Title :
Information rates achievable with algebraic codes on quantum discrete memoryless channels
Author_Institution :
Tamagawa Univ. Res. Inst., Tokyo
Abstract :
The highest information rate at which quantum error-correction schemes work reliably on a channel is called the quantum capacity. Here this is proven to be lower-bounded by the limit of coherent information maximized over the set of input density operators which are proportional to the projections onto the code spaces of symplectic stabilizer codes. The quantum channels to be considered are those subject to independent errors and modeled as tensor products of copies of a completely positive linear map on a Hilbert space of finite dimension. The codes that are proven to have the desired performance are symplectic stabilizer codes. On the depolarizing channel, the bound proven here is actually the highest possible rate at which symplectic stabilizer codes work reliably
Keywords :
algebraic geometric codes; channel capacity; channel coding; discrete systems; error correction codes; memoryless systems; Hilbert space; algebraic code; density operator; depolarizing channel; discrete memoryless channel; error-correction scheme; positive linear map; quantum channel capacity; symplectic stabilizer code; Code standards; Concatenated codes; Conferences; Error correction codes; Information rates; Information theory; Memoryless systems; Quantum computing; Quantum mechanics; Upper bound; Completely positive (CP) linear maps; fidelity; quantum capacity; quantum error-correcting codes; symplectic geometry; the method of types;
Journal_Title :
Information Theory, IEEE Transactions on
DOI :
10.1109/TIT.2005.860824
