Commit cdbb9ce3 authored by Nouri-Alnahawi's avatar Nouri-Alnahawi
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add new papers for NIST conference

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......@@ -11,22 +11,27 @@ Evaluation of the performance of PQC algorithms in various facets, classified in
- PQC evaluation on selected hardware:
- [On Feasibility of Post-Quantum Cryptography on Small Devices](https://www.sciencedirect.com/science/article/pii/S2405896318308474) Experimental post-quantum cryptography implementations on small devices with different platforms [[MPD+18]](../../refs#mpd18)
- [Towards Practical Deployment of Post-quantum Cryptography on Constrained Platforms and Hardware-Accelerated Platforms](https://link.springer.com/chapter/10.1007/978-3-030-41025-4_8) Evaluation of the NIST candidates regarding their suitability for the implementation on special hardware platforms [[MRD+20]](../../refs#mrd20)
- [Rainbow on Cortex-M4](https://kannwischer.eu/papers/2021_rainbowm4.pdf) Cortex-M4 implementation of the NIST PQC signature finalist Rainbow [[TKY21]](../../refs#tky21)
- [Classic McEliece on the ARM Cortex-M4](https://eprint.iacr.org/2021/492.pdf) Constant-time implementation of Classic McEliece for ARM Cortex-M4 [[ChCh21]](../../refs#chch21)
- [Verifying Post-Quantum Signatures in 8 kB of RAM](https://kannwischer.eu/papers/2021_streamingpqc.pdf) Verification of NIST PQC round-3 signature scheme candidates Dilithium, Falcon, Rainbow, GeMSS, and SPHINCS+ [[GHK+21]](../../refs#ghk21)
- Improvements to PQC algorithms:
- [Performance Optimization of Lattice Post-Quantum Cryptographic Algorithms on Many-Core Processors](https://ieeexplore.ieee.org/abstract/document/9238630?casa_token=j7T_SBR8ECgAAAAA:Skx0Ze-JY3YP5CSLn20TOmrWviAP_-aUZ0b9W_gpR5fDpO8AWLigR52JC4qZVPTbLlIzv-3p2g) 52% and 83% improvement in performance for the CRYSTALS-Kyber KEM SHA3 variant and AES variant through Vectorization [[KKP20]](../../refs#kkp20)
- [Memory-Efficient High-Speed Implementation of Kyber on Cortex-M4](http://link.springer.com/10.1007/978-3-030-23696-0_11) Optimized software implementation of Kyber for the ARM Cortex-M4 microcontroller [[BKS19]](../../refs#bks19)
- [CTIDH: Faster Constant-Time CSIDH](https://eprint.iacr.org/2021/633.pdf) Speed records for constant-time CSIDH (Commutative Supersingular Isogeny Diffie–Hellman) through combining a new key space with a new algorithm [[BBC+21]](../../refs#bbc21)
- [BUFFing signature schemes beyond unforgeability and the case of post-quantum signatures](https://publications.cispa.saarland/3417/1/Buff.pdf) In-depth analysis of the NIST signature scheme candidates with respect to their security properties beyond unforgeability [[CDF+21]](../../refs#cdf21)
- PQC evaluation on selected architectures:
- [Towards Post-Quantum Security for Cyber-Physical Systems: Integrating PQC into Industrial M2M Communication](https://link.springer.com/chapter/10.1007/978-3-030-59013-0_15) Two solutions for the integration of PQ primitives into the industrial protocol Open Platform Communications Unified Architecture (OPC UA) [[PASC20]](../../refs#pasc20)
- [Incorporating Post-Quantum Cryptographyin a Microservice Environment](https://homepages.staff.os3.nl/~delaat/rp/2019-2020/p13/report.pdf) On the practical feasibility of using PQCin a microservice architecture [[WvdG20]](../../refs#wvdg20)
- [Portable Implementation of Postquantum Encryption Schemes and Key Exchange Protocols on JavaScript-Enabled Platforms](https://www.hindawi.com/journals/scn/2018/9846168/) Implementation of several lattice-based encryption schemes and public-key exchange protocols including Lizard, ring-Lizard, Kyber, Frodo, and NewHope in JavaScript [[YXF+18]](../../refs#yxf18)
- PQC in IoT:
- PQC evaluation in IoT:
- [From Pre-Quantum to Post-Quantum IoT Security: A Survey on Quantum-Resistant Cryptosystems for the Internet of Things](https://ieeexplore.ieee.org/abstract/document/8932459) A wide view of post-quantum IoT security and give useful guidelines [[FC20]](../../refs#fc20)
- PQC in Distributed Ledger:
- PQC evaluation in Distributed Ledger:
- [Evaluation of Post-Quantum Distributed Ledger Cryptography](https://jbba.scholasticahq.com/article/7679.pdf): Performance evaluation of qTesla in BC and DLTs [[Cam19]](../../refs#cam19)
##### **Hardware Performance**
- CRYSTALS-Dilithium and qTesla:
- Hardware implementations:
- [NIST Post-Quantum Cryptography - A Hardware Evaluation Study](https://eprint.iacr.org/2019/047) A hardware-based comparison of the NIST PQC candidates [[BSNK19]](../../refs#bsnk19)
- [Hardware Deployment of Hybrid PQC](https://eprint.iacr.org/2021/541.pdf) Small architecture for quantum-safe hybrid key exchange targeting ECDH and SIKE [[AEK+21]](../../refs#aek21)
- Performance critical use cases:
- [Ultra-Fast Modular Multiplication Implementation for Isogeny-Based Post-Quantum Cryptography](https://ieeexplore.ieee.org/document/9020384) Improved unconventional-radix finite-field multiplication (IFFM) algorithm reducing computational complexity by about 20% [[TLW19]](../../refs#tlw19)
- FPGA performance benefits:
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......@@ -14,6 +14,7 @@ weight: 3
##### **Cryptanalysis**
- Anonymity:
- [NTRU leads to Anonymous, Robust Public-Key Encryption](https://eprint.iacr.org/2021/741.pdf) Solution to the open problem of the anonymity and robustness of NTRU [[Xag21]](../../refs#xag21)
- [Anonymous, Robust Post-Quantum Public Key Encryption](https://eprint.iacr.org/2021/708.pdf) Study of the anonymity and robustness of NIST finalists Classic McEliece, Kyber, NTRU and Saber [[GMP21]](../../refs#gmp21)
- PQC schemes broken by cryptanalysis:
- [Cryptanalysis of the Lifted Unbalanced Oil Vinegar Signature Scheme](https://eprint.iacr.org/2019/1490.pdf): A new type of attack called Subfield Differential Attack (SDA) on Lifted Unbalanced Oil and Vinegar (LUOV) [[DDS+20]](../../refs#dds20)
- [Quantum cryptanalysis on some generalized Feistel schemes](https://eprint.iacr.org/2017/1249.pdf): Quantum distinguishers to introduce generic quantum key-recovery attacks [[DLW19]](../../refs#dlw19)
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......@@ -30,6 +30,9 @@ weight: 8
###### [ADPS16]
[E. Alkim, L. Ducas, T. Pöppelmann, and P. Schwabe. Post-quantum key exchange—a new hope. In 25Th {USENIX } security symposium ( {USENIX } security 16), pages 327–343, 2016](https://eprint.iacr.org/2015/1092.pdf)
###### [AEK+21]
[Azarderakhsh, R., El Khatib, R., Koziel, B., & Langenberg, B. (2021). Hardware Deployment of Hybrid PQC. IACR Cryptol. ePrint Arch., 2021, 541.](https://eprint.iacr.org/2021/541.pdf)
###### [AJO+20]
[Alagic G, Jeffery S, Ozols M, Poremba A. On Quantum Chosen-Ciphertext Attacks and Learning with Errors. Cryptography. 2020; 4(1):10. https://doi.org/10.3390/cryptography4010010](https://www.mdpi.com/2410-387X/4/1/10)
......@@ -102,6 +105,12 @@ weight: 8
###### [CDH+19]
[C. Chen, O. Danba, J. Hoffstein, A. Hülsing, J. Rijneveld, J. M Schanck, P. Schwabe, W. Whyte, and Z. Zhang. Ntru algorithm specifications and supporting documentation. Round-3 submission to the NIST PQC project, March 2019](https://ntru.org/f/ntru-20190330.pdf)
###### [CDF+21]
[Cremers, C., Düzlü, S., Fiedler, R., Fischlin, M., & Janson, C. (2021). BUFFing signature schemes beyond unforgeability and the case of post-quantum signatures. In Proceedings of the 42nd IEEE Symposium on Security and Privacy (S&P'21). IEEE Press.](https://publications.cispa.saarland/3417/)
###### [ChCh21]
[Chen, Ming-Shing, and Tung Chou. "Classic McEliece on the ARM Cortex-M4." IACR Cryptol. ePrint Arch. 2021 (2021): 492.](https://eprint.iacr.org/2021/492.pdf)
###### [CFP+19]
[Casanova, J. C. Faugere, G. M. R. J. Patarin, L. Perret, and J. Ryckeghem.2019. GeMSS: a great multivariate short signature.Submission to NIST PQCcompetition Round-2(2019)](https://www-polsys.lip6.fr/Links/NIST/GeMSS_specification.pdf)
......@@ -147,9 +156,15 @@ weight: 8
###### [FMK19]
[Fluhrer, S., McGrew, D., Kampanakis, P., & Smyslov, V. (2019). Postquantum preshared keys for IKEv2. Internet Engineering Task Force, Internet-Draft draft-ietf-ipsecme-qr-ikev2-11.](https://datatracker.ietf.org/doc/html/draft-ietf-ipsecme-qr-ikev2-11)
###### [GHK+21]
[Gonzalez, Ruben, Andreas Hülsing, Matthias J. Kannwischer, Juliane Krämer, Tanja Lange, Marc Stöttinger, Elisabeth Waitz, Thom Wiggers, and Bo-Yin Yang. "Verifying Post-Quantum Signatures in 8 kB of RAM." (2021).](https://kannwischer.eu/papers/2021_streamingpqc.pdf)
###### [GKT13]
[R. Gagliano, S. Kent, and S. Turner. Algorithm Agility Procedure for the Resource Public Key Infrastructure (RPKI). Request for Comments. 2013. RFC 6916.](https://tools.ietf.org/html/rfc6916)
###### [GMP21]
[Grubbs, Paul, Varun Maram, and Kenneth G. Paterson. Anonymous, Robust Post-Quantum Public Key Encryption. Cryptology ePrint Archive, Report 2021/708, 2021. h ps://eprint. iacr. org/2021/708. 1, 5, 7, 13, 14, 2021.](https://eprint.iacr.org/2021/708.pdf)
###### [GoKa15]
[Ghosh, S., & Kate, A. (2015, June). Post-quantum forward-secure onion routing. In International Conference on Applied Cryptography and Network Security (pp. 263-286). Springer, Cham](https://ieeexplore.ieee.org/abstract/document/9363165)
......@@ -312,6 +327,9 @@ weight: 8
###### [SWZ16]
[Schanck, John M., William Whyte, and Zhenfei Zhang. "Quantum-safe hybrid (QSH) ciphersuite for Transport Layer Security (TLS) version 1.2." IETF, Internet-Draft draft-whyte-qsh-tls (2016)](https://datatracker.ietf.org/doc/html/draft-whyte-qsh-tls12-02)
###### [TKY21]
[Chou, Tung, Matthias J. Kannwischer, and Bo-Yin Yang. "Rainbow on Cortex-M4." IACR Cryptol. ePrint Arch. 2021 (2021): 532.](https://kannwischer.eu/papers/2021_rainbowm4.pdf)
###### [TLW19]
[J. Tian, J. Lin, and Z. Wang. 2019. Ultra-Fast Modular Multiplication Implementa-tion for Isogeny-Based Post-Quantum Cryptography. In2019 IEEE InternationalWorkshop on Signal Processing Systems (SiPS). 97–102 doi:10.1109/SiPS47522.2019.9020384](https://ieeexplore.ieee.org/document/9020384)
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