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Tight Quantum Time-Space Tradeoffs for Permutation Inversion

Computational Complexity 2025-10-15 v1 Information Theory math.IT

Abstract

In permutation inversion, we are given a permutation π:[N][N]\pi : [N] \rightarrow [N], and want to prepare some advice of size SS, such that we can efficiently invert any image in time TT. This is a fundamental cryptographic problem with profound connections to communication complexity and circuit lower bounds. In the classical setting, a tight ST=Θ~(N)ST = \tilde{\Theta}(N) bound has been established since the seminal work of Hellman (1980) and Yao (1990). In the quantum setting, a lower bound of ST2=Ω~(N)ST^2 = \tilde{\Omega}(N) is proved by Nayebi, Aaronson, Belovs, and Trevisan (2015) against classical advice, and by Hhan, Xagawa and Yamakawa (2019) against quantum advice. It left open an intriguing possibility that Grover's search can be sped up to time O~(N/S)\tilde{O}(\sqrt{N / S}). In this work, we prove an ST+T2=Ω(N)ST + T^2 = \Omega(N) lower bound for permutation inversion with even quantum advice. This bound matches the best known attacks and shows that Grover's search and the classical Hellman's algorithm cannot be further sped up. Our proof combines recent techniques by Liu (2023) and by Rosmanis (2022). Specifically, we first reduce the permutation inversion problem against quantum advice to a variant by Liu's technique, then we analyze this variant via representation theory inspired by Rosmanis (2022).

Cite

@article{arxiv.2510.12112,
  title  = {Tight Quantum Time-Space Tradeoffs for Permutation Inversion},
  author = {Akshima and Tyler Besselman and Kai-Min Chung and Siyao Guo and Tzu-Yi Yang},
  journal= {arXiv preprint arXiv:2510.12112},
  year   = {2025}
}
R2 v1 2026-07-01T06:35:27.396Z