Device-independence for two-party cryptography and position verification

Jeremy Ribeiro; Le Phuc Thinh; Jedrzej Kaniewski; Jonas Helsen; Stephanie Wehner

Device-independence for two-party cryptography and position verification

Jeremy Ribeiro, Le Phuc Thinh, Jedrzej Kaniewski, Jonas Helsen, Stephanie Wehner

Department of Mathematical Sciences

Abstract

Quantum communication has demonstrated its usefulness for quantum cryptography far beyond quantum key distribution. One domain is two-party cryptography, whose goal is to allow two parties who may not trust each other to solve joint tasks. Another interesting application is position-based cryptography whose goal is to use the geographical location of an entity as its only identifying credential. Unfortunately, security of these protocols is not possible against an all powerful adversary. However, if we impose some realistic physical constraints on the adversary, there exist protocols for which security can be proven, but these so far relied on the knowledge of the quantum operations performed during the protocols. In this work we give device-independent security proofs of two-party cryptography and Position Verification for memoryless devices under different physical constraints on the adversary. We assess the quality of the devices by observing a Bell violation and we show that security can be attained for any violation of the Clauser-Holt-Shimony-Horne inequality.

Original language	English
Publisher	arXiv.org
Number of pages	28
Publication status	Published - 28 Jun 2016

Keywords

quant-ph

Access to Document

https://arxiv.org/abs/1606.08750

Cite this

@techreport{182be05e0e1f4e6081b9ccbe2840dd1d,

title = "Device-independence for two-party cryptography and position verification",

abstract = "Quantum communication has demonstrated its usefulness for quantum cryptography far beyond quantum key distribution. One domain is two-party cryptography, whose goal is to allow two parties who may not trust each other to solve joint tasks. Another interesting application is position-based cryptography whose goal is to use the geographical location of an entity as its only identifying credential. Unfortunately, security of these protocols is not possible against an all powerful adversary. However, if we impose some realistic physical constraints on the adversary, there exist protocols for which security can be proven, but these so far relied on the knowledge of the quantum operations performed during the protocols. In this work we give device-independent security proofs of two-party cryptography and Position Verification for memoryless devices under different physical constraints on the adversary. We assess the quality of the devices by observing a Bell violation and we show that security can be attained for any violation of the Clauser-Holt-Shimony-Horne inequality.",

keywords = "quant-ph",

author = "Jeremy Ribeiro and Thinh, {Le Phuc} and Jedrzej Kaniewski and Jonas Helsen and Stephanie Wehner",

note = "28 pages, 4 figures, 2 tables",

year = "2016",

month = jun,

day = "28",

language = "English",

publisher = "arXiv.org",

type = "WorkingPaper",

institution = "arXiv.org",

}

TY - UNPB

T1 - Device-independence for two-party cryptography and position verification

AU - Ribeiro, Jeremy

AU - Thinh, Le Phuc

AU - Kaniewski, Jedrzej

AU - Helsen, Jonas

AU - Wehner, Stephanie

N1 - 28 pages, 4 figures, 2 tables

PY - 2016/6/28

Y1 - 2016/6/28

N2 - Quantum communication has demonstrated its usefulness for quantum cryptography far beyond quantum key distribution. One domain is two-party cryptography, whose goal is to allow two parties who may not trust each other to solve joint tasks. Another interesting application is position-based cryptography whose goal is to use the geographical location of an entity as its only identifying credential. Unfortunately, security of these protocols is not possible against an all powerful adversary. However, if we impose some realistic physical constraints on the adversary, there exist protocols for which security can be proven, but these so far relied on the knowledge of the quantum operations performed during the protocols. In this work we give device-independent security proofs of two-party cryptography and Position Verification for memoryless devices under different physical constraints on the adversary. We assess the quality of the devices by observing a Bell violation and we show that security can be attained for any violation of the Clauser-Holt-Shimony-Horne inequality.

AB - Quantum communication has demonstrated its usefulness for quantum cryptography far beyond quantum key distribution. One domain is two-party cryptography, whose goal is to allow two parties who may not trust each other to solve joint tasks. Another interesting application is position-based cryptography whose goal is to use the geographical location of an entity as its only identifying credential. Unfortunately, security of these protocols is not possible against an all powerful adversary. However, if we impose some realistic physical constraints on the adversary, there exist protocols for which security can be proven, but these so far relied on the knowledge of the quantum operations performed during the protocols. In this work we give device-independent security proofs of two-party cryptography and Position Verification for memoryless devices under different physical constraints on the adversary. We assess the quality of the devices by observing a Bell violation and we show that security can be attained for any violation of the Clauser-Holt-Shimony-Horne inequality.

KW - quant-ph

M3 - Working paper

BT - Device-independence for two-party cryptography and position verification

PB - arXiv.org

ER -

Device-independence for two-party cryptography and position verification

Abstract

Keywords

Access to Document

Fingerprint

Cite this