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Filters: Author is Khalid, Ayesha  [Clear All Filters]
2023-06-29
Campbell, Donal, Rafferty, Ciara, Khalid, Ayesha, O'Neill, Maire.  2022.  Acceleration of Post Quantum Digital Signature Scheme CRYSTALS-Dilithium on Reconfigurable Hardware. 2022 32nd International Conference on Field-Programmable Logic and Applications (FPL). :462–463.
This research investigates efficient architectures for the implementation of the CRYSTALS-Dilithium post-quantum digital signature scheme on reconfigurable hardware, in terms of speed, memory usage, power consumption and resource utilisation. Post quantum digital signature schemes involve a significant computational effort, making efficient hardware accelerators an important contributor to future adoption of schemes. This is work in progress, comprising the establishment of a comprehensive test environment for operational profiling, and the investigation of the use of novel architectures to achieve optimal performance.
ISSN: 1946-1488
2019-10-08
Khalid, Ayesha, Oder, Tobias, Valencia, Felipe, O' Neill, Maire, Güneysu, Tim, Regazzoni, Francesco.  2018.  Physical Protection of Lattice-Based Cryptography: Challenges and Solutions. Proceedings of the 2018 on Great Lakes Symposium on VLSI. :365–370.

The impending realization of scalable quantum computers will have a significant impact on today's security infrastructure. With the advent of powerful quantum computers public key cryptographic schemes will become vulnerable to Shor's quantum algorithm, undermining the security current communications systems. Post-quantum (or quantum-resistant) cryptography is an active research area, endeavoring to develop novel and quantum resistant public key cryptography. Amongst the various classes of quantum-resistant cryptography schemes, lattice-based cryptography is emerging as one of the most viable options. Its efficient implementation on software and on commodity hardware has already been shown to compete and even excel the performance of current classical security public-key schemes. This work discusses the next step in terms of their practical deployment, i.e., addressing the physical security of lattice-based cryptographic implementations. We survey the state-of-the-art in terms of side channel attacks (SCA), both invasive and passive attacks, and proposed countermeasures. Although the weaknesses exposed have led to countermeasures for these schemes, the cost, practicality and effectiveness of these on multiple implementation platforms, however, remains under-studied.

2017-05-22
O'Neill, Maire, O'Sullivan, Elizabeth, McWilliams, Gavin, Saarinen, Markku-Juhani, Moore, Ciara, Khalid, Ayesha, Howe, James, del Pino, Rafael, Abdalla, Michel, Regazzoni, Francesco et al..  2016.  Secure Architectures of Future Emerging Cryptography SAFEcrypto. Proceedings of the ACM International Conference on Computing Frontiers. :315–322.

Funded under the European Union's Horizon 2020 research and innovation programme, SAFEcrypto will provide a new generation of practical, robust and physically secure post-quantum cryptographic solutions that ensure long-term security for future ICT systems, services and applications. The project will focus on the remarkably versatile field of Lattice-based cryptography as the source of computational hardness, and will deliver optimised public key security primitives for digital signatures and authentication, as well identity based encryption (IBE) and attribute based encryption (ABE). This will involve algorithmic and design optimisations, and implementations of lattice-based cryptographic schemes addressing cost, energy consumption, performance and physical robustness. As the National Institute of Standards and Technology (NIST) prepares for the transition to a post-quantum cryptographic suite B, urging organisations that build systems and infrastructures that require long-term security to consider this transition in architectural designs; the SAFEcrypto project will provide Proof-of-concept demonstrators of schemes for three practical real-world case studies with long-term security requirements, in the application areas of satellite communications, network security and cloud. The goal is to affirm Lattice-based cryptography as an effective replacement for traditional number-theoretic public-key cryptography, by demonstrating that it can address the needs of resource-constrained embedded applications, such as mobile and battery-operated devices, and of real-time high performance applications for cloud and network management infrastructures.