from the drawn convolutional encoder,  which is characterized by the following parameters:

Convolutional encoder with  $k = 1, \ n = 2, \ m = 2$
  • $k = 1, \ n = 2$   ⇒   code rate $R = 1/2$,
  • Memory  $m = 2$   ⇒   influence length $\nu = m+1=3$,
  • Transfer function matrix in octal form  $(7, 5)$:
$$\mathbf{G}(D) = (1 + D + D^2, \ 1 + D^2).$$

The encoded sequence  $\underline{x}_i = (x_i^{(1)}, \ x_i^{(2)})$   at time  $i$  depends not only on the information bit  $u_i$  but also on the content  $(u_{i-1}, \ u_{i-2})$  of the memory.

  • There are   $2^m = 4$   possibilities for this,  namely the states  $S_0, \ S_1, \ S_2,\ S_3$.
  • Let the register state  $S_{\mu}$  be defined by the index
\[\mu = u_{i-1} + 2 \cdot u_{i-2}\hspace{0.05cm}, \hspace{0.5cm}{\rm general\hspace{-0.1cm}:}\hspace{0.15cm} \mu = \sum_{l = 1}^{m} \hspace{0.1cm}2\hspace{0.03cm}^{l-1} \cdot u_{i-l} \hspace{0.05cm}.\]

To avoid confusion,  we distinguish in the following by upper or lower case letters:

  1.   the possible states  $S_{\mu}$  with the indices  $0 ≤ \mu ≤ 2^m \,-1$,
  2.   the current states  $s_i$  at the times  $i = 1, \ 2, \ 3, \ \text{...}$


$\text{Example 1:}$  The graph shows for the convolutional encoder sketched above

To illustrate the states  $S_{\mu}$


  • the information sequence  $\underline{u} = (u_1,u_2, \text{...} \ ) $
      ⇒   information bits  $u_i$,
  • the current states at times  $i$
      ⇒   $s_i ∈ \{S_0, \ S_1, \ S_2, \ S_3\}$,
  • the 2–bit sequences  $\underline{x}_i = (x_i^{(1)}, \ x_i^{(2)})$
      ⇒   encoding the information bit $u_i$.


For example,  you can see from this illustration  $($the colors are to facilitate the transition to later graphics$)$:

  1.   At time  $i = 5$   ⇒   $u_{i-1} = u_4 = 0$,  $u_{i-2} = u_3 = 1$  holds.  That is,  the automat is in state  $s_5 = S_2$. 
  2.   With the information bit  $u_i = u_5 = 0$,  the encoded sequence  $\underline{x}_5 = (11)$  is obtained.
  3.   The state for time  $i = 6$  results from  $u_{i-1} = u_5 = 0$  and  $u_{i-2} = u_4 = 0$  to  $s_6 = S_0$.
  4.   Because of  $u_6 = 0$   ⇒   $\underline{x}_6 = (00)$  is output and the new state  $s_7$  is again  $S_0$.
  5.   At time  $i = 12$  the encoded sequence  $\underline{x}_{12} = (11)$  is output because of  $u_{12} = 0$  as at time  $i = 5$. 
  6.   Here,  one passes from state  $s_{12} = S_2$  to state  $s_{13} = S_0$ .
  7.   In contrast,  at time  $i = 9$  the encoded sequence  $\underline{x}_{9} = (00)$  is output and state  $s_9 = S_2$  is followed by  $s_{10} = S_1$.
  8.   The same is true for  $i = 15$.  In both cases,  the current information bit is  $u_i = 1$.


$\text{Conclusion:}$  From this example it can be seen that the encoded sequence  $\underline{x}_i$  at time  $i$  depends solely on

  1.   the current state  $s_i = S_{\mu} \ (0 ≤ \mu ≤ 2^m -1)$, as well as
  2.   the current information bit  $u_i$.

  • Similarly,  the successor state  $s_{i+1}$  is determined by  $s_i$  and  $u_i$  alone.
  • These properties are considered in the so-called  "state transition diagram"  in the next section.


Representation in the state transition diagram


The graph shows the state transition diagram for the  $(n = 2, \ k = 1, \ m = 2)$  convolutional encoder.

State transition diagram  $\rm A$  for the  $(n = 2, \ k = 1, \ m = 2)$  convolutional encoder;
      in the following:  "our standard convolutional encoder"
  1.  This diagram provides all information about this special convolutional encoder in compact form.
  2.  The color scheme is aligned with the  $\text{sequential representation}$  in the previous section.
  3.  For the sake of completeness,  the derivation table is also given again.
  4.  The  $2^{m+k}$  transitions are labeled  "$u_i \ | \ \underline{x}_i$".


For example,  it can be read:

  • The information bit   $u_i = 0$   $($indicated by a red label$)$  takes you from state   $s_i = S_1$   to state   $s_{i+1} = S_2$   and the two code bits are   $x_i^{(1)} = 1, \ x_i^{(2)} = 0$.
  • With the information bit   $u_i = 1$   $($blue label$)$  in the state   $s_i = S_1$   the code bits result in   $x_i^{(1)} = 0, \ x_i^{(2)} = 1$,  and one arrives at the new state  $s_{i+1} = S_3$.


State transition diagram  $\rm B$  for another  $(n = 2, \ k = 1, \ m = 2)$  convolutional encoder;
      in the following:  "equivalent systematic representation"

We now consider another systematic encoder with same parameters:

$$n = 2, \ k = 1, \ m = 2.$$

This is the  $\text{equivalent systematic representation}$  of our standard convolutional encoder,  also referred to as  "recursive systematic convolutional encoder".

Compared to the upper state transition diagram  $\rm A$,  one can see the following differences:

  • Since the earlier information bits  $u_{i-1}$  and  $u_{i-2}$  are not stored, here the states  $s_i = S_{\mu}$  are related to the processed quantities  $w_{i-1}$  and  $w_{i-2}$, where  $w_i = u_i + w_{i-1} + w_{i-2}$  holds.


$\text{Conclusion:}$  The comparison of the graphics shows that a similar state transition diagram is obtained for both encoders:

  • The structure of the state transition diagram is determined solely by the parameters  $m$  and  $k$ .
  • The number of states is  $2^{m \hspace{0.05cm}\cdot \hspace{0.05cm}k}$  and  $2^k$  arrows go from each state.
  • You also get from each state  $s_i ∈ \{S_0, \ S_1, \ S_2, \ S_3\}$  to the same successor states  $s_{i+1}$.
  • A difference exists solely with respect to the encoded sequences output,  where in both cases  $\underline{x}_i ∈ \{00, \ 01, \ 10, \ 11\}$  applies.



Representation in the trellis diagram


One gets from the state transition diagram to the so-called  "trellis diagram"  $($short:  $\text{trellis)}$  by additionally considering a time component   ⇒   control variable  $i$.  The following graph contrasts both diagrams for  "our standard convolutional encoder".  The bottom illustration has a resemblance to a  "garden trellis" – assuming some imagination.

State transition diagram vs. trellis diagram for  "our standard convolutional encoder"

Further is to be recognized on the basis of this diagram:

  1.   Since all memory registers are preallocated with zeros,  the trellis always starts from the state  $s_1 = S_0$.  At the next time  $(i = 2)$  only the two states  $S_0$  and  $S_1$  are possible.
  2.   From time  $i = m + 1 = 3$  the trellis has exactly the same appearance for each transition from  $s_i$  to  $s_{i+1}$.  Each state  $S_{\mu}$  is connected to a successor state by a red arrow  $(u_i = 0)$  and a blue arrow  $(u_i = 1)$.
  3.   Versus a  "code tree"  that grows exponentially with each time step  $i$   – see for example section  "Error sizes and total error sizes"   in the book  "Digital Signal Transmission" –  here the number of nodes  $($i.e. possible states$)$  is limited to  $2^m$ .
  4.   This pleasing property of any trellis diagram is also used by the  $\text{Viterbi algorithm}$  for efficient maximum likelihood decoding of convolutional codes.

The following example is to show that there is a  "$1\text{:}1$"  mapping between the string of encoded sequences  $\underline{x}_i$  and the paths through the trellis diagram.

  • Also the information sequence  $\underline{u}$  can be read from the selected trellis path based on the colors of the individual branches.
  • A red branch stands for the information bit  $u_i = 0$,   a blue one for  $u_i = 1$.


$\text{Example 2:}$  In the former  $\text{Example 1}$  the encoded sequence  $\underline{x}$  was derived

  • for our rate  $1/2$  standard convolutional encoder with memory  $m = 2$  and
  • the information sequence  $\underline{u} = (1, 1, 1, 0, 0, 0, 1, 0, 1, \ \text{. ..})$
Trellis diagram of a sample sequence


The table on the right shows the result for  $i ≤ 9$  once again.  The trellis diagram is drawn below.  You can see:

  1.   The selected path through the trellis is obtained by lining up red and blue arrows representing the possible information bits  $u_i \in \{ 0, \ 1\}$ .
  2.   This statement is true for any rate  $1/n$  convolutional code. For a code with  $k > 1$  there would be  $2^k$  different colored arrows.
  3.   For a rate  $1/n$  convolutional code,  the arrows are labeled with the code words  $\underline{x}_i = (x_i^{(1)}, \ \text{...} \ , \ x_i^{(n)})$  which are derived from the information bit  $u_i$  and the current register states  $s_i$.
  4.   For  $n = 2$  there are only four possible code words,  namely  $00, \ 01, \ 10$  and  $11$.
  5.   In vertical direction,  one recognizes from the trellis the register states  $S_{\mu}$.  Given a rate $k/n$ convolutional code with memory order  $m$  there are  $2^{k \hspace{0.05cm}\cdot \hspace{0.05cm}m}$  different states.
  6.   In the present example  $(k = 1, \ m = 2)$  these are the states  $S_0, \ S_1, \ S_2$ and $S_3$.


Definition of the free distance


An important parameter of linear block codes is the  $\text{minimum Hamming distance}$  between any two code words  $\underline{x}$  and  $\underline{x}\hspace{0.05cm}'$:

\[d_{\rm min}(\mathcal{C}) = \min_{\substack{\underline{x},\hspace{0.05cm}\underline{x}' \hspace{0.05cm}\in \hspace{0.05cm} \mathcal{C} \\ {\underline{x}} \hspace{0.05cm}\ne \hspace{0.05cm} \underline{x}\hspace{0.03cm}'}}\hspace{0.1cm}d_{\rm H}(\underline{x}, \hspace{0.05cm}\underline{x}\hspace{0.03cm}')\hspace{0.05cm}.\]
  • Due to linearity,  the zero word   $\underline{0}$   also belongs to each block code.  Thus  $d_{\rm min}$  is identical to the minimum  $\text{Hamming weight}$  $w_{\rm H}(\underline{x})$  of a code word  $\underline{x} ≠ \underline{0}$.
  • For convolutional codes,  however,  the description of the distance ratios proves to be much more complex,  since a convolutional code consists of infinitely long and infinitely many encoded sequences.  Therefore we define here instead of the minimum Hamming distance:


$\text{Definition:}$ 

  • The  »free distance«   $d_{\rm F}$  of a convolutional code is equal to the number of bits in which any two encoded sequences   $\underline{x}$   and   $\underline{x}\hspace{0.03cm}' $  differ  $($at least$)$.
  • In other words:   The free distance is equal to the minimum Hamming distance  between any two paths  through the trellis.


Since convolutional codes are linear,  we can also use the infinite zero sequence as a reference sequence:   $\underline{x}\hspace{0.03cm}' = \underline{0}$.  Thus,  the free distance  $d_{\rm F}$  is equal to the minimum Hamming weight  $($number of  "ones"$)$  of a encoded sequence  $\underline{x} ≠ \underline{0}$.

$\text{Example 3:}$  We consider the null sequence  $\underline{0}$  (marked with white filled circles) as well as two other encoded sequences  $\underline{x}$  and  $\underline{x}\hspace{0.03cm}'$  (with yellow and dark background, respectively) in our standard trellis and characterize these sequences based on the state sequences:

On the definition of free distance
$$\underline{0} =\left ( S_0 \rightarrow S_0 \rightarrow S_0\rightarrow S_0\rightarrow S_0\rightarrow \hspace{0.05cm}\text{...} \hspace{0.05cm}\right)$$
$$\hspace{0.3cm} \Rightarrow \hspace{0.3cm} \underline{0} = \left ( 00, 00, 00, 00, 00,\hspace{0.05cm} \text{...} \hspace{0.05cm}\right) \hspace{0.05cm},$$


$$\ \underline{x} =\left ( S_0 \rightarrow S_1 \rightarrow S_2\rightarrow S_0\rightarrow S_0\rightarrow \hspace{0.05cm}\text{...} \hspace{0.05cm}\right)$$
$$\hspace{0.3cm} \Rightarrow \hspace{0.3cm}\underline{x} == \left ( 11, 10, 11, 00, 00,\hspace{0.05cm} \text{...} \hspace{0.05cm}\right) \hspace{0.05cm},$$


$$\underline{x}\hspace{0.03cm}' = \left ( S_0 \rightarrow S_1 \rightarrow S_3\rightarrow S_2\rightarrow S_0\rightarrow \hspace{0.05cm}\text{...} \hspace{0.05cm}\right)$$
$$\hspace{0.3cm} \Rightarrow \hspace{0.3cm}\underline{x}\hspace{0.03cm}' = \left ( 11, 01, 01, 11, 00,\hspace{0.05cm} \text{...} \hspace{0.05cm}\right) \hspace{0.05cm}.$$


One can see from these plots:

  1.   The free distance  $d_{\rm F} = 5$  is equal to the Hamming weight  $w_{\rm H}(\underline{x})$.
  2.   No sequence other than the one highlighted in yellow differs from   $\underline{0}$   by less than five bits.  For example  $w_{\rm H}(\underline{x}') = 6$.
  3.   In this example,  the free distance   $d_{\rm F} = 5$   also results as the Hamming distance between the sequences   $\underline{x}$   and   $\underline{x}\hspace{0.03cm}'$,  which differ in exactly five bit positions.


The larger the free distance  $d_{\rm F}$,  the better is the  "asymptotic behavior"  of the convolutional encoder.


Optimal convolutional codes of rate  $1/2$

At the outset,  just a few remarks:

  1.   The free distance  $d_{\rm F}$  increases with increasing memory  $m$  provided that one uses appropriate polynomials for the transfer function matrix  $\mathbf{G}(D)$ .
  2.   In the table for rate  $1/2$  convolutional codes,  the  $n = 2$  polynomials are given together with the  $d_{\rm F}$  value.
  3.   Of greater practical importance is the  "industry standard code"  with  $m = 6$  ⇒   $64$  states and the free distance  $d_{\rm F} = 10$  $($in the table this is highlighted in red$)$.


The following example shows the effects of using unfavorable polynomials.

$\text{Example 4:}$  In  $\text{Example 3}$  it was shown that our standard convolutional encoder  $(n = 2, \ k = 1, \ m = 2)$  has the free distance  $d_{\rm F} = 5$.  This is based on the transfer function matrix   $\mathbf{G}(D) = (1 + D + D^2, \ 1 + D^2)$,  as shown in the model  $($without red deletion$)$.

State transition diagram  $\rm C$  for the  modified standard convolutional encoder

Using  $\mathbf{G}(D) = (1 + D, \ 1 + D^2)$   ⇒   red change,  the state transition diagram changes from the  $\text{state transition diagram $\rm A$}$  little at first glance.  However, the  effects are serious:

  1.   The free distance is no longer  $d_{\rm F} = 5$,  but  $d_{\rm F} = 3$,  where the encoded sequence   $\underline{x} = (11, \ 01, \ 00, \ 00, \text{. ..})$   with only three  ones  belonging to the information sequence   $\underline{u} = \underline{1} = (1, \ 1, \ 1, \ 1, \ \text{...})$.
  2.   That is:  By only three transmission errors at positions  12,  and  4,  one falsifies the  "one sequence"  $(\underline{1})$  into the  "zero sequence"  $(\underline{0})$  and thus produces infinitely many decoding errors in state  $S_3$.
  3.   A convolutional encoder with these properties is called  "catastrophic".  The reason for this extremely unfavorable behavior is that here the two polynomials   $1 + D$   and   $1 + D^2$   are not divisor-remote.


Terminated convolutional codes


In the theoretical description of convolutional codes,  one always assumes information sequences  $\underline{u}$  and encoded sequences  $\underline{x}$  that are by definition infinite in length.

  • On the other hand, in practical applications e.g.  $\text{GSM}$  and  $\text{UMTS}$,  one always uses an information sequence of finite length  $L$.
  • For a rate $1/n$ convolutional code,  the encoded sequence then has at least length  $n \cdot L$.


The graph  $($without the gray background$)$  shows the trellis of our standard rate  $1/2$  convolutional code at binary input sequence   $\underline{u}$  of finite length  $L = 128$. 

Terminated convolutional code of rate  $R = 128/260$
  • Thus the encoded sequence  $\underline{x}$  has length  $2 \cdot L = 256$.
  • However,  due to the undefined final state,  a complete maximum likelihood decoding of the transmitted sequence is not possible.
  • Since it is not known which of the states   $S_0, \ \text{...} \ , \ S_3$   would occur for  $i > L$,  the error probability will be  $($somewhat$)$  larger than in the limiting case  $L → ∞$.
  • To prevent this,  the convolutional code is terminated as shown in the diagram:  You add  $m = 2$  zeros to the  $L = 128$  information bits   ⇒   $L' = 130$.
  • This results,  for example,  for the color highlighted path through the trellis:
$$\underline{x}' = (11\hspace{0.05cm},\hspace{0.05cm} 01\hspace{0.05cm},\hspace{0.05cm} 01\hspace{0.05cm},\hspace{0.05cm} 00 \hspace{0.05cm},\hspace{0.05cm} \text{...}\hspace{0.1cm},\hspace{0.05cm} 10\hspace{0.05cm},\hspace{0.05cm}00\hspace{0.05cm},\hspace{0.05cm} 01\hspace{0.05cm},\hspace{0.05cm} 01\hspace{0.05cm},\hspace{0.05cm} 11 \hspace{0.05cm} ) $$
$$\Rightarrow \hspace{0.3cm}\underline{u}' = (1\hspace{0.05cm},\hspace{0.05cm} 1\hspace{0.05cm},\hspace{0.05cm} 0\hspace{0.05cm},\hspace{0.05cm} 1 \hspace{0.05cm},\hspace{0.05cm} \text{...}\hspace{0.1cm},\hspace{0.05cm} 0\hspace{0.05cm},\hspace{0.05cm}1\hspace{0.05cm},\hspace{0.05cm} 1\hspace{0.05cm},\hspace{0.05cm} 0\hspace{0.05cm},\hspace{0.05cm} 0 \hspace{0.05cm} ) \hspace{0.05cm}.$$

The trellis now ends always  $($independent of the data$)$  in the defined final state  $S_0$;  one thus achieves the best possible error probability according to maximum likelihood.

  • However,  the improvement in error probability comes at the cost of a lower code rate.
  • For  $L \gg m$  this loss is only small.  In the considered example,  instead of  $R = 0.5$  with termination the code rate results in
$$R\hspace{0.05cm}' = 0.5 \cdot L/(L + m) \approx 0.492.$$

Punctured convolutional codes


$\text{Definition:}$ 

  • We assume a convolutional code of rate  $R_0 = 1/n_0$  which we call  "mother code".
  • If one deletes some bits from its encoded sequence according to a given pattern,  it is called a  »punctured convolutional code«  with code rate  $R > R_0$.


The puncturing is done using the puncturing matrix  $\mathbf{P}$  with the following properties:

  1.   The row number is  $n_0$,  the column number is equal to the puncturing period  $p$,  which is determined by the desired code rate.
  2.   The  $n_0 \cdot p$  matrix elements  $P_{ij}$  are binary  $(0$  or  $1)$.
  3.   If  $P_{ij} = 1$  the corresponding code bit  $x_{ij}$  is taken,  if  $P_{ij} = 0$  not.
  4.   The rate of the punctured code is equal to the quotient of the puncturing period  $p$  and the number  $N_1$  of  ones  in the  $\mathbf{P}$ matrix.


One can usually find favorably punctured convolutional codes only by means of computer-aided search.  Here,  a punctured convolutional code is said to be favorable if it has

  • the same memory order  $m$  as the parent code,  and also the total influence length is the same in both cases:   $\nu = m + 1$,
  • a free distance  $d_{\rm F}$  as large as possible which is of course smaller than that of the mother code.

$\text{Example 5:}$  Starting from our  $\text{rate 1/2 standard code}$  with parameters  $n_0 = 2$  and  $m = 2$,  we obtain with the puncturing matrix

\[{\boldsymbol{\rm P} } = \begin{pmatrix} 1 & 1 & 0 \\ 1 & 0 & 1 \end{pmatrix}\hspace{0.3cm}\Rightarrow \hspace{0.3cm} p = 3\hspace{0.05cm}, \hspace{0.2cm}N_1 = 4\]

a punctured convolutional code of rate  $R = p/N_1 = 3/4$.

We consider the following constellation for this purpose:

  1.   Information sequence: $\hspace{2.5cm} \underline{u} = (1, 0, 0, 1, 1, 0, \ \text{...}\hspace{0.03cm})$,
  2.   encoded sequence without puncturing: $\hspace{0.35cm} \underline{x} = (11, 1 \color{grey}{0}, \color{gray}{1}1, 11, 0\color{gray}{1}, \color{gray}{0}1, \ \text{...}\hspace{0.03cm})$,
  3.   encoded sequence with puncturing: $\hspace{0.90cm} \underline{x}\hspace{0.05cm}' = (11, 1\_, \_1, 11, 0\_, \_1, \ \text{...}\hspace{0.03cm})$,
  4.   received sequence without errors: $\hspace{0.58cm} \underline{y} = (11, 1\_, \_1, 11, 0\_, \_1, \ \text{...}\hspace{0.03cm})$,
  5.   modified received sequence: $\hspace{1.4cm} \underline{y}\hspace{0.05cm}' = (11, 1\rm E, E1, 11, 0E, E1, \ \text{...}\hspace{0.03cm})$.

Note:

  • So each punctured bit in the received sequence  $\underline{y}$  $($marked by an underscore$)$   is replaced by an  "Erasure"  $\rm (E)$,  see  "Binary Erasure Channel".
  • Such an erasure created by the puncturing  is treated by the decoder in the same way as an erasure by the channel.
  • Of course,  the puncturing increases the error probability.  This can already be seen from the fact that the free distance decreases to  $d_{\rm F} = 3$  after the puncturing.
  • In contrast,  the mother code has the free distance  $d_{\rm F} = 5$.


For example,  puncturing is used in the so-called  $\text{RCPC codes}$  $($"rate compatible punctured convolutional codes"$)$.  More about this in  "Exercise 3.8".


Exercises for the chapter


Exercise 3.6: State Transition Diagram

Exercise 3.6Z: Transition Diagram at 3 States

Exercise 3.7: Comparison of Two Convolutional Encoders

Exercise 3.7Z: Which Code is Catastrophic?

Exercise 3.8: Rate Compatible Punctured Convolutional Codes