中文

Computational Indistinguishability between Quantum States and Its Cryptographic Application

量子物理 2016-05-25 v6 密码学与安全

摘要

We introduce a computational problem of distinguishing between two specific quantum states as a new cryptographic problem to design a quantum cryptographic scheme that is "secure" against any polynomial-time quantum adversary. Our problem, QSCDff, is to distinguish between two types of random coset states with a hidden permutation over the symmetric group of finite degree. This naturally generalizes the commonly-used distinction problem between two probability distributions in computational cryptography. As our major contribution, we show that QSCDff has three properties of cryptographic interest: (i) QSCDff has a trapdoor; (ii) the average-case hardness of QSCDff coincides with its worst-case hardness; and (iii) QSCDff is computationally at least as hard as the graph automorphism problem in the worst case. These cryptographic properties enable us to construct a quantum public-key cryptosystem, which is likely to withstand any chosen plaintext attack of a polynomial-time quantum adversary. We further discuss a generalization of QSCDff, called QSCDcyc, and introduce a multi-bit encryption scheme that relies on similar cryptographic properties of QSCDcyc.

关键词

引用

@article{arxiv.quant-ph/0403069,
  title  = {Computational Indistinguishability between Quantum States and Its Cryptographic Application},
  author = {Akinori Kawachi and Takeshi Koshiba and Harumichi Nishimura and Tomoyuki Yamakami},
  journal= {arXiv preprint arXiv:quant-ph/0403069},
  year   = {2016}
}

备注

24 pages, 2 figures. We improved presentation, and added more detail proofs and follow-up of recent work