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Noah Stephens-Davidowitz
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2020 – today
- 2024
- [c33]Surendra Ghentiyala, Noah Stephens-Davidowitz:
More Basis Reduction for Linear Codes: Backward Reduction, BKZ, Slide Reduction, and More. APPROX/RANDOM 2024: 19:1-19:22 - [i36]Surendra Ghentiyala, Noah Stephens-Davidowitz:
More basis reduction for linear codes: backward reduction, BKZ, slide reduction, and more. CoRR abs/2408.08507 (2024) - [i35]Huck Bennett, Surendra Ghentiyala, Noah Stephens-Davidowitz:
The more the merrier! On the complexity of finding multicollisions, with connections to codes and lattices. Electron. Colloquium Comput. Complex. TR24 (2024) - 2023
- [c32]Alexander Golovnev, Siyao Guo, Spencer Peters, Noah Stephens-Davidowitz:
The (Im)possibility of Simple Search-To-Decision Reductions for Approximation Problems. APPROX/RANDOM 2023: 10:1-10:20 - [c31]Alexander Golovnev, Siyao Guo, Spencer Peters, Noah Stephens-Davidowitz:
Revisiting Time-Space Tradeoffs for Function Inversion. CRYPTO (2) 2023: 453-481 - [c30]Huck Bennett, Atul Ganju, Pura Peetathawatchai, Noah Stephens-Davidowitz:
Just How Hard Are Rotations of $\mathbb {Z}^n$? Algorithms and Cryptography with the Simplest Lattice. EUROCRYPT (5) 2023: 252-281 - [c29]Divesh Aggarwal, Huck Bennett, Zvika Brakerski, Alexander Golovnev, Rajendra Kumar, Zeyong Li, Spencer Peters, Noah Stephens-Davidowitz, Vinod Vaikuntanathan:
Lattice Problems beyond Polynomial Time. STOC 2023: 1516-1526 - [i34]Divesh Aggarwal, Thomas Espitau, Spencer Peters, Noah Stephens-Davidowitz:
Recursive lattice reduction - A framework for finding short lattice vectors. CoRR abs/2311.15064 (2023) - [i33]Eldon Chung, Alexander Golovnev, Zeyong Li, Maciej Obremski, Sidhant Saraogi, Noah Stephens-Davidowitz:
On the randomized complexity of range avoidance, with applications to cryptography and metacomplexity. Electron. Colloquium Comput. Complex. TR23 (2023) - 2022
- [c28]Sandro Coretti, Yevgeniy Dodis, Harish Karthikeyan, Noah Stephens-Davidowitz, Stefano Tessaro:
On Seedless PRNGs and Premature Next. ITC 2022: 9:1-9:20 - [i32]Divesh Aggarwal, Huck Bennett, Zvika Brakerski, Alexander Golovnev, Rajendra Kumar, Zeyong Li, Spencer Peters, Noah Stephens-Davidowitz, Vinod Vaikuntanathan:
Lattice Problems Beyond Polynomial Time. CoRR abs/2211.11693 (2022) - [i31]Alexander Golovnev, Siyao Guo, Spencer Peters, Noah Stephens-Davidowitz:
Revisiting Time-Space Tradeoffs for Function Inversion. Electron. Colloquium Comput. Complex. TR22 (2022) - [i30]Sandro Coretti, Yevgeniy Dodis, Harish Karthikeyan, Noah Stephens-Davidowitz, Stefano Tessaro:
On Seedless PRNGs and Premature Next. IACR Cryptol. ePrint Arch. 2022: 558 (2022) - 2021
- [c27]Zvika Brakerski, Noah Stephens-Davidowitz, Vinod Vaikuntanathan:
On the Hardness of Average-Case k-SUM. APPROX-RANDOM 2021: 29:1-29:19 - [c26]Yevgeniy Dodis, Siyao Guo, Noah Stephens-Davidowitz, Zhiye Xie:
Online Linear Extractors for Independent Sources. ITC 2021: 14:1-14:14 - [c25]Yevgeniy Dodis, Siyao Guo, Noah Stephens-Davidowitz, Zhiye Xie:
No Time to Hash: On Super-Efficient Entropy Accumulation. CRYPTO (4) 2021: 548-576 - [c24]Divesh Aggarwal, Zeyong Li, Noah Stephens-Davidowitz:
A 2n/2-Time Algorithm for $\sqrt{n}$-SVP and $\sqrt{n}$-Hermite SVP, and an Improved Time-Approximation Tradeoff for (H)SVP. EUROCRYPT (1) 2021: 467-497 - [c23]Divesh Aggarwal, Huck Bennett, Alexander Golovnev, Noah Stephens-Davidowitz:
Fine-grained hardness of CVP(P) - Everything that we can prove (and nothing else). SODA 2021: 1816-1835 - [c22]Divesh Aggarwal, Yanlin Chen, Rajendra Kumar, Zeyong Li, Noah Stephens-Davidowitz:
Dimension-Preserving Reductions Between SVP and CVP in Different p-Norms. SODA 2021: 2444-2462 - [i29]Divesh Aggarwal, Yanlin Chen, Rajendra Kumar, Zeyong Li, Noah Stephens-Davidowitz:
Dimension-Preserving Reductions Between SVP and CVP in Different p-Norms. CoRR abs/2104.06576 (2021) - [i28]Alexander Golovnev, Siyao Guo, Spencer Peters, Noah Stephens-Davidowitz:
On the (im)possibility of branch-and-bound search-to-decision reductions for approximate optimization. Electron. Colloquium Comput. Complex. TR21 (2021) - [i27]Yevgeniy Dodis, Siyao Guo, Noah Stephens-Davidowitz, Zhiye Xie:
No Time to Hash: On Superefficient Entropy Accumulation. IACR Cryptol. ePrint Arch. 2021: 523 (2021) - [i26]Yevgeniy Dodis, Siyao Guo, Noah Stephens-Davidowitz, Zhiye Xie:
Online Linear Extractors for Independent Sources. IACR Cryptol. ePrint Arch. 2021: 1002 (2021) - [i25]Huck Bennett, Atul Ganju, Pura Peetathawatchai, Noah Stephens-Davidowitz:
Just how hard are rotations of ℤn? Algorithms and cryptography with the simplest lattice. IACR Cryptol. ePrint Arch. 2021: 1548 (2021) - 2020
- [c21]Divesh Aggarwal, Siyao Guo, Maciej Obremski, João Ribeiro, Noah Stephens-Davidowitz:
Extractor Lower Bounds, Revisited. APPROX-RANDOM 2020: 1:1-1:20 - [c20]Tamalika Mukherjee, Noah Stephens-Davidowitz:
Lattice Reduction for Modules, or How to Reduce ModuleSVP to ModuleSVP. CRYPTO (2) 2020: 213-242 - [c19]Divesh Aggarwal, Jianwei Li, Phong Q. Nguyen, Noah Stephens-Davidowitz:
Slide Reduction, Revisited - Filling the Gaps in SVP Approximation. CRYPTO (2) 2020: 274-295 - [i24]Divesh Aggarwal, Zeyong Li, Noah Stephens-Davidowitz:
A 2n/2-Time Algorithm for √n-SVP and √n-Hermite SVP, and an Improved Time-Approximation Tradeoff for (H)SVP. CoRR abs/2007.09556 (2020) - [i23]Zvika Brakerski, Noah Stephens-Davidowitz, Vinod Vaikuntanathan:
On the Hardness of Average-case k-SUM. CoRR abs/2010.08821 (2020)
2010 – 2019
- 2019
- [j3]Stephen D. Miller, Noah Stephens-Davidowitz:
Kissing Numbers and Transference Theorems from Generalized Tail Bounds. SIAM J. Discret. Math. 33(3): 1313-1325 (2019) - [c18]Noah Stephens-Davidowitz:
A Time-Distance Trade-Off for GDD with Preprocessing - Instantiating the DLW Heuristic. CCC 2019: 11:1-11:8 - [c17]Noah Stephens-Davidowitz, Vinod Vaikuntanathan:
SETH-Hardness of Coding Problems. FOCS 2019: 287-301 - [i22]Noah Stephens-Davidowitz:
A time-distance trade-off for GDD with preprocessing - Instantiating the DLW heuristic. CoRR abs/1902.08340 (2019) - [i21]Divesh Aggarwal, Jianwei Li, Phong Q. Nguyen, Noah Stephens-Davidowitz:
Slide Reduction, Revisited - Filling the Gaps in SVP Approximation. CoRR abs/1908.03724 (2019) - [i20]Divesh Aggarwal, Huck Bennett, Alexander Golovnev, Noah Stephens-Davidowitz:
Fine-grained hardness of CVP(P) - Everything that we can prove (and nothing else). CoRR abs/1911.02440 (2019) - [i19]Divesh Aggarwal, Siyao Guo, Maciej Obremski, João Ribeiro, Noah Stephens-Davidowitz:
Extractor Lower Bounds, Revisited. Electron. Colloquium Comput. Complex. TR19 (2019) - [i18]Noah Stephens-Davidowitz, Vinod Vaikuntanathan:
SETH-hardness of Coding Problems. Electron. Colloquium Comput. Complex. TR19 (2019) - [i17]Tamalika Mukherjee, Noah Stephens-Davidowitz:
Lattice Reduction for Modules, or How to Reduce ModuleSVP to ModuleSVP. IACR Cryptol. ePrint Arch. 2019: 1142 (2019) - 2018
- [c16]Navid Alamati, Chris Peikert, Noah Stephens-Davidowitz:
New (and Old) Proof Systems for Lattice Problems. Public Key Cryptography (2) 2018: 619-643 - [c15]Divesh Aggarwal, Noah Stephens-Davidowitz:
Just Take the Average! An Embarrassingly Simple 2^n-Time Algorithm for SVP (and CVP). SOSA 2018: 12:1-12:19 - [c14]Divesh Aggarwal, Noah Stephens-Davidowitz:
(Gap/S)ETH hardness of SVP. STOC 2018: 228-238 - [i16]Stephen D. Miller, Noah Stephens-Davidowitz:
Generalizations of Banaszczyk's transference theorems and tail bound. IACR Cryptol. ePrint Arch. 2018: 188 (2018) - 2017
- [b1]Noah Stephens-Davidowitz:
On the Gaussian Measure Over Lattices. New York University, USA, 2017 - [j2]Yevgeniy Dodis, Adi Shamir, Noah Stephens-Davidowitz, Daniel Wichs:
How to Eat Your Entropy and Have it Too: Optimal Recovery Strategies for Compromised RNGs. Algorithmica 79(4): 1196-1232 (2017) - [j1]Oded Regev, Noah Stephens-Davidowitz:
An Inequality for Gaussians on Lattices. SIAM J. Discret. Math. 31(2): 749-757 (2017) - [c13]Shai Halevi, Tzipora Halevi, Victor Shoup, Noah Stephens-Davidowitz:
Implementing BP-Obfuscation Using Graph-Induced Encoding. CCS 2017: 783-798 - [c12]Huck Bennett, Alexander Golovnev, Noah Stephens-Davidowitz:
On the Quantitative Hardness of CVP. FOCS 2017: 13-24 - [c11]Chris Peikert, Oded Regev, Noah Stephens-Davidowitz:
Pseudorandomness of ring-LWE for any ring and modulus. STOC 2017: 461-473 - [c10]Oded Regev, Noah Stephens-Davidowitz:
A reverse Minkowski theorem. STOC 2017: 941-953 - [i15]Huck Bennett, Alexander Golovnev, Noah Stephens-Davidowitz:
On the Quantitative Hardness of CVP. CoRR abs/1704.03928 (2017) - [i14]Divesh Aggarwal, Noah Stephens-Davidowitz:
Just Take the Average! An Embarrassingly Simple $2^n$-Time Algorithm for SVP (and CVP). CoRR abs/1709.01535 (2017) - [i13]Divesh Aggarwal, Noah Stephens-Davidowitz:
(Gap/S)ETH Hardness of SVP. CoRR abs/1712.00942 (2017) - [i12]Shai Halevi, Tzipora Halevi, Victor Shoup, Noah Stephens-Davidowitz:
Implementing BP-Obfuscation Using Graph-Induced Encoding. IACR Cryptol. ePrint Arch. 2017: 104 (2017) - [i11]Chris Peikert, Oded Regev, Noah Stephens-Davidowitz:
Pseudorandomness of Ring-LWE for Any Ring and Modulus. IACR Cryptol. ePrint Arch. 2017: 258 (2017) - [i10]Navid Alamati, Chris Peikert, Noah Stephens-Davidowitz:
New (and Old) Proof Systems for Lattice Problems. IACR Cryptol. ePrint Arch. 2017: 1226 (2017) - 2016
- [c9]Noah Stephens-Davidowitz:
Search-to-Decision Reductions for Lattice Problems with Approximation Factors (Slightly) Greater Than One. APPROX-RANDOM 2016: 19:1-19:18 - [c8]Yevgeniy Dodis, Ilya Mironov, Noah Stephens-Davidowitz:
Message Transmission with Reverse Firewalls - Secure Communication on Corrupted Machines. CRYPTO (1) 2016: 341-372 - [c7]Huck Bennett, Daniel Dadush, Noah Stephens-Davidowitz:
On the Lattice Distortion Problem. ESA 2016: 9:1-9:17 - [c6]Noah Stephens-Davidowitz:
Discrete Gaussian Sampling Reduces to CVP and SVP. SODA 2016: 1748-1764 - [i9]Huck Bennett, Daniel Dadush, Noah Stephens-Davidowitz:
On the Lattice Distortion Problem. CoRR abs/1605.03613 (2016) - 2015
- [c5]Ilya Mironov, Noah Stephens-Davidowitz:
Cryptographic Reverse Firewalls. EUROCRYPT (2) 2015: 657-686 - [c4]Divesh Aggarwal, Daniel Dadush, Noah Stephens-Davidowitz:
Solving the Closest Vector Problem in 2^n Time - The Discrete Gaussian Strikes Again! FOCS 2015: 563-582 - [c3]Divesh Aggarwal, Daniel Dadush, Oded Regev, Noah Stephens-Davidowitz:
Solving the Shortest Vector Problem in 2n Time Using Discrete Gaussian Sampling: Extended Abstract. STOC 2015: 733-742 - [i8]Divesh Aggarwal, Daniel Dadush, Noah Stephens-Davidowitz:
Solving the Closest Vector Problem in $2^n$ Time - The Discrete Gaussian Strikes Again! CoRR abs/1504.01995 (2015) - [i7]Noah Stephens-Davidowitz:
Discrete Gaussian Sampling Reduces to CVP and SVP. CoRR abs/1506.07490 (2015) - [i6]Noah Stephens-Davidowitz:
Search-to-Decision Reductions for Lattice Problems with Approximation Factors (Slightly) Greater Than One. CoRR abs/1512.04138 (2015) - [i5]Yevgeniy Dodis, Ilya Mironov, Noah Stephens-Davidowitz:
Message Transmission with Reverse Firewalls - Secure Communication on Corrupted Machines. IACR Cryptol. ePrint Arch. 2015: 548 (2015) - 2014
- [c2]Daniel Dadush, Oded Regev, Noah Stephens-Davidowitz:
On the Closest Vector Problem with a Distance Guarantee. CCC 2014: 98-109 - [c1]Yevgeniy Dodis, Adi Shamir, Noah Stephens-Davidowitz, Daniel Wichs:
How to Eat Your Entropy and Have It Too - Optimal Recovery Strategies for Compromised RNGs. CRYPTO (2) 2014: 37-54 - [i4]Daniel Dadush, Oded Regev, Noah Stephens-Davidowitz:
On the Closest Vector Problem with a Distance Guarantee. CoRR abs/1409.8063 (2014) - [i3]Divesh Aggarwal, Daniel Dadush, Oded Regev, Noah Stephens-Davidowitz:
Solving the Shortest Vector Problem in $2^n$ Time via Discrete Gaussian Sampling. CoRR abs/1412.7994 (2014) - [i2]Yevgeniy Dodis, Adi Shamir, Noah Stephens-Davidowitz, Daniel Wichs:
How to Eat Your Entropy and Have it Too - Optimal Recovery Strategies for Compromised RNGs. IACR Cryptol. ePrint Arch. 2014: 167 (2014) - [i1]Ilya Mironov, Noah Stephens-Davidowitz:
Cryptographic Reverse Firewalls. IACR Cryptol. ePrint Arch. 2014: 758 (2014)
Coauthor Index
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