Author_Institution :
AT&T Shannon Lab., Florham Park, NJ, USA
Abstract :
In a previous paper, Shor and Laflamme (see Phys. Rev. Lett., vol.78, p.1600-02, 1997) define two “weight enumerators” for quantum error-correcting codes, connected by a MacWilliams (1977) transform, and use them to give a linear-programming bound for quantum codes. We extend their work by introducing another enumerator, based on the classical theory of shadow codes, that tightens their bounds significantly. In particular, nearly all of the codes known to be optimal among additive quantum codes (codes derived from orthogonal geometry) can be shown to be optimal among all quantum codes. We also use the shadow machinery to extend a bound on additive codes to general codes, obtaining as a consequence that any code of length, can correct at most [(n+1)/6] errors
Keywords :
dual codes; error correction codes; linear programming; quantum cryptography; transforms; MacWilliams transform; additive codes; additive quantum codes; code length; general codes; linear-programming bound; nonnegative enumerator; optimal codes; orthogonal geometry; parity; quantum codes; quantum error-correcting codes; quantum shadow enumerators; self dual codes; shadow codes; weight enumerators; Cryptography; Error correction codes; Geometry; Hilbert space; Linear programming; Machinery; Quantum mechanics; Rain; State-space methods; Upper bound;
