Hamming space

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The Hamming space of binary strings of length 3. The distance between vertices in the cube graph equals the Hamming distance between the strings.

In statistics and coding theory, a Hamming space (named after American mathematician Richard Hamming) is usually the set of all [math]\displaystyle{ 2^N }[/math] binary strings of length N.[1][2] It is used in the theory of coding signals and transmission.

More generally, a Hamming space can be defined over any alphabet (set) Q as the set of words of a fixed length N with letters from Q.[3][4] If Q is a finite field, then a Hamming space over Q is an N-dimensional vector space over Q. In the typical, binary case, the field is thus GF(2) (also denoted by Z2).[3]

In coding theory, if Q has q elements, then any subset C (usually assumed of cardinality at least two) of the N-dimensional Hamming space over Q is called a q-ary code of length N; the elements of C are called codewords.[3][4] In the case where C is a linear subspace of its Hamming space, it is called a linear code.[3] A typical example of linear code is the Hamming code. Codes defined via a Hamming space necessarily have the same length for every codeword, so they are called block codes when it is necessary to distinguish them from variable-length codes that are defined by unique factorization on a monoid.

The Hamming distance endows a Hamming space with a metric, which is essential in defining basic notions of coding theory such as error detecting and error correcting codes.[3]

Hamming spaces over non-field alphabets have also been considered, especially over finite rings (most notably over Z4) giving rise to modules instead of vector spaces and ring-linear codes (identified with submodules) instead of linear codes. The typical metric used in this case the Lee distance. There exist a Gray isometry between [math]\displaystyle{ \mathbb{Z}_2^{2m} }[/math] (i.e. GF(22m)) with the Hamming distance and [math]\displaystyle{ \mathbb{Z}_4^m }[/math] (also denoted as GR(4,m)) with the Lee distance.[5][6][7]

References

  1. Baylis, D. J. (1997), Error Correcting Codes: A Mathematical Introduction, Chapman Hall/CRC Mathematics Series, 15, CRC Press, p. 62, ISBN 9780412786907, https://books.google.com/books?id=ZAdDuZoJdn8C&pg=PA62 
  2. Cohen, G.; Honkala, I.; Litsyn, S.; Lobstein, A. (1997), Covering Codes, North-Holland Mathematical Library, 54, Elsevier, p. 1, ISBN 9780080530079, https://books.google.com/books?id=7KBYOt44sugC&pg=PA1 
  3. 3.0 3.1 3.2 3.3 3.4 Derek J.S. Robinson (2003). An Introduction to Abstract Algebra. Walter de Gruyter. pp. 254–255. ISBN 978-3-11-019816-4. 
  4. 4.0 4.1 Cohen et al., Covering Codes, p. 15
  5. Marcus Greferath (2009). "An Introduction to Ring-Linear Coding Theory". Gröbner Bases, Coding, and Cryptography. Springer Science & Business Media. ISBN 978-3-540-93806-4. 
  6. "Kerdock and Preparata codes - Encyclopedia of Mathematics". http://www.encyclopediaofmath.org/index.php/Kerdock_and_Preparata_codes. 
  7. J.H. van Lint (1999). Introduction to Coding Theory (3rd ed.). Springer. Chapter 8: Codes over [math]\displaystyle{ \mathbb{Z}_4 }[/math]. ISBN 978-3-540-64133-9. https://archive.org/details/introductiontoco0000lint_a3b9. 




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