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David Jao
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2020 – today
- 2024
- [i24]Youcef Mokrani, David Jao:
Zero-Knowledge Proofs for SIDH variants with Masked Degree or Torsion. IACR Cryptol. ePrint Arch. 2024: 56 (2024) - [i23]Christopher Battarbee, Giacomo Borin, Ryann Cartor, Nadia Heninger, David Jao, Laura Maddison, Edoardo Persichetti, Angela Robinson, Daniel Smith-Tone, Rainer Steinwandt:
On the Semidirect Discrete Logarithm Problem in Finite Groups. IACR Cryptol. ePrint Arch. 2024: 905 (2024) - [i22]David Jao, Jeanne Laflamme:
Isogeny interpolation and the computation of isogenies from higher dimensional representations. IACR Cryptol. ePrint Arch. 2024: 1796 (2024) - 2023
- [c33]Youcef Mokrani, David Jao
:
Generating Supersingular Elliptic Curves over $\mathbb {F}_p$ with Unknown Endomorphism Ring. INDOCRYPT (1) 2023: 159-174 - [c32]Youcef Mokrani, David Jao
Zero-Knowledge Proofs for SIDH Variants with Masked Degree or Torsion. SPACE 2023: 48-65 - [i21]Youcef Mokrani, David Jao:
Generating Supersingular Elliptic Curves over 픽p with Unknown Endomorphism Ring. IACR Cryptol. ePrint Arch. 2023: 984 (2023) - 2022
- [c31]Yen-Kang Fu, Jonathan Chang, David Jao:
Optimal Generic Attack Against Basic Boneh-Boyen Signatures. ISPEC 2022: 505-519 - 2021
- [j11]Geovandro C. C. F. Pereira
x-only point addition formula and faster compressed SIKE. J. Cryptogr. Eng. 11(1): 57-69 (2021) - [j10]Oleg Taraskin, Vladimir Soukharev, David Jao
Towards Isogeny-Based Password-Authenticated Key Establishment. J. Math. Cryptol. 15(1): 18-30 (2021) - [c30]Edward Eaton, David Jao, Chelsea Komlo, Youcef Mokrani:
Towards Post-Quantum Key-Updatable Public-Key Encryption via Supersingular Isogenies. SAC 2021: 461-482 - 2020
- [j9]David Urbanik, David Jao
New Techniques for SIDH-based NIKE. J. Math. Cryptol. 14(1): 120-128 (2020) - [j8]David Jao
A subexponential-time, polynomial quantum space algorithm for inverting the CM group action. J. Math. Cryptol. 14(1): 129-138 (2020) - [c29]Reza Azarderakhsh, David Jao
How Not to Create an Isogeny-Based PAKE. ACNS (1) 2020: 169-186 - [i20]Reza Azarderakhsh, David Jao, Brian Koziel, Jason T. LeGrow, Vladimir Soukharev, Oleg Taraskin:
How Not to Create an Isogeny-Based PAKE. IACR Cryptol. ePrint Arch. 2020: 361 (2020) - [i19]Geovandro C. C. F. Pereira, Javad Doliskani, David Jao:
x-only point addition formula and faster torsion basis generation in compressed SIKE. IACR Cryptol. ePrint Arch. 2020: 431 (2020) - [i18]Edward Eaton, David Jao, Chelsea Komlo:
Towards Post-Quantum Updatable Public-Key Encryption via Supersingular Isogenies. IACR Cryptol. ePrint Arch. 2020: 1593 (2020)
2010 – 2019
- 2019
- [j7]Amir Jalali
ARMv8 SIKE: Optimized Supersingular Isogeny Key Encapsulation on ARMv8 Processors. IEEE Trans. Circuits Syst. I Regul. Pap. 66-I(11): 4209-4218 (2019) - [j6]Amir Jalali
Supersingular Isogeny Diffie-Hellman Key Exchange on 64-Bit ARM. IEEE Trans. Dependable Secur. Comput. 16(5): 902-912 (2019) - [c28]Amir Jalali, Reza Azarderakhsh, Mehran Mozaffari Kermani
Towards Optimized and Constant-Time CSIDH on Embedded Devices. COSADE 2019: 215-231 - [c27]Xiu Xu, Christopher Leonardi, Anzo Teh, David Jao
Improved Digital Signatures Based on Elliptic Curve Endomorphism Rings. ISPEC 2019: 293-309 - [i17]Amir Jalali, Reza Azarderakhsh, Mehran Mozaffari Kermani, David Jao:
Towards Optimized and Constant-Time CSIDH on Embedded Devices. IACR Cryptol. ePrint Arch. 2019: 297 (2019) - [i16]Reza Azarderakhsh, Amir Jalali, David Jao, Vladimir Soukharev:
Practical Supersingular Isogeny Group Key Agreement. IACR Cryptol. ePrint Arch. 2019: 330 (2019) - [i15]Amir Jalali, Reza Azarderakhsh, Mehran Mozaffari Kermani, Matthew Campagna, David Jao:
Optimized Supersingular Isogeny Key Encapsulation on ARMv8 Processors. IACR Cryptol. ePrint Arch. 2019: 331 (2019) - 2018
- [c26]David Urbanik, David Jao
SoK: The Problem Landscape of SIDH. APKC@AsiaCCS 2018: 53-60 - [c25]Brian Koziel, Reza Azarderakhsh, David Jao
An Exposure Model for Supersingular Isogeny Diffie-Hellman Key Exchange. CT-RSA 2018: 452-469 - [c24]Reza Azarderakhsh, Elena Bakos Lang, David Jao
EdSIDH: Supersingular Isogeny Diffie-Hellman Key Exchange on Edwards Curves. SPACE 2018: 125-141 - [i14]Jason T. LeGrow, David Jao, Reza Azarderakhsh:
Modeling Quantum-Safe Authenticated Key Establishment, and an Isogeny-Based Protocol. IACR Cryptol. ePrint Arch. 2018: 282 (2018) - [i13]David Urbanik, David Jao:
SoK: The Problem Landscape of SIDH. IACR Cryptol. ePrint Arch. 2018: 336 (2018) - [i12]Oleg Taraskin, Vladimir Soukharev, David Jao, Jason T. LeGrow:
An Isogeny-Based Password-Authenticated Key Establishment Protocol. IACR Cryptol. ePrint Arch. 2018: 886 (2018) - 2017
- [j5]Brian Koziel, Reza Azarderakhsh, Mehran Mozaffari Kermani
Post-Quantum Cryptography on FPGA Based on Isogenies on Elliptic Curves. IEEE Trans. Circuits Syst. I Regul. Pap. 64-I(1): 86-99 (2017) - [j4]Reza Azarderakhsh, Dieter Fishbein, Gurleen Grewal, Shi Hu, David Jao
Fast Software Implementations of Bilinear Pairings. IEEE Trans. Dependable Secur. Comput. 14(6): 605-619 (2017) - [c23]Craig Costello
Efficient Compression of SIDH Public Keys. EUROCRYPT (1) 2017: 679-706 - [c22]Youngho Yoo, Reza Azarderakhsh, Amir Jalali, David Jao
A Post-quantum Digital Signature Scheme Based on Supersingular Isogenies. Financial Cryptography 2017: 163-181 - [c21]Brian Koziel, Reza Azarderakhsh, David Jao:
On secure implementations of quantum-resistant supersingular isogeny Diffie-Hellman. HOST 2017: 160 - [c20]Reza Azarderakhsh, David Jao
Post-Quantum Static-Static Key Agreement Using Multiple Protocol Instances. SAC 2017: 45-63 - [c19]Brian Koziel, Reza Azarderakhsh, David Jao
Side-Channel Attacks on Quantum-Resistant Supersingular Isogeny Diffie-Hellman. SAC 2017: 64-81 - [i11]Youngho Yoo, Reza Azarderakhsh, Amir Jalali, David Jao, Vladimir Soukharev:
A Post-Quantum Digital Signature Scheme Based on Supersingular Isogenies. IACR Cryptol. ePrint Arch. 2017: 186 (2017) - 2016
- [c18]Brian Koziel, Amir Jalali, Reza Azarderakhsh, David Jao
NEON-SIDH: Efficient Implementation of Supersingular Isogeny Diffie-Hellman Key Exchange Protocol on ARM. CANS 2016: 88-103 - [c17]Reza Azarderakhsh, David Jao
Key Compression for Isogeny-Based Cryptosystems. AsiaPKC@AsiaCCS 2016: 1-10 - [c16]Brian Koziel, Reza Azarderakhsh, David Jao
On Fast Calculation of Addition Chains for Isogeny-Based Cryptography. Inscrypt 2016: 323-342 - [c15]Vladimir Soukharev, David Jao
Post-Quantum Security Models for Authenticated Encryption. PQCrypto 2016: 64-78 - [i10]Reza Azarderakhsh, David Jao, Kassem Kalach, Brian Koziel, Christopher Leonardi:
Key Compression for Isogeny-Based Cryptosystems. IACR Cryptol. ePrint Arch. 2016: 229 (2016) - [i9]Reza Azarderakhsh, Brian Koziel, Amir Jalali, Mehran Mozaffari Kermani, David Jao:
NEON-SIDH: Effi cient Implementation of Supersingular Isogeny Diffi e-Hellman Key-Exchange Protocol on ARM. IACR Cryptol. ePrint Arch. 2016: 669 (2016) - [i8]Craig Costello, David Jao, Patrick Longa, Michael Naehrig, Joost Renes, David Urbanik:
Efficient compression of SIDH public keys. IACR Cryptol. ePrint Arch. 2016: 963 (2016) - [i7]Brian Koziel, Reza Azarderakhsh, David Jao, Mehran Mozaffari Kermani:
On Fast Calculation of Addition Chains for Isogeny-Based Cryptography. IACR Cryptol. ePrint Arch. 2016: 1045 (2016) - 2015
- [j3]Reza Azarderakhsh, David Jao
Common Subexpression Algorithms for Space-Complexity Reduction of Gaussian Normal Basis Multiplication. IEEE Trans. Inf. Theory 61(5): 2357-2369 (2015) - 2014
- [j2]Andrew M. Childs
Constructing elliptic curve isogenies in quantum subexponential time. J. Math. Cryptol. 8(1): 1-29 (2014) - [j1]Luca De Feo
Towards quantum-resistant cryptosystems from supersingular elliptic curve isogenies. J. Math. Cryptol. 8(3): 209-247 (2014) - [c14]Jean-François Biasse
A Quantum Algorithm for Computing Isogenies between Supersingular Elliptic Curves. INDOCRYPT 2014: 428-442 - [c13]David Jao
Isogeny-Based Quantum-Resistant Undeniable Signatures. PQCrypto 2014: 160-179 - 2012
- [c12]Gurleen Grewal, Reza Azarderakhsh, Patrick Longa, Shi Hu, David Jao
Efficient Implementation of Bilinear Pairings on ARM Processors. Selected Areas in Cryptography 2012: 149-165 - [i6]Gurleen Grewal, Reza Azarderakhsh, Patrick Longa, Shi Hu, David Jao:
Efficient Implementation of Bilinear Pairings on ARM Processors. IACR Cryptol. ePrint Arch. 2012: 408 (2012) - 2011
- [c11]Roy D'Souza, David Jao
Publicly Verifiable Secret Sharing for Cloud-Based Key Management. INDOCRYPT 2011: 290-309 - [c10]David Jao
Towards Quantum-Resistant Cryptosystems from Supersingular Elliptic Curve Isogenies. PQCrypto 2011: 19-34 - [i5]David Jao, Luca De Feo:
Towards quantum-resistant cryptosystems from supersingular elliptic curve isogenies. IACR Cryptol. ePrint Arch. 2011: 506 (2011) - 2010
- [c9]David Jao
A Subexponential Algorithm for Evaluating Large Degree Isogenies. ANTS 2010: 219-233 - [p1]David Jao:
Elliptic Curve Cryptography. Handbook of Information and Communication Security 2010: 35-57 - [i4]Andrew M. Childs, David Jao, Vladimir Soukharev:
Constructing elliptic curve isogenies in quantum subexponential time. CoRR abs/1012.4019 (2010)
2000 – 2009
- 2009
- [c8]Colleen Swanson, David Jao
A Study of Two-Party Certificateless Authenticated Key-Agreement Protocols. INDOCRYPT 2009: 57-71 - [c7]David Jao
Boneh-Boyen Signatures and the Strong Diffie-Hellman Problem. Pairing 2009: 1-16 - [i3]David Jao, Kayo Yoshida:
Boneh-Boyen signatures and the Strong Diffie-Hellman problem. IACR Cryptol. ePrint Arch. 2009: 221 (2009) - 2008
- [c6]Xinxin Fan, Guang Gong, David Jao
Speeding Up Pairing Computations on Genus 2 Hyperelliptic Curves with Efficiently Computable Automorphisms. Pairing 2008: 243-264 - [c5]Xinxin Fan, Guang Gong, David Jao
Efficient Pairing Computation on Genus 2 Curves in Projective Coordinates. Selected Areas in Cryptography 2008: 18-34 - 2007
- [c4]David Jao
On the Bits of Elliptic Curve Diffie-Hellman Keys. INDOCRYPT 2007: 33-47 - [c3]David Jao
Digit Set Randomization in Elliptic Curve Cryptography. SAGA 2007: 105-117 - 2005
- [c2]David Jao
Do All Elliptic Curves of the Same Order Have the Same Difficulty of Discrete Log? ASIACRYPT 2005: 21-40 - [c1]Qiang Huang, David Jao
Applications of secure electronic voting to automated privacy-preserving troubleshooting. CCS 2005: 68-80 - 2004
- [i2]David Jao, Stephen D. Miller, Ramarathnam Venkatesan:
Ramanujan Graphs and the Random Reducibility of Discrete Log on Isogenous Elliptic Curves. CoRR math.NT/0411378 (2004) - [i1]David Jao, Stephen D. Miller, Ramarathnam Venkatesan:
Ramanujan Graphs and the Random Reducibility of Discrete Log on Isogenous Elliptic Curves. IACR Cryptol. ePrint Arch. 2004: 312 (2004)
Coauthor Index
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last updated on 2024-11-11 21:30 CET by the dblp team
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