Your search keyword '"Ryan Amiri"' showing total 14 results

1. Experimental demonstration of quantum digital signatures over 43 dB channel loss using differential phase shift quantum key distribution

Author

Robert J. Collins, Ryan Amiri, Mikio Fujiwara, Toshimori Honjo, Kaoru Shimizu, Kiyoshi Tamaki, Masahiro Takeoka, Masahide Sasaki, Erika Andersson, and Gerald S. Buller

Subjects

Medicine, Science

Abstract

Abstract Ensuring the integrity and transferability of digital messages is an important challenge in modern communications. Although purely mathematical approaches exist, they usually rely on the computational complexity of certain functions, in which case there is no guarantee of long-term security. Alternatively, quantum digital signatures offer security guaranteed by the physical laws of quantum mechanics. Prior experimental demonstrations of quantum digital signatures in optical fiber have typically been limited to operation over short distances and/or operated in a laboratory environment. Here we report the experimental transmission of quantum digital signatures over channel losses of up to 42.8 ± 1.2 dB in a link comprised of 90 km of installed fiber with additional optical attenuation introduced to simulate longer distances. The channel loss of 42.8 ± 1.2 dB corresponds to an equivalent distance of 134.2 ± 3.8 km and this represents the longest effective distance and highest channel loss that quantum digital signatures have been shown to operate over to date. Our theoretical model indicates that this represents close to the maximum possible channel attenuation for this quantum digital signature protocol, defined as the loss for which the signal rate is comparable to the dark count rate of the detectors.

Published

2017

2. Imperfect 1-Out-of-2 Quantum Oblivious Transfer: Bounds, a Protocol, and its Experimental Implementation

Author

Ryan Amiri, Robert Stárek, David Reichmuth, Ittoop V. Puthoor, Michal Mičuda, Ladislav Mišta, Jr., Miloslav Dušek, Petros Wallden, and Erika Andersson

Subjects

Physics, QC1-999, Computer software, QA76.75-76.765

Abstract

Oblivious transfer is an important primitive in modern cryptography. Applications include secure multiparty computation, oblivious sampling, e-voting, and signatures. Information-theoretically secure perfect 1-out-of 2 oblivious transfer is impossible to achieve. Imperfect variants, where both participants’ ability to cheat is still limited, are possible using quantum means while remaining classically impossible. Precisely what security parameters are attainable remains unknown. We introduce a theoretical framework for studying semirandom quantum oblivious transfer, which is shown to be equivalent to regular oblivious transfer in terms of cheating probabilities. We then use it to derive bounds on cheating. We also present a protocol with lower cheating probabilities than previous schemes, together with its optical realization. We show that a lower bound of 2/3 on the minimum achievable cheating probability can be directly derived for semirandom protocols using a different method and definition of cheating than used previously. The lower bound increases from 2/3 to approximately 0.749 if the states output by the protocol are pure and symmetric. The oblivious transfer scheme we present uses unambiguous state elimination measurements and can be implemented with the same technological requirements as standard quantum cryptography. In particular, it does not require honest participants to prepare or measure entangled states. The cheating probabilities are 3/4 and approximately 0.729 for sender and receiver, respectively, which is lower than in existing protocols. Using a photonic testbed, we have implemented the protocol with honest parties, as well as optimal cheating strategies. Because of the asymmetry of the receiver’s and sender’s cheating probabilities, the protocol can be combined with a “trivial” protocol to achieve an overall protocol with lower average cheating probabilities of approximately 0.74 for both sender and receiver. This demonstrates that, interestingly, protocols where the final output states are pure and symmetric are not optimal in terms of average cheating probability.

Published

2021

3. Unconditionally Secure Quantum Signatures

Author

Ryan Amiri and Erika Andersson

Subjects

quantum information, information-theoretic security, digital signatures, Science, Astrophysics, QB460-466, Physics, QC1-999

Abstract

Signature schemes, proposed in 1976 by Diffie and Hellman, have become ubiquitous across modern communications. They allow for the exchange of messages from one sender to multiple recipients, with the guarantees that messages cannot be forged or tampered with and that messages also can be forwarded from one recipient to another without compromising their validity. Signatures are different from, but no less important than encryption, which ensures the privacy of a message. Commonly used signature protocols—signatures based on the Rivest–Adleman–Shamir (RSA) algorithm, the digital signature algorithm (DSA), and the elliptic curve digital signature algorithm (ECDSA)—are only computationally secure, similar to public key encryption methods. In fact, since these rely on the difficulty of finding discrete logarithms or factoring large primes, it is known that they will become completely insecure with the emergence of quantum computers. We may therefore see a shift towards signature protocols that will remain secure even in a post-quantum world. Ideally, such schemes would provide unconditional or information-theoretic security. In this paper, we aim to provide an accessible and comprehensive review of existing unconditionally securesecure signature schemes for signing classical messages, with a focus on unconditionally secure quantum signature schemes.

Published

2015

4. Efficient Unconditionally Secure Signatures Using Universal Hashing.

Author

Ryan Amiri, Aysajan Abidin, Petros Wallden, and Erika Andersson

Published

2018

5. Imperfect 1-Out-of-2 Quantum Oblivious Transfer: Bounds, a Protocol, and its Experimental Implementation

Author

Miloslav Dusek, Ittoop Vergheese Puthoor, Michal Mičuda, Robert Stárek, Petros Wallden, Erika Andersson, Ryan Amiri, L. Mišta, and David Reichmuth

Subjects

TheoryofComputation_MISCELLANEOUS, Quantum Physics, Theoretical computer science, Oblivious transfer, Computer science, business.industry, Cheating, General Engineering, FOS: Physical sciences, Cryptography, 01 natural sciences, 010305 fluids & plasmas, Quantum cryptography, 0103 physical sciences, General Earth and Planetary Sciences, Imperfect, Quantum Physics (quant-ph), 010306 general physics, Quantum information science, business, Protocol (object-oriented programming), Quantum, General Environmental Science

Abstract

Oblivious transfer is an important primitive in modern cryptography. Applications include secure multiparty computation, oblivious sampling, e-voting, and signatures. Information-theoretically secure perfect 1-out-of 2 oblivious transfer is impossible to achieve. Imperfect variants, where both participants' ability to cheat is still limited, are possible using quantum means while remaining classically impossible. Precisely what security parameters are attainable remains unknown. We introduce a theoretical framework for studying semirandom quantum oblivious transfer, which is shown to be equivalent to regular oblivious transfer in terms of cheating probabilities. We then use it to derive bounds on cheating. We also present a protocol with lower cheating probabilities than previous schemes, together with its optical realization. We show that a lower bound of 2/3 on the minimum achievable cheating probability can be directly derived for semirandom protocols using a different method and definition of cheating than used previously. The lower bound increases from 2/3 to approximately 0.749 if the states output by the protocol are pure and symmetric. The oblivious transfer scheme we present uses unambiguous state elimination measurements and can be implemented with the same technological requirements as standard quantum cryptography. The cheating probabilities are 3/4 and approximately 0.729 for sender and receiver respectively, which is lower than in existing protocols. Using a photonic test-bed, we have implemented the protocol with honest parties, as well as optimal cheating strategies., 22 pages, 1 figure, v2 moderate changes, published version

Published

2021

6. Secret-key expansion from covert communication

Author

Ryan Amiri and Juan Miguel Arrazola

Subjects

TheoryofComputation_MISCELLANEOUS, Physics, Quantum Physics, FOS: Physical sciences, Key distribution, 020206 networking & telecommunications, Data_CODINGANDINFORMATIONTHEORY, 02 engineering and technology, Shared secret, Adversary, Computer security, computer.software_genre, 01 natural sciences, Transmission (telecommunications), Covert, 0103 physical sciences, 0202 electrical engineering, electronic engineering, information engineering, Key (cryptography), Noise (video), Quantum Physics (quant-ph), 010306 general physics, Protocol (object-oriented programming), computer

Abstract

Covert communication allows us to transmit messages in such a way that it is not possible to detect that the communication is occurring. This provides protection in situations where knowledge that people are talking to each other may be incriminating to them. In this work, we study how covert communication can be used for a different purpose: secret key expansion. First, we show that any message transmitted in a secure covert protocol is also secret and therefore unknown to an adversary. We then propose a protocol that uses covert communication where the amount of key consumed in the protocol is smaller than the transmitted key, thus leading to secure secret key expansion. We derive precise conditions showing that secret key expansion from covert communication is possible when there are sufficiently low levels of noise for a given security level. We conclude by examining how secret key expansion from covert communication can be performed in a computational security model., Comment: 6 pages, 2 figures

Published

2018

7. Unconditionally Secure Quantum Signatures

Author

Erika Andersson and Ryan Amiri

Subjects

FOS: Computer and information sciences, Computer Science - Cryptography and Security, Computer science, FOS: Physical sciences, General Physics and Astronomy, lcsh:Astrophysics, Encryption, Computer security, computer.software_genre, 01 natural sciences, 010305 fluids & plasmas, Public-key cryptography, Digital Signature Algorithm, Digital signature, quantum information, 0103 physical sciences, lcsh:QB460-466, 010306 general physics, lcsh:Science, Quantum Physics, business.industry, Elliptic Curve Digital Signature Algorithm, Information-theoretic security, Signature (logic), lcsh:QC1-999, information-theoretic security, Quantum digital signature, digital signatures, lcsh:Q, Quantum Physics (quant-ph), business, Cryptography and Security (cs.CR), computer, lcsh:Physics

Abstract

Signature schemes, proposed in 1976 by Diffie and Hellman, have become ubiquitous across modern communications. They allow for the exchange of messages from one sender to multiple recipients, with the guarantees that messages cannot be forged or tampered with and that messages also can be forwarded from one recipient to another without compromising their validity. Signatures are different from, but no less important than encryption, which ensures the privacy of a message. Commonly used signature protocols - signatures based on the Rivest-Adleman-Shamir (RSA) algorithm, the digital signature algorithm (DSA), and the elliptic curve digital signature algorithm (ECDSA) - are only computationally secure, similar to public key encryption methods. In fact, since these rely on the difficulty of finding discrete logarithms or factoring large primes, it is known that they will become completely insecure with the emergence of quantum computers. We may therefore see a shift towards signature protocols that will remain secure even in a post-quantum world. Ideally, such schemes would provide unconditional or information-theoretic security. In this paper, we aim to provide an accessible and comprehensive review of existing unconditionally secure signature schemes for signing classical messages, with a focus on unconditionally secure quantum signature schemes., Comment: 16 pages; an accessible short review paper in a special issue on Quantum Cryptography

Published

2015

8. Measurement-Device-Independent Quantum Digital Signatures

Author

Erika Andersson, Ittoop Vergheese Puthoor, Ryan Amiri, Marcos Curty, and Petros Wallden

Subjects

Physics, Quantum network, Quantum Physics, business.industry, FOS: Physical sciences, Cryptography, Quantum key distribution, Software distribution, 01 natural sciences, 010309 optics, Quantum cryptography, Computer engineering, Digital signature, Quantum digital signature, 0103 physical sciences, Cryptosystem, 010306 general physics, business, Quantum Physics (quant-ph)

Abstract

Digital signatures play an important role in software distribution, modern communication and financial transactions, where it is important to detect forgery and tampering. Signatures are a cryptographic technique for validating the authenticity and integrity of messages, software, or digital documents. The security of currently used classical schemes relies on computational assumptions. Quantum digital signatures (QDS), on the other hand, provide information-theoretic security based on the laws of quantum physics. Recent work on QDS shows that such schemes do not require trusted quantum channels and are unconditionally secure against general coherent attacks. However, in practical QDS, just as in quantum key distribution (QKD), the detectors can be subjected to side-channel attacks, which can make the actual implementations insecure. Motivated by the idea of measurement-device-independent quantum key distribution (MDI-QKD), we present a measurement-device-independent QDS (MDI-QDS) scheme, which is secure against all detector side-channel attacks. Based on the rapid development of practical MDI-QKD, our MDI-QDS protocol could also be experimentally implemented, since it requires a similar experimental setup., 12 pages, 2 figures and supplementary material is included

Published

2017

9. Experimental preparation and verification of quantum money

Author

Juan Miguel Arrazola, Ryan Amiri, Weijun Zhang, Hao Li, Lixing You, Zhen Wang, Jian-Wei Pan, Qiang Zhang, and Jian-Yu Guan

Subjects

Physics, Discrete mathematics, Quantum Physics, Security analysis, Measure (physics), FOS: Physical sciences, Limiting, 01 natural sciences, 010305 fluids & plasmas, 0103 physical sciences, Verifiable secret sharing, 010306 general physics, Quantum Physics (quant-ph), Quantum, Quantum money

Abstract

A quantum money scheme enables a trusted bank to provide untrusted users with verifiable quantum banknotes that cannot be forged. In this work, we report an experimental demonstration of the preparation and verification of unforgeable quantum banknotes. We employ a security analysis that takes experimental imperfections fully into account. We measure a total of $3.6\times 10^6$ states in one verification round, limiting the forging probability to $10^{-7}$ based on the security analysis. Our results demonstrate the feasibility of preparing and verifying quantum banknotes using currently available experimental techniques., Comment: 12 pages, 4 figures

Published

2017

10. Photonic quantum digital signatures operating over kilometer ranges in installed optical fiber

Author

Mikio Fujiwara, Erika Andersson, Kaoru Shimizu, Masahiro Takeoka, Toshimori Honjo, Ryan Amiri, Kiyoshi Tamaki, Masahide Sasaki, Robert J. Collins, and Gerald S. Buller

Subjects

business.industry, Computer science, Computer security, computer.software_genre, Signature (logic), Digital signature, Digital security, Quantum information, Photonics, business, Quantum information science, Quantum, computer, Implementation, Computer Science::Cryptography and Security, Computer network

Abstract

The security of electronic communications is a topic that has gained noteworthy public interest in recent years. As a result, there is an increasing public recognition of the existence and importance of mathematically based approaches to digital security. Many of these implement digital signatures to ensure that a malicious party has not tampered with the message in transit, that a legitimate receiver can validate the identity of the signer and that messages are transferable. The security of most digital signature schemes relies on the assumed computational difficulty of solving certain mathematical problems. However, reports in the media have shown that certain implementations of such signature schemes are vulnerable to algorithmic breakthroughs and emerging quantum processing technologies. Indeed, even without quantum processors, the possibility remains that classical algorithmic breakthroughs will render these schemes insecure. There is ongoing research into information-theoretically secure signature schemes, where the security is guaranteed against an attacker with arbitrary computational resources. One such approach is quantum digital signatures. Quantum signature schemes can be made information-theoretically secure based on the laws of quantum mechanics while comparable classical protocols require additional resources such as anonymous broadcast and/or a trusted authority. Previously, most early demonstrations of quantum digital signatures required dedicated single-purpose hardware and operated over restricted ranges in a laboratory environment. Here, for the first time, we present a demonstration of quantum digital signatures conducted over several kilometers of installed optical fiber. The system reported here operates at a higher signature generation rate than previous fiber systems.

Published

2016

11. Quantum money with nearly optimal error tolerance

Author

Ryan Amiri and Juan Miguel Arrazola

Subjects

Physics, Matching (statistics), Quantum Physics, Conjecture, FOS: Physical sciences, 01 natural sciences, 010305 fluids & plasmas, Noise, Dimension (vector space), 0103 physical sciences, Coherent states, 010306 general physics, Constant (mathematics), Quantum Physics (quant-ph), Algorithm, Quantum, Quantum money

Abstract

We present a family of quantum money schemes with classical verification which display a number of benefits over previous proposals. Our schemes are based on hidden matching quantum retrieval games and they tolerate noise up to 23%, which we conjecture reaches 25% asymptotically as the dimension of the underlying hidden matching states is increased. Furthermore, we prove that 25% is the maximum tolerable noise for a wide class of quantum money schemes with classical verification, meaning our schemes are almost optimally noise tolerant. We use methods in semi-definite programming to prove security in a substantially different manner to previous proposals, leading to two main advantages: first, coin verification involves only a constant number of states (with respect to coin size), thereby allowing for smaller coins; second, the re-usability of coins within our scheme grows linearly with the size of the coin, which is known to be optimal. Lastly, we suggest methods by which the coins in our protocol could be implemented using weak coherent states and verified using existing experimental techniques, even in the presence of detector inefficiencies., Comment: 17 pages, 5 figures

Published

2016

12. Experimental demonstration of kilometer-range quantum digital signatures

Author

Klaudia Kleczkowska, Erika Andersson, Vedran Dunjko, Ryan Amiri, Robert J. Collins, John Jeffers, Petros Wallden, Gerald S. Buller, and Ross J. Donaldson

Subjects

Physics, Quantum network, Quantum Physics, Quantum sensor, FOS: Physical sciences, Quantum channel, Quantum capacity, Quantum imaging, 01 natural sciences, Computational physics, 010309 optics, Quantum digital signature, Quantum error correction, Quantum mechanics, ComputerSystemsOrganization_MISCELLANEOUS, 0103 physical sciences, Quantum information, 010306 general physics, Quantum Physics (quant-ph), key distribution, discrete logarithms, hash functions, authentication, system, fiber, long, QC

Abstract

We present an experimental realization of a quantum digital signature protocol which, together with a standard quantum key distribution link, increases transmission distance to kilometer ranges, three orders of magnitude larger than in previous realizations. The bit rate is also significantly increased compared with previous quantum signature demonstrations. This work illustrates that quantum digital signatures can be realized with optical components similar to those used for quantum key distribution and could be implemented in existing quantum optical fiber networks.

Published

2016

13. Secure Quantum Signatures Using Insecure Quantum Channels

Author

Ryan Amiri, Petros Wallden, Adrian Kent, Erika Andersson, Kent, Adrian [0000-0003-2624-3687], and Apollo - University of Cambridge Repository

Subjects

Physics, Quantum Physics, Theoretical computer science, FOS: Physical sciences, Quantum channel, Quantum key distribution, 01 natural sciences, Signature (logic), 5108 Quantum Physics, 010305 fluids & plasmas, Transmission (telecommunications), Digital signature, 5102 Atomic, Molecular and Optical Physics, Quantum state, Quantum digital signature, ComputerSystemsOrganization_MISCELLANEOUS, 0103 physical sciences, 010306 general physics, Quantum Physics (quant-ph), Quantum, 51 Physical Sciences, Computer Science::Cryptography and Security

Abstract

Digital signatures are widely used in modern communication to guarantee authenticity and transferability of messages, The security of currently used classical schemes relies on computational assumptions. We present a quantum signature scheme that does not require trusted quantum channels. We prove that it is unconditionally secure against the most general coherent attacks, and show that it requires the transmission of significantly fewer quantum states than previous schemes. We also show that the quantum channel noise threshold for our scheme is less strict than for distilling a secure key using quantum key distribution. This shows that direct quantum signature schemes can be preferable to signature schemes relying on secret shared keys generated using quantum key distribution., Comment: 11 pages including supplementary material

Published

2015

14. Experimental transmission of quantum digital signatures over 90 km of installed optical fiber using a differential phase shift quantum key distribution system

Author

Kaoru Shimizu, Toshimori Honjo, Mikio Fujiwara, Masahide Sasaki, Ryan Amiri, Kiyoshi Tamaki, Masahiro Takeoka, Robert J. Collins, Erika Andersson, and Gerald S. Buller

Subjects

Physics, Quantum optics, Quantum Physics, Optical fiber, business.industry, FOS: Physical sciences, Quantum key distribution, 01 natural sciences, Atomic and Molecular Physics, and Optics, Differential phase, law.invention, 010309 optics, Optics, Transmission (telecommunications), Digital signature, law, Quantum digital signature, 0103 physical sciences, Quantum Physics (quant-ph), 010306 general physics, business, Quantum, Computer Science::Cryptography and Security

Abstract

Quantum digital signatures apply quantum mechanics to the problem of guaranteeing message integrity and non-repudiation with information-theoretical security, which are complementary to the confidentiality realized by quantum key distribution. Previous experimental demonstrations have been limited to transmission distances of less than 5-km of optical fiber in a laboratory setting. Here we report the first demonstration of quantum digital signatures over installed optical fiber as well as the longest transmission link reported to date. This demonstration used a 90-km long differential phase shift quantum key distribution system to achieve approximately one signed bit per second - an increase in the signature generation rate of several orders of magnitude over previous optical fiber demonstrations.

Published

2016