Difference between revisions of "Channel Coding/Definition and Properties of Reed-Solomon Codes"

From LNTwww
 
(24 intermediate revisions by 3 users not shown)
Line 8: Line 8:
 
== Coding principle and code parameters ==
 
== Coding principle and code parameters ==
 
<br>
 
<br>
A <i>Reed&ndash;Solomon Code</i>&nbsp; &ndash; hereafter sometimes shortened to&nbsp; '''RS code'''&nbsp; is a&nbsp; [[Channel_Coding/General_Description_of_Linear_Block_Codes#Linear_codes_and_cyclic_codes| "linear block code"]] that is
+
A&nbsp; "Reed&ndash;Solomon code"&nbsp; &ndash; hereafter sometimes shortened to&nbsp; "RS code" &nbsp; &ndash; is a&nbsp; [[Channel_Coding/General_Description_of_Linear_Block_Codes#Linear_codes_and_cyclic_codes|$\text{linear block code}$]] which assigns
[[File:P ID2515 KC T 2 3 S1 v2.png|right|frame|Linear $(n, \, k)$ block code|class=fit]]  
+
*an information block&nbsp; $\underline{u}$&nbsp; with&nbsp; $k$&nbsp; symbols
*an information block&nbsp; $\underline{u}$&nbsp; with&nbsp; $k$&nbsp; symbols.
+
*assings a corresponding codeword&nbsp; $\underline{c}$&nbsp; with&nbsp; $n > k$  
+
*to a corresponding code word&nbsp; $\underline{c}$&nbsp; with&nbsp; $n > k$&nbsp; symbols.
  
  
symbols. These codes, still widely used today, were invented as early as 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;.<br>
+
[[File:P ID2515 KC T 2 3 S1 v2.png|right|frame|Linear&nbsp; $(n, \, k)$&nbsp; block code with new nomenclature|class=fit]] 
 +
These codes,&nbsp; still widely used today,&nbsp; were invented as early as the early 1960s
 +
*by&nbsp; [https://en.wikipedia.org/wiki/Irving_S._Reed $\text{Irving Stoy Reed}$]&nbsp;  
  
In the chapter&nbsp; [[Channel_Coding/Objective_of_Channel_Coding#Block_diagram_and_requirements|"Objective of Channel Coding"]]&nbsp; the information block was denoted by&nbsp; $\underline{u}= (u_1,$ ... , $u_k)$&nbsp; and the codeword by&nbsp; $\underline{x}= (x_1,$ ... , $x_n)$&nbsp;.
+
*and&nbsp; [https://en.wikipedia.org/wiki/Gustave_Solomon $\text{Gustave Solomon}$].<br>
  
The nomenclature change&nbsp; $\underline{x} \to \underline{c}$&nbsp; (see graphic) was made to eliminate confusion with the argument of polynomials and to simplify the description of RS codes.
 
  
 +
In the chapter&nbsp; [[Channel_Coding/Objective_of_Channel_Coding#Block_diagram_and_requirements|"Objective of Channel Coding"]]&nbsp;
 +
*the information block was denoted by&nbsp; $\underline{u}= (u_1,$ ... , $u_k)$&nbsp; and
  
All the properties of linear cyclic block codes mentioned in the section&nbsp; [[Channel_Coding/General_Description_of_Linear_Block_Codes#Linear_codes_and_cyclic_codes|"linear codes and cyclic codes"]]&nbsp; also apply to a Reed&ndash;Solomon&ndash;code. In addition:
+
*the code word by&nbsp; $\underline{x}= (x_1,$ ... , $x_n)$.&nbsp;  
  
*Construction and decoding of Reed&ndash;Solomon codes are based on the arithmetic of a Galois field&nbsp; ${\rm GF}(q)$, where we restrict ourselves here to binary extension fields with&nbsp; $q=2^m$ elements&nbsp;:
 
  
 +
The nomenclature change &nbsp; $\underline{x} \to \underline{c}$ &nbsp; $($see graphic$)$&nbsp; was made to eliminate confusion with the argument of polynomials and to simplify the description of Reed&ndash;Solomon codes.
  
 +
All the properties of linear cyclic block codes mentioned in the section&nbsp; [[Channel_Coding/General_Description_of_Linear_Block_Codes#Linear_codes_and_cyclic_codes|"Linear codes and cyclic codes"]]&nbsp; also apply to the Reed&ndash;Solomon codes.&nbsp;  In addition:
 +
 +
*Construction and decoding of Reed&ndash;Solomon codes are based on the arithmetic of a Galois field&nbsp; ${\rm GF}(q)$,&nbsp; where we restrict ourselves here to binary extension fields with&nbsp; $q=2^m$&nbsp; elements;:
 
::<math>{\rm GF}(2^m) = \big \{\hspace{0.05cm}0\hspace{0.05cm},\hspace{0.1cm} \alpha^{0}  ,\hspace{0.05cm}\hspace{0.1cm}
 
::<math>{\rm GF}(2^m) = \big \{\hspace{0.05cm}0\hspace{0.05cm},\hspace{0.1cm} \alpha^{0}  ,\hspace{0.05cm}\hspace{0.1cm}
 
\alpha^{1}\hspace{0.05cm},\hspace{0.1cm} \alpha^{2}\hspace{0.05cm},\hspace{0.1cm}\text{...}\hspace{0.1cm},  \alpha^{q-2}\hspace{0.05cm} \big \}\hspace{0.05cm}. </math>
 
\alpha^{1}\hspace{0.05cm},\hspace{0.1cm} \alpha^{2}\hspace{0.05cm},\hspace{0.1cm}\text{...}\hspace{0.1cm},  \alpha^{q-2}\hspace{0.05cm} \big \}\hspace{0.05cm}. </math>
  
*Principally different from the first chapter is that the coefficients&nbsp; $u_0$,&nbsp; $u_1$, ... ,&nbsp; $u_{k-1}$&nbsp; now no longer specify individual bits of information&nbsp; $(0$ or $1)$&nbsp; but are also elements of&nbsp; ${\rm GF}(2^m)$&nbsp;. Each of the&nbsp; $n$&nbsp; symbols represents&nbsp; $m$&nbsp; bits.<br>
+
*Principally different from the first chapter is that the coefficients&nbsp; $u_0$,&nbsp; $u_1$, ... ,&nbsp; $u_{k-1}$&nbsp; now no longer specify individual bits of information&nbsp; $(0$&nbsp; or&nbsp; $1)$&nbsp; but they are also elements of&nbsp; ${\rm GF}(2^m)$.&nbsp; Each of the&nbsp; $n$&nbsp; symbols represents&nbsp; $m$&nbsp; bits.<br>
  
*For Reed&ndash;Solomon codes, the parameter&nbsp; $n$&nbsp; (code length) is always equal to the number of elements of the Galois field excluding the zero word: &nbsp; $n= q-1$. <br>We use the following nomenclature for this purpose:
+
*For Reed&ndash;Solomon codes,&nbsp; the parameter&nbsp; $n$&nbsp; ("code length")&nbsp; is always equal to the number of elements of the Galois field excluding the zero word: &nbsp; $n= q-1$. <br>We use for this purpose the following nomenclature:
  
 
::<math>{\rm GF}(2^m) \hspace{-0.05cm}\setminus \hspace{-0.05cm} \{0\} = \big \{\hspace{0.05cm} \alpha^{0}  ,\hspace{0.05cm}\hspace{0.1cm}
 
::<math>{\rm GF}(2^m) \hspace{-0.05cm}\setminus \hspace{-0.05cm} \{0\} = \big \{\hspace{0.05cm} \alpha^{0}  ,\hspace{0.05cm}\hspace{0.1cm}
 
\alpha^{1}\hspace{0.05cm},\hspace{0.1cm} \alpha^{2}\hspace{0.05cm},\hspace{0.1cm}...\hspace{0.1cm},  \alpha^{n-1}\hspace{0.05cm} \big \}\hspace{0.05cm}. </math>
 
\alpha^{1}\hspace{0.05cm},\hspace{0.1cm} \alpha^{2}\hspace{0.05cm},\hspace{0.1cm}...\hspace{0.1cm},  \alpha^{n-1}\hspace{0.05cm} \big \}\hspace{0.05cm}. </math>
  
*The&nbsp; $k$&nbsp; coefficients&nbsp; $u_i \in {\rm GF}(2^m)$&nbsp; of the information block&nbsp; $\underline{u}$, where for the index&nbsp; $ 0 \le i < k$&nbsp; holds, can also be formally expressed by a polynomial&nbsp; $u(x)$&nbsp; . The degree of the polynomial is here&nbsp; $k-1$:
+
*The&nbsp; $k$&nbsp; coefficients&nbsp; $u_i \in {\rm GF}(2^m)$&nbsp; of the information block&nbsp; $\underline{u}$,&nbsp; where for the index&nbsp; $ 0 \le i < k$&nbsp; holds,&nbsp; can also be formally expressed by a polynomial&nbsp; $u(x)$.&nbsp; The degree of this polynomial is&nbsp; $k-1$:
  
 
::<math>u(x) = \sum_{i = 0}^{k-1} u_i \cdot x^{i}  = u_0 + u_1 \cdot x + u_2 \cdot x^2 + \hspace{0.1cm}\text{...}\hspace{0.1cm}+ u_{k-1} \cdot x^{k-1}  \hspace{0.05cm},\hspace{0.4cm} u_i \in {\rm GF}(2^m)
 
::<math>u(x) = \sum_{i = 0}^{k-1} u_i \cdot x^{i}  = u_0 + u_1 \cdot x + u_2 \cdot x^2 + \hspace{0.1cm}\text{...}\hspace{0.1cm}+ u_{k-1} \cdot x^{k-1}  \hspace{0.05cm},\hspace{0.4cm} u_i \in {\rm GF}(2^m)
 
\hspace{0.05cm}.</math>
 
\hspace{0.05cm}.</math>
  
*The&nbsp; $n$&nbsp; symbols of the associated codeword&nbsp; $\underline{c}= (c_0, c_1,$ ... , $c_{n-1})$&nbsp; result with this polynomial&nbsp; $u(x)$&nbsp; to be
+
*The&nbsp; $n$&nbsp; symbols of the associated code word&nbsp; $\underline{c}= (c_0, c_1,$ ... , $c_{n-1})$&nbsp; result with this polynomial&nbsp; $u(x)$&nbsp; to be
  
 
::<math>c_0 = u(\alpha^{0}) \hspace{0.05cm},\hspace{0.3cm} c_1 = u(\alpha^{1})\hspace{0.05cm},\hspace{0.1cm}...\hspace{0.1cm},\hspace{0.3cm} c_{n-1}= u(\alpha^{n-1}) \hspace{0.05cm}.</math>
 
::<math>c_0 = u(\alpha^{0}) \hspace{0.05cm},\hspace{0.3cm} c_1 = u(\alpha^{1})\hspace{0.05cm},\hspace{0.1cm}...\hspace{0.1cm},\hspace{0.3cm} c_{n-1}= u(\alpha^{n-1}) \hspace{0.05cm}.</math>
  
*Mostly the code symbols&nbsp; $c_i \in {\rm GF}(2^m)$&nbsp; are converted back to binary &nbsp; &#8658; &nbsp; ${\rm GF}(2)$&nbsp; before transmission, where each symbol is then represented by &nbsp;$m$&nbsp; bits.<br>
+
*Mostly the code symbols&nbsp; $c_i \in {\rm GF}(2^m)$&nbsp; are converted back to binary &nbsp; &#8658; &nbsp; ${\rm GF}(2)$&nbsp; before transmission,&nbsp; where each symbol is then represented by &nbsp;$m$&nbsp; bits.<br>
  
  
Line 51: Line 57:
  
 
{{BlaueBox|TEXT=   
 
{{BlaueBox|TEXT=   
$\text{Definition:}$&nbsp; A&nbsp; $(n, k)$'''&ndash;Reed&ndash;Solomon code'''&nbsp; for the Galois field&nbsp; ${\rm GF}(2^m)$&nbsp; is defined by.
+
$\text{Definition:}$&nbsp; An &nbsp; $(n,\ k)\text{ Reed&ndash;Solomon code}$&nbsp; for the Galois field&nbsp; ${\rm GF}(2^m)$&nbsp; is defined by
*the&nbsp; $n= 2^{m-1}$&nbsp; elements of&nbsp; ${\rm GF}(2^m) \hspace{-0.05cm}\setminus \hspace{-0.05cm} \{0\} =\{ \alpha^0, \alpha^1, \, \text{...} \, , \alpha^{n-1}\}$, where&nbsp; $\alpha$&nbsp; denotes a&nbsp; [[Channel_Coding/Extension_Field#Binary_extension_fields_.E2.80.93_Primitive_polynomials|"primitive element"]]&nbsp; of&nbsp; ${\rm GF}(2^m)$&nbsp; denotes,
+
*the&nbsp; $n= 2^{m-1}$&nbsp; elements of&nbsp; ${\rm GF}(2^m) \hspace{-0.05cm}\setminus \hspace{-0.05cm} \{0\} =\{ \alpha^0, \alpha^1, \, \text{...} \, , \alpha^{n-1}\}$,&nbsp; where&nbsp; $\alpha$&nbsp; denotes a&nbsp; [[Channel_Coding/Extension_Field#Binary_extension_fields_.E2.80.93_Primitive_polynomials|$\text{primitive element}$]]&nbsp; of&nbsp; ${\rm GF}(2^m)$,&nbsp;
 
 
*an information blockt&nbsp; $\underline{u}$&nbsp; matched&nbsp; [[Channel_Coding/Extension_Field#Generalized_definition_of_an_extension_field|"polynomial"]]&nbsp; of degree&nbsp; $k-1$&nbsp; the form
 
  
::<math>u(x) = \sum_{i = 0}^{k-1} u_i \cdot x^{i}  = u_0 + u_1 \cdot x + u_2 \cdot x^2 + \hspace{0.1cm}... \hspace{0.1cm}+ u_{k-1} \cdot x^{k-1}  \hspace{0.05cm},\hspace{0.4cm} u_i \in {\rm GF}(2^m)
+
* a&nbsp; [[Channel_Coding/Extension_Field#Generalized_definition_of_an_extension_field|$\text{polynomial}$]]&nbsp; of degree&nbsp; $k-1$&nbsp; matched to an information block&nbsp; $\underline{u}$:&nbsp;
 +
:::<math>u(x) = \sum_{i = 0}^{k-1} u_i \cdot x^{i}  = u_0 + u_1 \cdot x + u_2 \cdot x^2 + \hspace{0.1cm}... \hspace{0.1cm}+ u_{k-1} \cdot x^{k-1}  \hspace{0.05cm},\hspace{0.4cm} u_i \in {\rm GF}(2^m)
 
\hspace{0.05cm}.</math>
 
\hspace{0.05cm}.</math>
  
Thus, the&nbsp; $(n, k)$&ndash;Reed&ndash;Solomon code can be described as.
+
&rArr; &nbsp; Thus,&nbsp; the&nbsp; $(n,k)$&nbsp; Reed&ndash;Solomon code can be described as follows:
  
 
::<math>C_{\rm RS} = \Big \{ \underline {c} =  \big ( u(\alpha^{0}) \hspace{0.05cm},\hspace{0.1cm} u(\alpha^{1})\hspace{0.05cm},\hspace{0.1cm}...\hspace{0.1cm},  u(\alpha^{n-1})\hspace{0.1cm}  \big )
 
::<math>C_{\rm RS} = \Big \{ \underline {c} =  \big ( u(\alpha^{0}) \hspace{0.05cm},\hspace{0.1cm} u(\alpha^{1})\hspace{0.05cm},\hspace{0.1cm}...\hspace{0.1cm},  u(\alpha^{n-1})\hspace{0.1cm}  \big )
Line 67: Line 72:
 
The previous information will now be illustrated by two simple examples.
 
The previous information will now be illustrated by two simple examples.
  
[[File:P ID2517 KC T 2 3 S1b v3.png|right|frame|$\rm GF(2^2)$&nbsp; in three different representations: <br>Exponential, polynomial and coefficient form |class=fit]]
 
 
{{GraueBox|TEXT=   
 
{{GraueBox|TEXT=   
 
$\text{Example 1:}$&nbsp; We consider the following code parameters:
 
$\text{Example 1:}$&nbsp; We consider the following code parameters:
 
+
[[File:KC_T_2_3_S1b_neu2.png|right|frame|$\rm GF(2^2)$&nbsp; in three different representations: <br>Exponential, polynomial and coefficient form|class=fit]]
::<math>k = 2 \hspace{0.05cm},\hspace{0.15cm}n = 3 \hspace{0.5cm} \Rightarrow  \hspace{0.5cm} \underline {u} = (u_0, u_1)\hspace{0.05cm},\hspace{0.15cm}  
+
::<math>k = 2 \hspace{0.05cm},\hspace{0.15cm}n = 3 \hspace{0.5cm} \Rightarrow  \hspace{0.5cm} \underline {u} = (u_0,\ u_1)\hspace{0.05cm},\hspace{0.15cm}  
\underline {c} = (c_0, c_1, c_2)\hspace{0.05cm},</math>
+
\underline {c} = (c_0,\ c_1,\ c_2)\hspace{0.05cm},</math>
 
 
 
::<math>q = n+1 = 4 \hspace{0.45cm} \Rightarrow  \hspace{0.5cm} {\rm GF} (q) = {\rm GF} (2^m)  
 
::<math>q = n+1 = 4 \hspace{0.45cm} \Rightarrow  \hspace{0.5cm} {\rm GF} (q) = {\rm GF} (2^m)  
 
\hspace{0.5cm} \Rightarrow  \hspace{0.5cm} m = 2\hspace{0.05cm}.</math>
 
\hspace{0.5cm} \Rightarrow  \hspace{0.5cm} m = 2\hspace{0.05cm}.</math>
  
Starting from the conditional equation&nbsp; $p(\alpha) = \alpha^2 + \alpha + 1 = 0$&nbsp; &#8658; &nbsp; $\alpha^2 = \alpha + 1$&nbsp; one obtains the assignments between  
+
Starting from the conditional equation&nbsp;  
*the exponential representation,  
+
:$$p(\alpha) = \alpha^2 + \alpha + 1 = 0 \hspace{0.3cm} &rArr; \hspace{0.3cm} \alpha^2 = \alpha + 1,$$
 +
one obtains the assignments between  
 +
*the exponential representation,
 +
 
*the polynomial representation and  
 
*the polynomial representation and  
 +
 
*the coefficient representation  
 
*the coefficient representation  
  
  
of&nbsp; ${\rm GF}(2^2)$&nbsp; according to the above table. From this it can be seen:
+
of&nbsp; ${\rm GF}(2^2)$&nbsp; according to the above table.&nbsp; From this it can be seen:
  
*The coefficient vector is expressed by the polynomial&nbsp; $u(x) = u_0 + u_1 \cdot x$&nbsp;. The polynomial degree is&nbsp; $k- 1 = 1$.  
+
# The coefficient vector is expressed by the polynomial &nbsp; $u(x) = u_0 + u_1 \cdot x$. &nbsp; The polynomial degree is&nbsp; $k- 1 = 1$.  
*For&nbsp; $u_0 = \alpha^1$&nbsp; and&nbsp; $u_1 = \alpha^2$&nbsp; we obtain, for example, the polynomial&nbsp; $u(x) = \alpha + \alpha^2 \cdot x$&nbsp; and thus
+
# For&nbsp; $u_0 = \alpha^1$&nbsp; and&nbsp; $u_1 = \alpha^2$&nbsp; we obtain e.g. the polynomial &nbsp; $u(x) = \alpha + \alpha^2 \cdot x$ &nbsp; and thus
 +
:::<math>c_0 = u (x = \alpha^0) = u (x = 1) =  \alpha + \alpha^2 \cdot 1 = \alpha + (\alpha + 1) =1 \hspace{0.05cm},</math>
 +
:::<math>c_1 =u (x = \alpha^1) =  \alpha + \alpha^2 \cdot \alpha = \alpha + \alpha^3 =  \alpha + \alpha^0  =  \alpha + 1 = \alpha^2 \hspace{0.05cm},</math>
 +
:::<math>c_2 =u (x = \alpha^2) =  \alpha + \alpha^2 \cdot \alpha^2 = \alpha + \alpha^4 =  \alpha + \alpha^1 = 0 \hspace{0.05cm}.</math>
  
::<math>c_0 = u (x = \alpha^0) = u (x = 1) =  \alpha + \alpha^2 \cdot 1 = \alpha + (\alpha + 1) =1 \hspace{0.05cm},</math>
+
&rArr; &nbsp; This results in the following assignments on symbol or bit level:
::<math>c_1 =u (x = \alpha^1) =  \alpha + \alpha^2 \cdot \alpha = \alpha + \alpha^3 =  \alpha + \alpha^0  =  \alpha + 1 = \alpha^2 \hspace{0.05cm},</math>
 
::<math>c_2 =u (x = \alpha^2) =  \alpha + \alpha^2 \cdot \alpha^2 = \alpha + \alpha^4 =  \alpha + \alpha^1 = 0 \hspace{0.05cm}.</math>
 
  
This results in the following assignments on symbol or bit level:
+
:$$\underline {u} =(\alpha^1, \ \alpha^2)\hspace{0.57cm}\leftrightarrow\hspace{0.3cm}
 +
\underline {c} = (1, \ \alpha^2, \ 0)\hspace{0.05cm},$$
 +
:$$\underline {u}_{\rm bin} =(1,\ 0,\ 1,\ 1)\hspace{0.3cm}\leftrightarrow\hspace{0.3cm}
 +
\underline {c}_{\rm bin} = (0,\ 1,\ 1,\ 1,\ 0,\ 0)\hspace{0.05cm}.$$}}<br>
  
::<math>\underline {u} =(\alpha^1, \ \alpha^2)\hspace{0.57cm}\leftrightarrow\hspace{0.3cm}
 
\underline {c} = (1, \ \alpha^2, \ 0)\hspace{0.05cm},\hspace{1cm}\underline {u}_{\rm bin} =(1,\ 0,\ 1,\ 1)\hspace{0.3cm}\leftrightarrow\hspace{0.3cm}
 
\underline {c}_{\rm bin} = (0,\ 1,\ 1,\ 1,\ 0,\ 0)\hspace{0.05cm}.</math>}}<br>
 
 
[[File:P ID2570 KC T 2 3 S1bb v3.png|right|frame||Codetabelle des&nbsp; $\text{RSC (3, 2, 2)}_4$]]
 
 
{{GraueBox|TEXT=   
 
{{GraueBox|TEXT=   
 
$\text{Example 2:}$&nbsp;   
 
$\text{Example 2:}$&nbsp;   
On the right is the code table of the&nbsp; $\text{RSC (3, 2, 2)}_4$&nbsp; named Reed&ndash;Solomon code.
+
On the right you see the code table of a special Reed&ndash;Solomon code named&nbsp; $\text{RSC (3, 2, 2)}_4$.
*The label refers to the parameters&nbsp; $n=3$,&nbsp; $k=2$,&nbsp; $d_{\rm min}=2$&nbsp; and&nbsp; $q = 4$.  
+
[[File:P ID2570 KC T 2 3 S1bb v3.png|right|frame||Code table of the&nbsp; $\text{RSC (3, 2, 2)}_4$]]
 +
 +
*The label refers to the parameters&nbsp; $n=3$,&nbsp; $k=2$,&nbsp; $d_{\rm min}=2$&nbsp; and&nbsp; $q = 4$.
 +
 
*In columns 1 to 3, one can see the relationship &nbsp;$\underline {u} \ &#8594; \ u(x) \ &#8594; \ \underline {c}$.
 
*In columns 1 to 3, one can see the relationship &nbsp;$\underline {u} \ &#8594; \ u(x) \ &#8594; \ \underline {c}$.
 +
 
*In the last two columns, the coding rule &nbsp;$\underline {u}_{\rm bin} \ &#8596; \ \underline {c}_{\rm bin}$ is given.<br>
 
*In the last two columns, the coding rule &nbsp;$\underline {u}_{\rm bin} \ &#8596; \ \underline {c}_{\rm bin}$ is given.<br>
  
  
For clarification again the entry for $(\alpha^0, \ \alpha^2)$:
+
&rArr; &nbsp; For clarification the entry for&nbsp; $(\alpha^0, \ \alpha^2)$:
  
 
::<math>u(x) = u_0 + u_1 \cdot x = \alpha^0 +  \alpha^2 \cdot x. </math>
 
::<math>u(x) = u_0 + u_1 \cdot x = \alpha^0 +  \alpha^2 \cdot x. </math>
  
This results in the following code symbols:
+
This results in the following code symbols&nbsp; (see red mark):
  
 
::<math>c_0 = u (x = \alpha^0) =  1 + \alpha^2 \cdot 1 = 1 + (1+\alpha ) =\alpha \hspace{0.05cm},</math>
 
::<math>c_0 = u (x = \alpha^0) =  1 + \alpha^2 \cdot 1 = 1 + (1+\alpha ) =\alpha \hspace{0.05cm},</math>
Line 117: Line 127:
 
::<math>c_2 =u (x = \alpha^2) =  1 + \alpha^2 \cdot \alpha^2 = 1 + \alpha =  \alpha^2  \hspace{0.05cm}.</math>
 
::<math>c_2 =u (x = \alpha^2) =  1 + \alpha^2 \cdot \alpha^2 = 1 + \alpha =  \alpha^2  \hspace{0.05cm}.</math>
  
<i>Hints:</i>  
+
<u>Notes:</u>  
*From the element set $\{0, \ \alpha^0 = 1, \ \alpha^1 = \alpha, \ \alpha^2\}$ it should not be concluded that for this code the 3D&ndash;representation with axes&nbsp; $\alpha^0 = 1$,&nbsp; $\alpha^1 = \alpha$,&nbsp; $\alpha^2$&nbsp; applies. See section &nbsp; [[Channel_Coding/Extension_Field#Binary_extension_fields_.E2.80.93_Primitive_polynomials|"primitive polynomials"]]&nbsp;&ndash; example 5.
+
*From the element set&nbsp; $\{0, \ \alpha^0 = 1, \ \alpha^1 = \alpha, \ \alpha^2\}$&nbsp; it should not be concluded that for this code the three-dimensional representation with axes &nbsp; $\alpha^0 = 1$, &nbsp; $\alpha^1 = \alpha$, &nbsp; $\alpha^2$ &nbsp; applies.&nbsp; See section &nbsp; [[Channel_Coding/Extension_Field#Binary_extension_fields_.E2.80.93_Primitive_polynomials|"Primitive Polynomials"]]&nbsp;&ndash; Example 5.
*On the contrary, from the coefficient representation in&nbsp; $\text{Example 1}$&nbsp; it is clear that &nbsp; ${\rm GF} (2^2)$&nbsp; is two-dimensional, where the axes of the two dimensional representation are to be labeled&nbsp; $\alpha^0 = 1$&nbsp; and&nbsp; $\alpha^1 = \alpha$&nbsp; .
+
 
 +
*On the contrary,&nbsp; from the coefficient representation in&nbsp; $\text{Example 1}$&nbsp; it is clear that &nbsp; ${\rm GF} (2^2)$&nbsp; is two-dimensional,&nbsp; where the axes of the two dimensional representation are to be labeled&nbsp; $\alpha^0 = 1$&nbsp; and&nbsp; $\alpha^1 = \alpha$.
 
}}<br>
 
}}<br>
  
 
== Generator matrix of Reed-Solomon codes ==
 
== Generator matrix of Reed-Solomon codes ==
 
<br>
 
<br>
Since the Reed&ndash;Solomon code is a linear block code, the relationship between information word&nbsp; $\underline {u}$&nbsp; and codeword&nbsp; $\underline {c}$&nbsp; given by the&nbsp; [[Channel_Coding/General_Description_of_Linear_Block_Codes#Code_definition_by_the_generator_matrix| "Generator Matrix"]]&nbsp; $\boldsymbol{\rm G}$&nbsp;:
+
Since the Reed&ndash;Solomon code is a linear block code,&nbsp; the relationship between the information word&nbsp; $\underline {u}$&nbsp; and the  code word&nbsp; $\underline {c}$&nbsp; is given by the&nbsp; [[Channel_Coding/General_Description_of_Linear_Block_Codes#Code_definition_by_the_generator_matrix|$\text{generator matrix}$]]&nbsp; $\boldsymbol{\rm G}$:
  
 
::<math>\underline {c} = \underline {u} \cdot { \boldsymbol{\rm G}}
 
::<math>\underline {c} = \underline {u} \cdot { \boldsymbol{\rm G}}
 
\hspace{0.05cm}.</math>
 
\hspace{0.05cm}.</math>
  
As with any linear&nbsp; $(n, k)$&ndash;block code, the generator matrix consists of&nbsp; $k$&nbsp; rows and&nbsp; $n$&nbsp; columns. In contrast to the chapter&nbsp; [[Channel_Coding/General_Description_of_Linear_Block_Codes#Linear_codes_and_cyclic_codes|"General Description of Linear Block Codes"]]&nbsp; however, now the elements of the generator matrix are no longer binary&nbsp; $(0$ or $1)$, but come from the Galois field&nbsp; ${\rm GF}(2^m) \hspace{-0.05cm}\setminus \hspace{-0.05cm} \{0\} $.<br>
+
As with any linear&nbsp; $(n,\ k)$&nbsp; block code,&nbsp; the generator matrix consists of&nbsp;  
 +
*$k$&nbsp; rows and&nbsp;  
 +
*$n$&nbsp; columns.  
 +
 
 +
 
 +
In contrast to the chapter&nbsp; [[Channel_Coding/General_Description_of_Linear_Block_Codes#Linear_codes_and_cyclic_codes|"General Description of Linear Block Codes"]]&nbsp;  
 +
*now the elements of the generator matrix are no longer binary&nbsp; $(0$&nbsp; or&nbsp; $1)$,  
 +
 
 +
*but come from the Galois field&nbsp; ${\rm GF}(2^m) \hspace{-0.05cm}\setminus \hspace{-0.05cm} \{0\} $.<br>
 +
 
  
 
{{GraueBox|TEXT=   
 
{{GraueBox|TEXT=   
$\text{Example 3:}$&nbsp; We consider as in&nbsp; $\text{Example 2}$&nbsp; (previous page) the&nbsp; $\text{RSC (3, 2, 2)}_4$ whose generator matrix has the following form:
+
$\text{Example 3:}$&nbsp; We consider as in&nbsp; [[Channel_Coding/Definition_and_Properties_of_Reed-Solomon_Codes#Coding_principle_and_code_parameters|$\text{Example 2}$]]&nbsp; (see previous section)&nbsp; the&nbsp; $\text{RSC (3, 2, 2)}_4$&nbsp; whose generator matrix has the following form:
  
:<math> { \boldsymbol{\rm G} } =  
+
::<math> { \boldsymbol{\rm G} } =  
 
\begin{pmatrix}
 
\begin{pmatrix}
 
g_{00} & g_{01} & g_{02}\\
 
g_{00} & g_{01} & g_{02}\\
Line 143: Line 163:
  
 
Beside this:
 
Beside this:
*The first row of&nbsp; $\boldsymbol{\rm G}$&nbsp; gives the codeword for the information word&nbsp; $\underline {u}_1 = (1, 0)$&nbsp; respectively for the polynomial function $u_1(x) = 1$. Thus one receives the matrix elements of the first row
+
*The first row of&nbsp; $\boldsymbol{\rm G}$&nbsp; gives the code word for the information word&nbsp; $\underline {u}_1 = (1,\ 0)$&nbsp; respectively for the polynomial function&nbsp; $u_1(x) = 1$.&nbsp; Thus one receives the matrix elements of the first row
  
::<math>g_{00} = u_{1}(\alpha^{0}) = 1\hspace{0.05cm},\hspace{0.3cm}
+
:$$g_{00} = u_{1}(\alpha^{0}) = 1\hspace{0.05cm},$$
g_{01} = u_{1}(\alpha^{1}) = 1\hspace{0.05cm},\hspace{0.3cm}
+
:$$g_{01} = u_{1}(\alpha^{1}) = 1\hspace{0.05cm},$$
g_{02} = u_{1}(\alpha^{2}) = 1\hspace{0.05cm}.</math>
+
:$$g_{02} = u_{1}(\alpha^{2}) = 1\hspace{0.05cm}.$$
  
*The second row is equal to the code word for the information word $\underline {u}_2 = (0, 1)$ &nbsp; &#8658; &nbsp; $u_2(x) = x$. Thus, the matrix elements of the second row are:
+
*The second row is equal to the code word for the information word $\underline {u}_2 = (0,\ 1)$ &nbsp; &#8658; &nbsp; $u_2(x) = x$.&nbsp; Thus,&nbsp; the matrix elements of the second row are:
  
::<math>g_{10} = u_{2}(\alpha^{0}) = \alpha^{0} = 1\hspace{0.05cm},\hspace{0.3cm}
+
:$$g_{10} = u_{2}(\alpha^{0}) = \alpha^{0} = 1\hspace{0.05cm},$$
g_{11} = u_{2}(\alpha^{1}) =  \alpha \hspace{0.05cm},\hspace{0.3cm}
+
:$$g_{11} = u_{2}(\alpha^{1}) =  \alpha \hspace{0.05cm},$$
g_{12} = u_{2}(\alpha^{2}) = \alpha^{2}\hspace{0.05cm}.</math>
+
:$$g_{12} = u_{2}(\alpha^{2}) = \alpha^{2}\hspace{0.05cm}.$$
 
+
* So the complete generator matrix is:
::<math>\Rightarrow\hspace{0.3cm} { \boldsymbol{\rm G} } =  
+
:$$ { \boldsymbol{\rm G} } =  
 
\begin{pmatrix}
 
\begin{pmatrix}
 
1 & 1 & 1\\
 
1 & 1 & 1\\
 
1 & \alpha & \alpha^2
 
1 & \alpha & \alpha^2
\end{pmatrix}\hspace{0.05cm}.</math>
+
\end{pmatrix}\hspace{0.05cm}.$$
 +
[[File:P ID2519 KC T 2 3 S2a v1.png|right|frame|Code table of the&nbsp; $\text{RSC (3, 2, 2)}_4$&nbsp; at symbol level|class=fit]]
  
For the information word $\underline {u}= (u_0, \ u_1)$ mit den Symbolen $u_0, \ u_1 &#8712; \{0, \ \alpha^0, \ \alpha^1 = \alpha, \ \alpha^2\}$&nbsp; one obtains, considering the two equations&nbsp; $\alpha^2 = \alpha + 1$&nbsp; and&nbsp; $\alpha^3 = \alpha^0 = 1$&nbsp; again the code table of the&nbsp; $\text{RSC (3, 2, 2)}_4$&nbsp; at symbol level.<br>
+
*For the information word&nbsp; $\underline {u}= (u_0, \ u_1)$&nbsp; with symbols&nbsp;
 +
:$$u_0, \ u_1 &#8712; \{0, \ \alpha^0 = 1, \ \alpha^1 = \alpha, \ \alpha^2\}$$
 +
:one obtains,&nbsp; considering the two equations &nbsp; $\alpha^2 = \alpha + 1$ &nbsp; and &nbsp; $\alpha^3 = \alpha^0 = 1$ &nbsp; again the code table of the&nbsp; $\text{RSC (3, 2, 2)}_4$&nbsp; at symbol level.<br>
  
[[File:P ID2519 KC T 2 3 S2a v1.png|center|frame|Code table of the&nbsp; $\text{RSC (3, 2, 2)}_4$&nbsp; at symbol level|class=fit]]
+
#Of course,&nbsp; with the same generator matrix you get exactly the same code table&nbsp; $\underline {u} &nbsp; &#8596; &nbsp; \underline {c}$&nbsp; as after the calculation via the function&nbsp; $u(x)$.  
 +
#The corresponding code table on bit level&nbsp; $($see&nbsp; $\text{Example 2}$&nbsp; in the previous section$)$&nbsp; results again,&nbsp; if the elements are not given in exponent representation,&nbsp; but in coefficient form:
  
*Of course, with the generator matrix you get exactly the same code table&nbsp; $\underline {u} &nbsp; &#8596; &nbsp; \underline {c}$&nbsp; as after the calculation via the function&nbsp; $u(x)$.
+
:::<math>(0, \hspace{0.1cm}\alpha^{0}, \hspace{0.1cm}\alpha^{1}, \hspace{0.1cm}\alpha^{2}) \hspace{0.3cm}\Leftrightarrow\hspace{0.3cm}(00, \hspace{0.1cm}01, \hspace{0.1cm}10, \hspace{0.1cm}11)  
*The corresponding code table on bit level (see&nbsp; $\text{Example 2}$&nbsp; on the previous page) results again, if the elements are not given in exponent representation, but in coefficient form:
 
 
 
::<math>(0, \hspace{0.1cm}\alpha^{0}, \hspace{0.1cm}\alpha^{1}, \hspace{0.1cm}\alpha^{2}) \hspace{0.3cm}\Leftrightarrow\hspace{0.3cm}(00, \hspace{0.1cm}01, \hspace{0.1cm}10, \hspace{0.1cm}11)  
 
 
\hspace{0.05cm}. </math>}}<br>
 
\hspace{0.05cm}. </math>}}<br>
  
 
== Generator matrix and parity-check matrix ==
 
== Generator matrix and parity-check matrix ==
 
<br>
 
<br>
We now generalize the result of the last page for a Reed&ndash;Solomon code with
+
We now generalize the result of the last section for a Reed&ndash;Solomon code with
*the dimension&nbsp; $k$&nbsp; (number of symbols per information block),<br>
+
*dimension&nbsp; $k$&nbsp; $($number of symbols per information block$)$,<br>
  
*the codeword length&nbsp; $n$&nbsp; (number of symbols per codeword).<br><br>
+
*code word length&nbsp; $n$&nbsp; $($number of symbols per code word$)$.<br>
  
[[Channel_Coding/General_Description_of_Linear_Block_Codes#Code_definition_by_the_generator_matrix| "generator matrix"]]&nbsp; $\boldsymbol{\rm G}$&nbsp; $(k$ rows,&nbsp; $n$ columns$)$&nbsp; and&nbsp;  [[Channel_Coding/General_Description_of_Linear_Block_Codes#Code_definition_by_the_parity-check_matrix| "parity-check matrix"]]&nbsp; $\boldsymbol{\rm H}$&nbsp; $(n-k$ rows,&nbsp; $n$&nbsp; columns$)$ must jointly satisfy the following equation:
 
  
::<math>{ \boldsymbol{\rm G}} \cdot { \boldsymbol{\rm H }}^{\rm T}= { \boldsymbol{\rm 0}}\hspace{0.05cm}.</math>
+
{{BlaueBox|TEXT=
 +
&rArr; &nbsp; The&nbsp; [[Channel_Coding/General_Description_of_Linear_Block_Codes#Code_definition_by_the_generator_matrix|$\text{generator matrix}$]]&nbsp; $\boldsymbol{\rm G}$&nbsp; $(k$ rows,&nbsp; $n$ columns$)$&nbsp; and the&nbsp;  [[Channel_Coding/General_Description_of_Linear_Block_Codes#Code_definition_by_the_parity-check_matrix|$\text{parity-check matrix}$]]&nbsp; $\boldsymbol{\rm H}$&nbsp; $(n-k$ rows,&nbsp; $n$&nbsp; columns$)$&nbsp; must jointly satisfy the following equation:
 +
 
 +
:$${\boldsymbol{\rm G} } \cdot { \boldsymbol{\rm H } }^{\rm T}= { \boldsymbol{\rm 0} }\hspace{0.05cm}.$$
 +
 
 +
Here,&nbsp; "$\boldsymbol{\rm 0}$"&nbsp; denotes a zero matrix&nbsp; $($all elements equal&nbsp; $0)$ &nbsp; with&nbsp; $k$&nbsp; rows and&nbsp; $n-k$&nbsp; columns.<br>}}
  
Here,&nbsp; $\boldsymbol{\rm 0}$&nbsp; denotes a zero matrix $($all elements equal $0)$&nbsp; with&nbsp; $k$&nbsp; rows and&nbsp; $n-k$&nbsp; columns.<br>
 
  
 
{{GraueBox|TEXT=   
 
{{GraueBox|TEXT=   
$\text{Example 4:}$&nbsp; We consider the&nbsp; $\text{RSC (7, 3, 5)}_8$ &nbsp; &#8658; &nbsp; code parameter&nbsp; $n= 7$,&nbsp; $k= 3$, based on the Galois field&nbsp; $\rm GF(2^3 = 8)$&nbsp; with the constraint&nbsp; $\alpha^3 =\alpha + 1$. Note with respect to the code name:
+
$\text{Example 4:}$&nbsp; We consider the &nbsp; $\text{RSC (7, 3, 5)}_8$:
*The third parameter of the nomenclature commonly used for block codes names the free distance&nbsp; $d_{\rm min}= 5$.<br>
+
*code parameters&nbsp; $n= 7$,&nbsp; $k= 3$,
 +
 +
*based on the Galois field&nbsp; $\rm GF(2^3 = 8)$&nbsp;
 +
 +
*with the constraint&nbsp; $\alpha^3 =\alpha + 1$.  
 +
 
  
*Unlike the binary codes discussed in the chapter&nbsp; [[Channel_Coding/Examples_of_Binary_Block_Codes|"Examples of binary block codes"]]&nbsp; (single parity-check code, repetition code, Hamming code), the Reed&ndash;Solomon codes still have the hint&nbsp; $q$&nbsp; added to the Galois field&nbsp; $($here: &nbsp; $q = 8)$.<br><br>
+
Note with respect to the code name:
 +
#The third parameter of the nomenclature commonly used for block codes names the free distance&nbsp; $d_{\rm min}= 5$.<br>
 +
#Unlike the binary codes discussed in the chapter&nbsp; [[Channel_Coding/Examples_of_Binary_Block_Codes|"Examples of binary block codes"]]&nbsp; $($single parity-check code, repetition code, Hamming code$)$,&nbsp; the Reed&ndash;Solomon codes still have the hint&nbsp; $q$&nbsp; added to the Galois field&nbsp; $($here: &nbsp; $q = 8)$.<br><br>
  
 
All elements of the generator matrix and the parity-check matrix,
 
All elements of the generator matrix and the parity-check matrix,
Line 230: Line 261:
  
 
This will be demonstrated here for two elements only:
 
This will be demonstrated here for two elements only:
*First row, first column:
+
*First row,&nbsp; first column:
  
 
::<math>1 \hspace{0.1cm}  \cdot  \hspace{0.1cm} \big [1 + \alpha^1 + \alpha^2 + \alpha^3 + \alpha^4 + \alpha^5 + \alpha^6 \big ] =  1 + \alpha + \alpha^2 + (\alpha + 1) + (\alpha^2 + \alpha)+ (\alpha^2 + \alpha +1)+ (\alpha^2 + 1) = 0 \hspace{0.05cm}; </math>
 
::<math>1 \hspace{0.1cm}  \cdot  \hspace{0.1cm} \big [1 + \alpha^1 + \alpha^2 + \alpha^3 + \alpha^4 + \alpha^5 + \alpha^6 \big ] =  1 + \alpha + \alpha^2 + (\alpha + 1) + (\alpha^2 + \alpha)+ (\alpha^2 + \alpha +1)+ (\alpha^2 + 1) = 0 \hspace{0.05cm}; </math>
  
*Last row, last column:
+
*Last row,&nbsp; last column:
  
 
::<math>1 \hspace{0.1cm}  \cdot  \hspace{0.1cm} 1 + \alpha^2 \cdot \alpha^4 + \alpha^4 \cdot \alpha^1
 
::<math>1 \hspace{0.1cm}  \cdot  \hspace{0.1cm} 1 + \alpha^2 \cdot \alpha^4 + \alpha^4 \cdot \alpha^1
Line 242: Line 273:
 
== Singleton bound and minimum distance ==
 
== Singleton bound and minimum distance ==
 
<br>
 
<br>
An important parameter of any block code is the&nbsp; [[Channel_Coding/Objective_of_Channel_Coding#Important_definitions_for_block_coding| "minimum distance"]]&nbsp; between any two code words&nbsp; $\underline {c}_i$&nbsp; and&nbsp; $\underline {c}_j$.  
+
An important parameter of any block code is the&nbsp; [[Channel_Coding/Objective_of_Channel_Coding#Important_definitions_for_block_coding|$\text{minimum distance}$]]&nbsp; between any two code words&nbsp; $\underline {c}_i$&nbsp; and&nbsp; $\underline {c}_j$.  
*The Reed&ndash;Solomon&ndash;codes belong to the class of&nbsp; <i>linear</i>&nbsp; and&nbsp; <i>cyclic</i>&nbsp; codes. For these, one can start from the zero word&nbsp; $\underline {c}_0 = (0, 0, \hspace{0.05cm} \text{...} \hspace{0.05cm}, 0)$&nbsp; as the reference.  
+
*The Reed&ndash;Solomon&ndash;codes belong to the class of&nbsp; &raquo;'''linear&nbsp; and&nbsp; cyclic codes'''&laquo;.&nbsp; For these,&nbsp; one can start from the zero word&nbsp; $\underline {c}_0 = (0, 0, \hspace{0.05cm} \text{...} \hspace{0.05cm}, 0)$&nbsp; as the reference.
*From the number of zeros in the other codewords&nbsp; $\underline {c}_j &ne; \underline {c}_0$&nbsp; the [[Channel_Coding/Bounds_for_Block_Error_Probability#Distance_spectrum_of_a_linear_code| "distance spectrum"]]&nbsp; $\{ \hspace{0.05cm}W_j\hspace{0.05cm}\}$&nbsp; can be specified.<br>
+
 +
*From the number of zeros in the other code words&nbsp; $\underline {c}_j &ne; \underline {c}_0$&nbsp; the&nbsp; [[Channel_Coding/Bounds_for_Block_Error_Probability#Distance_spectrum_of_a_linear_code|$\text{distance spectrum}$]]&nbsp; $\{ \hspace{0.05cm}W_j\hspace{0.05cm}\}$&nbsp; can be specified.<br>
  
  
 
{{GraueBox|TEXT=   
 
{{GraueBox|TEXT=   
 
$\text{Example 5:}$&nbsp; The table illustrates the determination of the distance spectrum for the&nbsp; $\text{RSC (3, 2, 2)}_4$.  
 
$\text{Example 5:}$&nbsp; The table illustrates the determination of the distance spectrum for the&nbsp; $\text{RSC (3, 2, 2)}_4$.  
*Compared to the previous graphs, the symbol set is simplified by&nbsp; $\{0,\ 1,\ 2,\ 3\}$&nbsp; instead of $\{0,\ \alpha^0,\ \alpha^1,\ \alpha^2\}$&nbsp;.  
+
*Compared to the previous graphs,&nbsp; the symbol set is simplified by &nbsp; $\{0,\ 1,\ 2,\ 3\}$ &nbsp; instead of &nbsp; $\{0,\ \alpha^0,\ \alpha^1,\ \alpha^2\}$.
*The distance&nbsp; $d$&nbsp; between&nbsp; $\underline {c}_j$&nbsp; and the null word&nbsp; $\underline {c}_0$&nbsp; is identical to&nbsp; [[Channel_Coding/Objective_of_Channel_Coding#Important_definitions_for_block_coding|"Hamming weight"]]&nbsp; $w_{\rm H}(\underline {c}_j)$.<br>
+
 +
*The distance&nbsp; $d$&nbsp; between&nbsp; $\underline {c}_j$&nbsp; and the null word&nbsp; $\underline {c}_0$&nbsp; is identical to the&nbsp; [[Channel_Coding/Objective_of_Channel_Coding#Important_definitions_for_block_coding|$\text{Hamming weight}$]]&nbsp; $w_{\rm H}(\underline {c}_j)$.<br>
  
[[File:P ID2520 KC T 2 3 S3 v1.png|center|frame|To derive the distance spectrum for the|class=fit]]
+
[[File:EN_KC_T_2_3_S3.png|right|frame|To derive the distance spectrum for the&nbsp; $\text{RSC (3, 2, 2)}_4$|class=fit]]
 +
<br>
 +
&rArr; &nbsp; From the upper table can be read among others:
 +
#Nine code words differ from the zero word in two symbols and six code words in three symbols: &nbsp; $W_2 = 9$,&nbsp; $W_3 = 6$.
 +
#There is not a single code word with only one zero.&nbsp; That means: &nbsp; The minimum distance here is&nbsp; $d_{\rm min} = 2$. <br>
  
From the upper table can be read, among others:
 
*Nine codewords differ from the zero word in two symbols and six codewords differ in three symbols: &nbsp; $W_2 = 9$,&nbsp; $W_3 = 6$.
 
*There is not a single codeword with only one zero. That means: &nbsp; The minimum distance here is&nbsp; $d_{\rm min} = 2$. <br>
 
  
 
+
&rArr; &nbsp; From the table below one can see that also for the binary representation holds&nbsp; $d_{\rm min} = 2$.}}<br>
From the table below one can see that also for the binary representation&nbsp; $d_{\rm min} = 2$&nbsp; holds.}}<br>
 
  
 
This empirical result will now be generalized:
 
This empirical result will now be generalized:
Line 265: Line 298:
 
{{BlaueBox|TEXT=   
 
{{BlaueBox|TEXT=   
 
$\text{Without proof:}$&nbsp;  
 
$\text{Without proof:}$&nbsp;  
*The&nbsp; <i>minimum distance</i>&nbsp; of each&nbsp; $(n, k)$&ndash;Reed&ndash;Solomon codes is&nbsp; $d_{\rm min} =n-k+1$ &nbsp; &rArr; &nbsp; symbol errors can be detected&nbsp; $e = d_{\rm min} -1 =n-k$&nbsp;.<br>
+
#The&nbsp; "minimum distance"&nbsp; of each&nbsp; $(n,\ k)$&nbsp; Reed&ndash;Solomon code is&nbsp; $d_{\rm min} =n-k+1$ &nbsp; &rArr; &nbsp; symbol errors can be detected &nbsp; &rArr; &nbsp; $e = d_{\rm min} -1 =n-k$&nbsp;.<br>
 +
#For&nbsp; "error correcting codes"&nbsp; one usually chooses&nbsp; $d_{\rm min} $&nbsp; odd &nbsp; &#8658; &nbsp; $n-k$&nbsp; even.&nbsp; 
 +
#For Reed&ndash;Solomon codes then up to &nbsp; $t =(n-k)/2$ &nbsp; symbol errors can be corrected.<br>
 +
#The&nbsp; [https://en.wikipedia.org/wiki/Singleton_bound $\text{Singleton bound}$]&nbsp; says that&nbsp; $d_{\rm min} \le n-k+1$&nbsp; holds for all linear codes.
 +
#Reed&ndash;Solomon codes reach this bound with equality;&nbsp; they are so-called&nbsp; [https://en.wikipedia.org/wiki/Singleton_bound#MDS_codes $\text{maximum distance separable codes}$]&nbsp; (short: "MDS codes").
 +
#The&nbsp; [[Channel_Coding/Bounds_for_Block_Error_Probability#Distance_spectrum_of_a_linear_code|$\text{distance spectrum}$]]&nbsp; is composed of&nbsp; $W_0 = 1$&nbsp; and other weight factors&nbsp; $W_i$&nbsp; with&nbsp; $d &#8804; i &#8804; n$,&nbsp; where in the following equation&nbsp; $d_{\rm min}$&nbsp; is abbreviated as&nbsp; $d$:
  
*For&nbsp; <i>error correcting codes</i>&nbsp; one usually chooses&nbsp; $d_{\rm min} $&nbsp; odd &nbsp; &#8658; &nbsp; $n-k$&nbsp; even. For RS&ndash;codes then up to&nbsp; $t =(n-k)/2$&nbsp; symbol errors can be corrected.<br>
+
:::<math>W_i =  {n \choose i} \cdot \sum_{j = 0}^{i-d}\hspace{0.15cm}(-1)^j \cdot {i \choose j} \cdot \bigg  [\hspace{0.03cm}q^{i\hspace{0.03cm}-\hspace{0.03cm}j\hspace{0.03cm}-\hspace{0.03cm}d\hspace{0.03cm}+\hspace{0.03cm}1}-1 \hspace{0.03cm} \bigg ]\hspace{0.05cm}.</math>}}
 
 
*The&nbsp; [https://en.wikipedia.org/wiki/Singleton_bound "Singleton bound"]&nbsp; says tat&nbsp; $d_{\rm min} \le n-k+1$&nbsp; holds for all linear codes. RS codes reach this bound with equality; they are so-called&nbsp; [https://en.wikipedia.org/wiki/Singleton_bound#MDS_codes "MDS codes"]&nbsp; (<i>Maximum Distance Separable</i>&nbsp;).
 
 
 
*The&nbsp; [[Channel_Coding/Bounds_for_Block_Error_Probability#Distance_spectrum_of_a_linear_code| "distance spectrum"]]&nbsp; is composed of&nbsp; $W_0 = 1$&nbsp; and other weight factors&nbsp; $W_i$&nbsp; with&nbsp; $d &#8804; i &#8804; n$, where in the following equation&nbsp; $d_{\rm min}$&nbsp; is abbreviated as&nbsp; $d$&nbsp;:
 
 
 
::<math>W_i =  {n \choose i} \cdot \sum_{j = 0}^{i-d}\hspace{0.15cm}(-1)^j \cdot {i \choose j} \cdot \bigg  [\hspace{0.03cm}q^{i\hspace{0.03cm}-\hspace{0.03cm}j\hspace{0.03cm}-\hspace{0.03cm}d\hspace{0.03cm}+\hspace{0.03cm}1}-1 \hspace{0.03cm} \bigg ]\hspace{0.05cm}.</math>}}
 
  
 
== Code name and code rate ==
 
== Code name and code rate ==
 
<br>
 
<br>
The usual designation for the Reed&ndash;Solomon codes is &nbsp;${\rm RSC} \ \ (n,\ k, \ d_{\rm min})_q$&nbsp; with.
+
The usual designation for the Reed&ndash;Solomon codes is &nbsp;${\rm RSC} \ \ (n,\ k, \ d_{\rm min})_q$&nbsp; with
*the length&nbsp; $n$&nbsp; of the code (symbol number of a codeword),<br>
+
*the length&nbsp; $n$&nbsp; of the code $($symbol number of a code word$)$,<br>
  
*of the dimension&nbsp; $k$&nbsp; of the code (symbol number of an information word),<br>
+
*the dimension&nbsp; $k$&nbsp; of the code&nbsp; $($symbol number of an information word$)$,<br>
  
*of the minimum distance&nbsp; $d_{\rm min} = n-k+1$, maximum corresponding to the&nbsp; ''Singleton bound'', and<br>
+
*the minimum distance&nbsp; $d_{\rm min} = n-k+1$,&nbsp; which is maximum corresponding to the&nbsp; "Singleton bound",&nbsp; and<br>
  
 
*the size&nbsp; $q = 2^m$&nbsp; of the Galois field&nbsp; ${\rm GF}(q)$.<br><br>
 
*the size&nbsp; $q = 2^m$&nbsp; of the Galois field&nbsp; ${\rm GF}(q)$.<br><br>
  
Alle Elemente&nbsp; $u_i$&nbsp; des Informationswortes&nbsp; $\underline{u}= (u_0, \hspace{0.05cm}\text{...} \hspace{0.05cm}, u_i, \hspace{0.05cm}\text{...} \hspace{0.05cm}, u_{k-1})$ and all elements <i>c<sub>i</sub></i> of the codeword $\underline{c}= (c_0, \hspace{0.05cm}\text{...} \hspace{0.05cm}, c_i, \hspace{0.05cm}\text{...} \hspace{0.05cm}, c_{n-1})$&nbsp; are non-binary symbols and come from the Galois field&nbsp; ${\rm GF}(q)$.<br>
+
&rArr; &nbsp; All elements&nbsp; $u_i$&nbsp; of the information word &nbsp; $\underline{u}= (u_0, \hspace{0.05cm}\text{...} \hspace{0.05cm}, u_i, \hspace{0.05cm}\text{...} \hspace{0.05cm}, u_{k-1})$ &nbsp; and all elements&nbsp; $c_i$&nbsp; of the code word $\underline{c}= (c_0, \hspace{0.05cm}\text{...} \hspace{0.05cm}, c_i, \hspace{0.05cm}\text{...} \hspace{0.05cm}, c_{n-1})$&nbsp; are non-binary symbols and come from the Galois field&nbsp; ${\rm GF}(q)$.<br>
  
For the realization these symbols are always also represented in binary and one arrives at the equivalent binary Reed&ndash;Solomon code &nbsp;${\rm RSC} \ \ (n_{\rm bin},\ k_{\rm bin}, \ d_{\rm min})_2$&nbsp; with.
+
&rArr; &nbsp; For the realization these symbols are also represented in binary and one arrives at the&nbsp;  "equivalent binary Reed&ndash;Solomon code" &nbsp;${\rm RSC} \ \ (n_{\rm bin},\ k_{\rm bin}, \ d_{\rm min})_2$&nbsp; with
*$n_{\rm bin} = n \cdot m$ &nbsp; bits of a codeword,<br>
+
*$n_{\rm bin} = n \cdot m$ &nbsp; bits of a code word,<br>
  
 
*$k_{\rm bin} = k \cdot m$ &nbsp; bit of an information word.<br><br>
 
*$k_{\rm bin} = k \cdot m$ &nbsp; bit of an information word.<br><br>
  
The code rate is not changed by this action:
+
&rArr; &nbsp; The code rate is not changed by this action:
  
 
::<math>R_{\rm bin} =  \frac{k_{\rm bin}}{n_{\rm bin}} = \frac{k \cdot m}{n \cdot m} = \frac{k}{n} = R
 
::<math>R_{\rm bin} =  \frac{k_{\rm bin}}{n_{\rm bin}} = \frac{k \cdot m}{n \cdot m} = \frac{k}{n} = R
 
\hspace{0.05cm}.</math>
 
\hspace{0.05cm}.</math>
  
Similarly, the transition from&nbsp; ${\rm GF}(q)$&nbsp; to&nbsp; ${\rm GF}(2)$&nbsp; does not change the minimum distance&nbsp; $d_{\rm min}$.<br>
+
&rArr; &nbsp; Similarly,&nbsp; the transition from&nbsp; ${\rm GF}(q)$&nbsp; to&nbsp; ${\rm GF}(2)$&nbsp; does not change the minimum distance&nbsp; $d_{\rm min}$.<br>
  
 
{{GraueBox|TEXT=   
 
{{GraueBox|TEXT=   
$\text{Example 6:}$&nbsp; As in&nbsp; $\text{Example 5}$&nbsp; (previous page), we again consider the&nbsp; $\text{RSC (3, 2, 2)}_4$&nbsp; and give its&nbsp; <i>distance spectrum</i>&nbsp; $\{ \hspace{0.05cm}W_j\hspace{0.05cm}\}$&nbsp; again (upper table). The lower table applies to the equivalent binary Reed&ndash;Solomon code&nbsp; $\text{RSC (6, 4, 2)}_2$.
+
$\text{Example 6:}$&nbsp; As in&nbsp; [[Channel_Coding/Definition_and_Properties_of_Reed-Solomon_Codes#Singleton_bound_and_minimum_distance|$\text{Example 5}$]]&nbsp; $($previous section$)$,&nbsp; we consider the&nbsp; $\text{RSC (3, 2, 2)}_4$.&nbsp;
 +
[[File:EN_KC_T_2_3_S3.png|right|frame|Derivation of the distance spectra of&nbsp; $\text{RSC (3, 2, 2)}_4$&nbsp; and &nbsp;$\text{RSC (6, 4, 2)}_2$|class=fit]]
 +
#The upper table shows again the&nbsp; "distance spectrum"&nbsp; $\{ \hspace{0.05cm}W_j\hspace{0.05cm}\}$&nbsp; of the&nbsp; $\text{RSC (3, 2, 2)}_4$.  
 +
#The lower table applies to the equivalent binary Reed&ndash;Solomon code&nbsp; $\text{RSC (6, 4, 2)}_2$.
 +
<br>
 +
<u>Note.</u>
 +
*Both codes have the same code rate &nbsp;$R = k/n =2/3$.
  
[[File:P ID2521 KC T 2 3 S3 v1.png|center|frame|Derivation of the distance spectra of&nbsp; $\text{RSC (3, 2, 2)}_4$&nbsp; and &nbsp;$\text{RSC (6, 4, 2)}_2$|class=fit]]
+
*Both codes have the same  minimum distance &nbsp;$d_{\rm min} = 2$.
  
*Both codes have the same code rate &nbsp;$R = k/n =2/3$&nbsp; and also the same minimum distance &nbsp;$d_{\rm min} = 2$.
+
*But the two codes differ in terms of the distance spectrum&nbsp; $\{ \hspace{0.05cm}W_j\hspace{0.05cm}\}$&nbsp; and the&nbsp; [[Channel_Coding/Bounds_for_Block_Error_Probability#Distance_spectrum_of_a_linear_code|$\text{weight enumerator function}$]]&nbsp; $W(X)$:
*But the two codes differ in terms of the distance spectrum &nbsp;$\{ \hspace{0.05cm}W_j\hspace{0.05cm}\}$&nbsp; and the&nbsp; [[Channel_Coding/Bounds_for_Block_Error_Probability#Distance_spectrum_of_a_linear_code|"weight enumerator function"]]&nbsp; $W(X)$:
 
  
:$$\text{RSC (3, 2, 2)}_4\text{:} \hspace{0.3cm} W_0 =  1\hspace{0.05cm}, \hspace{0.2cm}W_2 =  9\hspace{0.05cm}, \hspace{0.2cm}W_3 =  6\hspace{0.3cm}\Rightarrow\hspace{0.3cm}W(X) = 1 + 9 \cdot X^2 + 6 \cdot X^3\hspace{0.05cm}.$$
+
:$$\text{RSC (3, 2, 2)}_4\text{:} \hspace{0.3cm} W_0 =  1\hspace{0.05cm}, \hspace{0.2cm}W_2 =  9\hspace{0.05cm}, \hspace{0.2cm}W_3 =  6\hspace{0.3cm}$$
 +
:$$\Rightarrow\hspace{0.3cm}W(X) = 1 + 9 \cdot X^2 + 6 \cdot X^3\hspace{0.05cm}.$$
  
 
:$$\text{RSC (6, 4, 2)}_2\text{:} \hspace{0.3cm} W_0 =  1\hspace{0.05cm}, \hspace{0.2cm}W_2 =  3\hspace{0.05cm}, \hspace{0.2cm}W_3 =  8
 
:$$\text{RSC (6, 4, 2)}_2\text{:} \hspace{0.3cm} W_0 =  1\hspace{0.05cm}, \hspace{0.2cm}W_2 =  3\hspace{0.05cm}, \hspace{0.2cm}W_3 =  8
\hspace{0.05cm}, \hspace{0.2cm}W_4 =  3\hspace{0.05cm}, \hspace{0.2cm}W_6 =  1
+
\hspace{0.05cm}, \hspace{0.2cm}W_4 =  3\hspace{0.05cm}, \hspace{0.2cm}W_6 =  1.$$
\hspace{0.3cm}\Rightarrow\hspace{0.3cm}W(X) = 1 + 3 \cdot X^2 + 8 \cdot X^3 + 4 \cdot X^4 + X^6 \hspace{0.05cm}.$$}}
+
:$$\Rightarrow\hspace{0.3cm}W(X) = 1 + 3 \cdot X^2 + 8 \cdot X^3 + 4 \cdot X^4 + X^6 \hspace{0.05cm}.$$}}
  
  
Line 318: Line 356:
 
== Meaning of the Reed-Solomon codes ==
 
== Meaning of the Reed-Solomon codes ==
 
<br>
 
<br>
Anhand des hier oft beispielhaft betrachteten&nbsp; $\text{RSC (3, 2, 2)}_4$&nbsp; konnten wir viele Eigenschaften der Reed&ndash;Solomon&ndash;Codes in überschaubarem Rahmen kennenlernen. Praxisrelevant ist dieser Code allerdings nicht, da wegen&nbsp; $d_{\rm min} = 2$&nbsp; kein einziger Fehler korrigiert und auch nur ein einziger Fehler erkannt werden kann. Schon der nächstgrößere Code&nbsp; $\text{RSC (7, 3, 5)}_8$, der bis zu&nbsp; $t = 2$&nbsp; Fehler korrigieren kann, weist bereits eine Codetabelle mit&nbsp;  $8^3 = 512$&nbsp; Einträgen auf und ist zu Demonstrationszwecken ungeeignet.<br>
+
Using the&nbsp; $\text{RSC (3, 2, 2)}_4$&nbsp; often considered here as an example,&nbsp; we were able to learn many properties of Reed&ndash;Solomon codes in a manageable way.  
 
+
*However,&nbsp; this code is not relevant in practice,&nbsp; since due to&nbsp; $d_{\rm min} = 2$&nbsp; not a single error can be corrected,&nbsp; and not even a single error can be detected.  
In der Praxis werden meist sehr große RS&ndash;Codes eingesetzt, zum Beispiel der&nbsp; $\text{RSC (255, 223, 33)}_{256}$&nbsp; mit folgenden Eigenschaften:
 
*Der Code basiert auf dem Galoisfeld&nbsp; $\rm GF(2^8)$. Jedes Symbol entspricht somit einem Byte. Die Coderate ist mit&nbsp; $R = 0.8745$&nbsp; relativ groß.<br>
 
 
 
*Trotz dieser großen Coderate (also geringe Redundanz) können mit diesem Code bis zu&nbsp; $e = 32$&nbsp; Fehler innerhalb eines Blocks aus&nbsp; $255$&nbsp; Symbolen erkannt und&nbsp; $t = 16$&nbsp; Fehler korrigiert werden.<br>
 
 
 
*Die Codetabelle würde allerdings&nbsp; $2^{8 \hspace{0.05cm}\cdot \hspace{0.05cm} 223}= 2^{ \hspace{0.05cm} 1784} &asymp; 10^{537}$&nbsp; Einträge aufweisen und wird deshalb wahrscheinlich auch von niemanden tatsächlich erstellt.<br><br>
 
 
 
Der große Vorteil der Reed&ndash;Solomon&ndash;Codes (und einer ganzen Reihe davon abgeleiteter weiterer Codes) ist zum einen, dass sie analytisch geschlossen konstruiert werden können, zum anderen ihre große Flexibilität hinsichtlich der Codeparameter. Meist geht man wie folgt vor:
 
*Man gibt die Korrekturfähigkeit in Form des Parameters&nbsp; $t$&nbsp; vor. Daraus ergibt sich die minimale Distanz&nbsp; $d_{\rm min} = 2t + 1$&nbsp; und die Differenz&nbsp; $n-k = 2t$&nbsp; entsprechend der Singleton&ndash;Schranke. Einen besseren Wert gibt es nicht.<br>
 
  
*Ein weiterer Entwurfsparameter ist die Coderate&nbsp; $R=k/n$, wobei die Codewortlänge&nbsp; $n = 2^m -1$&nbsp; nicht völlig frei wählbar ist. Durch Erweiterung, Verkürzung und Punktierung &ndash; siehe&nbsp; [[Aufgaben:Aufgabe_1.09Z:_Erweiterung_und/oder_Punktierung|Aufgabe 1.9Z]]&nbsp; &ndash; kann die Vielzahl an möglichen Codes weiter vergrößert werden.<br>
+
*The next larger code&nbsp; $\text{RSC (7, 3, 5)}_8$,&nbsp; which can correct up to&nbsp; $t = 2$&nbsp; errors,&nbsp; has a code table with&nbsp; $8^3 = 512$&nbsp; entries and is unsuitable for demonstration purposes.<br>
  
*Bei Reed&ndash;Solomon&ndash;Codes ist die Gewichtsverteilung exakt bekannt und es ist eine Anpassung an die Fehlerstruktur des Kanals möglich. Diese Codes sind insbesondere für Bündelfehlerkanäle gut geeignet, die bei mobilen Funksystemen aufgrund von temporären Abschattungen häufig vorliegen.<br>
 
  
*Im Falle statistisch unabhängiger Fehler sind&nbsp; [https://de.wikipedia.org/wiki/BCH-Code BCH&ndash;Codes]&nbsp; (von $\rm B$ose&ndash;$\rm C$haudhuri&ndash;$\rm H$ocquenghem) besser geeignet. Diese sind mit den RS&ndash;Codes eng verwandt, allerdings erfüllen sie nicht immer das Singleton&ndash;Kriterium. Eine ausführliche Beschreibung finden Sie in [Fri96]<ref name='Fri96'>Friedrichs, B.: ''Kanalcodierung – Grundlagen und Anwendungen in modernen Kommunikations- systemen.'' Berlin – Heidelberg: Springer, 1996.</ref>.<br>
+
In practice, very large Reed&ndash;Solomon codes are usually used,&nbsp; for example the&nbsp; $\text{RSC (255, 223, 33)}_{256}$&nbsp; with the following properties:
 +
# The code is based on the Galois field&nbsp; $\rm GF(2^8)$.&nbsp; Each symbol thus corresponds to one byte.&nbsp; The code rate is relatively large with&nbsp; $R = 0.8745$.<br>
 +
# Despite this large code rate&nbsp; (i.e., low redundancy),&nbsp; this code can detect up to&nbsp; $e = 32$&nbsp; errors within a block of&nbsp; $255$&nbsp; symbols and can correct up to &nbsp; $t = 16$&nbsp; errors.<br>
 +
#The code table,&nbsp; however,&nbsp; would have&nbsp; $2^{8 \hspace{0.05cm}\cdot \hspace{0.05cm} 223}= 2^{ \hspace{0.05cm} 1784} &asymp; 10^{537}$&nbsp; entries,&nbsp; and is therefore unlikely to be actually created by anyone.<br><br>
  
*Die Decodierung nach dem&nbsp; [https://en.wikipedia.org/wiki/Lattice_problem BDD&ndash;Prinzip]&nbsp; (<i>Bounded Distance Decoding</i>&nbsp;) kann rechentechnisch sehr einfach erfolgen, zum Beispiel mit dem&nbsp; [https://de.wikipedia.org/wiki/Berlekamp-Massey-Algorithmus Berlekamp&ndash;Massey&ndash;Algorithmus]. Zudem kann der Decoder ohne großen Mehraufwand auch&nbsp; [https://en.wikipedia.org/wiki/Soft-decision_decoder ''Soft Decision Information'']&nbsp; verarbeiten.<br>
+
The great advantage of Reed&ndash;Solomon codes&nbsp; $($and a whole series of further codes derived from them$)$&nbsp; is on the one hand that they can be constructed analytically closed,&nbsp; on the other hand their large flexibility regarding the code parameters.&nbsp; Usually one proceeds as follows:
 +
# One specifies the correction capability in the form of the parameter&nbsp; $t$.&nbsp; From this,&nbsp; the minimum distance&nbsp; $d_{\rm min} = 2t + 1$&nbsp; and the difference&nbsp; $n-k = 2t$&nbsp; corresponding to the Singleton bound.&nbsp; There is no better value.<br>
 +
# Another design parameter is the code rate&nbsp; $R=k/n$,&nbsp; where the code word length&nbsp; $n = 2^m -1$&nbsp; is not completely arbitrary.&nbsp; By extension,&nbsp; shortening and puncturing &ndash; see&nbsp; [[Aufgaben:Exercise_1.09Z:_Extension_and/or_Puncturing|"Exercise 1.9Z"]]&nbsp; &ndash; the variety of possible codes can be further increased.<br>
 +
# For Reed&ndash;Solomon codes,&nbsp; the weight distribution is known exactly and adaptation to the error structure of the channel is possible.&nbsp; These codes are particularly well suited for burst error channels,&nbsp; which are often present in mobile radio systems due to temporary shadowing.<br>
 +
# In the case of statistically independent errors,&nbsp; [https://en.wikipedia.org/wiki/BCH_code $\text{BCH codes}$]&nbsp; $($from the inventors&nbsp; $\rm B$ose&ndash;$\rm C$haudhuri&ndash;$\rm H$ocquenghem$)$&nbsp; are more suitable.&nbsp; These codes are closely related to Reed&ndash;Solomon codes,&nbsp; but they do not always satisfy the Singleton criterion.&nbsp; A detailed description can be found in [Fri96]<ref name='Fri96'>Friedrichs, B.:&nbsp; Kanalcodierung - Grundlagen und Anwendungen in modernen Kommunikations- systemen.&nbsp; Berlin - Heidelberg: Springer, 1996.</ref>.<br>
 +
# Decoding according to the&nbsp; [https://en.wikipedia.org/wiki/Lattice_problem $\text{BDD Principle}$]&nbsp; ("Bounded Distance Decoding")&nbsp; can be done computationally very easily,&nbsp; for example with the&nbsp; [https://en.wikipedia.org/wiki/Berlekamp%E2%80%93Massey_algorithm $\text{Berlekamp&ndash;Massey Algorithm}$].&nbsp; Moreover,&nbsp; the decoder can also process&nbsp; [https://en.wikipedia.org/wiki/Soft-decision_decoder $\text{Soft Decision Information}$]&nbsp; without much additional effort.<br>
  
== Aufgaben zum Kapitel==
+
== Exercises for the chapter==
 
<br>
 
<br>
[[Aufgaben:Aufgabe_2.07:_Reed–Solomon–Code_(7,_3,_5)_zur_Basis_8|Aufgabe 2.7: Reed–Solomon–Code (7, 3, 5) zur Basis 8]]
+
[[Aufgaben:Exercise_2.07:_Reed-Solomon_Code_(7,_3,_5)_to_Base_8|Exercise 2.07: Reed-Solomon Code (7, 3, 5) to Base 8]]
  
[[Aufgaben:Aufgabe_2.07Z:_Reed–Solomon–Code_(15,_5,_11)_zur_Basis_16|Aufgabe 2.7Z: Reed–Solomon–Code (15, 5, 11) zur Basis 16]]
+
[[Aufgaben:Exercise_2.07Z:_Reed-Solomon_Code_(15,_5,_11)_to_Base_16|Exercise 2.07Z: Reed-Solomon Code (15, 5, 11) to Base 16]]
  
[[Aufgaben:Aufgabe_2.08:_Generatorpolynome_für_Reed-Solomon|Aufgabe 2.8: Generatorpolynome für Reed-Solomon]]
+
[[Aufgaben:Exercise_2.08:_Generator_Polynomials_for_Reed-Solomon|Exercise 2.08: Generator Polynomials for Reed-Solomon]]
  
[[Aufgaben:Aufgabe_2.08Z:_„Plus”_und_„Mal”_in_GF(2_hoch_3)|Aufgabe 2.8Z: „Plus” und „Mal” in GF(2 hoch 3)]]
+
[[Aufgaben:Exercise_2.08Z:_Addition_and_Multiplication_in_GF(2_power_3)|Exercise 2.08Z: Addition and Multiplication in GF(2 power 3)]]
  
[[Aufgaben:Aufgabe_2.09:_Reed–Solomon–Parameter|Aufgabe 2.9: Reed–Solomon–Parameter]]
+
[[Aufgaben:Exercise_2.09:_Reed–Solomon_Parameters|Exercise 2.09: Reed–Solomon Parameters]]
  
[[Aufgaben:Aufgabe_2.10:_Fehlererkennung_bei_Reed–Solomon|Aufgabe 2.10: Fehlererkennung bei Reed–Solomon]]
+
[[Aufgaben:Exercise_2.10:_Reed-Solomon_Fault_Detection|Exercise 2.10: Reed-Solomon Fault Detection]]
  
[[Aufgaben:Aufgabe_2.10Z:_Coderate_und_minimale_Distanz|Aufgabe 2.10Z: Coderate und minimale Distanz]]
+
[[Aufgaben:Exercise_2.10Z:_Code_Rate_and_Minimum_Distance|Exercise 2.10Z: Code Rate and Minimum Distance]]
  
==Quellenverzeichnis==
+
==References==
 
<references/>
 
<references/>
  
 
{{Display}}
 
{{Display}}

Latest revision as of 20:46, 23 November 2022

Coding principle and code parameters


A  "Reed–Solomon code"  – hereafter sometimes shortened to  "RS code"   – is a  $\text{linear block code}$ which assigns

  • an information block  $\underline{u}$  with  $k$  symbols
  • to a corresponding code word  $\underline{c}$  with  $n > k$  symbols.


Linear  $(n, \, k)$  block code with new nomenclature

These codes,  still widely used today,  were invented as early as the early 1960s


In the chapter  "Objective of Channel Coding" 

  • the information block was denoted by  $\underline{u}= (u_1,$ ... , $u_k)$  and
  • the code word by  $\underline{x}= (x_1,$ ... , $x_n)$. 


The nomenclature change   $\underline{x} \to \underline{c}$   $($see graphic$)$  was made to eliminate confusion with the argument of polynomials and to simplify the description of Reed–Solomon codes.

All the properties of linear cyclic block codes mentioned in the section  "Linear codes and cyclic codes"  also apply to the Reed–Solomon codes.  In addition:

  • Construction and decoding of Reed–Solomon codes are based on the arithmetic of a Galois field  ${\rm GF}(q)$,  where we restrict ourselves here to binary extension fields with  $q=2^m$  elements;:
\[{\rm GF}(2^m) = \big \{\hspace{0.05cm}0\hspace{0.05cm},\hspace{0.1cm} \alpha^{0} ,\hspace{0.05cm}\hspace{0.1cm} \alpha^{1}\hspace{0.05cm},\hspace{0.1cm} \alpha^{2}\hspace{0.05cm},\hspace{0.1cm}\text{...}\hspace{0.1cm}, \alpha^{q-2}\hspace{0.05cm} \big \}\hspace{0.05cm}. \]
  • Principally different from the first chapter is that the coefficients  $u_0$,  $u_1$, ... ,  $u_{k-1}$  now no longer specify individual bits of information  $(0$  or  $1)$  but they are also elements of  ${\rm GF}(2^m)$.  Each of the  $n$  symbols represents  $m$  bits.
  • For Reed–Solomon codes,  the parameter  $n$  ("code length")  is always equal to the number of elements of the Galois field excluding the zero word:   $n= q-1$.
    We use for this purpose the following nomenclature:
\[{\rm GF}(2^m) \hspace{-0.05cm}\setminus \hspace{-0.05cm} \{0\} = \big \{\hspace{0.05cm} \alpha^{0} ,\hspace{0.05cm}\hspace{0.1cm} \alpha^{1}\hspace{0.05cm},\hspace{0.1cm} \alpha^{2}\hspace{0.05cm},\hspace{0.1cm}...\hspace{0.1cm}, \alpha^{n-1}\hspace{0.05cm} \big \}\hspace{0.05cm}. \]
  • The  $k$  coefficients  $u_i \in {\rm GF}(2^m)$  of the information block  $\underline{u}$,  where for the index  $ 0 \le i < k$  holds,  can also be formally expressed by a polynomial  $u(x)$.  The degree of this polynomial is  $k-1$:
\[u(x) = \sum_{i = 0}^{k-1} u_i \cdot x^{i} = u_0 + u_1 \cdot x + u_2 \cdot x^2 + \hspace{0.1cm}\text{...}\hspace{0.1cm}+ u_{k-1} \cdot x^{k-1} \hspace{0.05cm},\hspace{0.4cm} u_i \in {\rm GF}(2^m) \hspace{0.05cm}.\]
  • The  $n$  symbols of the associated code word  $\underline{c}= (c_0, c_1,$ ... , $c_{n-1})$  result with this polynomial  $u(x)$  to be
\[c_0 = u(\alpha^{0}) \hspace{0.05cm},\hspace{0.3cm} c_1 = u(\alpha^{1})\hspace{0.05cm},\hspace{0.1cm}...\hspace{0.1cm},\hspace{0.3cm} c_{n-1}= u(\alpha^{n-1}) \hspace{0.05cm}.\]
  • Mostly the code symbols  $c_i \in {\rm GF}(2^m)$  are converted back to binary   ⇒   ${\rm GF}(2)$  before transmission,  where each symbol is then represented by  $m$  bits.


We briefly summarize these statements:

$\text{Definition:}$  An   $(n,\ k)\text{ Reed–Solomon code}$  for the Galois field  ${\rm GF}(2^m)$  is defined by

  • the  $n= 2^{m-1}$  elements of  ${\rm GF}(2^m) \hspace{-0.05cm}\setminus \hspace{-0.05cm} \{0\} =\{ \alpha^0, \alpha^1, \, \text{...} \, , \alpha^{n-1}\}$,  where  $\alpha$  denotes a  $\text{primitive element}$  of  ${\rm GF}(2^m)$, 
  • $\text{polynomial}$  of degree  $k-1$  matched to an information block  $\underline{u}$: 
\[u(x) = \sum_{i = 0}^{k-1} u_i \cdot x^{i} = u_0 + u_1 \cdot x + u_2 \cdot x^2 + \hspace{0.1cm}... \hspace{0.1cm}+ u_{k-1} \cdot x^{k-1} \hspace{0.05cm},\hspace{0.4cm} u_i \in {\rm GF}(2^m) \hspace{0.05cm}.\]

⇒   Thus,  the  $(n,\ k)$  Reed–Solomon code can be described as follows:

\[C_{\rm RS} = \Big \{ \underline {c} = \big ( u(\alpha^{0}) \hspace{0.05cm},\hspace{0.1cm} u(\alpha^{1})\hspace{0.05cm},\hspace{0.1cm}...\hspace{0.1cm}, u(\alpha^{n-1})\hspace{0.1cm} \big ) \hspace{0.1cm} \big \vert \hspace{0.2cm} u(x) = \sum_{i = 0}^{k-1} u_i \cdot x^{i}\hspace{0.05cm},\hspace{0.2cm} u_i \in {\rm GF}(2^m) \Big \} \hspace{0.05cm}.\]


The previous information will now be illustrated by two simple examples.

$\text{Example 1:}$  We consider the following code parameters:

$\rm GF(2^2)$  in three different representations:
Exponential, polynomial and coefficient form
\[k = 2 \hspace{0.05cm},\hspace{0.15cm}n = 3 \hspace{0.5cm} \Rightarrow \hspace{0.5cm} \underline {u} = (u_0,\ u_1)\hspace{0.05cm},\hspace{0.15cm} \underline {c} = (c_0,\ c_1,\ c_2)\hspace{0.05cm},\]
\[q = n+1 = 4 \hspace{0.45cm} \Rightarrow \hspace{0.5cm} {\rm GF} (q) = {\rm GF} (2^m) \hspace{0.5cm} \Rightarrow \hspace{0.5cm} m = 2\hspace{0.05cm}.\]

Starting from the conditional equation 

$$p(\alpha) = \alpha^2 + \alpha + 1 = 0 \hspace{0.3cm} ⇒ \hspace{0.3cm} \alpha^2 = \alpha + 1,$$

one obtains the assignments between

  • the exponential representation,
  • the polynomial representation and
  • the coefficient representation


of  ${\rm GF}(2^2)$  according to the above table.  From this it can be seen:

  1. The coefficient vector is expressed by the polynomial   $u(x) = u_0 + u_1 \cdot x$.   The polynomial degree is  $k- 1 = 1$.
  2. For  $u_0 = \alpha^1$  and  $u_1 = \alpha^2$  we obtain e.g. the polynomial   $u(x) = \alpha + \alpha^2 \cdot x$   and thus
\[c_0 = u (x = \alpha^0) = u (x = 1) = \alpha + \alpha^2 \cdot 1 = \alpha + (\alpha + 1) =1 \hspace{0.05cm},\]
\[c_1 =u (x = \alpha^1) = \alpha + \alpha^2 \cdot \alpha = \alpha + \alpha^3 = \alpha + \alpha^0 = \alpha + 1 = \alpha^2 \hspace{0.05cm},\]
\[c_2 =u (x = \alpha^2) = \alpha + \alpha^2 \cdot \alpha^2 = \alpha + \alpha^4 = \alpha + \alpha^1 = 0 \hspace{0.05cm}.\]

⇒   This results in the following assignments on symbol or bit level:

$$\underline {u} =(\alpha^1, \ \alpha^2)\hspace{0.57cm}\leftrightarrow\hspace{0.3cm} \underline {c} = (1, \ \alpha^2, \ 0)\hspace{0.05cm},$$
$$\underline {u}_{\rm bin} =(1,\ 0,\ 1,\ 1)\hspace{0.3cm}\leftrightarrow\hspace{0.3cm} \underline {c}_{\rm bin} = (0,\ 1,\ 1,\ 1,\ 0,\ 0)\hspace{0.05cm}.$$


$\text{Example 2:}$  On the right you see the code table of a special Reed–Solomon code named  $\text{RSC (3, 2, 2)}_4$.

Code table of the  $\text{RSC (3, 2, 2)}_4$
  • The label refers to the parameters  $n=3$,  $k=2$,  $d_{\rm min}=2$  and  $q = 4$.
  • In columns 1 to 3, one can see the relationship  $\underline {u} \ → \ u(x) \ → \ \underline {c}$.
  • In the last two columns, the coding rule  $\underline {u}_{\rm bin} \ ↔ \ \underline {c}_{\rm bin}$ is given.


⇒   For clarification the entry for  $(\alpha^0, \ \alpha^2)$:

\[u(x) = u_0 + u_1 \cdot x = \alpha^0 + \alpha^2 \cdot x. \]

This results in the following code symbols  (see red mark):

\[c_0 = u (x = \alpha^0) = 1 + \alpha^2 \cdot 1 = 1 + (1+\alpha ) =\alpha \hspace{0.05cm},\]
\[c_1 = u (x = \alpha^1) = 1 + \alpha^2 \cdot \alpha = 1 + (1+\alpha ) \cdot \alpha = 1 + \alpha + \alpha^2 = 0 \hspace{0.05cm},\]
\[c_2 =u (x = \alpha^2) = 1 + \alpha^2 \cdot \alpha^2 = 1 + \alpha = \alpha^2 \hspace{0.05cm}.\]

Notes:

  • From the element set  $\{0, \ \alpha^0 = 1, \ \alpha^1 = \alpha, \ \alpha^2\}$  it should not be concluded that for this code the three-dimensional representation with axes   $\alpha^0 = 1$,   $\alpha^1 = \alpha$,   $\alpha^2$   applies.  See section   "Primitive Polynomials" – Example 5.
  • On the contrary,  from the coefficient representation in  $\text{Example 1}$  it is clear that   ${\rm GF} (2^2)$  is two-dimensional,  where the axes of the two dimensional representation are to be labeled  $\alpha^0 = 1$  and  $\alpha^1 = \alpha$.


Generator matrix of Reed-Solomon codes


Since the Reed–Solomon code is a linear block code,  the relationship between the information word  $\underline {u}$  and the code word  $\underline {c}$  is given by the  $\text{generator matrix}$  $\boldsymbol{\rm G}$:

\[\underline {c} = \underline {u} \cdot { \boldsymbol{\rm G}} \hspace{0.05cm}.\]

As with any linear  $(n,\ k)$  block code,  the generator matrix consists of 

  • $k$  rows and 
  • $n$  columns.


In contrast to the chapter  "General Description of Linear Block Codes" 

  • now the elements of the generator matrix are no longer binary  $(0$  or  $1)$,
  • but come from the Galois field  ${\rm GF}(2^m) \hspace{-0.05cm}\setminus \hspace{-0.05cm} \{0\} $.


$\text{Example 3:}$  We consider as in  $\text{Example 2}$  (see previous section)  the  $\text{RSC (3, 2, 2)}_4$  whose generator matrix has the following form:

\[ { \boldsymbol{\rm G} } = \begin{pmatrix} g_{00} & g_{01} & g_{02}\\ g_{10} & g_{11} & g_{12} \end{pmatrix}\hspace{0.05cm},\hspace{0.3cm} g_{ij} \in {\rm GF}(2^2) \hspace{-0.01cm}\setminus \hspace{-0.01cm} \{0\} = \big \{\hspace{0.05cm} \alpha^{0} \hspace{0.05cm},\hspace{0.1cm} \alpha^{1}\hspace{0.05cm},\hspace{0.1cm} \alpha^{2} \hspace{0.05cm}\big \}\hspace{0.05cm}. \]

Beside this:

  • The first row of  $\boldsymbol{\rm G}$  gives the code word for the information word  $\underline {u}_1 = (1,\ 0)$  respectively for the polynomial function  $u_1(x) = 1$.  Thus one receives the matrix elements of the first row
$$g_{00} = u_{1}(\alpha^{0}) = 1\hspace{0.05cm},$$
$$g_{01} = u_{1}(\alpha^{1}) = 1\hspace{0.05cm},$$
$$g_{02} = u_{1}(\alpha^{2}) = 1\hspace{0.05cm}.$$
  • The second row is equal to the code word for the information word $\underline {u}_2 = (0,\ 1)$   ⇒   $u_2(x) = x$.  Thus,  the matrix elements of the second row are:
$$g_{10} = u_{2}(\alpha^{0}) = \alpha^{0} = 1\hspace{0.05cm},$$
$$g_{11} = u_{2}(\alpha^{1}) = \alpha \hspace{0.05cm},$$
$$g_{12} = u_{2}(\alpha^{2}) = \alpha^{2}\hspace{0.05cm}.$$
  • So the complete generator matrix is:
$$ { \boldsymbol{\rm G} } = \begin{pmatrix} 1 & 1 & 1\\ 1 & \alpha & \alpha^2 \end{pmatrix}\hspace{0.05cm}.$$
Code table of the  $\text{RSC (3, 2, 2)}_4$  at symbol level
  • For the information word  $\underline {u}= (u_0, \ u_1)$  with symbols 
$$u_0, \ u_1 ∈ \{0, \ \alpha^0 = 1, \ \alpha^1 = \alpha, \ \alpha^2\}$$
one obtains,  considering the two equations   $\alpha^2 = \alpha + 1$   and   $\alpha^3 = \alpha^0 = 1$   again the code table of the  $\text{RSC (3, 2, 2)}_4$  at symbol level.
  1. Of course,  with the same generator matrix you get exactly the same code table  $\underline {u}   ↔   \underline {c}$  as after the calculation via the function  $u(x)$.
  2. The corresponding code table on bit level  $($see  $\text{Example 2}$  in the previous section$)$  results again,  if the elements are not given in exponent representation,  but in coefficient form:
\[(0, \hspace{0.1cm}\alpha^{0}, \hspace{0.1cm}\alpha^{1}, \hspace{0.1cm}\alpha^{2}) \hspace{0.3cm}\Leftrightarrow\hspace{0.3cm}(00, \hspace{0.1cm}01, \hspace{0.1cm}10, \hspace{0.1cm}11) \hspace{0.05cm}. \]


Generator matrix and parity-check matrix


We now generalize the result of the last section for a Reed–Solomon code with

  • dimension  $k$  $($number of symbols per information block$)$,
  • code word length  $n$  $($number of symbols per code word$)$.


⇒   The  $\text{generator matrix}$  $\boldsymbol{\rm G}$  $(k$ rows,  $n$ columns$)$  and the  $\text{parity-check matrix}$  $\boldsymbol{\rm H}$  $(n-k$ rows,  $n$  columns$)$  must jointly satisfy the following equation:

$${\boldsymbol{\rm G} } \cdot { \boldsymbol{\rm H } }^{\rm T}= { \boldsymbol{\rm 0} }\hspace{0.05cm}.$$

Here,  "$\boldsymbol{\rm 0}$"  denotes a zero matrix  $($all elements equal  $0)$   with  $k$  rows and  $n-k$  columns.


$\text{Example 4:}$  We consider the   $\text{RSC (7, 3, 5)}_8$:

  • code parameters  $n= 7$,  $k= 3$,
  • based on the Galois field  $\rm GF(2^3 = 8)$ 
  • with the constraint  $\alpha^3 =\alpha + 1$.


Note with respect to the code name:

  1. The third parameter of the nomenclature commonly used for block codes names the free distance  $d_{\rm min}= 5$.
  2. Unlike the binary codes discussed in the chapter  "Examples of binary block codes"  $($single parity-check code, repetition code, Hamming code$)$,  the Reed–Solomon codes still have the hint  $q$  added to the Galois field  $($here:   $q = 8)$.

All elements of the generator matrix and the parity-check matrix,

\[{ \boldsymbol{\rm G} } = \begin{pmatrix} 1 & 1 & 1 & 1 & 1 & 1 & 1\\ 1 & \alpha^1 & \alpha^2 & \alpha^3 & \alpha^4 & \alpha^5 & \alpha^6\\ 1 & \alpha^2 & \alpha^4 & \alpha^6 & \alpha^1 & \alpha^{3} & \alpha^{5} \end{pmatrix}\hspace{0.05cm},\hspace{0.4cm} { \boldsymbol{\rm H} } = \begin{pmatrix} 1 & \alpha^1 & \alpha^2 & \alpha^3 & \alpha^4 & \alpha^5 & \alpha^6\\ 1 & \alpha^2 & \alpha^4 & \alpha^6 & \alpha^1 & \alpha^{3} & \alpha^{5}\\ 1 & \alpha^3 & \alpha^6 & \alpha^2 & \alpha^{5} & \alpha^{1} & \alpha^{4}\\ 1 & \alpha^4 & \alpha^1 & \alpha^{5} & \alpha^{2} & \alpha^{6} & \alpha^{3} \end{pmatrix}\hspace{0.05cm}, \]

originate from the Galois field  ${\rm GF}(2^3) \hspace{-0.01cm}\setminus \hspace{-0.01cm} \{0\} = \big \{\hspace{0.05cm} \alpha^{0} \hspace{0.05cm},\hspace{0.1cm}\alpha^{1}\hspace{0.05cm},\hspace{0.1cm} \alpha^{2} \hspace{0.05cm},\hspace{0.1cm} \alpha^{3} \hspace{0.05cm},\hspace{0.1cm}\alpha^{4}\hspace{0.05cm},\hspace{0.1cm} \alpha^{5} \hspace{0.05cm},\hspace{0.1cm} \alpha^{6} \hspace{0.05cm}\big \}$. For the matrix product holds:

\[{ \boldsymbol{\rm G} } \cdot { \boldsymbol{\rm H } }^{\rm T}= \begin{pmatrix} 1 & 1 & 1 & 1 & 1 & 1 & 1\\ 1 & \alpha^1 & \alpha^2 & \alpha^3 & \alpha^4 & \alpha^5 & \alpha^6\\ 1 & \alpha^2 & \alpha^4 & \alpha^6 & \alpha^1 & \alpha^{3} & \alpha^{5} \end{pmatrix} \begin{pmatrix} 1 & 1 & 1 & 1 \\ \alpha^1 & \alpha^2 & \alpha^3 & \alpha^4\\ \alpha^2 & \alpha^4 & \alpha^6 & \alpha^1\\ \alpha^3 & \alpha^6 & \alpha^2 & \alpha^{5}\\ \alpha^4 & \alpha^1 & \alpha^{5} & \alpha^{2}\\ \alpha^5 & \alpha^{3} & \alpha^{1} & \alpha^{6}\\ \alpha^6 & \alpha^{5} & \alpha^{4} & \alpha^{3} \end{pmatrix} = \begin{pmatrix} 0 & 0 & 0 & 0 \\ 0 & 0 & 0 & 0 \\ 0 & 0 & 0 & 0 \end{pmatrix} \hspace{0.05cm}.\]

This will be demonstrated here for two elements only:

  • First row,  first column:
\[1 \hspace{0.1cm} \cdot \hspace{0.1cm} \big [1 + \alpha^1 + \alpha^2 + \alpha^3 + \alpha^4 + \alpha^5 + \alpha^6 \big ] = 1 + \alpha + \alpha^2 + (\alpha + 1) + (\alpha^2 + \alpha)+ (\alpha^2 + \alpha +1)+ (\alpha^2 + 1) = 0 \hspace{0.05cm}; \]
  • Last row,  last column:
\[1 \hspace{0.1cm} \cdot \hspace{0.1cm} 1 + \alpha^2 \cdot \alpha^4 + \alpha^4 \cdot \alpha^1 + \alpha^6 \cdot \alpha^5+ \alpha^1 \cdot \alpha^2+ \alpha^3 \cdot \alpha^6+ \alpha^5 \cdot \alpha^3= 1 + \alpha^6 + \alpha^5 + \alpha^{11} + \alpha^{3}+ \alpha^{9}+ \alpha^{8} =\]
\[ \hspace{1.5cm} = \hspace{0.15cm} 1 + \alpha^6 + \alpha^5 + \alpha^{4} + \alpha^{3}+ \alpha^{2}+ \alpha^{1} =0 \hspace{0.05cm}.\]


Singleton bound and minimum distance


An important parameter of any block code is the  $\text{minimum distance}$  between any two code words  $\underline {c}_i$  and  $\underline {c}_j$.

  • The Reed–Solomon–codes belong to the class of  »linear  and  cyclic codes«.  For these,  one can start from the zero word  $\underline {c}_0 = (0, 0, \hspace{0.05cm} \text{...} \hspace{0.05cm}, 0)$  as the reference.
  • From the number of zeros in the other code words  $\underline {c}_j ≠ \underline {c}_0$  the  $\text{distance spectrum}$  $\{ \hspace{0.05cm}W_j\hspace{0.05cm}\}$  can be specified.


$\text{Example 5:}$  The table illustrates the determination of the distance spectrum for the  $\text{RSC (3, 2, 2)}_4$.

  • Compared to the previous graphs,  the symbol set is simplified by   $\{0,\ 1,\ 2,\ 3\}$   instead of   $\{0,\ \alpha^0,\ \alpha^1,\ \alpha^2\}$.
  • The distance  $d$  between  $\underline {c}_j$  and the null word  $\underline {c}_0$  is identical to the  $\text{Hamming weight}$  $w_{\rm H}(\underline {c}_j)$.
To derive the distance spectrum for the  $\text{RSC (3, 2, 2)}_4$


⇒   From the upper table can be read among others:

  1. Nine code words differ from the zero word in two symbols and six code words in three symbols:   $W_2 = 9$,  $W_3 = 6$.
  2. There is not a single code word with only one zero.  That means:   The minimum distance here is  $d_{\rm min} = 2$.


⇒   From the table below one can see that also for the binary representation holds  $d_{\rm min} = 2$.


This empirical result will now be generalized:

$\text{Without proof:}$ 

  1. The  "minimum distance"  of each  $(n,\ k)$  Reed–Solomon code is  $d_{\rm min} =n-k+1$   ⇒   symbol errors can be detected   ⇒   $e = d_{\rm min} -1 =n-k$ .
  2. For  "error correcting codes"  one usually chooses  $d_{\rm min} $  odd   ⇒   $n-k$  even. 
  3. For Reed–Solomon codes then up to   $t =(n-k)/2$   symbol errors can be corrected.
  4. The  $\text{Singleton bound}$  says that  $d_{\rm min} \le n-k+1$  holds for all linear codes.
  5. Reed–Solomon codes reach this bound with equality;  they are so-called  $\text{maximum distance separable codes}$  (short: "MDS codes").
  6. The  $\text{distance spectrum}$  is composed of  $W_0 = 1$  and other weight factors  $W_i$  with  $d ≤ i ≤ n$,  where in the following equation  $d_{\rm min}$  is abbreviated as  $d$:
\[W_i = {n \choose i} \cdot \sum_{j = 0}^{i-d}\hspace{0.15cm}(-1)^j \cdot {i \choose j} \cdot \bigg [\hspace{0.03cm}q^{i\hspace{0.03cm}-\hspace{0.03cm}j\hspace{0.03cm}-\hspace{0.03cm}d\hspace{0.03cm}+\hspace{0.03cm}1}-1 \hspace{0.03cm} \bigg ]\hspace{0.05cm}.\]

Code name and code rate


The usual designation for the Reed–Solomon codes is  ${\rm RSC} \ \ (n,\ k, \ d_{\rm min})_q$  with

  • the length  $n$  of the code $($symbol number of a code word$)$,
  • the dimension  $k$  of the code  $($symbol number of an information word$)$,
  • the minimum distance  $d_{\rm min} = n-k+1$,  which is maximum corresponding to the  "Singleton bound",  and
  • the size  $q = 2^m$  of the Galois field  ${\rm GF}(q)$.

⇒   All elements  $u_i$  of the information word   $\underline{u}= (u_0, \hspace{0.05cm}\text{...} \hspace{0.05cm}, u_i, \hspace{0.05cm}\text{...} \hspace{0.05cm}, u_{k-1})$   and all elements  $c_i$  of the code word $\underline{c}= (c_0, \hspace{0.05cm}\text{...} \hspace{0.05cm}, c_i, \hspace{0.05cm}\text{...} \hspace{0.05cm}, c_{n-1})$  are non-binary symbols and come from the Galois field  ${\rm GF}(q)$.

⇒   For the realization these symbols are also represented in binary and one arrives at the  "equivalent binary Reed–Solomon code"  ${\rm RSC} \ \ (n_{\rm bin},\ k_{\rm bin}, \ d_{\rm min})_2$  with

  • $n_{\rm bin} = n \cdot m$   bits of a code word,
  • $k_{\rm bin} = k \cdot m$   bit of an information word.

⇒   The code rate is not changed by this action:

\[R_{\rm bin} = \frac{k_{\rm bin}}{n_{\rm bin}} = \frac{k \cdot m}{n \cdot m} = \frac{k}{n} = R \hspace{0.05cm}.\]

⇒   Similarly,  the transition from  ${\rm GF}(q)$  to  ${\rm GF}(2)$  does not change the minimum distance  $d_{\rm min}$.

$\text{Example 6:}$  As in  $\text{Example 5}$  $($previous section$)$,  we consider the  $\text{RSC (3, 2, 2)}_4$. 

Derivation of the distance spectra of  $\text{RSC (3, 2, 2)}_4$  and  $\text{RSC (6, 4, 2)}_2$
  1. The upper table shows again the  "distance spectrum"  $\{ \hspace{0.05cm}W_j\hspace{0.05cm}\}$  of the  $\text{RSC (3, 2, 2)}_4$.
  2. The lower table applies to the equivalent binary Reed–Solomon code  $\text{RSC (6, 4, 2)}_2$.


Note.

  • Both codes have the same code rate  $R = k/n =2/3$.
  • Both codes have the same minimum distance  $d_{\rm min} = 2$.
$$\text{RSC (3, 2, 2)}_4\text{:} \hspace{0.3cm} W_0 = 1\hspace{0.05cm}, \hspace{0.2cm}W_2 = 9\hspace{0.05cm}, \hspace{0.2cm}W_3 = 6\hspace{0.3cm}$$
$$\Rightarrow\hspace{0.3cm}W(X) = 1 + 9 \cdot X^2 + 6 \cdot X^3\hspace{0.05cm}.$$
$$\text{RSC (6, 4, 2)}_2\text{:} \hspace{0.3cm} W_0 = 1\hspace{0.05cm}, \hspace{0.2cm}W_2 = 3\hspace{0.05cm}, \hspace{0.2cm}W_3 = 8 \hspace{0.05cm}, \hspace{0.2cm}W_4 = 3\hspace{0.05cm}, \hspace{0.2cm}W_6 = 1.$$
$$\Rightarrow\hspace{0.3cm}W(X) = 1 + 3 \cdot X^2 + 8 \cdot X^3 + 4 \cdot X^4 + X^6 \hspace{0.05cm}.$$


Meaning of the Reed-Solomon codes


Using the  $\text{RSC (3, 2, 2)}_4$  often considered here as an example,  we were able to learn many properties of Reed–Solomon codes in a manageable way.

  • However,  this code is not relevant in practice,  since due to  $d_{\rm min} = 2$  not a single error can be corrected,  and not even a single error can be detected.
  • The next larger code  $\text{RSC (7, 3, 5)}_8$,  which can correct up to  $t = 2$  errors,  has a code table with  $8^3 = 512$  entries and is unsuitable for demonstration purposes.


In practice, very large Reed–Solomon codes are usually used,  for example the  $\text{RSC (255, 223, 33)}_{256}$  with the following properties:

  1. The code is based on the Galois field  $\rm GF(2^8)$.  Each symbol thus corresponds to one byte.  The code rate is relatively large with  $R = 0.8745$.
  2. Despite this large code rate  (i.e., low redundancy),  this code can detect up to  $e = 32$  errors within a block of  $255$  symbols and can correct up to   $t = 16$  errors.
  3. The code table,  however,  would have  $2^{8 \hspace{0.05cm}\cdot \hspace{0.05cm} 223}= 2^{ \hspace{0.05cm} 1784} ≈ 10^{537}$  entries,  and is therefore unlikely to be actually created by anyone.

The great advantage of Reed–Solomon codes  $($and a whole series of further codes derived from them$)$  is on the one hand that they can be constructed analytically closed,  on the other hand their large flexibility regarding the code parameters.  Usually one proceeds as follows:

  1. One specifies the correction capability in the form of the parameter  $t$.  From this,  the minimum distance  $d_{\rm min} = 2t + 1$  and the difference  $n-k = 2t$  corresponding to the Singleton bound.  There is no better value.
  2. Another design parameter is the code rate  $R=k/n$,  where the code word length  $n = 2^m -1$  is not completely arbitrary.  By extension,  shortening and puncturing – see  "Exercise 1.9Z"  – the variety of possible codes can be further increased.
  3. For Reed–Solomon codes,  the weight distribution is known exactly and adaptation to the error structure of the channel is possible.  These codes are particularly well suited for burst error channels,  which are often present in mobile radio systems due to temporary shadowing.
  4. In the case of statistically independent errors,  $\text{BCH codes}$  $($from the inventors  $\rm B$ose–$\rm C$haudhuri–$\rm H$ocquenghem$)$  are more suitable.  These codes are closely related to Reed–Solomon codes,  but they do not always satisfy the Singleton criterion.  A detailed description can be found in [Fri96][1].
  5. Decoding according to the  $\text{BDD Principle}$  ("Bounded Distance Decoding")  can be done computationally very easily,  for example with the  $\text{Berlekamp–Massey Algorithm}$.  Moreover,  the decoder can also process  $\text{Soft Decision Information}$  without much additional effort.

Exercises for the chapter


Exercise 2.07: Reed-Solomon Code (7, 3, 5) to Base 8

Exercise 2.07Z: Reed-Solomon Code (15, 5, 11) to Base 16

Exercise 2.08: Generator Polynomials for Reed-Solomon

Exercise 2.08Z: Addition and Multiplication in GF(2 power 3)

Exercise 2.09: Reed–Solomon Parameters

Exercise 2.10: Reed-Solomon Fault Detection

Exercise 2.10Z: Code Rate and Minimum Distance

References

  1. Friedrichs, B.:  Kanalcodierung - Grundlagen und Anwendungen in modernen Kommunikations- systemen.  Berlin - Heidelberg: Springer, 1996.