Dual code

In coding theory, the dual code of a linear code

C\subset\mathbb{F}_q^n

is the linear code defined by

C^\perp = \{x \in \mathbb{F}_q^n \mid \langle x,c\rangle = 0\;\forall c \in C \}

where

\langle x, c \rangle = \sum_{i=1}^n x_i c_i

is a scalar product. In linear algebra terms, the dual code is the annihilator of C with respect to the bilinear form <,>. The dimension of C and its dual always add up to the length n:

\dim C + \dim C^\perp = n.

A generator matrix for the dual code is a parity-check matrix for the original code and vice versa. The dual of the dual code is always the original code.

Self-dual codes

A self-dual code is one which is its own dual. This implies that n is even and dim C = n/2. If a self-dual code is such that each codeword's weight is a multiple of some constant $c > 1$ , then it is of one of the following four types:^[1]

Type I codes are binary self-dual codes which are not doubly even. Type I codes are always even (every codeword has even Hamming weight).
Type II codes are binary self-dual codes which are doubly even.
Type III codes are ternary self-dual codes. Every codeword in a Type III code has Hamming weight divisible by 3.
Type IV codes are self-dual codes over F₄. These are again even.

Codes of types I, II, III, or IV exist only if the length n is a multiple of 2, 8, 4, or 2 respectively.

References

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External links

MATH32031: Coding Theory - Dual Code - pdf with some examples and explanations

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[1]

Dual code

Self-dual codes

References

External links

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