English

Diagonal-unitary 2-designs and their implementations by quantum circuits

Quantum Physics 2014-01-31 v5

Abstract

We study efficient generations of random diagonal-unitary matrices, an ensemble of unitary matrices diagonal in a given basis with randomly distributed phases for their eigenvalues. Despite the simple algebraic structure, they cannot be achieved by quantum circuits composed of a few-qubit diagonal gates. We introduce diagonal-unitary tt-designs and present two quantum circuits that implement diagonal-unitary 22-designs with the computational basis in NN-qubit systems. One is composed of single-qubit diagonal gates and controlled-phase gates with randomized phases, which achieves an exact diagonal-unitary 22-design after applying the gates on all pairs of qubits. The number of required gates is N(N1)/2N(N-1)/2. If the controlled-Z gates are used instead of the controlled-phase gates, the circuit cannot achieve an exact 22-design, but achieves an ϵ\epsilon-approximate 22-design by applying gates on randomly selected pairs of qubits. Due to the random choice of pairs, the circuit obtains extra randomness and the required number of gates is at most O(N2(N+log1/ϵ))O(N^2(N+\log1/\epsilon)). We also provide an application of the circuits, a protocol of generating an exact 22-design of random states by combining the circuits with a simple classical procedure requiring O(N)O(N) random classical bits.

Keywords

Cite

@article{arxiv.1206.4451,
  title  = {Diagonal-unitary 2-designs and their implementations by quantum circuits},
  author = {Yoshifumi Nakata and Mio Murao},
  journal= {arXiv preprint arXiv:1206.4451},
  year   = {2014}
}

Comments

Revised, 22 pages + Appendix, 3 figures; major revision from v2; presentation is improved in v4; v5 is a published version

R2 v1 2026-06-21T21:22:24.076Z