05/02/2010, 15:00 — 16:00 — Room P4.35, Mathematics Building
Francisco Marcos de Assis, U Federal de Campina Grande
Zero-Error Capacity of a Quantum Channel
Quantum channels have a number of capacities that depends fundamentally on the kind of information to be carried, the employed resources and the communication protocol. In this work, we generalize the definition of zero-error capacity of a classical channel to the zero-error capacity of a quantum channel. We propose a new kind of capacity for transmitting classical information through a quantum channel.
The
quantum zero-error capacity is defined by the maximum amount of classical information per channel use that can be sent over a noisy quantum channel, with the restriction that the probability of error must be equal to zero. The communication protocol used in the definition assumes codewords are built as tensor products of input quantum states, whereas entangled measurements can be performed between several channel outputs. Hence, our communication protocol is similar to the Holevo-Schumacher-Westmoreland protocol. Additionally we introduce some connection between concepts related to quantum channel capacity with concepts found in graph theory.
Supported by: Phys-Info (IT), SQIG (IT), CeFEMA and CAMGSD, with funding from FCT, FEDER and EU FP7, specifically through the Doctoral Programme in the Physics and Mathematics of Information (DP-PMI), FCT strategic projects PEst-OE/EEI/LA0008/2013 and UID/EEA/50008/2013, IT project QuSim, project CRUP-CPU CQVibes, the FP7 Coordination Action QUTE-EUROPE (600788), and the FP7 projects Landauer (GA 318287) and PAPETS (323901).
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