Random Numbers determine the security level of cryptographic applications as they are used to generate padding schemes in the encryption/decryption process as well as used to generate cryptographic keys. This paper utilizes the QKD to generate a random quantum bit rely on BB84 protocol, using the NIST and DIEHARD randomness test algorithms to test and evaluate the randomness rates for key generation. The results show that the bits generated using QKD are truly random, which in turn, overcomes the distance limitation (associated with QKD) issue, its well-known challenges with the sending / receiving data process between different communication parties
Security proofs of quantum key distribution (QKD) systems usually assume that the users have access ...
Quantum key distribution (QKD) is the future of the cryptography world. The QKD was invented to incr...
True randomness is necessary for the security of any cryptographic protocol, including quantum key d...
Cryptography is the study and practice of secure communication with digital data and focuses on conf...
Randomness is crucial to enabling secure and robust communications. Ideally one should harness high ...
Quantum technologies are today a reality, and they have been applied to different subjects, such as ...
Since quantum key distribution (QKD) can provide proven unconditional security guaranteed by the fun...
In quantum cryptography, random number generators play a crucial role in the quantum key distributio...
Cryptography plays a key role in today's digital society. The most widely used encryption method is ...
Presenting a new technology to fit quantum-randomness into a lump of matter where the randomness is ...
Random numbers are essential for cryptography and scientific simulation. Generating truly random num...
This report reviews two quantum key distribution (QKD) protocols: the BB84 protocol and the measurem...
AbstractAll traditional cryptographic algorithms used in the network communication environments, rel...
Random numbers play an essential role in various fields, especially cryptography. This is because of...
IoT endpoints and systems are popular targets for cyberattacks which is why they need to be protecte...
Security proofs of quantum key distribution (QKD) systems usually assume that the users have access ...
Quantum key distribution (QKD) is the future of the cryptography world. The QKD was invented to incr...
True randomness is necessary for the security of any cryptographic protocol, including quantum key d...
Cryptography is the study and practice of secure communication with digital data and focuses on conf...
Randomness is crucial to enabling secure and robust communications. Ideally one should harness high ...
Quantum technologies are today a reality, and they have been applied to different subjects, such as ...
Since quantum key distribution (QKD) can provide proven unconditional security guaranteed by the fun...
In quantum cryptography, random number generators play a crucial role in the quantum key distributio...
Cryptography plays a key role in today's digital society. The most widely used encryption method is ...
Presenting a new technology to fit quantum-randomness into a lump of matter where the randomness is ...
Random numbers are essential for cryptography and scientific simulation. Generating truly random num...
This report reviews two quantum key distribution (QKD) protocols: the BB84 protocol and the measurem...
AbstractAll traditional cryptographic algorithms used in the network communication environments, rel...
Random numbers play an essential role in various fields, especially cryptography. This is because of...
IoT endpoints and systems are popular targets for cyberattacks which is why they need to be protecte...
Security proofs of quantum key distribution (QKD) systems usually assume that the users have access ...
Quantum key distribution (QKD) is the future of the cryptography world. The QKD was invented to incr...
True randomness is necessary for the security of any cryptographic protocol, including quantum key d...