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Julia Kempe
Person information
- affiliation: Tel Aviv University, Israel
- affiliation: University of Paris 7, France
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2020 – today
- 2024
- [j18]Jingtong Su, Ya Shi Zhang, Nikolaos Tsilivis, Julia Kempe:
On the Robustness of Neural Collapse and the Neural Collapse of Robustness. Trans. Mach. Learn. Res. 2024 (2024) - [c25]Tim G. J. Rudner, Ya Shi Zhang, Andrew Gordon Wilson, Julia Kempe:
Mind the GAP: Improving Robustness to Subpopulation Shifts with Group-Aware Priors. AISTATS 2024: 127-135 - [c24]Yunzhen Feng, Shanmukha Ramakrishna Vedantam, Julia Kempe:
Embarrassingly Simple Dataset Distillation. ICLR 2024 - [c23]Elvis Dohmatob, Yunzhen Feng, Pu Yang, François Charton, Julia Kempe:
A Tale of Tails: Model Collapse as a Change of Scaling Laws. ICML 2024 - [c22]Artem Vysogorets, Anna Dawid, Julia Kempe:
Deconstructing the Goldilocks Zone of Neural Network Initialization. ICML 2024 - [i35]Artem Vysogorets, Anna Dawid, Julia Kempe:
Deconstructing the Goldilocks Zone of Neural Network Initialization. CoRR abs/2402.03579 (2024) - [i34]Elvis Dohmatob, Yunzhen Feng, Pu Yang, François Charton, Julia Kempe:
A Tale of Tails: Model Collapse as a Change of Scaling Laws. CoRR abs/2402.07043 (2024) - [i33]Elvis Dohmatob, Yunzhen Feng, Julia Kempe:
Model Collapse Demystified: The Case of Regression. CoRR abs/2402.07712 (2024) - [i32]Tim G. J. Rudner, Ya Shi Zhang, Andrew Gordon Wilson, Julia Kempe:
Mind the GAP: Improving Robustness to Subpopulation Shifts with Group-Aware Priors. CoRR abs/2403.09869 (2024) - [i31]Artem Vysogorets, Kartik Ahuja, Julia Kempe:
Robust Data Pruning: Uncovering and Overcoming Implicit Bias. CoRR abs/2404.05579 (2024) - [i30]Yunzhen Feng, Tim G. J. Rudner, Nikolaos Tsilivis, Julia Kempe:
Attacking Bayes: On the Adversarial Robustness of Bayesian Neural Networks. CoRR abs/2404.19640 (2024) - [i29]Vivien Cabannes, Charles Arnal, Wassim Bouaziz, Alice Yang, François Charton, Julia Kempe:
Iteration Head: A Mechanistic Study of Chain-of-Thought. CoRR abs/2406.02128 (2024) - [i28]Nikolaos Tsilivis, Natalie Frank, Nathan Srebro, Julia Kempe:
The Price of Implicit Bias in Adversarially Robust Generalization. CoRR abs/2406.04981 (2024) - [i27]Yunzhen Feng, Elvis Dohmatob, Pu Yang, François Charton, Julia Kempe:
Beyond Model Collapse: Scaling Up with Synthesized Data Requires Reinforcement. CoRR abs/2406.07515 (2024) - [i26]Jingtong Su, Julia Kempe, Karen Ullrich:
Mission Impossible: A Statistical Perspective on Jailbreaking LLMs. CoRR abs/2408.01420 (2024) - [i25]Elvis Dohmatob, Yunzhen Feng, Arjun Subramonian, Julia Kempe:
Strong Model Collapse. CoRR abs/2410.04840 (2024) - [i24]François Charton, Julia Kempe:
Emergent properties with repeated examples. CoRR abs/2410.07041 (2024) - 2023
- [j17]Artem Vysogorets, Julia Kempe:
Connectivity Matters: Neural Network Pruning Through the Lens of Effective Sparsity. J. Mach. Learn. Res. 24: 99:1-99:23 (2023) - [i23]Jingtong Su, Julia Kempe:
Wavelets Beat Monkeys at Adversarial Robustness. CoRR abs/2304.09403 (2023) - [i22]Francesco Cagnetta, Deborah Oliveira, Mahalakshmi Sabanayagam, Nikolaos Tsilivis, Julia Kempe:
Kernels, Data & Physics. CoRR abs/2307.02693 (2023) - [i21]Yunzhen Feng, Ramakrishna Vedantam, Julia Kempe:
Embarassingly Simple Dataset Distillation. CoRR abs/2311.07025 (2023) - [i20]Jingtong Su, Ya Shi Zhang, Nikolaos Tsilivis, Julia Kempe:
On the Robustness of Neural Collapse and the Neural Collapse of Robustness. CoRR abs/2311.07444 (2023) - [i19]Haowen Guan, Xuan Zhao, Zishi Wang, Zhiyang Li, Julia Kempe:
Discovering Galaxy Features via Dataset Distillation. CoRR abs/2311.17967 (2023) - 2022
- [c21]Nikolaos Tsilivis, Julia Kempe:
What Can the Neural Tangent Kernel Tell Us About Adversarial Robustness? NeurIPS 2022 - [i18]Nikolaos Tsilivis, Jingtong Su, Julia Kempe:
Can we achieve robustness from data alone? CoRR abs/2207.11727 (2022) - [i17]Dhrupad Bhardwaj, Julia Kempe, Artem Vysogorets, Angela M. Teng, Evaristus C. Ezekwem:
ImpressLearn: Continual Learning via Combined Task Impressions. CoRR abs/2210.01987 (2022) - [i16]Nikolaos Tsilivis, Julia Kempe:
What Can the Neural Tangent Kernel Tell Us About Adversarial Robustness? CoRR abs/2210.05577 (2022) - 2021
- [i15]Artem Vysogorets, Julia Kempe:
Connectivity Matters: Neural Network Pruning Through the Lens of Effective Sparsity. CoRR abs/2107.02306 (2021)
2010 – 2019
- 2014
- [j16]Sevag Gharibian, Julia Kempe:
Hardness of approximation for quantum problems. Quantum Inf. Comput. 14(5-6): 517-540 (2014) - 2012
- [j15]Andris Ambainis, Julia Kempe, Or Sattath:
A quantum lovász local lemma. J. ACM 59(5): 24:1-24:24 (2012) - [j14]Sevag Gharibian, Julia Kempe:
Approximation Algorithms for QMA-Complete Problems. SIAM J. Comput. 41(4): 1028-1050 (2012) - [j13]Roy Kasher, Julia Kempe:
Two-Source Extractors Secure Against Quantum Adversaries. Theory Comput. 8(1): 461-486 (2012) - [c20]Sevag Gharibian, Julia Kempe:
Hardness of Approximation for Quantum Problems. ICALP (1) 2012: 387-398 - [i14]Sevag Gharibian, Julia Kempe:
Hardness of approximation for quantum problems. CoRR abs/1209.1055 (2012) - 2011
- [j12]Julia Kempe, Hirotada Kobayashi, Keiji Matsumoto, Ben Toner, Thomas Vidick:
Entangled Games Are Hard to Approximate. SIAM J. Comput. 40(3): 848-877 (2011) - [c19]Sevag Gharibian, Julia Kempe:
Approximation Algorithms for QMA-Complete Problems. CCC 2011: 178-188 - [c18]Julia Kempe, Thomas Vidick:
Parallel repetition of entangled games. STOC 2011: 353-362 - [i13]Sevag Gharibian, Julia Kempe:
Approximation algorithms for QMA-complete problems. CoRR abs/1101.3884 (2011) - 2010
- [j11]Julia Kempe, Oded Regev, Falk Unger, Ronald de Wolf:
Upper bounds on the noise threshold for fault-tolerant quantum computing. Quantum Inf. Comput. 10(5&6): 361-376 (2010) - [j10]Julia Kempe, Oded Regev, Ben Toner:
Unique Games with Entangled Provers Are Easy. SIAM J. Comput. 39(7): 3207-3229 (2010) - [c17]Roy Kasher, Julia Kempe:
Two-Source Extractors Secure against Quantum Adversaries. APPROX-RANDOM 2010: 656-669 - [c16]Julia Kempe, Oded Regev:
No Strong Parallel Repetition with Entangled and Non-signaling Provers. CCC 2010: 7-15 - [c15]Andris Ambainis, Julia Kempe, Or Sattath:
A quantum lovász local lemma. STOC 2010: 151-160 - [i12]Roy Kasher, Julia Kempe:
Two-Source Extractors Secure Against Quantum Adversaries. CoRR abs/1005.0512 (2010)
2000 – 2009
- 2009
- [j9]Julia Kempe, Hirotada Kobayashi, Keiji Matsumoto, Thomas Vidick:
Using Entanglement in Quantum Multi-Prover Interactive Proofs. Comput. Complex. 18(2): 273-307 (2009) - [j8]Dmitry Gavinsky, Julia Kempe, Oded Regev, Ronald de Wolf:
Bounded-Error Quantum State Identification and Exponential Separations in Communication Complexity. SIAM J. Comput. 39(1): 1-24 (2009) - [i11]Julia Kempe, Oded Regev:
No Strong Parallel Repetition with Entangled and Non-signaling Provers. CoRR abs/0911.0201 (2009) - [i10]Andris Ambainis, Julia Kempe, Or Sattath:
A Quantum Lovasz Local Lemma. CoRR abs/0911.1696 (2009) - 2008
- [j7]Dmitry Gavinsky, Julia Kempe, Iordanis Kerenidis, Ran Raz, Ronald de Wolf:
Exponential Separation for One-Way Quantum Communication Complexity, with Applications to Cryptography. SIAM J. Comput. 38(5): 1695-1708 (2008) - [j6]Dorit Aharonov, Wim van Dam, Julia Kempe, Zeph Landau, Seth Lloyd, Oded Regev:
Adiabatic Quantum Computation Is Equivalent to Standard Quantum Computation. SIAM Rev. 50(4): 755-787 (2008) - [c14]Julia Kempe, Hirotada Kobayashi, Keiji Matsumoto, Thomas Vidick:
Using Entanglement in Quantum Multi-prover Interactive Proofs. CCC 2008: 211-222 - [c13]Julia Kempe, Hirotada Kobayashi, Keiji Matsumoto, Ben Toner, Thomas Vidick:
Entangled Games are Hard to Approximate. FOCS 2008: 447-456 - [c12]Julia Kempe, Oded Regev, Ben Toner:
Unique Games with Entangled Provers are Easy. FOCS 2008: 457-466 - [c11]Julia Kempe, Oded Regev, Falk Unger, Ronald de Wolf:
Upper Bounds on the Noise Threshold for Fault-Tolerant Quantum Computing. ICALP (1) 2008: 845-856 - 2007
- [j5]Dorit Aharonov, Wim van Dam, Julia Kempe, Zeph Landau, Seth Lloyd, Oded Regev:
Adiabatic Quantum Computation is Equivalent to Standard Quantum Computation. SIAM J. Comput. 37(1): 166-194 (2007) - [c10]Dorit Aharonov, Daniel Gottesman, Sandy Irani, Julia Kempe:
The Power of Quantum Systems on a Line. FOCS 2007: 373-383 - [c9]Dmitry Gavinsky, Julia Kempe, Iordanis Kerenidis, Ran Raz, Ronald de Wolf:
Exponential separations for one-way quantum communication complexity, with applications to cryptography. STOC 2007: 516-525 - [i9]Julia Kempe, Oded Regev, Ben Toner:
The Unique Games Conjecture with Entangled Provers is False. Algebraic Methods in Computational Complexity 2007 - 2006
- [j4]Julia Kempe, Alexei Y. Kitaev, Oded Regev:
The Complexity of the Local Hamiltonian Problem. SIAM J. Comput. 35(5): 1070-1097 (2006) - [j3]Jesse Fern, Julia Kempe, Slobodan N. Simic, Shankar Sastry:
Generalized Performance of Concatenated Quantum Codes - A Dynamical Systems Approach. IEEE Trans. Autom. Control. 51(3): 448-459 (2006) - [c8]Dmitry Gavinsky, Julia Kempe, Ronald de Wolf:
Strengths and Weaknesses of Quantum Fingerprinting. CCC 2006: 288-298 - [c7]Dmitry Gavinsky, Julia Kempe, Oded Regev, Ronald de Wolf:
Bounded-error quantum state identification and exponential separations in communication complexity. STOC 2006: 594-603 - [i8]Dmitry Gavinsky, Julia Kempe, Ronald de Wolf:
Strengths and Weaknesses of Quantum Fingerprinting. CoRR abs/quant-ph/0603173 (2006) - [i7]Dmitry Gavinsky, Julia Kempe, Ronald de Wolf:
Exponential Separation of Quantum and Classical One-Way Communication Complexity for a Boolean Function. CoRR abs/quant-ph/0607174 (2006) - [i6]Dmitry Gavinsky, Julia Kempe, Ronald de Wolf:
Exponential Separation of Quantum and Classical One-Way Communication Complexity for a Boolean Function. Electron. Colloquium Comput. Complex. TR06 (2006) - 2005
- [c6]Andris Ambainis, Julia Kempe, Alexander Rivosh:
Coins make quantum walks faster. SODA 2005: 1099-1108 - [c5]Julia Kempe, Aner Shalev:
The hidden subgroup problem and permutation group theory. SODA 2005: 1118-1125 - [i5]Dmitry Gavinsky, Julia Kempe, Oded Regev, Ronald de Wolf:
Bounded-Error Quantum State Identification and Exponential Separations in Communication Complexity. CoRR abs/quant-ph/0511013 (2005) - 2004
- [c4]Dorit Aharonov, Wim van Dam, Julia Kempe, Zeph Landau, Seth Lloyd, Oded Regev:
Adiabatic Quantum Computation is Equivalent to Standard Quantum Computation. FOCS 2004: 42-51 - [c3]Julia Kempe, Alexei Y. Kitaev, Oded Regev:
The Complexity of the Local Hamiltonian Problem. FSTTCS 2004: 372-383 - [i4]Julia Kempe, Aner Shalev:
The hidden subgroup problem and permutation group theory. CoRR quant-ph/0406046 (2004) - [i3]Julia Kempe, Alexei Y. Kitaev, Oded Regev:
The Complexity of the Local Hamiltonian Problem. CoRR quant-ph/0406180 (2004) - [i2]Dmitry Gavinsky, Julia Kempe, Ronald de Wolf:
Quantum Communication Cannot Simulate a Public Coin. CoRR quant-ph/0411051 (2004) - 2003
- [j2]Julia Kempe, Oded Regev:
3-local Hamiltonian is QMA-complete. Quantum Inf. Comput. 3(3): 258-264 (2003) - [c2]Julia Kempe:
Discrete Quantum Walks Hit Exponentially Faster. RANDOM-APPROX 2003: 354-369 - 2002
- [i1]Julia Kempe:
Quantum Random Walks Hit Exponentially Faster. CoRR quant-ph/0205083 (2002) - 2001
- [j1]Julia Kempe, David Bacon, David P. DiVincenzo, K. Brigitta Whaley:
Encoded universality from a single physical interaction. Quantum Inf. Comput. 1(4): 33-55 (2001) - [c1]Dorit Aharonov, Andris Ambainis, Julia Kempe, Umesh V. Vazirani:
Quantum walks on graphs. STOC 2001: 50-59
Coauthor Index
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