Continuous-variable quantum homomorphic signature

Ke Li; Tao Shang; Jian wei Liu

doi:10.1007/s11128-017-1689-5

Continuous-variable quantum homomorphic signature

Ke Li
, Tao Shang^*
, Jian wei Liu

^*Corresponding author for this work

School of Cyber Science and Technology

Beihang University

Research output: Contribution to journal › Article › peer-review

11 Scopus citations

Abstract

Quantum cryptography is believed to be unconditionally secure because its security is ensured by physical laws rather than computational complexity. According to spectrum characteristic, quantum information can be classified into two categories, namely discrete variables and continuous variables. Continuous-variable quantum protocols have gained much attention for their ability to transmit more information with lower cost. To verify the identities of different data sources in a quantum network, we propose a continuous-variable quantum homomorphic signature scheme. It is based on continuous-variable entanglement swapping and provides additive and subtractive homomorphism. Security analysis shows the proposed scheme is secure against replay, forgery and repudiation. Even under nonideal conditions, it supports effective verification within a certain verification threshold.

Original language	English
Article number	246
Journal	Quantum Information Processing
Volume	16
Issue number	10
DOIs	https://doi.org/10.1007/s11128-017-1689-5
State	Published - 1 Oct 2017

Keywords

Continuous variables
Entanglement swapping
Quantum homomorphic signature
Verification threshold

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10.1007/s11128-017-1689-5

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title = "Continuous-variable quantum homomorphic signature",

abstract = "Quantum cryptography is believed to be unconditionally secure because its security is ensured by physical laws rather than computational complexity. According to spectrum characteristic, quantum information can be classified into two categories, namely discrete variables and continuous variables. Continuous-variable quantum protocols have gained much attention for their ability to transmit more information with lower cost. To verify the identities of different data sources in a quantum network, we propose a continuous-variable quantum homomorphic signature scheme. It is based on continuous-variable entanglement swapping and provides additive and subtractive homomorphism. Security analysis shows the proposed scheme is secure against replay, forgery and repudiation. Even under nonideal conditions, it supports effective verification within a certain verification threshold.",

keywords = "Continuous variables, Entanglement swapping, Quantum homomorphic signature, Verification threshold",

author = "Ke Li and Tao Shang and Liu, \{Jian wei\}",

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AU - Shang, Tao

AU - Liu, Jian wei

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N2 - Quantum cryptography is believed to be unconditionally secure because its security is ensured by physical laws rather than computational complexity. According to spectrum characteristic, quantum information can be classified into two categories, namely discrete variables and continuous variables. Continuous-variable quantum protocols have gained much attention for their ability to transmit more information with lower cost. To verify the identities of different data sources in a quantum network, we propose a continuous-variable quantum homomorphic signature scheme. It is based on continuous-variable entanglement swapping and provides additive and subtractive homomorphism. Security analysis shows the proposed scheme is secure against replay, forgery and repudiation. Even under nonideal conditions, it supports effective verification within a certain verification threshold.

AB - Quantum cryptography is believed to be unconditionally secure because its security is ensured by physical laws rather than computational complexity. According to spectrum characteristic, quantum information can be classified into two categories, namely discrete variables and continuous variables. Continuous-variable quantum protocols have gained much attention for their ability to transmit more information with lower cost. To verify the identities of different data sources in a quantum network, we propose a continuous-variable quantum homomorphic signature scheme. It is based on continuous-variable entanglement swapping and provides additive and subtractive homomorphism. Security analysis shows the proposed scheme is secure against replay, forgery and repudiation. Even under nonideal conditions, it supports effective verification within a certain verification threshold.

KW - Continuous variables

KW - Entanglement swapping

KW - Quantum homomorphic signature

KW - Verification threshold

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ER -

Continuous-variable quantum homomorphic signature

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Keywords

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