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ORCIDAriel Nof
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- affiliation: Bar-Ilan University, Ramat-Gan, Israel
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2020 – today
- 2024
[c20]Anders P. K. Dalskov, Daniel Escudero, Ariel Nof:
Fully Secure MPC and zk-FLIOP over Rings: New Constructions, Improvements and Extensions. CRYPTO (8) 2024: 136-169- [i17]Gilad Asharov, Koki Hamada, Dai Ikarashi, Ryo Kikuchi, Ariel Nof, Benny Pinkas, Junichi Tomida:
Secure Statistical Analysis on Multiple Datasets: Join and Group-By. IACR Cryptol. ePrint Arch. 2024: 141 (2024) - [i16]Anders P. K. Dalskov, Daniel Escudero, Ariel Nof:
Fully Secure MPC and zk-FLIOP Over Rings: New Constructions, Improvements and Extensions. IACR Cryptol. ePrint Arch. 2024: 837 (2024) - 2023
- [j3]Koji Chida, Koki Hamada, Dai Ikarashi, Ryo Kikuchi, Daniel Genkin, Yehuda Lindell, Ariel Nof:
Fast Large-Scale Honest-Majority MPC for Malicious Adversaries. J. Cryptol. 36(3): 15 (2023) - [j2]Jun Furukawa
, Yehuda Lindell, Ariel Nof, Or Weinstein:
High-Throughput Secure Three-Party Computation with an Honest Majority. J. Cryptol. 36(3): 21 (2023) - [c19]Gilad Asharov, Koki Hamada, Ryo Kikuchi, Ariel Nof, Benny Pinkas, Junichi Tomida:
Secure Statistical Analysis on Multiple Datasets: Join and Group-By. CCS 2023: 3298-3312 - 2022
- [c18]Gilad Asharov, Koki Hamada, Dai Ikarashi, Ryo Kikuchi, Ariel Nof, Benny Pinkas, Katsumi Takahashi, Junichi Tomida:
Efficient Secure Three-Party Sorting with Applications to Data Analysis and Heavy Hitters. CCS 2022: 125-138 - [c17]Anders P. K. Dalskov, Daniel Escudero, Ariel Nof:
Fast Fully Secure Multi-Party Computation over Any Ring with Two-Thirds Honest Majority. CCS 2022: 653-666 - [c16]Elette Boyle, Niv Gilboa, Yuval Ishai, Ariel Nof:
Secure Multiparty Computation with Sublinear Preprocessing. EUROCRYPT (1) 2022: 427-457 - [c15]Damiano Abram, Ariel Nof, Claudio Orlandi, Peter Scholl, Omer Shlomovits:
Low-Bandwidth Threshold ECDSA via Pseudorandom Correlation Generators. SP 2022: 2554-2572 - [i15]Elette Boyle, Niv Gilboa, Yuval Ishai, Ariel Nof:
Sublinear GMW-Style Compiler for MPC with Preprocessing. IACR Cryptol. ePrint Arch. 2022: 261 (2022) - [i14]Anders P. K. Dalskov, Daniel Escudero, Ariel Nof:
Fast Fully Secure Multi-Party Computation over Any Ring with Two-Thirds Honest Majority. IACR Cryptol. ePrint Arch. 2022: 623 (2022) - [i13]Gilad Asharov, Koki Hamada, Dai Ikarashi, Ryo Kikuchi, Ariel Nof, Benny Pinkas, Katsumi Takahashi, Junichi Tomida:
Efficient Secure Three-Party Sorting with Applications to Data Analysis and Heavy Hitters. IACR Cryptol. ePrint Arch. 2022: 1595 (2022) - 2021
- [c14]Mark Abspoel, Anders P. K. Dalskov, Daniel Escudero, Ariel Nof:
An Efficient Passive-to-Active Compiler for Honest-Majority MPC over Rings. ACNS (2) 2021: 122-152 - [c13]Elette Boyle, Niv Gilboa, Yuval Ishai, Ariel Nof:
Sublinear GMW-Style Compiler for MPC with Preprocessing. CRYPTO (2) 2021: 457-485 - [c12]Fabrice Benhamouda, Elette Boyle, Niv Gilboa, Shai Halevi, Yuval Ishai, Ariel Nof:
Generalized Pseudorandom Secret Sharing and Efficient Straggler-Resilient Secure Computation. TCC (2) 2021: 129-161 - [i12]Fabrice Benhamouda, Elette Boyle, Niv Gilboa, Shai Halevi, Yuval Ishai, Ariel Nof:
Generalized Pseudorandom Secret Sharing and Efficient Straggler-Resilient Secure Computation. IACR Cryptol. ePrint Arch. 2021: 1223 (2021) - [i11]Damiano Abram, Ariel Nof, Claudio Orlandi, Peter Scholl, Omer Shlomovits:
Low-Bandwidth Threshold ECDSA via Pseudorandom Correlation Generators. IACR Cryptol. ePrint Arch. 2021: 1587 (2021) - 2020
- [c11]Elette Boyle, Niv Gilboa, Yuval Ishai, Ariel Nof:
Efficient Fully Secure Computation via Distributed Zero-Knowledge Proofs. ASIACRYPT (3) 2020: 244-276 - [c10]Carsten Baum, Ariel Nof:
Concretely-Efficient Zero-Knowledge Arguments for Arithmetic Circuits and Their Application to Lattice-Based Cryptography. Public Key Cryptography (1) 2020: 495-526 - [i10]Elette Boyle, Niv Gilboa, Yuval Ishai, Ariel Nof:
Efficient Fully Secure Computation via Distributed Zero-Knowledge Proofs. IACR Cryptol. ePrint Arch. 2020: 1451 (2020)
2010 – 2019
- 2019
- [c9]Elette Boyle, Niv Gilboa, Yuval Ishai, Ariel Nof:
Practical Fully Secure Three-Party Computation via Sublinear Distributed Zero-Knowledge Proofs. CCS 2019: 869-886 - [i9]Carsten Baum, Ariel Nof:
Concretely-Efficient Zero-Knowledge Arguments for Arithmetic Circuits and Their Application to Lattice-Based Cryptography. IACR Cryptol. ePrint Arch. 2019: 532 (2019) - [i8]Mark Abspoel, Anders P. K. Dalskov, Daniel Escudero, Ariel Nof:
An Efficient Passive-to-Active Compiler for Honest-Majority MPC over Rings. IACR Cryptol. ePrint Arch. 2019: 1298 (2019) - [i7]Elette Boyle, Niv Gilboa, Yuval Ishai, Ariel Nof:
Practical Fully Secure Three-Party Computation via Sublinear Distributed Zero-Knowledge Proofs. IACR Cryptol. ePrint Arch. 2019: 1390 (2019) - 2018
- [j1]Shay Gueron, Yehuda Lindell, Ariel Nof, Benny Pinkas:
Fast Garbling of Circuits Under Standard Assumptions. J. Cryptol. 31(3): 798-844 (2018) - [c8]Yehuda Lindell, Ariel Nof:
Fast Secure Multiparty ECDSA with Practical Distributed Key Generation and Applications to Cryptocurrency Custody. CCS 2018: 1837-1854 - [c7]Koji Chida, Daniel Genkin, Koki Hamada, Dai Ikarashi, Ryo Kikuchi, Yehuda Lindell, Ariel Nof:
Fast Large-Scale Honest-Majority MPC for Malicious Adversaries. CRYPTO (3) 2018: 34-64 - [i6]Koji Chida, Daniel Genkin, Koki Hamada, Dai Ikarashi, Ryo Kikuchi, Yehuda Lindell, Ariel Nof:
Fast Large-Scale Honest-Majority MPC for Malicious Adversaries. IACR Cryptol. ePrint Arch. 2018: 570 (2018) - [i5]Yehuda Lindell, Ariel Nof, Samuel Ranellucci:
Fast Secure Multiparty ECDSA with Practical Distributed Key Generation and Applications to Cryptocurrency Custody. IACR Cryptol. ePrint Arch. 2018: 987 (2018) - 2017
- [c6]Yehuda Lindell, Ariel Nof:
A Framework for Constructing Fast MPC over Arithmetic Circuits with Malicious Adversaries and an Honest-Majority. CCS 2017: 259-276 - [c5]Jun Furukawa, Yehuda Lindell, Ariel Nof, Or Weinstein:
High-Throughput Secure Three-Party Computation for Malicious Adversaries and an Honest Majority. EUROCRYPT (2) 2017: 225-255 - [c4]Toshinori Araki, Assi Barak, Jun Furukawa, Tamar Lichter, Yehuda Lindell, Ariel Nof, Kazuma Ohara, Adi Watzman, Or Weinstein:
Optimized Honest-Majority MPC for Malicious Adversaries - Breaking the 1 Billion-Gate Per Second Barrier. IEEE Symposium on Security and Privacy 2017: 843-862 - [i4]Yehuda Lindell, Ariel Nof:
A Framework for Constructing Fast MPC over Arithmetic Circuits with Malicious Adversaries and an Honest-Majority. IACR Cryptol. ePrint Arch. 2017: 816 (2017) - 2016
- [c3]Toshinori Araki, Jun Furukawa, Yehuda Lindell, Ariel Nof, Kazuma Ohara:
High-Throughput Semi-Honest Secure Three-Party Computation with an Honest Majority. CCS 2016: 805-817 - [c2]Toshinori Araki, Assaf Barak, Jun Furukawa, Yehuda Lindell, Ariel Nof, Kazuma Ohara:
DEMO: High-Throughput Secure Three-Party Computation of Kerberos Ticket Generation. CCS 2016: 1841-1843 - [i3]Toshinori Araki, Jun Furukawa, Yehuda Lindell, Ariel Nof, Kazuma Ohara:
High-Throughput Semi-Honest Secure Three-Party Computation with an Honest Majority. IACR Cryptol. ePrint Arch. 2016: 768 (2016) - [i2]Jun Furukawa, Yehuda Lindell, Ariel Nof, Or Weinstein:
High-Throughput Secure Three-Party Computation for Malicious Adversaries and an Honest Majority. IACR Cryptol. ePrint Arch. 2016: 944 (2016) - 2015
- [c1]Shay Gueron, Yehuda Lindell, Ariel Nof, Benny Pinkas:
Fast Garbling of Circuits Under Standard Assumptions. CCS 2015: 567-578 - [i1]Shay Gueron, Yehuda Lindell, Ariel Nof, Benny Pinkas:
Fast Garbling of Circuits Under Standard Assumptions. IACR Cryptol. ePrint Arch. 2015: 751 (2015)
Coauthor Index
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