English

(Pseudo) Random Quantum States with Binary Phase

Quantum Physics 2019-06-27 v2 Cryptography and Security

Abstract

We prove a quantum information-theoretic conjecture due to Ji, Liu and Song (CRYPTO 2018) which suggested that a uniform superposition with random \emph{binary} phase is statistically indistinguishable from a Haar random state. That is, any polynomial number of copies of the aforementioned state is within exponentially small trace distance from the same number of copies of a Haar random state. As a consequence, we get a provable elementary construction of \emph{pseudorandom} quantum states from post-quantum pseudorandom functions. Generating pseduorandom quantum states is desirable for physical applications as well as for computational tasks such as quantum money. We observe that replacing the pseudorandom function with a (2t)(2t)-wise independent function (either in our construction or in previous work), results in an explicit construction for \emph{quantum state tt-designs} for all tt. In fact, we show that the circuit complexity (in terms of both circuit size and depth) of constructing tt-designs is bounded by that of (2t)(2t)-wise independent functions. Explicitly, while in prior literature tt-designs required linear depth (for t>2t > 2), this observation shows that polylogarithmic depth suffices for all tt. We note that our constructions yield pseudorandom states and state designs with only real-valued amplitudes, which was not previously known. Furthermore, generating these states require quantum circuit of restricted form: applying one layer of Hadamard gates, followed by a sequence of Toffoli gates. This structure may be useful for efficiency and simplicity of implementation.

Keywords

Cite

@article{arxiv.1906.10611,
  title  = {(Pseudo) Random Quantum States with Binary Phase},
  author = {Zvika Brakerski and Omri Shmueli},
  journal= {arXiv preprint arXiv:1906.10611},
  year   = {2019}
}
R2 v1 2026-06-23T10:03:15.439Z