Your search keyword '"Kofler J"' showing total 2 results

1. Completely Device Independent Quantum Key Distribution

Author

Aguilar, E. A., Ramanathan, R., Kofler, J., and Pawlowski, M.

Subjects

Quantum Physics

Abstract

Quantum key distribution (QKD) is a provably secure way for two distant parties to establish a common secret key, which then can be used in a classical cryptographic scheme. Using quantum entanglement, one can reduce the necessary assumptions that the parties have to make about their devices, giving rise to device-independent QKD (DIQKD). However, in all existing protocols to date the parties need to have an initial (at least partially) random seed as a resource. In this work, we show that this requirement can be dropped. Using recent advances in the fields of randomness amplification and randomness expansion, we demonstrate that it is sufficient for the message the parties want to communicate to be (partially) unknown to the adversaries -- an assumption without which any type of cryptography would be pointless to begin with. One party can use her secret message to locally generate a secret sequence of bits, which can then be openly used by herself and the other party in a DIQKD protocol. Hence, our work reduces the requirements needed to perform secure DIQKD and establish safe communication., Comment: 7+7 pages , 4 figures

Published

2015

2. Nonlocal setting and outcome information for violation of Bell's inequality

Author

Pawlowski, M., Kofler, J., Paterek, T., Seevinck, M., and Brukner, C.

Subjects

Quantum Physics

Abstract

Bell's theorem is a no-go theorem stating that quantum mechanics cannot be reproduced by a physical theory based on realism, freedom to choose experimental settings and two locality conditions: setting (SI) and outcome (OI) independence. We provide a novel analysis of what it takes to violate Bell's inequality within the framework in which both realism and freedom of choice are assumed, by showing that it is impossible to model a violation without having information in one laboratory about both the setting and the outcome at the distant one. While it is possible that outcome information can be revealed from shared hidden variables, the assumed experimenter's freedom to choose the settings forces that setting information must be non-locally transferred, even when the SI condition is obeyed. The sufficient amount of transmitted information about the setting to violate the CHSH inequality up to its quantum mechanical maximum is 0.736 bits., Comment: 5 pages, published version

Published

2009