Lee distance

In coding theory, the Lee distance is a distance between two strings $x_{1}x_{2}\dots x_{n}$ and $y_{1}y_{2}\dots y_{n}$ of equal length n over the q-ary alphabet ${0, 1, \dots, q - 1$ } of size $q \geq 2$ . It is a metric defined as

\sum _{i=1}^{n}\min(|x_{i}-y_{i}|,\,q-|x_{i}-y_{i}|).

If $q = 2$ or $q = 3$ the Lee distance coincides with the Hamming distance, because both distances are 0 for two single equal symbols and 1 for two single non-equal symbols. For $q > 3$ this is not the case anymore; the Lee distance between single letters can become bigger than 1. However, there exists a Gray isometry (weight-preserving bijection) between $\mathbb {Z} _{4}$ with the Lee weight and $\mathbb {Z} _{2}^{2}$ with the Hamming weight.

Considering the alphabet as the additive group Z_q, the Lee distance between two single letters $x$ and $y$ is the length of shortest path in the Cayley graph (which is circular since the group is cyclic) between them. More generally, the Lee distance between two strings of length $n$ is the length of the shortest path between them in the Cayley graph of $\mathbf {Z} _{q}^{n}$ . This can also be thought of as the quotient metric resulting from reducing $Z n$ with the Manhattan distance modulo the lattice $q Z n$ . The analogous quotient metric on a quotient of $Z n$ modulo an arbitrary lattice is known as a Mannheim metric or Mannheim distance.

The metric space induced by the Lee distance is a discrete analog of the elliptic space.

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