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Your search keyword '"Kermani, Mehran Mozaffari"' showing total 27 results
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27 results on '"Kermani, Mehran Mozaffari"'

1. Efficient Algorithm Level Error Detection for Number-Theoretic Transform used for Kyber Assessed on FPGAs and ARM

Author

Ahmadi, Kasra, Aghapour, Saeed, Kermani, Mehran Mozaffari, and Azarderakhsh, Reza

Subjects
Computer Science - Cryptography and Security
Abstract

Polynomial multiplication stands out as a highly demanding arithmetic process in the development of post-quantum cryptosystems. The importance of the number-theoretic transform (NTT) extends beyond post-quantum cryptosystems, proving valuable in enhancing existing security protocols such as digital signature schemes and hash functions. CRYSTALS-KYBER stands out as the sole public key encryption (PKE) algorithm chosen by the National Institute of Standards and Technology (NIST) in its third round selection, making it highly regarded as a leading post-quantum cryptography (PQC) solution. Due to the potential for errors to significantly disrupt the operation of secure, cryptographically-protected systems, compromising data integrity, and safeguarding against side-channel attacks initiated through faults it is essential to incorporate mitigating error detection schemes. This paper introduces algorithm level fault detection schemes in the NTT multiplication using Negative Wrapped Convolution and the NTT tailored for Kyber Round 3, representing a significant enhancement compared to previous research. We evaluate this through the simulation of a fault model, ensuring that the conducted assessments accurately mirror the obtained results. Consequently, we attain a notably comprehensive coverage of errors. Furthermore, we assess the performance of our efficient error detection scheme for Negative Wrapped Convolution on FPGAs to showcase its implementation and resource requirements. Through implementation of our error detection approach on Xilinx/AMD Zynq Ultrascale+ and Artix-7, we achieve a comparable throughput with just a 9% increase in area and 13% increase in latency compared to the original hardware implementations. Finally, we attained an error detection ratio of nearly 100% for the NTT operation in Kyber Round 3, with a clock cycle overhead of 16% on the Cortex-A72 processor.

Published
2024

2. Efficient Fault Detection Architectures for Modular Exponentiation Targeting Cryptographic Applications Benchmarked on FPGAs

Author

Aghapour, Saeed, Ahmadi, Kasra, Kermani, Mehran Mozaffari, and Azarderakhsh, Reza

Subjects
Computer Science - Cryptography and Security
Abstract

Whether stemming from malicious intent or natural occurrences, faults and errors can significantly undermine the reliability of any architecture. In response to this challenge, fault detection assumes a pivotal role in ensuring the secure deployment of cryptosystems. Even when a cryptosystem boasts mathematical security, its practical implementation may remain susceptible to exploitation through side-channel attacks. In this paper, we propose a lightweight fault detection architecture tailored for modular exponentiation, a building block of numerous cryptographic applications spanning from classical cryptography to post quantum cryptography. Based on our simulation and implementation results on ARM Cortex-A72 processor, and AMD/Xilinx Zynq Ultrascale+, and Artix-7 FPGAs, our approach achieves an error detection rate close to 100%, all while introducing a modest computational overhead of approximately 7% and area overhead of less than 1% compared to the unprotected architecture. To the best of our knowledge, such an approach benchmarked on ARM processor and FPGA has not been proposed and assessed to date., Comment: 5 pages, 2 figures

Published
2024

3. Envisioning the Future of Cyber Security in Post-Quantum Era: A Survey on PQ Standardization, Applications, Challenges and Opportunities

Author

Darzi, Saleh, Ahmadi, Kasra, Aghapour, Saeed, Yavuz, Attila Altay, and Kermani, Mehran Mozaffari

Subjects
Computer Science - Cryptography and Security
Abstract

The rise of quantum computers exposes vulnerabilities in current public key cryptographic protocols, necessitating the development of secure post-quantum (PQ) schemes. Hence, we conduct a comprehensive study on various PQ approaches, covering the constructional design, structural vulnerabilities, and offer security assessments, implementation evaluations, and a particular focus on side-channel attacks. We analyze global standardization processes, evaluate their metrics in relation to real-world applications, and primarily focus on standardized PQ schemes, selected additional signature competition candidates, and PQ-secure cutting-edge schemes beyond standardization. Finally, we present visions and potential future directions for a seamless transition to the PQ era.

Published
2023

4. Algorithmic Security is Insufficient: A Comprehensive Survey on Implementation Attacks Haunting Post-Quantum Security

Author

Canto, Alvaro Cintas, Kaur, Jasmin, Kermani, Mehran Mozaffari, and Azarderakhsh, Reza

Subjects
Computer Science - Cryptography and Security
Abstract

This survey is on forward-looking, emerging security concerns in post-quantum era, i.e., the implementation attacks for 2022 winners of NIST post-quantum cryptography (PQC) competition and thus the visions, insights, and discussions can be used as a step forward towards scrutinizing the new standards for applications ranging from Metaverse, Web 3.0 to deeply-embedded systems. The rapid advances in quantum computing have brought immense opportunities for scientific discovery and technological progress; however, it poses a major risk to today's security since advanced quantum computers are believed to break all traditional public-key cryptographic algorithms. This has led to active research on PQC algorithms that are believed to be secure against classical and powerful quantum computers. However, algorithmic security is unfortunately insufficient, and many cryptographic algorithms are vulnerable to side-channel attacks (SCA), where an attacker passively or actively gets side-channel data to compromise the security properties that are assumed to be safe theoretically. In this survey, we explore such imminent threats and their countermeasures with respect to PQC. We provide the respective, latest advancements in PQC research, as well as assessments and providing visions on the different types of SCAs.

Published
2023

5. A Comprehensive Survey on the Implementations, Attacks, and Countermeasures of the Current NIST Lightweight Cryptography Standard

Author

Kaur, Jasmin, Canto, Alvaro Cintas, Kermani, Mehran Mozaffari, and Azarderakhsh, Reza

Subjects
Computer Science - Cryptography and Security, Computer Science - Hardware Architecture, Computer Science - Computers and Society
Abstract

This survey is the first work on the current standard for lightweight cryptography, standardized in 2023. Lightweight cryptography plays a vital role in securing resource-constrained embedded systems such as deeply-embedded systems (implantable and wearable medical devices, smart fabrics, smart homes, and the like), radio frequency identification (RFID) tags, sensor networks, and privacy-constrained usage models. National Institute of Standards and Technology (NIST) initiated a standardization process for lightweight cryptography and after a relatively-long multi-year effort, eventually, in Feb. 2023, the competition ended with ASCON as the winner. This lightweight cryptographic standard will be used in deeply-embedded architectures to provide security through confidentiality and integrity/authentication (the dual of the legacy AES-GCM block cipher which is the NIST standard for symmetric key cryptography). ASCON's lightweight design utilizes a 320-bit permutation which is bit-sliced into five 64-bit register words, providing 128-bit level security. This work summarizes the different implementations of ASCON on field-programmable gate array (FPGA) and ASIC hardware platforms on the basis of area, power, throughput, energy, and efficiency overheads. The presented work also reviews various differential and side-channel analysis attacks (SCAs) performed across variants of ASCON cipher suite in terms of algebraic, cube/cube-like, forgery, fault injection, and power analysis attacks as well as the countermeasures for these attacks. We also provide our insights and visions throughout this survey to provide new future directions in different domains. This survey is the first one in its kind and a step forward towards scrutinizing the advantages and future directions of the NIST lightweight cryptography standard introduced in 2023.

Published
2023

6. Fully Hybrid TLSv1.3 in WolfSSL on Cortex-M4

Author

Anastasova, Mila, Azarderakhsh, Reza, Kermani, Mehran Mozaffari, Goos, Gerhard, Series Editor, Hartmanis, Juris, Founding Editor, van Leeuwen, Jan, Series Editor, Hutchison, David, Editorial Board Member, Kanade, Takeo, Editorial Board Member, Kittler, Josef, Editorial Board Member, Kleinberg, Jon M., Editorial Board Member, Kobsa, Alfred, Series Editor, Mattern, Friedemann, Editorial Board Member, Mitchell, John C., Editorial Board Member, Naor, Moni, Editorial Board Member, Nierstrasz, Oscar, Series Editor, Pandu Rangan, C., Editorial Board Member, Sudan, Madhu, Series Editor, Terzopoulos, Demetri, Editorial Board Member, Tygar, Doug, Editorial Board Member, Weikum, Gerhard, Series Editor, Vardi, Moshe Y, Series Editor, Bertino, Elisa, Editorial Board Member, Gao, Wen, Editorial Board Member, Steffen, Bernhard, Editorial Board Member, Yung, Moti, Editorial Board Member, Woeginger, Gerhard, Editorial Board Member, and Andreoni, Martin, editor

Published
2024
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8. Time-Optimal Design of Finite Field Arithmetic for SIKE on Cortex-M4

Author

Anastasova, Mila, Azarderakhsh, Reza, Kermani, Mehran Mozaffari, Goos, Gerhard, Founding Editor, Hartmanis, Juris, Founding Editor, Bertino, Elisa, Editorial Board Member, Gao, Wen, Editorial Board Member, Steffen, Bernhard, Editorial Board Member, Yung, Moti, Editorial Board Member, You, Ilsun, editor, and Youn, Taek-Young, editor

Published
2023
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11. Efficient Algorithm Level Error Detection for Number-Theoretic Transform Assessed on FPGAs

Author

Ahmadi, Kasra, Aghapour, Saeed, Kermani, Mehran Mozaffari, Azarderakhsh, Reza, Ahmadi, Kasra, Aghapour, Saeed, Kermani, Mehran Mozaffari, and Azarderakhsh, Reza

Abstract

Polynomial multiplication stands out as a highly demanding arithmetic process in the development of post-quantum cryptosystems. The importance of number-theoretic transform (NTT) extends beyond post-quantum cryptosystems, proving valuable in enhancing existing security protocols such as digital signature schemes and hash functions. Due to the potential for errors to significantly disrupt the operation of secure, cryptographically-protected systems, compromising data integrity, and safeguarding against side-channel attacks initiated through faults it is essential to incorporate mitigating error detection schemes. This paper introduces algorithm level fault detection schemes in NTT multiplication, representing a significant enhancement compared to previous research. We evaluate this through the simulation of a fault model, ensuring that the conducted assessments accurately mirror the obtained results. Consequently, we attain a notably comprehensive coverage of errors. Finally, we assess the performance of our efficient error detection scheme on FPGAs to showcase its implementation and resource requirements. Through implementation of our error detection approach on Xilinx/AMD Zynq Ultrascale+ and Artix-7, we achieve a comparable throughput with just a 9% increase in area and 13% increase in latency compared to the original hardware implementations., Comment: 5 Pages, 4 Figures, and 3 Tables

Published
2024

26. Reliable Constructions for the Key Generator of Code-based Post-quantum Cryptosystems on FPGA.

Author

CANTO, ALVARO CINTAS, KERMANI, MEHRAN MOZAFFARI, and AZARDERAKHSH, REZA

Subjects
CRYPTOSYSTEMS, PUBLIC key cryptography, GATE array circuits, QUANTUM computing, RSA algorithm, CRYPTOGRAPHY
Abstract

Advances in quantum computing have urged the need for cryptographic algorithms that are low-power, lowenergy, and secure against attacks that can be potentially enabled. For this post-quantum age, different solutions have been studied. Code-based cryptography is one feasible solutionwhose hardware architectures have become the focus of research in the NIST standardization process and has been advanced to the final round (to be concluded by 2022-2024). Nevertheless, although these constructions, e.g., McEliece and Niederreiter public key cryptography, have strong error correction properties, previous studies have proved the vulnerability of their hardware implementations against faults product of the environment and intentional faults, i.e., differential fault analysis. It is previously shown that depending on the codes used, i.e., classical or reduced (using either quasi-dyadic Goppa codes or quasi-cyclic alternant codes), flaws in error detection could be observed. In this work, efficient fault detection constructions are proposed for the first time to account for such shortcomings. Such schemes are based on regular parity, interleaved parity, and two different cyclic redundancy checks (CRC), i.e., CRC-2 and CRC-8. Without losing the generality, we experiment on the McEliece variant, noting that the presented schemes can be used for other code-based cryptosystems. We perform error detection capability assessments and implementations on field-programmable gate array Kintex-7 device xc7k70tfbv676-1 to verify the practicality of the presented approaches. To demonstrate the appropriateness for constrained embedded systems, the performance degradation and overheads of the presented schemes are assessed. [ABSTRACT FROM AUTHOR]

Published
2023
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27. Error Detection Constructions for ITA Finite Field Inversions Over <inline-formula><tex-math notation="LaTeX">$\text{GF}(2^{m})$</tex-math></inline-formula> on FPGA Using CRC and Hamming Codes

Author

Cintas-Canto, Alvaro, Kermani, Mehran Mozaffari, and Azarderakhsh, Reza

Abstract

Finite field arithmetic operations over $\text{GF}(2^{m})$ are widely used in critical applications, such as cryptography, coding theory, error-correcting codes, and digital signal processing. Finite field inversions are the most time-consuming operations among other widely-used ones and require a large footprint as well as power/energy to be performed. To reduce such complexity, the Itoh–Tsujii algorithm (ITA) has received prominent attention in the literature; however, implementations using ITA are still vulnerable to natural very-large-scale integration defects. To overcome the challenge of detecting naturally-induced faults in such constructions, for the first time, we propose error detection schemes based on Hamming codes for architectures performing finite field inversions using the ITA algorithm over $\text{GF}(2^{m})$ with polynomial basis. Additionally, CRC-oriented error detection schemes for inversions in $\text{GF}(2^{m})$ with normal basis are also studied and new approaches to protect them are presented. In this article, general formulations are provided along with different case studies to show the feasibility of our schemes with any finite field size. Moreover, field-programmable gate array (FPGA) implementations are performed on two Xilinx FPGA families, i.e., Kintex UltraScale+ and Xilinx Virtex-7 UltraScale+, to verify that the overheads added by the error detection architectures to provide reliability are suitable for deeply-constrained embedded systems.

Published
2023
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