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Optimal universal quantum circuits for unitary complex conjugation

Quantum Physics 2024-08-28 v3

Abstract

Let UdU_d be a unitary operator representing an arbitrary dd-dimensional unitary quantum operation. This work presents optimal quantum circuits for transforming a number kk of calls of UdU_d into its complex conjugate Udˉ\bar{U_d}. Our circuits admit a parallel implementation and are proven to be optimal for any kk and dd with an average fidelity of F=k+1d(dk)\left\langle{F}\right\rangle =\frac{k+1}{d(d-k)}. Optimality is shown for average fidelity, robustness to noise, and other standard figures of merit. This extends previous works which considered the scenario of a single call (k=1k=1) of the operation UdU_d, and the special case of k=d1k=d-1 calls. We then show that our results encompass optimal transformations from kk calls of UdU_d to f(Ud)f(U_d) for any arbitrary homomorphism ff from the group of dd-dimensional unitary operators to itself, since complex conjugation is the only non-trivial automorphisms on the group of unitary operators. Finally, we apply our optimal complex conjugation implementation to design a probabilistic circuit for reversing arbitrary quantum evolutions.

Keywords

Cite

@article{arxiv.2206.00107,
  title  = {Optimal universal quantum circuits for unitary complex conjugation},
  author = {Daniel Ebler and Michał Horodecki and Marcin Marciniak and Tomasz Młynik and Marco Túlio Quintino and Michał Studziński},
  journal= {arXiv preprint arXiv:2206.00107},
  year   = {2024}
}

Comments

20 pages, 5 figures. Improved presentation, typos corrected, and some proofs are now clearer. Close to the published version

R2 v1 2026-06-24T11:35:09.849Z