Difference between revisions of "Aufgaben:Exercise 2.10Z: Code Rate and Minimum Distance"
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[[File:P_ID2526__KC_Z_2_10.png|right|frame|The inventors of the Reed-Solomon codes]] | [[File:P_ID2526__KC_Z_2_10.png|right|frame|The inventors of the Reed-Solomon codes]] | ||
| − | The codes developed by [https://en.wikipedia.org/wiki/Irving_S._Reed | + | The codes developed by [https://en.wikipedia.org/wiki/Irving_S._Reed Irving Stoy Reed] and [https://en.wikipedia.org/wiki/Gustave_Solomon Gustave Solomon] in the early 1960s are referred to in this tutorial as follows: |
:$${\rm RSC} \, (n, \, k, \, d_{\rm min}) _q.$$ | :$${\rm RSC} \, (n, \, k, \, d_{\rm min}) _q.$$ | ||
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* $q = 2^m$ is an indication of the "size" of the Galois field ⇒ ${\rm GF}(q)$, | * $q = 2^m$ is an indication of the "size" of the Galois field ⇒ ${\rm GF}(q)$, | ||
| − | * $n = q - 1$ is the "code length" (symbol number of a code word), | + | * $n = q - 1$ is the "code length" $($symbol number of a code word$)$, |
| − | * $k$ indicates the "dimension" (symbol number of an information block), | + | * $k$ indicates the "dimension" $($symbol number of an information block$)$, |
* $d_{\rm min}$ denotes the "minimum distance" between two codewords. | * $d_{\rm min}$ denotes the "minimum distance" between two codewords. | ||
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Hints: | Hints: | ||
* The exercise belongs to the chapter [[Channel_Coding/Definition_and_Properties_of_Reed-Solomon_Codes| "Definition and properties of Reed–Solomon Codes"]]. | * The exercise belongs to the chapter [[Channel_Coding/Definition_and_Properties_of_Reed-Solomon_Codes| "Definition and properties of Reed–Solomon Codes"]]. | ||
| + | |||
* Information relevant to this exercise can be found on the [[Channel_Coding/Definition_and_Properties_of_Reed-Solomon_Codes#Code_name_and_code_rate|"Code name and code rate"]] page. | * Information relevant to this exercise can be found on the [[Channel_Coding/Definition_and_Properties_of_Reed-Solomon_Codes#Code_name_and_code_rate|"Code name and code rate"]] page. | ||
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===Questions=== | ===Questions=== | ||
<quiz display=simple> | <quiz display=simple> | ||
| − | {Specify the characteristics of the ${\rm RSC} \, (255, \, 223, \, d_{\rm min})_q$ . | + | {Specify the characteristics of the ${\rm RSC} \, (255, \, 223, \, d_{\rm min})_q$ . |
|type="{}"} | |type="{}"} | ||
$q \hspace{0.2cm} = \ ${ 256 } | $q \hspace{0.2cm} = \ ${ 256 } | ||
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$d_{\rm min} \ = \ ${ 33 } | $d_{\rm min} \ = \ ${ 33 } | ||
| − | {Specify the characteristics of the $\rm RSC \, (2040, \, 1784, \, d_{\rm min})_2$ . | + | {Specify the characteristics of the $\rm RSC \, (2040, \, 1784, \, d_{\rm min})_2$ . |
|type="{}"} | |type="{}"} | ||
$R \hspace{0.2cm} = \ ${ 0.8745 3% } | $R \hspace{0.2cm} = \ ${ 0.8745 3% } | ||
$d_{\rm min} \ = \ ${ 33 } | $d_{\rm min} \ = \ ${ 33 } | ||
| − | {How many bit errors $(N_3)$ may a received word $\underline{y}$ have at most, so that it is <u>certainly decoded correctly</u>? | + | {How many bit errors $(N_3)$ may a received word $\underline{y}$ have at most, so that it is <u>certainly decoded correctly</u>? |
|type="{}"} | |type="{}"} | ||
$N_{3} \ = \ $ { 16 } | $N_{3} \ = \ $ { 16 } | ||
| − | {How many bit errors $(N_4)$ may a received word $\underline{y}$ have in the best case so that it could still be <u>correctly decoded</u>? | + | {How many bit errors $(N_4)$ may a received word $\underline{y}$ have <u>in the best case</u> so that it could still be <u>correctly decoded</u>? |
|type="{}"} | |type="{}"} | ||
$N_{4} \ = \ $ { 128 } | $N_{4} \ = \ $ { 128 } | ||
Revision as of 11:02, 12 October 2022
The inventors of the Reed-Solomon codes
The codes developed by Irving Stoy Reed and Gustave Solomon in the early 1960s are referred to in this tutorial as follows:
- $${\rm RSC} \, (n, \, k, \, d_{\rm min}) _q.$$
The code parameters have the following meanings:
- $q = 2^m$ is an indication of the "size" of the Galois field ⇒ ${\rm GF}(q)$,
- $n = q - 1$ is the "code length" $($symbol number of a code word$)$,
- $k$ indicates the "dimension" $($symbol number of an information block$)$,
- $d_{\rm min}$ denotes the "minimum distance" between two codewords.
- For any Reed-Solomon code:
- $$d_{\rm min} = n - k + 1.$$
No other code with the same $k$ and $n$ yields a larger value.
Hints:
- The exercise belongs to the chapter "Definition and properties of Reed–Solomon Codes".
- Information relevant to this exercise can be found on the "Code name and code rate" page.
Questions
Solution
(1) From the code length $n = 255$ follows $q \ \underline{= 256}$.
- The code rate is given by $R = {223}/{255} \hspace{0.15cm}\underline {=0.8745}\hspace{0.05cm}.$
- The minimum distance is $d_{\rm min} = n - k +1 = 255 - 223 +1 \hspace{0.15cm}\underline {=33}\hspace{0.05cm}.$
- This allows
- $e = d_{\rm min} - 1 \ \underline{= 32}$ symbol errors can be detected, and.
- $t = e/2$ (rounded down), so $\underline{t = 16}$ symbol errors can be corrected.
(2) The code $\rm RSC \, (2040, \, 1784, \, d_{\rm min})_2$ is the binary representation of the ${\rm RSC} discussed in (1) \, (255, \, 223, \, 33)_{256}$ with exactly the same code rate $R \ \underline{= 0.8745}$ and also the same minimum distance $d_{\rm min} \ \underline{= 33}$ as this one. Here $8$ bits (1 byte) are used per code symbol.
(3) From $d_{\rm min} = 33$ follows again $t = 16 \ \Rightarrow \ N_{3} \ \underline{= 16}$.
- If exactly one bit is corrupted in each code symbol, this also means 16 symbol errors.
- This is the maximum value that the Reed–Solomon decoder can still handle.
(4) The RS decoder can correct 16 corrupted code symbols,
- whereby it does not matter whether in a code symbol only one bit or all $m = 8$ bits have been corrupted.
- Therefore, with the most favorable error distribution, up to $N_4 = 8 \cdot 16 \ \underline{= 128}$ bits can be corrupted without the code word being incorrectly decoded.
