Difference between revisions of "Channel Coding/Some Basics of Algebra"

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== # OVERVIEW OF THE SECOND MAIN CHAPTER # ==
 
== # OVERVIEW OF THE SECOND MAIN CHAPTER # ==
 
<br>
 
<br>
This chapter discusses the ''Reed-Solomon codes'', invented in the early 1960s by&nbsp; [https://en.wikipedia.org/wiki/Irving_S._Reed Irving Stoy Reed]&nbsp; and&nbsp; [https://en.wikipedia.org/wiki/Gustave_Solomon Gustave Solomon]&nbsp;. Unlike binary block codes, these are based on a Galois field&nbsp; ${\rm GF}(2^m)$&nbsp; with&nbsp; $m > 1$. So they work with multilevel symbols instead of binary characters (bits).
+
This chapter discusses the&nbsp; &raquo;Reed-Solomon codes&laquo;,&nbsp; invented in the early 1960s by&nbsp; [https://en.wikipedia.org/wiki/Irving_S._Reed $\text{Irving Stoy Reed}$]&nbsp; and&nbsp; [https://en.wikipedia.org/wiki/Gustave_Solomon $\text{Gustave Solomon}$].&nbsp; Unlike binary block codes,&nbsp; these codes are based on a Galois field &nbsp; ${\rm GF}(2^m)$ &nbsp; with&nbsp; $m > 1$.&nbsp; So they work with multi-level symbols instead of binary characters&nbsp; ("bits").
  
Specifically, this chapter covers:
+
Specifically,&nbsp; this chapter covers:
  
*The basics of linear algebra: &nbsp; set, group, ring, field, finite field,
+
*The basics of&nbsp; &raquo;linear algebra&laquo;: &nbsp; &raquo;set&laquo;, &nbsp; &raquo;group&laquo;, &nbsp; &raquo;ring&laquo;, &nbsp; &raquo;field&laquo;,&nbsp; finite field&laquo;,
*the definition of extension fields &nbsp; ⇒ &nbsp; ${\rm GF}(2^m)$&nbsp; and the corresponding operations,
+
 
*the meaning of irreducible polynomials and primitive elements,
+
*the definition of&nbsp; &raquo;extension fields&laquo; &nbsp; ⇒ &nbsp; ${\rm GF}(2^m)$&nbsp; and the corresponding operations,
*the description and realization possibilities of a Reed-Solomon code,
+
 
*the error correction of such a code at the binary ersaure channel (BEC),
+
*the meaning of&nbsp; &raquo;irreducible polynomials&laquo; &nbsp; and&nbsp; &raquo;primitive elements&laquo;,
*the decoding using the ''Error Locator Polynomial'' &nbsp; ⇒ &nbsp; ''Bounded Distance Decoding'' (BDD),
+
 
*the block error probability of Reed-Solomon codes and typical applications.
+
*the&nbsp; &raquo;description and realization possibilities&laquo; &nbsp; of a Reed-Solomon code,
 +
 
 +
*the error correction of such a code at the&nbsp; &raquo;binary ersaure channel&laquo; &nbsp; $\rm (BEC)$,
 +
 
 +
*the decoding using the&nbsp; &raquo;Error Locator Polynomial &nbsp; ⇒ &nbsp; "Bounded Distance Decoding" &nbsp; $\rm (BDD)$,
 +
 
 +
*the&nbsp; &raquo;block error probability&laquo; &nbsp; of Reed-Solomon codes&nbsp; and &nbsp; &raquo;typical applications&laquo;.
  
  
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== Definition of a Galois field ==
 
== Definition of a Galois field ==
 
<br>
 
<br>
Before we can turn to the description of Reed&ndash;Solomon codes, we need some basic algebraic notions. We begin with the properties of the Galois field&nbsp; ${\rm GF}(q)$, named after the Frenchman&nbsp; [https://en.wikipedia.org/wiki/%C3%89variste_Galois Évariste Galois], whose biography is rather unusual for a mathematician.<br>
+
Before we can turn to the description of&nbsp; Reed&ndash;Solomon codes,&nbsp; we need some basic algebraic notions.&nbsp; We begin with the properties of the Galois field &nbsp; ${\rm GF}(q)$,&nbsp; named after the Frenchman&nbsp; [https://en.wikipedia.org/wiki/%C3%89variste_Galois $\text{Évariste Galois}$], whose biography is rather unusual for a mathematician.<br>
  
 
{{BlaueBox|TEXT=   
 
{{BlaueBox|TEXT=   
$\text{Definition:}$&nbsp;  A&nbsp; $\rm Galois\:field$&nbsp; ${\rm GF}(q)$&nbsp; is a&nbsp; [[Channel_Coding/Some_Basics_of_Algebra#Definition_and_Examples_of_an_Algebraic_Ring| finite field]]&nbsp; with&nbsp; $q$&nbsp; elements&nbsp; $z_0$,&nbsp; $z_1$,&nbsp; ... ,&nbsp; $z_{q-1}$, if the eight statements listed below &nbsp;$\rm (A)$&nbsp; ... &nbsp;$\rm (H)$&nbsp; with respect to ''addition'' ("$+$") and ''multiplication'' ("$\cdot $") are true.   
+
$\text{Definition:}$&nbsp;  A &nbsp; $\rm Galois\:field$&nbsp; ${\rm GF}(q)$&nbsp; is a&nbsp; [[Channel_Coding/Some_Basics_of_Algebra#Group.2C_ring.2C_field_-_basic_algebraic_concepts|$\text{finite field}$]]&nbsp; with&nbsp; $q$&nbsp; elements&nbsp; $z_0$,&nbsp; $z_1$,&nbsp; ... ,&nbsp; $z_{q-1}$, if the eight statements listed below &nbsp;$\rm (A)$&nbsp; ... &nbsp;$\rm (H)$&nbsp; with respect to&nbsp; "addition" &nbsp; &rArr; &nbsp; "$+$" &nbsp; and&nbsp; "multiplication"&nbsp; &rArr; &nbsp;"$\hspace{0.05cm}\cdot \hspace{0.05cm}$" &nbsp; are true.   
 
*Addition and multiplication are to be understood here modulo&nbsp; $q$&nbsp;.
 
*Addition and multiplication are to be understood here modulo&nbsp; $q$&nbsp;.
*The&nbsp; $\rm order$&nbsp; $q$&nbsp; indicates the number of elements of the Galois field}}.
+
 
 +
*The&nbsp; $\rm order$&nbsp; $q$&nbsp; indicates the number of elements of the Galois field.}}
  
  
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\hspace{0.05cm}. </math>
 
\hspace{0.05cm}. </math>
  
$\rm (B)$&nbsp; There is a neutral element $N_{\rm A}$ with respect to addition, the so-called <i>zero element</i>. $\hspace{0.2cm}\Rightarrow \hspace{0.2cm}\rm Identity \ for \ "\hspace{-0.05cm}+\hspace{0.05cm}"$:
+
$\rm (B)$&nbsp; There is a neutral element&nbsp; $N_{\rm A}$&nbsp; with respect to addition,&nbsp; the so-called&nbsp; "zero element" $\hspace{0.2cm}\Rightarrow \hspace{0.2cm}\rm Identity \ for \ "\hspace{-0.05cm}+\hspace{0.05cm}"$:
  
 
::<math>\exists \hspace{0.15cm} z_j \in {\rm GF}(q)\text{:}
 
::<math>\exists \hspace{0.15cm} z_j \in {\rm GF}(q)\text{:}
 
\hspace{0.25cm}z_i + z_j  = z_i \hspace{0.25cm} \Rightarrow \hspace{0.25cm} z_j  = N_{\rm A} = \text{ 0} \hspace{0.05cm}.</math>
 
\hspace{0.25cm}z_i + z_j  = z_i \hspace{0.25cm} \Rightarrow \hspace{0.25cm} z_j  = N_{\rm A} = \text{ 0} \hspace{0.05cm}.</math>
  
$\rm (C)$&nbsp; There is a neutral element $N_{\rm M}$ with respect to multiplication, the so-called <i>identity element</i> $\hspace{0.2cm}\Rightarrow \hspace{0.2cm}\rm Identity \ for \ "\hspace{-0.05cm}&middot;\hspace{0.05cm}"$:
+
$\rm (C)$&nbsp; There is a neutral element&nbsp; $N_{\rm M}$&nbsp; with respect to multiplication,&nbsp; the so-called&nbsp; "identity element" $\hspace{0.2cm}\Rightarrow \hspace{0.2cm}\rm Identity \ for \ "\hspace{-0.05cm}&middot;\hspace{0.05cm}"$:
  
 
::<math>\exists \hspace{0.15cm} z_j \in {\rm GF}(q)\text{:}
 
::<math>\exists \hspace{0.15cm} z_j \in {\rm GF}(q)\text{:}
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\hspace{0.05cm}. </math>
 
\hspace{0.05cm}. </math>
  
$\rm (D)$&nbsp; For each&nbsp; $z_i$&nbsp; there exists an ''additive inverse'' &nbsp; ${\rm Inv_A}(z_i)$  $\hspace{0.2cm}\Rightarrow \hspace{0.2cm}\rm Inverse \ for \ "\hspace{-0.05cm}+\hspace{0.05cm}"$:
+
$\rm (D)$&nbsp; For each&nbsp; $z_i$&nbsp; there exists an&nbsp; "additive inverse" &nbsp; ${\rm Inv_A}(z_i)$  $\hspace{0.2cm}\Rightarrow \hspace{0.2cm}\rm Inverse \ for \ "\hspace{-0.05cm}+\hspace{0.05cm}"$:
  
 
::<math>\forall \hspace{0.15cm}  z_i \in {\rm GF}(q),\hspace{0.15cm} \exists \hspace{0.15cm} {\rm Inv_A}(z_i) \in {\rm GF}(q)\text{:}
 
::<math>\forall \hspace{0.15cm}  z_i \in {\rm GF}(q),\hspace{0.15cm} \exists \hspace{0.15cm} {\rm Inv_A}(z_i) \in {\rm GF}(q)\text{:}
\hspace{0.25cm}z_i + {\rm Inv_A}(z_i) = N_{\rm A} = {0}  \hspace{0.3cm}\Rightarrow \hspace{0.3cm}\text{kurz:}\hspace{0.3cm}
+
\hspace{0.25cm}z_i + {\rm Inv_A}(z_i) = N_{\rm A} = {0}  \hspace{0.3cm}\Rightarrow \hspace{0.3cm}\text{short:}\hspace{0.3cm}
 
{\rm Inv_A}(z_i) = - z_i \hspace{0.05cm}. </math>
 
{\rm Inv_A}(z_i) = - z_i \hspace{0.05cm}. </math>
  
$\rm (E)$&nbsp; For each&nbsp; $z_i$&nbsp; except the zero element, there exists the ''multiplicative inverse'' &nbsp; ${\rm Inv_M}(z_i)$ $\hspace{0.2cm}\Rightarrow \hspace{0.2cm}\rm Inverse \ for \ "\hspace{-0.05cm}\cdot\hspace{0.05cm}"$:
+
$\rm (E)$&nbsp; For each&nbsp; $z_i$&nbsp; except the zero element,&nbsp; there exists the&nbsp; "multiplicative inverse" &nbsp; ${\rm Inv_M}(z_i)$ $\hspace{0.2cm}\Rightarrow \hspace{0.2cm}\rm Inverse \ for \ "\hspace{-0.05cm}\cdot\hspace{0.05cm}"$:
  
 
::<math>\forall \hspace{0.15cm}  z_i \in {\rm GF}(q),\hspace{0.15cm} z_i \ne N_{\rm A}, \hspace{0.15cm} \exists \hspace{0.15cm} {\rm Inv_M}(z_i) \in {\rm GF}(q)\text{:}
 
::<math>\forall \hspace{0.15cm}  z_i \in {\rm GF}(q),\hspace{0.15cm} z_i \ne N_{\rm A}, \hspace{0.15cm} \exists \hspace{0.15cm} {\rm Inv_M}(z_i) \in {\rm GF}(q)\text{:}
\hspace{0.25cm}z_i \cdot {\rm Inv_M}(z_i) = N_{\rm M} = {1}\hspace{0.3cm}\Rightarrow \hspace{0.3cm}\text{kurz:}\hspace{0.3cm}
+
\hspace{0.25cm}z_i \cdot {\rm Inv_M}(z_i) = N_{\rm M} = {1}\hspace{0.3cm}\Rightarrow \hspace{0.3cm}\text{short:}\hspace{0.3cm}
 
{\rm Inv_M}(z_i) = z_i^{-1}
 
{\rm Inv_M}(z_i) = z_i^{-1}
 
\hspace{0.05cm}. </math>
 
\hspace{0.05cm}. </math>
  
$\rm (F)$&nbsp; For addition and multiplication the ''commutative law'' applies in each case $\hspace{0.2cm}\Rightarrow \hspace{0.2cm}\rm Commutative \ Law$:
+
$\rm (F)$&nbsp; For addition and multiplication applies in each case the&nbsp; "$\rm Commutative \ Law$":
  
 
::<math>\forall \hspace{0.15cm}  z_i,\hspace{0.15cm} z_j \in {\rm GF}(q)\text{:}
 
::<math>\forall \hspace{0.15cm}  z_i,\hspace{0.15cm} z_j \in {\rm GF}(q)\text{:}
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\hspace{0.05cm}.</math>
 
\hspace{0.05cm}.</math>
  
$\rm (G)$&nbsp; For addition and multiplication, the ''associative law'' applies in each case $\hspace{0.2cm}\Rightarrow \hspace{0.2cm}\rm Associative \ Law$:
+
$\rm (G)$&nbsp; For addition and multiplication applies in each case the&nbsp; "$\rm Associative \ Law$":
  
 
::<math>\forall \hspace{0.15cm}  z_i,\hspace{0.1cm} z_j ,\hspace{0.1cm} z_k \in {\rm GF}(q)\text{:}
 
::<math>\forall \hspace{0.15cm}  z_i,\hspace{0.1cm} z_j ,\hspace{0.1cm} z_k \in {\rm GF}(q)\text{:}
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\hspace{0.05cm}.</math>
 
\hspace{0.05cm}.</math>
  
$\rm (H)$&nbsp; For the combination "addition &ndash; multiplication" the ''distributive law'' is valid $\hspace{0.2cm}\Rightarrow \hspace{0.2cm}\rm Distributive \ Law$:
+
$\rm (H)$&nbsp; For the combination&nbsp; "addition &ndash; multiplication"&nbsp; holds the&nbsp; "$\rm Distributive \ Law$":
 
::<math>\forall \hspace{0.15cm}  z_i,\hspace{0.15cm} z_j ,\hspace{0.15cm} z_k \in {\rm GF}(q)\text{:}
 
::<math>\forall \hspace{0.15cm}  z_i,\hspace{0.15cm} z_j ,\hspace{0.15cm} z_k \in {\rm GF}(q)\text{:}
 
\hspace{0.25cm}(z_i + z_j) \cdot z_k = z_i \cdot z_k + z_j \cdot z_k  
 
\hspace{0.25cm}(z_i + z_j) \cdot z_k = z_i \cdot z_k + z_j \cdot z_k  
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== Examples and Properties of Galois fields ==
+
== Examples and properties of Galois fields ==
 
<br>
 
<br>
Wir überprüfen zunächst, ob für die binäre Zahlenmenge&nbsp; $Z_2 = \{0, 1\}$ &nbsp; &#8658; &nbsp; $q=2$&nbsp; (gültig für den einfachen Binärcode) die auf der letzten Seite genannten acht Kriterien erfüllt werden, so dass man tatsächlich von "${\rm GF}(2)$" sprechen kann. Sie sehen nachfolgend die Additions&ndash; und Multiplikationstabelle:
+
We first check that for the binary number set&nbsp; $Z_2 = \{0, 1\}$ &nbsp; &#8658; &nbsp; $q=2$ &nbsp; $($valid for the simple binary code$)$
 +
*the eight criteria mentioned in the last section are met,
 +
 +
*so that we can indeed speak of&nbsp; "${\rm GF}(2)$".  
 +
 
 +
 
 +
You can see the addition table and multiplication table below:
  
 
:$$Z_2 = \{0, 1\}\hspace{0.25cm} \Rightarrow\hspace{0.25cm}\text{Addition:      }  
 
:$$Z_2 = \{0, 1\}\hspace{0.25cm} \Rightarrow\hspace{0.25cm}\text{Addition:      }  
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                                                           0 & 0 & 1  \\  
 
                                                           0 & 0 & 1  \\  
 
                                                           1 & 1 & 0   
 
                                                           1 & 1 & 0   
\end{array} \right] \hspace{-0.1cm} ,\hspace{0.25cm}\text{Multiplikation:      }  
+
\end{array} \right] \hspace{-0.1cm} ,\hspace{0.25cm}\text{Multiplication:      }  
 
\left[ \begin{array}{c|cccccc} \cdot & 0 & 1 \\ \hline  
 
\left[ \begin{array}{c|cccccc} \cdot & 0 & 1 \\ \hline  
 
                                                           0 & 0 & 0  \\
 
                                                           0 & 0 & 0  \\
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$$
 
$$
  
Man erkennt aus dieser Darstellung:
+
One can see from this representation:
*Jedes Element der Additions&ndash; und der Multiplikationstabelle von&nbsp; $Z_2$&nbsp; ist wieder&nbsp; $z_0 = 0$&nbsp; oder&nbsp; $z_0 = 1$ &nbsp; &#8658; &nbsp; das Kriterium&nbsp; $\rm (A)$&nbsp; ist erfüllt.<br>
+
#Each element of the addition and multiplication table of&nbsp; $Z_2$&nbsp; is again&nbsp; $z_0 = 0$&nbsp; or&nbsp; $z_0 = 1$ &nbsp; &#8658; &nbsp; the criterion&nbsp; $\rm (A)$&nbsp; is satisfied.<br>
 
+
#The set&nbsp; $Z_2$&nbsp; contains the zero element&nbsp; $(\hspace{-0.05cm}N_{\rm A} = z_0 = 0)$&nbsp; and the one element $(\hspace{-0.05cm}N_{\rm M} = z_1 = 1)$&nbsp; &#8658; &nbsp; the criteria&nbsp; $\rm (B)$&nbsp; and&nbsp; $\rm (C)$&nbsp; are satisfied.<br>
*Die Menge&nbsp; $Z_2$&nbsp; enthält das Nullelement&nbsp; $(\hspace{-0.05cm}N_{\rm A} = z_0 = 0)$&nbsp; und das Einselement  $(\hspace{-0.05cm}N_{\rm M} = z_1 = 1)$ &nbsp; &#8658; &nbsp; die Kriterien&nbsp; $\rm (B)$&nbsp; und&nbsp; $\rm (C)$&nbsp; sind erfüllt.<br>
+
#The additive inverses&nbsp; ${\rm Inv_A}(0) = 0$&nbsp; and&nbsp; ${\rm Inv_A}(1) = -1 \ {\rm mod}\  2 = 1$&nbsp; exist and belong to&nbsp; $Z_2$ &nbsp; &#8658; &nbsp; the criterion&nbsp; $\rm (D)$&nbsp; is satisfied.  
 
+
#Similarly, the multiplicative inverse&nbsp; ${\rm Inv_M}(1) = 1$ &nbsp; &#8658; &nbsp; the criterion&nbsp; $\rm (E)$&nbsp; is satisfied.<br>
*Die additiven Inversen&nbsp; ${\rm Inv_A}(0) = 0$&nbsp; und&nbsp; ${\rm Inv_A}(1) = -1 \ {\rm mod}\  2 = 1$&nbsp; existieren und gehören zu&nbsp; $Z_2$.  
+
#The validity of the commutative law&nbsp; $\rm (F)$&nbsp; in the set&nbsp; $Z_2$&nbsp; can be recognized by the symmetry with respect to the table diagonals.  
*Ebenso gibt es die multiplikative Inverse&nbsp; ${\rm Inv_M}(1) = 1$ &nbsp; &#8658; &nbsp; die Kriterien&nbsp; $\rm (D)$&nbsp; und&nbsp; $\rm (E)$&nbsp; sind erfüllt.<br>
+
#The criteria&nbsp; $\rm (G)$&nbsp; and&nbsp; $\rm (H)$&nbsp; are also satisfied here&nbsp; &#8658; &nbsp; all eight criteria are satisfied&nbsp; &#8658; &nbsp; $Z_2 = \rm GF(2)$.<br>
 
 
*Die Gültigkeit des Kommutativgesetzes&nbsp; $\rm (F)$&nbsp; in der Menge&nbsp; $Z_2$&nbsp; erkennt man an der Symmetrie bezüglich der Tabellendiagonalen.  
 
*Die Kriterien&nbsp; $\rm (G)$&nbsp; und&nbsp; $\rm (H)$&nbsp; werden hier ebenfalls erfüllt &nbsp; &#8658; &nbsp; alle acht Kriterien sind erfüllt &nbsp; &#8658; &nbsp; $Z_2 = \rm GF(2)$.<br>
 
  
  
 
{{GraueBox|TEXT=   
 
{{GraueBox|TEXT=   
$\text{Beispiel 1:}$&nbsp;  Die Zahlenmenge&nbsp; $Z_3 = \{0, 1, 2\}$ &nbsp; &#8658; &nbsp; $q = 3$&nbsp; erfüllt alle acht Kriterien und ist somit ein Galoisfeld&nbsp; $\rm GF(3)$:
+
$\text{Example 1:}$&nbsp;  The number set&nbsp; $Z_3 = \{0, 1, 2\}$ &nbsp; &#8658; &nbsp; $q = 3$&nbsp; satisfies all eight criteria and is thus a Galois field&nbsp; $\rm GF(3)$:
  
 
:$$Z_3 = \{0, 1, 2\}\hspace{0.25cm} \Rightarrow\hspace{0.25cm}\text{Addition:      }  
 
:$$Z_3 = \{0, 1, 2\}\hspace{0.25cm} \Rightarrow\hspace{0.25cm}\text{Addition:      }  
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                                                           1 & 1 & 2 & 0 \\  
 
                                                           1 & 1 & 2 & 0 \\  
 
                                                           2 & 2 & 0 & 1   
 
                                                           2 & 2 & 0 & 1   
\end{array} \right] \hspace{-0.1cm} ,\hspace{0.25cm}\text{Multiplikation:      }  
+
\end{array} \right] \hspace{-0.1cm} ,\hspace{0.25cm}\text{Multiplication:      }  
 
\left[ \begin{array}{c {{!}} cccccc} \cdot & 0 & 1  & 2\\ \hline  
 
\left[ \begin{array}{c {{!}} cccccc} \cdot & 0 & 1  & 2\\ \hline  
 
                                                           0 & 0 & 0 & 0 \\  
 
                                                           0 & 0 & 0 & 0 \\  
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{{GraueBox|TEXT=   
 
{{GraueBox|TEXT=   
$\text{Beispiel 2:}$&nbsp;  Dagegen ist die Zahlenmenge&nbsp; $Z_4 = \{0, 1, 2, 3\}$ &nbsp; &#8658; &nbsp; $q = 4$&nbsp; kein Galoisfeld.  
+
$\text{Example 2:}$&nbsp;  In contrast,&nbsp; the number set&nbsp; $Z_4 = \{0, 1, 2, 3\}$ &nbsp; &#8658; &nbsp; $q = 4$&nbsp; is&nbsp; &raquo;'''not'''&laquo;&nbsp; a Galois field.  
*Der Grund hierfür ist, dass es hier zum Element&nbsp; $z_2 = 2$&nbsp; keine multiplikative Inverse gibt. Bei einem Galoisfeld müsste nämlich gelten: &nbsp; $2 \cdot {\rm Inv_M}(2) = 1$.
+
*The reason for this is that here is no multiplicative inverse to the element&nbsp; $z_2 = 2$.&nbsp; For a Galois field it would have to be true: &nbsp; $2 \cdot {\rm Inv_M}(2) = 1$.
*In der Multiplikationstabelle gibt es aber in der dritten Zeile und dritten Spalte  $($jeweils gültig für den Multiplikanden&nbsp; $z_2 = 2)$&nbsp; keinen Eintrag mit "$1$".
+
 
 +
*But in the multiplication table there is no entry with&nbsp; "$1$"&nbsp; in the third row and third column&nbsp; $($each valid for the multiplicand&nbsp; $z_2 = 2)$.
  
 
:$$Z_4 = \{0, 1, 2, 3\}\hspace{0.25cm} \Rightarrow\hspace{0.25cm}\text{Addition:      }  
 
:$$Z_4 = \{0, 1, 2, 3\}\hspace{0.25cm} \Rightarrow\hspace{0.25cm}\text{Addition:      }  
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                                                           2 & 2 & 3 & 0 & 1\\  
 
                                                           2 & 2 & 3 & 0 & 1\\  
 
                                                           3 & 3 & 0 & 1 & 2  
 
                                                           3 & 3 & 0 & 1 & 2  
\end{array} \right] \hspace{-0.1cm} ,\hspace{0.25cm}\text{Multiplikation:      }  
+
\end{array} \right] \hspace{-0.1cm} ,\hspace{0.25cm}\text{Multiplication:      }  
 
\left[ \begin{array}{c {{!}} cccccc} \cdot& 0 & 1  & 2 & 3\\ \hline  
 
\left[ \begin{array}{c {{!}} cccccc} \cdot& 0 & 1  & 2 & 3\\ \hline  
 
                                                           0 & 0 & 0 & 0 & 0\\  
 
                                                           0 & 0 & 0 & 0 & 0\\  
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                                                           2 & 0 & 2 & 0 & 2\\  
 
                                                           2 & 0 & 2 & 0 & 2\\  
 
                                                           3 & 0 & 3 & 2 & 1  
 
                                                           3 & 0 & 3 & 2 & 1  
\end{array} \right]\hspace{0.25cm} \Rightarrow\hspace{0.25cm}\text{kein }{\rm GF}(4) .
+
\end{array} \right]\hspace{0.25cm} \Rightarrow\hspace{0.25cm}\text{no }{\rm GF}(4) .
 
$$}}
 
$$}}
  
  
 
{{BlaueBox|TEXT=   
 
{{BlaueBox|TEXT=   
$\text{Verallgemeinerung (vorerst ohne Beweis):}$
+
$\text{Generalization (without proof for now):}$
*Ein Galoisfeld&nbsp; ${\rm GF}(q)$&nbsp; kann in der hier beschriebenen Weise als&nbsp; [[Channel_Coding/Einige_Grundlagen_der_Algebra#Definition_und_Beispiele_eines_algebraischen_Rings| "Ring"]]&nbsp; von Integergrößen modulo&nbsp; $q$&nbsp; nur dann gebildet werden, wenn&nbsp; $q$&nbsp; eine Primzahl ist: &nbsp; <br> &nbsp; &nbsp; $q = 2$,&nbsp; $q = 3$,&nbsp; $q = 5$,&nbsp; $q = 7$,&nbsp; $q = 11$, ...<br>
+
*A Galois field&nbsp; ${\rm GF}(q)$&nbsp; can be formed in the manner described here as&nbsp; [[Channel_Coding/Some_Basics_of_Algebra#Definition_and_examples_of_an_algebraic_ring| $\text{ring}$]]&nbsp; of integer sizes modulo&nbsp; $q$&nbsp; only if&nbsp; $q$&nbsp; is a prime number: &nbsp; <br> &nbsp; &nbsp; $q = 2$,&nbsp; $q = 3$,&nbsp; $q = 5$,&nbsp; $q = 7$,&nbsp; $q = 11$, ...<br>
  
*Kann man aber die Ordnung&nbsp; $q$&nbsp; in der Form&nbsp; $q = P^m$&nbsp; mit einer Primzahl&nbsp; $P$&nbsp; und ganzzahligem&nbsp; $m$&nbsp; ausdrücken, so lässt sich das Galoisfeld&nbsp; ${\rm GF}(q)$&nbsp; über einen&nbsp; [[Channel_Coding/Erweiterungskörper#Verallgemeinerte_Definition_eines_Erweiterungsk.C3.B6rpers|Erweiterungskörper]]&nbsp; finden.}}<br>
+
*But if the order&nbsp; $q$&nbsp; can be expressed in the form&nbsp; $q = P^m$&nbsp; with a prime&nbsp; $P$&nbsp; and integer&nbsp; $m$,&nbsp; the Galois field&nbsp; ${\rm GF}(q)$&nbsp; can be found via an&nbsp; [[Channel_Coding/Extension_Field#Generalized_definition_of_an_extension_field|$\text{extension field}$]].&nbsp; }}<br>
  
== Gruppe, Ring, Körper – algebraische Grundbegriffe ==
+
== Group, ring, field - basic algebraic concepts ==
 
<br>
 
<br>
Auf den ersten Seiten sind bereits einige algebraische Grundbegriffe gefallen, ohne dass deren Bedeutungen genauer erläutert wurden. Dies soll nun in aller Kürze aus Sicht eines Nachrichtentechnikers nachgeholt werden, wobei wir uns vorwiegend auf die Darstellung in&nbsp; [Fri96]<ref name='Fri96'>Friedrichs, B.: ''Kanalcodierung – Grundlagen und Anwendungen in modernen Kommunikationssystemen.'' Berlin – Heidelberg: Springer, 1996.</ref>&nbsp; und&nbsp;  [KM+08]<ref name='KM+08'>Kötter, R.; Mayer, T.; Tüchler, M.; Schreckenbach, F.; Brauchle, J.: ''Channel Coding.'' Vorlesungsmanuskript, Lehrstuhl für Nachrichtentechnik, TU München, 2008.</ref>&nbsp; beziehen. Zusammenfassend lässt sich sagen:<br>
+
In the first sections,&nbsp; some basic algebraic terms have already been mentioned,&nbsp; without their meanings having been explained in more detail.&nbsp; This is to be made up now in all shortness from view of a communication engineer, whereby we mainly refer to the representation in&nbsp; [Fri96]<ref name='Fri96'>Friedrichs, B.:&nbsp; Kanalcodierung – Grundlagen und Anwendungen in modernen Kommunikationssystemen.&nbsp; Berlin – Heidelberg: Springer, 1996.</ref>&nbsp; and&nbsp;  [KM+08]<ref name='KM+08'>Kötter, R.; Mayer, T.; Tüchler, M.; Schreckenbach, F.; Brauchle, J.:&nbsp; Channel Coding.&nbsp; Lecture manuscript, Chair of Communications Engineering, TU Munich, 2008.</ref>.&nbsp; To summarize:<br>
  
 
{{BlaueBox|TEXT=   
 
{{BlaueBox|TEXT=   
$\text{Definition:}$&nbsp;  Ein&nbsp; $\rm Galoisfeld$&nbsp; ${\rm GF}(q)$ ist ein ''Körper''&nbsp; (englisch: &nbsp;<i>Field</i>) mit einer begrenzten Anzahl&nbsp; $(q)$&nbsp; an Elementen &nbsp; &#8658; &nbsp; <i>endlicher Körper</i>. Jeder Körper ist wieder ein Sonderfall eines ''Rings''&nbsp; (gleichlautende englische Bezeichnung), der sich selbst wieder als Spezialfall einer ''Abelschen Gruppe''&nbsp; (englisch: &nbsp;<i>Abelian Group</i>) darstellen lässt.}}<br>
+
$\text{Definition:}$&nbsp;   
 +
*A&nbsp; $\rm Galois\, field$&nbsp; ${\rm GF}(q)$ is a&nbsp; "field"&nbsp; with a finite number&nbsp; $(q)$&nbsp; of elements &nbsp; &#8658; &nbsp; &raquo;'''finite field'''&laquo;.&nbsp;
 +
 
 +
*Each field is again a special case of a&nbsp; "ring",&nbsp; which itself can be represented again as a special case of an&nbsp; "Abelian group".}}<br>
 +
 
 +
[[File:EN_KC_T_2_1_S2.png|right|frame|Algebraic relations between group, ring and field|class=fit]]
 +
The diagram illustrates step by step how the following subordinate sets arise from a set&nbsp; $\mathcal{M}$&nbsp; by definition of addition, multiplication and division:
 +
*Abelian group&nbsp; $\mathcal{G}$ ,
 +
*ring&nbsp; $\mathcal{R}$,
 +
*field&nbsp; $\mathcal{F}$,
 +
*finite field&nbsp; $\mathcal{F}_q$&nbsp; or Galois field&nbsp; ${\rm GF}(q)$.
  
[[File:EN_KC_T_2_1_S2.png|right|frame|Algebraische Zusammenhänge zwischen Gruppe, Ring und Körper|class=fit]]
 
Die Grafik verdeutlicht schrittweise, wie sich aus einer Menge durch Definition von Additition, Multiplikation und Division innerhalb dieser Menge&nbsp; $\mathcal{M}$&nbsp; folgende untergeordnete Mengen ergeben:
 
*Abelsche Gruppe&nbsp; $\mathcal{G}$&nbsp;  (englisch: &nbsp;<i>Field</i>&nbsp;) ,
 
*Ring&nbsp; $\mathcal{R}$,
 
*Körper&nbsp; $\mathcal{K}$&nbsp;  (englisch: &nbsp;<i>Field</i> $\mathcal{F}$),
 
*endlicher Körper&nbsp; $\mathcal{F}_q$&nbsp; oder Galoisfeld&nbsp; ${\rm GF}(q)$.
 
  
 +
In the next two sections, the algebraic terms mentioned here will be discussed in more detail.
 +
*For understanding the Reed&ndash;Solomon codes, however, this knowledge is not absolutely necessary.
  
Auf den beiden nächsten Seiten werden die hier genannten algebraischen Begriffe genauer behandelt.
+
*So you could jump directly to the chapter&nbsp; [[Channel_Coding/Extension_Field#Verallgemeinerte_Definition_eines_Erweiterungsk.C3.B6rpers| "Extension Field"]]&nbsp;.<br>  
*Zum Verstehen der Reed&ndash;Solomon&ndash;Codes sind diese Kenntnisse allerdings nicht unbedingt erforderlich.
 
*Sie könnten also direkt zum Kapitel&nbsp; [[Channel_Coding/Erweiterungskörper| Erweiterungskörper]]&nbsp; springen.<br>  
 
  
  
== Definition und  Beispiele einer algebraischen Gruppe ==
+
== Definition and examples of an algebraic group ==
 
<br>
 
<br>
Für die allgemeinen Definitionen von Gruppe (und später Ring) gehen wir von einer Menge mit unendlich vielen Elementen aus:
+
For the general definitions of&nbsp; "group"&nbsp; (and later&nbsp; "ring")&nbsp; we assume a set with infinitely many elements:
  
 
::<math>\mathcal{M} = \{\hspace{0.1cm}z_1,\hspace{0.1cm} z_2,\hspace{0.1cm} z_3 ,\hspace{0.1cm}\text{ ...} \hspace{0.1cm}\}\hspace{0.05cm}. </math>
 
::<math>\mathcal{M} = \{\hspace{0.1cm}z_1,\hspace{0.1cm} z_2,\hspace{0.1cm} z_3 ,\hspace{0.1cm}\text{ ...} \hspace{0.1cm}\}\hspace{0.05cm}. </math>
  
 
{{BlaueBox|TEXT=   
 
{{BlaueBox|TEXT=   
$\text{Definition:}$&nbsp;  Eine&nbsp; $\text{algebraische Gruppe}$&nbsp; $(\mathcal{G}, +)$&nbsp; ist eine (beliebige) Teilmenge&nbsp; $\mathcal{G} &#8834; \mathcal{M}$&nbsp; zusammen mit einer zwischen allen Elementen definierten additiven Verknüpfung ("$+$"), allerdings nur dann, wenn die folgenden Eigenschaften zwingend erfüllt sind:
+
$\text{Definition:}$&nbsp;  A&nbsp; $\text{algebraic group}$&nbsp; $(\mathcal{G}, +)$&nbsp; is an&nbsp; (arbitrary)&nbsp; subset&nbsp; $\mathcal{G} &#8834; \mathcal{M}$&nbsp; together with an additive linkage&nbsp; $($"$+$"$)$&nbsp; defined between all elements,&nbsp; but only if the following properties are necessarily satisfied:
*Für alle&nbsp; $z_i, z_j &#8712; \mathcal{G}$&nbsp; gilt&nbsp; $(z_i + z_j) &#8712; \mathcal{G}$ &nbsp; &#8658; &nbsp; <i>Closure</i>&ndash;Kriterium für&nbsp; "$+$".<br>
+
#For all&nbsp; $z_i, z_j &#8712; \mathcal{G}$&nbsp; holds&nbsp; $(z_i + z_j) &#8712; \mathcal{G}$ &nbsp; &#8658; &nbsp; "Closure&ndash;criterion for&nbsp; $+$".<br>
*Es gibt stets ein hinsichtlich der Addition neutrales Element&nbsp; $N_{\rm A} &#8712; \mathcal{G}$, so dass für alle&nbsp; $z_i &#8712; \mathcal{G}$ gilt: &nbsp; $z_i +N_{\rm A} = z_i$. Bei einer Zahlengruppe ist&nbsp; $N_{\rm A} \equiv 0$.<br>
+
#There is always a neutral element&nbsp; $N_{\rm A} &#8712; \mathcal{G}$&nbsp; with respect to addition,&nbsp; so that for all&nbsp; $z_i &#8712; \mathcal{G}$ holds: &nbsp; $z_i +N_{\rm A} = z_i$.&nbsp; Given a group of numbers: &nbsp; $N_{\rm A} \equiv 0$.<br>
 +
#For all&nbsp; $z_i &#8712; \mathcal{G}$&nbsp; there is an inverse element&nbsp; ${\rm Inv_A}(z_i) &#8712; \mathcal{G}$&nbsp; with respect to addition:&nbsp; $z_i + {\rm Inv_A}(z_i)= N_{\rm A} $.&nbsp; For a number group:&nbsp; ${\rm Inv_A}(z_i) =- z_i$.<br>
 +
#For all&nbsp; $z_i, z_j, z_k &#8712; \mathcal{G}$&nbsp; holds:&nbsp; $z_i + (z_j + z_k)= (z_i + z_j) + z_k$ &nbsp; &#8658; &nbsp; "Associative law&nbsp; for&nbsp; $+$".<br>
 +
#If in addition for all&nbsp; $z_i, z_j &#8712; \mathcal{G}$&nbsp; the&nbsp; "commutative law"&nbsp; $z_i + z_j= z_j + z_i$&nbsp; is satisfied,&nbsp; one speaks of a&nbsp;  "commutative group"&nbsp; or an&nbsp;  "Abelian group",&nbsp; named after the Norwegian mathematician&nbsp; [https://en.wikipedia.org/wiki/Niels_Henrik_Abel $\text{Niels Hendrik Abel}$].}}<br>
  
*Für alle&nbsp; $z_i &#8712; \mathcal{G}$&nbsp; gibt es zudem ein hinsichtlich der Addition inverses Element&nbsp; ${\rm Inv_A}(z_i) &#8712; \mathcal{G}$&nbsp; mit der Eigenschaft&nbsp; $z_i + {\rm Inv_A}(z_i)= N_{\rm A} $. <br>Bei einer Zahlengruppe ist&nbsp; ${\rm Inv_A}(z_i) =- z_i$.<br>
+
{{GraueBox|TEXT= 
 +
$\text{Examples of algebraic groups:}$
  
*Für alle&nbsp; $z_i, z_j, z_k &#8712; \mathcal{G}$&nbsp; gilt:&nbsp; $z_i + (z_j + z_k)= (z_i + z_j) + z_k$ &nbsp; &#8658; &nbsp; ''Assoziativgesetz''&nbsp; für&nbsp; "$+$".<br><br>
+
'''(1)'''&nbsp; The&nbsp; "set of rational numbers"&nbsp; is defined as the set of all quotients&nbsp; $I/J$&nbsp; with integers&nbsp; $I$&nbsp; and&nbsp; $J &ne; 0$.
 +
:This set is a group&nbsp; $(\mathcal{G}, +)$&nbsp; with respect to addition,&nbsp; since
 +
:*for all&nbsp; $a &#8712; \mathcal{G}$&nbsp; and&nbsp; $b &#8712; \mathcal{G}$&nbsp; also the sum&nbsp; $a+b$&nbsp; belongs to&nbsp; $\mathcal{G}$&nbsp;,<br>
 +
:*the associative law applies,<br>
 +
:*with&nbsp; $ N_{\rm A} = 0$&nbsp; the neutral element of the addition is contained in&nbsp; $\mathcal{G}$&nbsp; and<br>
 +
:*it exists for each&nbsp; $a$&nbsp; the additive inverse&nbsp; ${\rm Inv_A}(a) = -a$&nbsp;.<br>
 +
:Since moreover the commutative law is fulfilled,&nbsp; it is an&nbsp; "abelian group".<br>
  
Wird zusätzlich für alle&nbsp; $z_i, z_j &#8712; \mathcal{G}$&nbsp; das ''Kommutativgesetz''&nbsp; $z_i + z_j= z_j + z_i$&nbsp; erfüllt, so spricht man von einer ''kommutativen Gruppe''&nbsp; oder einer ''Abelschen Gruppe'', benannt nach dem norwegischen Mathematiker&nbsp; [https://de.wikipedia.org/wiki/Niels_Henrik_Abel Niels Hendrik Abel].}}<br>
+
'''(2)'''&nbsp; The&nbsp; "set of natural numbers" &nbsp; &rArr; &nbsp; $\{0, 1, 2, \text{...}\}$&nbsp; is not an algebraic group with respect to addition, <br> &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; since for no single element&nbsp; $z_i$&nbsp; there exists the additive inverse&nbsp; ${\rm Inv_A}(z_i) = -z_i$&nbsp;.<br>
  
{{GraueBox|TEXT= 
+
'''(3)'''&nbsp; The&nbsp; "bounded set of natural numbers" &nbsp; &rArr; &nbsp; $\{0, 1, 2, \text{...}\hspace{0.05cm}, q\hspace{-0.05cm}-\hspace{-0.05cm}1\}$&nbsp; on the other hand then satisfies the conditions on a group&nbsp; $(\mathcal{G}, +)$, <br> &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; if one defines the addition modulo&nbsp; $q$.
$\text{Beispiele für algebraische Gruppen:}$
 
  
'''(1)'''&nbsp; Die <i>Menge der rationalen Zahlen</i> ist definiert als die Menge aller Quotienten&nbsp; $I/J$&nbsp; mit ganzen Zahlen&nbsp; $I$&nbsp; und&nbsp; $J &ne; 0$.
+
'''(4)'''&nbsp; On the other hand,&nbsp; $\{1, 2, 3, \text{...}\hspace{0.05cm},q\}$&nbsp; is not a group because the neutral element of addition&nbsp; $(N_{\rm A} = 0)$&nbsp; is missing.}}<br>
:Diese Menge ist eine Gruppe&nbsp; $(\mathcal{G}, +)$&nbsp; hinsichtlich der Addition, da
 
:*für alle&nbsp; $a &#8712; \mathcal{G}$&nbsp; und&nbsp; $b &#8712; \mathcal{G}$&nbsp; auch die Summe&nbsp; $a+b$&nbsp; wieder zu&nbsp; $\mathcal{G}$&nbsp; gehört,<br>
 
:*das Assozitativgesetz gilt,<br>
 
:*mit&nbsp; $ N_{\rm A} = 0$&nbsp; das neutrale Element der Addition in&nbsp; $\mathcal{G}$&nbsp; enthalten ist, und<br>
 
:*es für jedes&nbsp; $a$&nbsp; die additive Inverse&nbsp; ${\rm Inv_A}(a) = -a$&nbsp; existiert.<br>
 
:Da zudem das Kommutativgesetz erfüllt ist, handelt es sich um eine <i>Abelsche Gruppe</i>.<br>
 
  
'''(2)'''&nbsp; Die <i>Menge der natürlichen Zahlen</i> &nbsp; &rArr; &nbsp; $\{0, 1, 2, \text{...}\}$&nbsp; ist hinsichtlich Addition keine algebraische Gruppe,
+
== Definition and examples of an algebraic ring  ==
:*da es für kein einziges Element&nbsp; $z_i$&nbsp; die additive Inverse&nbsp; ${\rm Inv_A}(z_i) = -z_i$&nbsp; gibt.<br>
+
<br>
 +
According to the&nbsp; [[Channel_Coding/Some_Basics_of_Algebra#Group.2C_ring.2C_field_-_basic_algebraic_concepts|$\text{overview graphic}$]]&nbsp;  
 +
*one gets from the group&nbsp; $(\mathcal{G}, +)$&nbsp;  
  
'''(3)'''&nbsp; Die <i>begrenzte natürliche Zahlenmenge</i> &nbsp; &rArr; &nbsp; $\{0, 1, 2, \text{...}\hspace{0.05cm}, q-1\}$&nbsp; erfüllt dagegen dann die Bedingungen an eine Gruppe&nbsp; $(\mathcal{G}, +)$,
+
*by defining a second arithmetic operation&nbsp; "multiplication"&nbsp; ("$\cdot$")&nbsp; to the&nbsp; "ring"&nbsp; $(\mathcal{R}, +, \cdot)$.&nbsp;  
:*wenn man die Addition modulo&nbsp; $q$&nbsp; definiert.
 
  
'''(4)'''&nbsp; Dagegen ist&nbsp; $\{1, 2, 3, \text{...}\hspace{0.05cm},q\}$&nbsp; keine Gruppe, da das neutrale Element der Addition&nbsp; $(N_{\rm A} = 0)$&nbsp; fehlt.}}<br>
 
  
== Definition and Examples of an Algebraic Ring  ==
+
So you need a multiplication table as well as an addition table for this.<br>
<br>
 
Entsprechend der&nbsp; [[Channel_Coding/Einige_Grundlagen_der_Algebra#Gruppe.2C_Ring.2C_K.C3.B6rper_.E2.80.93_algebraische_Grundbegriffe |Übersichtsgrafik]]&nbsp; kommt man von der Gruppe&nbsp; $(\mathcal{G}, +)$&nbsp; durch Definition einer zweiten Rechenoperation &ndash; der Multiplikation&nbsp; ("$\cdot$")&nbsp; &ndash; zum Ring&nbsp; $(\mathcal{R}, +, \cdot)$. Man benötigt hierfür also neben einer Additionstabelle auch eine Multiplikationstabelle.<br>
 
  
 
{{BlaueBox|TEXT=   
 
{{BlaueBox|TEXT=   
$\text{Definition:}$&nbsp; Ein&nbsp; $\text{algebraischer Ring}$&nbsp; $(\mathcal{R}, +, \cdot)$ ist eine Teilmenge&nbsp; $\mathcal{R} &#8834; \mathcal{G} &#8834; \mathcal{M}$&nbsp; zusammen mit zwei in dieser Menge definierten Rechenoperationen, der Addition&nbsp; ("$+$")&nbsp; und der Multiplikation&nbsp; ("$&middot;$"). Dabei müssen die folgenden Eigenschaften erfüllt werden:
+
$\text{Definition:}$&nbsp; A&nbsp; $\text{algebraic ring}$ &nbsp; $(\mathcal{R}, +, \cdot)$ &nbsp; is a subset&nbsp; $\mathcal{R} &#8834; \mathcal{G} &#8834; \mathcal{M}$&nbsp; together with two arithmetic operations defined in this set,  
*Hinsichtlich der Addition ist  der Ring&nbsp; $(\mathcal{R}, +, \cdot)$&nbsp; eine&nbsp; [[Channel_Coding/Einige_Grundlagen_der_Algebra#Definition_und_Beispiele_einer_algebraischen_Gruppe|Abelsche Gruppe]]&nbsp; $(\mathcal{G}, +)$.<br>
+
*addition&nbsp; ("$+$")&nbsp;  
*Zusätzlich gilt für alle&nbsp; $z_i, z_j &#8712; \mathcal{R}$&nbsp; auch&nbsp; $(z_i \cdot z_j) &#8712; \mathcal{R}$ &nbsp; &#8658; &nbsp; <i>Closure</i>&ndash;Kriterium für "$\cdot$".<br>
+
*and multiplication&nbsp; ("$&middot;$").&nbsp;  
*Es gibt stets auch ein hinsichtlich der Multiplikation neutrales Element&nbsp; $N_{\rm M} &#8712; \mathcal{R}$, so dass für alle&nbsp; $z_i &#8712; \mathcal{R}$&nbsp; gilt: &nbsp; $z_i \cdot N_{\rm M} = z_i$. <br>Bei einer Zahlengruppe ist stets&nbsp;  $N_{\rm M} = 1$.<br>
 
  
*Für alle&nbsp; $z_i, z_j, z_k &#8712; \mathcal{R}$&nbsp; gilt: &nbsp; $z_i + (z_j + z_k)= (z_i + z_j) + z_k$ &nbsp; &#8658; &nbsp; ''Assoziativgesetz''&nbsp; für&nbsp; "$\cdot $".<br>
 
  
*Für alle&nbsp; $z_i, z_j, z_k &#8712; \mathcal{R}$ gilt: &nbsp; $z_i \cdot (z_j + z_k) = z_i \cdot z_j + z_i \cdot z_k$ &nbsp; &#8658; &nbsp; ''Distributivgesetz''&nbsp; für&nbsp; "$\cdot $".}}<br>
+
The following properties must be satisfied:
 +
#In terms of addition,&nbsp; the ring&nbsp; $(\mathcal{R}, +, \cdot)$&nbsp; is an&nbsp; [[Channel_Coding/Some_Basics_of_Algebra#Definition_and_examples_of_an_algebraic_group|$\text{Abelian group}$]]&nbsp; $(\mathcal{G}, +)$.<br>
 +
#In addition,&nbsp; for all&nbsp; $z_i, z_j &#8712; \mathcal{R}$&nbsp; also&nbsp; $(z_i \cdot z_j) &#8712; \mathcal{R}$ &nbsp; &#8658; &nbsp; "Closure criterion for&nbsp; $\cdot$".<br>
 +
#There is always also a neutral element&nbsp; $N_{\rm M} &#8712; \mathcal{R}$&nbsp; with respect to multiplication,&nbsp; so that for all&nbsp; $z_i &#8712; \mathcal{R}$&nbsp; holds: &nbsp; $z_i \cdot N_{\rm M} = z_i$.&nbsp; For a number group:&nbsp;  $N_{\rm M} \equiv 1$.<br>
 +
#For all&nbsp; $z_i, z_j, z_k &#8712; \mathcal{R}$&nbsp; holds: &nbsp; $z_i + (z_j + z_k)= (z_i + z_j) + z_k$ &nbsp; &#8658; &nbsp; "Associative law&nbsp; for&nbsp; $\cdot $".<br>
 +
#For all&nbsp; $z_i, z_j, z_k &#8712; \mathcal{R}$ holds: &nbsp; $z_i \cdot (z_j + z_k) = z_i \cdot z_j + z_i \cdot z_k$ &nbsp; &#8658; &nbsp; "Distributive law&nbsp; for&nbsp; $\cdot $".}}<br>
  
Weiter sollen die folgenden Vereinbarungen gelten:
+
Further the following agreements shall hold:
*Ein Ring&nbsp; $(\mathcal{R}, +, \cdot)$&nbsp; ist nicht notwendigerweise kommutativ. Gilt tatsächlich auch für alle Elemente&nbsp; $z_i, z_j &#8712; \mathcal{R}$&nbsp; das ''Kommutativgesetz''&nbsp; $z_i \cdot z_j= z_j \cdot z_i$&nbsp; hinsichtlich der Multiplikation, so spricht man in der Fachliteratur von einem&nbsp; '''kommutativen Ring'''.  
+
*A ring&nbsp; $(\mathcal{R}, +, \cdot)$&nbsp; is not necessarily commutative.&nbsp; If in fact the&nbsp; "commutative law"&nbsp; also holds for all elements&nbsp; $z_i, z_j &#8712; \mathcal{R}$&nbsp; with respect to multiplication&nbsp; $(z_i \cdot z_j= z_j \cdot z_i)$&nbsp; then it is called  in the technical literature a&nbsp; &raquo;'''commutative ring'''&laquo;.
*Existiert für jedes Element&nbsp; $z_i &#8712; \mathcal{R}$&nbsp; mit Ausnahme von&nbsp; $N_{\rm A}$&nbsp; (neutrales Element der Addition, Nullelement) ein hinsichtlich der Multiplikation inverses Element&nbsp; ${\rm Inv_M}(z_i)$, so dass&nbsp; $z_i \cdot {\rm Inv_M}(z_i) = 1$&nbsp; gilt, so liegt ein&nbsp; <b>Divisionsring</b>&nbsp; (englisch: &nbsp; <i>Division Ring</i>) vor.<br>
+
*Der Ring ist&nbsp; <b>nullteilerfrei</b>&nbsp; (englisch: <i>free of zero devisors</i>), wenn aus&nbsp; $z_i \cdot  z_j  = 0$&nbsp; zwingend&nbsp; $z_i = 0$&nbsp; oder&nbsp; $z_j = 0$&nbsp; folgt. In der abstrakten Algebra ist ein Nullteiler eines Ringes ein vom Nullelement verschiedenes Element&nbsp; $z_i$, falls es ein Element&nbsp; $z_j \ne 0$&nbsp; gibt, so dass das Produkt&nbsp;  $z_i \cdot  z_j  = 0$&nbsp; ist.<br>
+
*Exists for each element&nbsp; $z_i &#8712; \mathcal{R}$&nbsp; except&nbsp; $N_{\rm A}$&nbsp; $($neutral element of addition,&nbsp; zero element$)$&nbsp; an element&nbsp; ${\rm Inv_M}(z_i)$&nbsp;  inverse with respect to multiplication such that&nbsp; $z_i \cdot {\rm Inv_M}(z_i) = 1$&nbsp; holds, then there is a&nbsp; &raquo;<b>division ring</b>&laquo;.<br>
*Ein kommutativer nullteilerfreier Ring wird als&nbsp; <b>Integritätsring</b>&nbsp; oder &nbsp;<b>Integritätsbereich</b>&nbsp; (englisch: &nbsp;<i>Integral Domain</i>) bezeichnet.<br><br>
 
  
{{BlaueBox|TEXT=
+
*The ring is&nbsp; &raquo;<b>free of zero divisors</b>&laquo;&nbsp; if from&nbsp; $z_i \cdot z_j = 0$&nbsp; follows necessarily&nbsp; $z_i = 0$&nbsp; or&nbsp; $z_j = 0$.&nbsp; In abstract algebra,&nbsp; a zero divisor of a ring is an element&nbsp; $z_i$ different from the zero element if there exists an element&nbsp; $z_j \ne 0$&nbsp; such that the product&nbsp; $z_i \cdot z_j = 0$&nbsp;.<br>
$\text{Fazit:}$&nbsp;
 
  
Vergleicht man die Definitionen von&nbsp; [[Channel_Coding/Einige_Grundlagen_der_Algebra#Definition_und_Beispiele_einer_algebraischen_Gruppe| Gruppe]],&nbsp; Ring (siehe oben), [[Aufgaben:2.1_Gruppe,_Ring,_Körper|Körper]]&nbsp; und&nbsp; [[Channel_Coding/Einige_Grundlagen_der_Algebra#Definition_eines_Galoisfeldes| Galoisfeld]], so erkennt man, dass ein Galoisfeld&nbsp; ${\rm GF}(q)$
+
*A commutative ring free of zero divisors is called&nbsp; &raquo;<b>integral domain</b>&laquo;.<br><br>
*ein endlicher Körper (englisch: &nbsp;<i>Field</i>&nbsp;) mit&nbsp; $q$&nbsp; Elementen ist,<br>
 
  
*gleichzeitig als <i>Commutative Division Ring</i>&nbsp; aufgefasst werden kann, und auch <br>
+
{{BlaueBox|TEXT= 
 
+
$\text{Conclusion:}$&nbsp;  Comparing the definitions of&nbsp; [[Channel_Coding/Some_Basics_of_Algebra#Definition_and_examples_of_an_algebraic_group| $\text{group}$]],&nbsp; "ring"&nbsp; (see above), [[Aufgaben:Aufgabe_2.1:_Gruppe,_Ring,_Körper|$\text{field}$]]&nbsp; and&nbsp; [[Channel_Coding/Some_Basics_of_Algebra#Definition_of_a_Galois_field|$\text{Galois field}$]],&nbsp; we recognize that a&nbsp; &raquo;'''Galois field'''&laquo;&nbsp; ${\rm GF}(q)$
*einen Integritätsbereich (englisch: <i>Integral Domain</i>&nbsp;) beschreibt.}}<br><br>
+
#is a finite field with&nbsp; $q$&nbsp; elements,<br>
 +
#is at the same time a&nbsp; "commutative division ring",&nbsp; and <br>
 +
#also describes an&nbsp; "integral domain".}}<br><br>
  
== Aufgaben zum Kapitel ==
+
== Exercises for the chapter ==
 
<br>
 
<br>
[[Aufgaben:2.1_Gruppe,_Ring,_Körper|Aufgabe 2.1: Gruppe, Ring, Körper]]
+
[[Aufgaben:Exercise_2.1:_Group,_Ring,_Field|Exercise 2.1: Group, Ring, Field]]
  
[[Aufgaben:Aufgabe_2.1Z:_Welche_Tabellen_beschreiben_Gruppen%3F|Aufgabe 2.1Z: Welche Tabellen beschreiben Gruppen?]]
+
[[Aufgaben:Exercise_2.1Z:_Which_Tables_Describe_Groups%3F|Exercise 2.1Z: Which Tables Describe Groups?]]
  
[[Aufgaben:2.2_Eigenschaften_von_Galoisfeldern|Aufgabe 2.2: Eigenschaften von Galoisfeldern]]
+
[[Aufgaben:Exercise_2.2:_Properties_of_Galois_Fields|Exercise 2.2: Properties of Galois Fields]]
  
[[Aufgaben:2.2Z_Galoisfeld_GF(5)|Aufgabe 2.2Z: Galoisfeld GF(5)]]
+
[[Aufgaben:Exercise_2.2Z:_Galois_Field_GF(5)|Exercise 2.2Z: Galois Field GF(5)]]
  
==Quellenverzeichnis==
+
==References==
 
<references/>
 
<references/>
  
  
 
{{Display}}
 
{{Display}}

Latest revision as of 15:09, 19 November 2022

# OVERVIEW OF THE SECOND MAIN CHAPTER #


This chapter discusses the  »Reed-Solomon codes«,  invented in the early 1960s by  $\text{Irving Stoy Reed}$  and  $\text{Gustave Solomon}$.  Unlike binary block codes,  these codes are based on a Galois field   ${\rm GF}(2^m)$   with  $m > 1$.  So they work with multi-level symbols instead of binary characters  ("bits").

Specifically,  this chapter covers:

  • The basics of  »linear algebra«:   »set«,   »group«,   »ring«,   »field«,  finite field«,
  • the definition of  »extension fields«   ⇒   ${\rm GF}(2^m)$  and the corresponding operations,
  • the meaning of  »irreducible polynomials«   and  »primitive elements«,
  • the  »description and realization possibilities«   of a Reed-Solomon code,
  • the error correction of such a code at the  »binary ersaure channel«   $\rm (BEC)$,
  • the decoding using the  »Error Locator Polynomial   ⇒   "Bounded Distance Decoding"   $\rm (BDD)$,
  • the  »block error probability«   of Reed-Solomon codes  and   »typical applications«.



Definition of a Galois field


Before we can turn to the description of  Reed–Solomon codes,  we need some basic algebraic notions.  We begin with the properties of the Galois field   ${\rm GF}(q)$,  named after the Frenchman  $\text{Évariste Galois}$, whose biography is rather unusual for a mathematician.

$\text{Definition:}$  A   $\rm Galois\:field$  ${\rm GF}(q)$  is a  $\text{finite field}$  with  $q$  elements  $z_0$,  $z_1$,  ... ,  $z_{q-1}$, if the eight statements listed below  $\rm (A)$  ...  $\rm (H)$  with respect to  "addition"   ⇒   "$+$"   and  "multiplication"  ⇒  "$\hspace{0.05cm}\cdot \hspace{0.05cm}$"   are true.

  • Addition and multiplication are to be understood here modulo  $q$ .
  • The  $\rm order$  $q$  indicates the number of elements of the Galois field.


$\text{Criteria of a Galois field:}$ 

$\rm (A)$  ${\rm GF}(q)$  is closed $\hspace{0.2cm}\Rightarrow \hspace{0.2cm}\rm Closure$:

\[\forall \hspace{0.15cm} z_i \in {\rm GF}(q),\hspace{0.15cm} z_j \in {\rm GF}(q)\text{:} \hspace{0.25cm}(z_i + z_j)\in {\rm GF}(q),\hspace{0.15cm}(z_i \cdot z_j)\in {\rm GF}(q) \hspace{0.05cm}. \]

$\rm (B)$  There is a neutral element  $N_{\rm A}$  with respect to addition,  the so-called  "zero element" $\hspace{0.2cm}\Rightarrow \hspace{0.2cm}\rm Identity \ for \ "\hspace{-0.05cm}+\hspace{0.05cm}"$:

\[\exists \hspace{0.15cm} z_j \in {\rm GF}(q)\text{:} \hspace{0.25cm}z_i + z_j = z_i \hspace{0.25cm} \Rightarrow \hspace{0.25cm} z_j = N_{\rm A} = \text{ 0} \hspace{0.05cm}.\]

$\rm (C)$  There is a neutral element  $N_{\rm M}$  with respect to multiplication,  the so-called  "identity element" $\hspace{0.2cm}\Rightarrow \hspace{0.2cm}\rm Identity \ for \ "\hspace{-0.05cm}·\hspace{0.05cm}"$:

\[\exists \hspace{0.15cm} z_j \in {\rm GF}(q)\text{:} \hspace{0.25cm}z_i \cdot z_j = z_i \hspace{0.3cm}\Rightarrow \hspace{0.3cm} z_j = N_{\rm M} = {1} \hspace{0.05cm}. \]

$\rm (D)$  For each  $z_i$  there exists an  "additive inverse"   ${\rm Inv_A}(z_i)$ $\hspace{0.2cm}\Rightarrow \hspace{0.2cm}\rm Inverse \ for \ "\hspace{-0.05cm}+\hspace{0.05cm}"$:

\[\forall \hspace{0.15cm} z_i \in {\rm GF}(q),\hspace{0.15cm} \exists \hspace{0.15cm} {\rm Inv_A}(z_i) \in {\rm GF}(q)\text{:} \hspace{0.25cm}z_i + {\rm Inv_A}(z_i) = N_{\rm A} = {0} \hspace{0.3cm}\Rightarrow \hspace{0.3cm}\text{short:}\hspace{0.3cm} {\rm Inv_A}(z_i) = - z_i \hspace{0.05cm}. \]

$\rm (E)$  For each  $z_i$  except the zero element,  there exists the  "multiplicative inverse"   ${\rm Inv_M}(z_i)$ $\hspace{0.2cm}\Rightarrow \hspace{0.2cm}\rm Inverse \ for \ "\hspace{-0.05cm}\cdot\hspace{0.05cm}"$:

\[\forall \hspace{0.15cm} z_i \in {\rm GF}(q),\hspace{0.15cm} z_i \ne N_{\rm A}, \hspace{0.15cm} \exists \hspace{0.15cm} {\rm Inv_M}(z_i) \in {\rm GF}(q)\text{:} \hspace{0.25cm}z_i \cdot {\rm Inv_M}(z_i) = N_{\rm M} = {1}\hspace{0.3cm}\Rightarrow \hspace{0.3cm}\text{short:}\hspace{0.3cm} {\rm Inv_M}(z_i) = z_i^{-1} \hspace{0.05cm}. \]

$\rm (F)$  For addition and multiplication applies in each case the  "$\rm Commutative \ Law$":

\[\forall \hspace{0.15cm} z_i,\hspace{0.15cm} z_j \in {\rm GF}(q)\text{:} \hspace{0.25cm}z_i + z_j = z_j + z_i ,\hspace{0.15cm}z_i \cdot z_j = z_j \cdot z_i \hspace{0.05cm}.\]

$\rm (G)$  For addition and multiplication applies in each case the  "$\rm Associative \ Law$":

\[\forall \hspace{0.15cm} z_i,\hspace{0.1cm} z_j ,\hspace{0.1cm} z_k \in {\rm GF}(q)\text{:} \hspace{0.25cm}(z_i + z_j) + z_k = z_i + (z_j + z_k ),\hspace{0.15cm}(z_i \cdot z_j) \cdot z_k = z_i \cdot (z_j \cdot z_k ) \hspace{0.05cm}.\]

$\rm (H)$  For the combination  "addition – multiplication"  holds the  "$\rm Distributive \ Law$":

\[\forall \hspace{0.15cm} z_i,\hspace{0.15cm} z_j ,\hspace{0.15cm} z_k \in {\rm GF}(q)\text{:} \hspace{0.25cm}(z_i + z_j) \cdot z_k = z_i \cdot z_k + z_j \cdot z_k \hspace{0.05cm}.\]



Examples and properties of Galois fields


We first check that for the binary number set  $Z_2 = \{0, 1\}$   ⇒   $q=2$   $($valid for the simple binary code$)$

  • the eight criteria mentioned in the last section are met,
  • so that we can indeed speak of  "${\rm GF}(2)$".


You can see the addition table and multiplication table below:

$$Z_2 = \{0, 1\}\hspace{0.25cm} \Rightarrow\hspace{0.25cm}\text{Addition: } \left[ \begin{array}{c|cccccc} + & 0 & 1 \\ \hline 0 & 0 & 1 \\ 1 & 1 & 0 \end{array} \right] \hspace{-0.1cm} ,\hspace{0.25cm}\text{Multiplication: } \left[ \begin{array}{c|cccccc} \cdot & 0 & 1 \\ \hline 0 & 0 & 0 \\ 1 & 0 & 1 \end{array} \right]\hspace{0.25cm} \Rightarrow\hspace{0.25cm}{\rm GF}(2) . $$

One can see from this representation:

  1. Each element of the addition and multiplication table of  $Z_2$  is again  $z_0 = 0$  or  $z_0 = 1$   ⇒   the criterion  $\rm (A)$  is satisfied.
  2. The set  $Z_2$  contains the zero element  $(\hspace{-0.05cm}N_{\rm A} = z_0 = 0)$  and the one element $(\hspace{-0.05cm}N_{\rm M} = z_1 = 1)$  ⇒   the criteria  $\rm (B)$  and  $\rm (C)$  are satisfied.
  3. The additive inverses  ${\rm Inv_A}(0) = 0$  and  ${\rm Inv_A}(1) = -1 \ {\rm mod}\ 2 = 1$  exist and belong to  $Z_2$   ⇒   the criterion  $\rm (D)$  is satisfied.
  4. Similarly, the multiplicative inverse  ${\rm Inv_M}(1) = 1$   ⇒   the criterion  $\rm (E)$  is satisfied.
  5. The validity of the commutative law  $\rm (F)$  in the set  $Z_2$  can be recognized by the symmetry with respect to the table diagonals.
  6. The criteria  $\rm (G)$  and  $\rm (H)$  are also satisfied here  ⇒   all eight criteria are satisfied  ⇒   $Z_2 = \rm GF(2)$.


$\text{Example 1:}$  The number set  $Z_3 = \{0, 1, 2\}$   ⇒   $q = 3$  satisfies all eight criteria and is thus a Galois field  $\rm GF(3)$:

$$Z_3 = \{0, 1, 2\}\hspace{0.25cm} \Rightarrow\hspace{0.25cm}\text{Addition: } \left[ \begin{array}{c | cccccc} + & 0 & 1 & 2\\ \hline 0 & 0 & 1 & 2 \\ 1 & 1 & 2 & 0 \\ 2 & 2 & 0 & 1 \end{array} \right] \hspace{-0.1cm} ,\hspace{0.25cm}\text{Multiplication: } \left[ \begin{array}{c | cccccc} \cdot & 0 & 1 & 2\\ \hline 0 & 0 & 0 & 0 \\ 1 & 0 & 1 & 2 \\ 2& 0 & 2 & 1 \end{array} \right]\hspace{0.25cm} \Rightarrow\hspace{0.25cm}{\rm GF}(3) . $$


$\text{Example 2:}$  In contrast,  the number set  $Z_4 = \{0, 1, 2, 3\}$   ⇒   $q = 4$  is  »not«  a Galois field.

  • The reason for this is that here is no multiplicative inverse to the element  $z_2 = 2$.  For a Galois field it would have to be true:   $2 \cdot {\rm Inv_M}(2) = 1$.
  • But in the multiplication table there is no entry with  "$1$"  in the third row and third column  $($each valid for the multiplicand  $z_2 = 2)$.
$$Z_4 = \{0, 1, 2, 3\}\hspace{0.25cm} \Rightarrow\hspace{0.25cm}\text{Addition: } \left[ \begin{array}{c | cccccc} + & 0 & 1 & 2 & 3\\ \hline 0 & 0 & 1 & 2 & 3\\ 1 & 1 & 2 & 3 & 0\\ 2 & 2 & 3 & 0 & 1\\ 3 & 3 & 0 & 1 & 2 \end{array} \right] \hspace{-0.1cm} ,\hspace{0.25cm}\text{Multiplication: } \left[ \begin{array}{c | cccccc} \cdot& 0 & 1 & 2 & 3\\ \hline 0 & 0 & 0 & 0 & 0\\ 1 & 0 & 1 & 2 & 3\\ 2 & 0 & 2 & 0 & 2\\ 3 & 0 & 3 & 2 & 1 \end{array} \right]\hspace{0.25cm} \Rightarrow\hspace{0.25cm}\text{no }{\rm GF}(4) . $$


$\text{Generalization (without proof for now):}$

  • A Galois field  ${\rm GF}(q)$  can be formed in the manner described here as  $\text{ring}$  of integer sizes modulo  $q$  only if  $q$  is a prime number:  
        $q = 2$,  $q = 3$,  $q = 5$,  $q = 7$,  $q = 11$, ...
  • But if the order  $q$  can be expressed in the form  $q = P^m$  with a prime  $P$  and integer  $m$,  the Galois field  ${\rm GF}(q)$  can be found via an  $\text{extension field}$


Group, ring, field - basic algebraic concepts


In the first sections,  some basic algebraic terms have already been mentioned,  without their meanings having been explained in more detail.  This is to be made up now in all shortness from view of a communication engineer, whereby we mainly refer to the representation in  [Fri96][1]  and  [KM+08][2].  To summarize:

$\text{Definition:}$ 

  • A  $\rm Galois\, field$  ${\rm GF}(q)$ is a  "field"  with a finite number  $(q)$  of elements   ⇒   »finite field«. 
  • Each field is again a special case of a  "ring",  which itself can be represented again as a special case of an  "Abelian group".


Algebraic relations between group, ring and field

The diagram illustrates step by step how the following subordinate sets arise from a set  $\mathcal{M}$  by definition of addition, multiplication and division:

  • Abelian group  $\mathcal{G}$ ,
  • ring  $\mathcal{R}$,
  • field  $\mathcal{F}$,
  • finite field  $\mathcal{F}_q$  or Galois field  ${\rm GF}(q)$.


In the next two sections, the algebraic terms mentioned here will be discussed in more detail.

  • For understanding the Reed–Solomon codes, however, this knowledge is not absolutely necessary.


Definition and examples of an algebraic group


For the general definitions of  "group"  (and later  "ring")  we assume a set with infinitely many elements:

\[\mathcal{M} = \{\hspace{0.1cm}z_1,\hspace{0.1cm} z_2,\hspace{0.1cm} z_3 ,\hspace{0.1cm}\text{ ...} \hspace{0.1cm}\}\hspace{0.05cm}. \]

$\text{Definition:}$  A  $\text{algebraic group}$  $(\mathcal{G}, +)$  is an  (arbitrary)  subset  $\mathcal{G} ⊂ \mathcal{M}$  together with an additive linkage  $($"$+$"$)$  defined between all elements,  but only if the following properties are necessarily satisfied:

  1. For all  $z_i, z_j ∈ \mathcal{G}$  holds  $(z_i + z_j) ∈ \mathcal{G}$   ⇒   "Closure–criterion for  $+$".
  2. There is always a neutral element  $N_{\rm A} ∈ \mathcal{G}$  with respect to addition,  so that for all  $z_i ∈ \mathcal{G}$ holds:   $z_i +N_{\rm A} = z_i$.  Given a group of numbers:   $N_{\rm A} \equiv 0$.
  3. For all  $z_i ∈ \mathcal{G}$  there is an inverse element  ${\rm Inv_A}(z_i) ∈ \mathcal{G}$  with respect to addition:  $z_i + {\rm Inv_A}(z_i)= N_{\rm A} $.  For a number group:  ${\rm Inv_A}(z_i) =- z_i$.
  4. For all  $z_i, z_j, z_k ∈ \mathcal{G}$  holds:  $z_i + (z_j + z_k)= (z_i + z_j) + z_k$   ⇒   "Associative law  for  $+$".
  5. If in addition for all  $z_i, z_j ∈ \mathcal{G}$  the  "commutative law"  $z_i + z_j= z_j + z_i$  is satisfied,  one speaks of a  "commutative group"  or an  "Abelian group",  named after the Norwegian mathematician  $\text{Niels Hendrik Abel}$.


$\text{Examples of algebraic groups:}$

(1)  The  "set of rational numbers"  is defined as the set of all quotients  $I/J$  with integers  $I$  and  $J ≠ 0$.

This set is a group  $(\mathcal{G}, +)$  with respect to addition,  since
  • for all  $a ∈ \mathcal{G}$  and  $b ∈ \mathcal{G}$  also the sum  $a+b$  belongs to  $\mathcal{G}$ ,
  • the associative law applies,
  • with  $ N_{\rm A} = 0$  the neutral element of the addition is contained in  $\mathcal{G}$  and
  • it exists for each  $a$  the additive inverse  ${\rm Inv_A}(a) = -a$ .
Since moreover the commutative law is fulfilled,  it is an  "abelian group".

(2)  The  "set of natural numbers"   ⇒   $\{0, 1, 2, \text{...}\}$  is not an algebraic group with respect to addition,
          since for no single element  $z_i$  there exists the additive inverse  ${\rm Inv_A}(z_i) = -z_i$ .

(3)  The  "bounded set of natural numbers"   ⇒   $\{0, 1, 2, \text{...}\hspace{0.05cm}, q\hspace{-0.05cm}-\hspace{-0.05cm}1\}$  on the other hand then satisfies the conditions on a group  $(\mathcal{G}, +)$,
          if one defines the addition modulo  $q$.

(4)  On the other hand,  $\{1, 2, 3, \text{...}\hspace{0.05cm},q\}$  is not a group because the neutral element of addition  $(N_{\rm A} = 0)$  is missing.


Definition and examples of an algebraic ring


According to the  $\text{overview graphic}$ 

  • one gets from the group  $(\mathcal{G}, +)$ 
  • by defining a second arithmetic operation  "multiplication"  ("$\cdot$")  to the  "ring"  $(\mathcal{R}, +, \cdot)$. 


So you need a multiplication table as well as an addition table for this.

$\text{Definition:}$  A  $\text{algebraic ring}$   $(\mathcal{R}, +, \cdot)$   is a subset  $\mathcal{R} ⊂ \mathcal{G} ⊂ \mathcal{M}$  together with two arithmetic operations defined in this set,

  • addition  ("$+$") 
  • and multiplication  ("$·$"). 


The following properties must be satisfied:

  1. In terms of addition,  the ring  $(\mathcal{R}, +, \cdot)$  is an  $\text{Abelian group}$  $(\mathcal{G}, +)$.
  2. In addition,  for all  $z_i, z_j ∈ \mathcal{R}$  also  $(z_i \cdot z_j) ∈ \mathcal{R}$   ⇒   "Closure criterion for  $\cdot$".
  3. There is always also a neutral element  $N_{\rm M} ∈ \mathcal{R}$  with respect to multiplication,  so that for all  $z_i ∈ \mathcal{R}$  holds:   $z_i \cdot N_{\rm M} = z_i$.  For a number group:  $N_{\rm M} \equiv 1$.
  4. For all  $z_i, z_j, z_k ∈ \mathcal{R}$  holds:   $z_i + (z_j + z_k)= (z_i + z_j) + z_k$   ⇒   "Associative law  for  $\cdot $".
  5. For all  $z_i, z_j, z_k ∈ \mathcal{R}$ holds:   $z_i \cdot (z_j + z_k) = z_i \cdot z_j + z_i \cdot z_k$   ⇒   "Distributive law  for  $\cdot $".


Further the following agreements shall hold:

  • A ring  $(\mathcal{R}, +, \cdot)$  is not necessarily commutative.  If in fact the  "commutative law"  also holds for all elements  $z_i, z_j ∈ \mathcal{R}$  with respect to multiplication  $(z_i \cdot z_j= z_j \cdot z_i)$  then it is called in the technical literature a  »commutative ring«.
  • Exists for each element  $z_i ∈ \mathcal{R}$  except  $N_{\rm A}$  $($neutral element of addition,  zero element$)$  an element  ${\rm Inv_M}(z_i)$  inverse with respect to multiplication such that  $z_i \cdot {\rm Inv_M}(z_i) = 1$  holds, then there is a  »division ring«.
  • The ring is  »free of zero divisors«  if from  $z_i \cdot z_j = 0$  follows necessarily  $z_i = 0$  or  $z_j = 0$.  In abstract algebra,  a zero divisor of a ring is an element  $z_i$ different from the zero element if there exists an element  $z_j \ne 0$  such that the product  $z_i \cdot z_j = 0$ .
  • A commutative ring free of zero divisors is called  »integral domain«.

$\text{Conclusion:}$  Comparing the definitions of  $\text{group}$,  "ring"  (see above), $\text{field}$  and  $\text{Galois field}$,  we recognize that a  »Galois field«  ${\rm GF}(q)$

  1. is a finite field with  $q$  elements,
  2. is at the same time a  "commutative division ring",  and
  3. also describes an  "integral domain".



Exercises for the chapter


Exercise 2.1: Group, Ring, Field

Exercise 2.1Z: Which Tables Describe Groups?

Exercise 2.2: Properties of Galois Fields

Exercise 2.2Z: Galois Field GF(5)

References

  1. Friedrichs, B.:  Kanalcodierung – Grundlagen und Anwendungen in modernen Kommunikationssystemen.  Berlin – Heidelberg: Springer, 1996.
  2. Kötter, R.; Mayer, T.; Tüchler, M.; Schreckenbach, F.; Brauchle, J.:  Channel Coding.  Lecture manuscript, Chair of Communications Engineering, TU Munich, 2008.