Quantum secure direct communication based on quantum homomorphic encryption

Huang, Xi; Zhang, Shibin; Chang, Yan; Yang, Fan; Hou, Min; Cheng, Wen

doi:10.1142/s0217732321502631

Cited by 10 publications

(3 citation statements)

References 39 publications

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“…Since Bennett and Brassard [1] introduced the pioneering quantum key distribution (QKD) protocol in 1984, leveraging the distinctive properties of quantum mechanics instead of relying on computational complexity problems and demonstrating its unconditional security, a multitude of quantum cryptographic protocols have since been developed. These include quantum secret sharing [2][3][4], quantum secure direct communication [5][6][7], and quantum key agreement [8,9], aiming to address various cryptographic tasks. Quantum cryptography offers significant security advantages compared to classical cryptography, which is vulnerable to attacks from quantum algorithms (e.g., Shor's algorithm [10]).…”

Section: Introductionmentioning

confidence: 99%

Single-photon-based quantum secure protocol for the socialist millionaires’ problem

Hou,

2024

Front. Phys.

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The socialist millionaires' problem, emanating from the millionaires’ problem, allows two millionaires to determine whether they happen to be equally rich while remaining their riches undisclosed to each other. Most of the current quantum solutions to the socialist millionaires’ problem have lower efficiency and are theoretically feasible. In this paper, we introduce a practical quantum secure protocol for the socialist millionaires’ problem based on single photons, which can be easily implemented and manipulated with current technology. Our protocol necessitates the involvement of a semi-honest third party (TP) responsible for preparing the single-photon sequences and transmitting them to Alice who performs Identity or Hadamard operations on the received quantum sequences via her private inputs and the secret keys, producing new quantum sequences that are subsequently sent to Bob. Similarly, Bob encodes his private inputs into the received quantum sequences to produce new quantum sequences, which are then sent to TP. By conducting single-particle measurements on the quantum sequences received from Bob, TP can ascertain the equality of private inputs between Alice and Bob, and subsequently communicate the comparison result to them. To assess the feasibility, the proposed protocol is simulated on IBM Quantum Cloud Platform. Furthermore, security analysis demonstrates that our protocol can withstand attacks from outsiders, such as eavesdroppers, and from insider participants attempting to grab the private input of another participant.

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Section: Introductionmentioning

confidence: 99%

Single-photon-based quantum secure protocol for the socialist millionaires’ problem

Hou,

2024

Front. Phys.

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“…In this context, quantum cryptography has emerged, leveraging the principles of quantum mechanics to enhance the security and privacy of information processing tasks in the communication process. Various quantum cryptography protocols, such as quantum key distribution (QKD) [ 3 , 4 , 5 , 6 ], quantum key agreement (QKA) [ 7 , 8 ], and quantum secure direct communication [ 9 , 10 , 11 ], have emerged to address various tasks.…”

Section: Introductionmentioning

confidence: 99%

New Quantum Private Comparison Using Four-Particle Cluster State

Hou,

Wu,

Zhang

2024

Entropy

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Quantum private comparison (QPC) enables two users to securely conduct private comparisons in a network characterized by mutual distrust while guaranteeing the confidentiality of their private inputs. Most previous QPC protocols were primarily used to determine the equality of private information between two users, which constrained their scalability. In this paper, we propose a QPC protocol that leverages the entanglement correlation between particles in a four-particle cluster state. This protocol can compare the information of two groups of users within one protocol execution, with each group consisting of two users. A semi-honest third party (TP), who will not deviate from the protocol execution or conspire with any participant, is involved in assisting users to achieve private comparisons. Users encode their inputs into specific angles of rotational operations performed on the received quantum sequence, which is then sent back to TP. Security analysis shows that both external attacks and insider threats are ineffective at stealing private data. Finally, we compare our protocol with some previously proposed QPC protocols.

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“…In 1984, Bennett and Brassard [9] proposed the groundbreaking quantum key distribution protocol (i.e., the BB84 QKD protocol), marking the official birth of quantum cryptography. Since then, many different quantum cryptographic protocols have emerged in various branches of cryptography, including Quantum Key Protocol (QKA) [10][11][12], Quantum Secure Direct Communication (QSDC) [13][14][15], Quantum Secret sharing (QSS) [16][17][18], quantum oblivious transmission [19,20] and so on.…”

Section: Introductionmentioning

confidence: 99%

Quantum secure multiparty computing XOR protocol based on single photons and its application in quantum secure communications for intelligence agents

Li,

Shi,

Jia

2024

Phys. Scr.

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In this paper, we consider an interesting and important privacy-preserving issue, i.e., how to implement anonymous and secure communications for several intelligence agents, hiding in n participants. To solve this issue, we first propose a quantum Secure Multiparty Computing XOR (SMC_XOR) protocol based on single photons, which can guarantee the unconditional security of the protocol. By implementing rotation encryption, the practicality of quantum SMC_XOR protocol can be significantly improved without other complex quantum techniques. Security analysis shows that the proposed protocol can resist various types of attacks. Furthermore, a special network model is designed to solve this issue, using hash function to verify the identity of the communication parties and key recycling to reduce resource consumption. Finally, the proposed quantum SMC_XOR protocol is simulated in IBM Qiskit, and the simulation results show that the protocol is correct and feasible.

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Quantum secure direct communication based on quantum homomorphic encryption

Cited by 10 publications

References 39 publications

Single-photon-based quantum secure protocol for the socialist millionaires’ problem

Single-photon-based quantum secure protocol for the socialist millionaires’ problem

New Quantum Private Comparison Using Four-Particle Cluster State

Quantum secure multiparty computing XOR protocol based on single photons and its application in quantum secure communications for intelligence agents

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