Quantum pseudorandomness in Algorithmica, and its implications to cryptography and complexity

Channel:
United States Simons Institute for the Theory of Computing
Subscribers:
68,700
Published on ● Video Link: https://www.youtube.com/watch?v=vw0lcXWluWE


Duration: 46:00
384 views
8

Luowen Qian (Boston University)
https://simons.berkeley.edu/talks/luowen-qian-boston-university-2023-05-05
Minimal Complexity Assumptions for Cryptography

Quantum pseudorandomness in Algorithmica, and its implications to cryptography and complexity

Abstract: Pseudorandom quantum states (PRS) are a form of quantum pseudorandomness that mimics the Haar random quantum states against efficient distinguishers. Recently, it has been shown that the existence of PRS is separated from (post-quantum) one-way functions or even P vs NP and BQP vs QMA. In particular, there exists a property of a cryptographic hash function called "hardness of shifted Forrelation" that is simultaneously useful (suffices to construct single-copy-secure PRS), plausible (holds for a random oracle), and is weaker than 𝖯 ≠ 𝖭𝖯 (in the black-box setting).

As a corollary, any black-box implication of PRS can be plausibly established without one-way functions. Especially for cryptography, this implies that a lot of quantum computational cryptography could potentially be realized from much weaker assumptions than one-way functions. This also motivates how a theory of quantum (meta-)complexity may be needed in order to study the complexity theoretic foundations of quantum computational cryptography.



Other Videos By Simons Institute for the Theory of Computing


2023-05-23KEYNOTE: Differential Privacy & Variants
2023-05-23Information-theoretic Foundations of Generative Adversarial Models: ...
2023-05-23Generalization bounds for Neural Network Based Decoders
2023-05-23Optimal Neural Network Compressors and the Manifold Hypothesis
2023-05-23Fairness without Imputation: A Decision Tree Approach for Fair Prediction with Missing Values
2023-05-23Secure Distributed Matrix Multiplication
2023-05-23On the Robustness to Misspecification of α-Posteriors and Their Variational Approximations
2023-05-23Majorizing Measures, Codes, and Information
2023-05-22KEYNOTE: A (Con)Sequential View of Information for Statistical Learning and Optimization
2023-05-06Black-Box Separations in Quantum Cryptography *Presented Virtually
2023-05-06Quantum pseudorandomness in Algorithmica, and its implications to cryptography and complexity
2023-05-06On the Computational Hardness Needed for Quantum Cryptography
2023-05-06Commitments to Quantum States
2023-05-06Quantum Minimalism
2023-05-05Cryptography with Certified Deletion *Presented Virtually
2023-05-05Black-Hole Radiation Decoding as a Cryptographic Assumption
2023-05-05Geometry of Secure Computation
2023-05-05Collision-Resistance from Multi-Collision-Resistance
2023-05-05New Ways to Garble Arithmetic Circuits
2023-05-05Unclonable Polymers and Their Cryptographic Applications
2023-05-05Batch Proofs are Statistically Hiding


Tags:
Simons Institute
theoretical computer science
UC Berkeley
Computer Science
Theory of Computation
Theory of Computing
Minimal Complexity Assumptions for Cryptography
Luowen Qian