Title :
Quantum circuits and quantum message integrity
Author :
Lin, Tien-Sheng ; Chang, Ting-Hsu ; Chien, Chia-Hung ; Kuo, Sy-Yen
Author_Institution :
Dept. of Marketing & Distrib. Manage., Lan Yang Inst. of Technol., I Lan, Taiwan
Abstract :
In the wireless communication networks, quantum message integrity can be applied with quantum authentication and quantum signature if the source and destination are indirect communication. Eavesdroppers and malicious nodes may exist in the routing path from the source to the destination. There is major threat in the indirect communication. Based on quantum nature, we design quantum permutation model to verify quantum transmission sequence of a quantum transmission frame if an attacker wants to crack the content of a quantum transmission frame. Quantum permutation model can determine the real position of data qubits and verification qubits. However, Eves is not able to obtain the position of date qubits because quantum permutation switching cannot be owned by Eve. So quantum transmission sequence can be reserved. The receiver has the capability to verify it and obtains the content of data qubits.
Keywords :
message authentication; quantum computing; quantum cryptography; quantum optics; radio receivers; radiocommunication; telecommunication network routing; data qubits; eavesdropper; malicious node; quantum authentication; quantum circuit; quantum message integrity; quantum permutation model; quantum permutation switching; quantum signature; quantum transmission frame; quantum transmission sequence; receiver; routing path; verification qubits; wireless communication network; Integrated circuit modeling; Logic gates; Receivers; Routing; Security; Switches; Indirect communication; eavesdropper; quantum nature; quantum permutation model; quantum transmission frame;
Conference_Titel :
Security Technology (ICCST), 2011 IEEE International Carnahan Conference on
Conference_Location :
Barcelona
Print_ISBN :
978-1-4577-0902-9
DOI :
10.1109/CCST.2011.6095928
