English

Efficient synthesis of probabilistic quantum circuits with fallback

Quantum Physics 2015-06-11 v2 Emerging Technologies

Abstract

Recently it has been shown that Repeat-Until-Success (RUS) circuits can approximate a given single-qubit unitary with an expected number of TT gates of about 1/31/3 of what is required by optimal, deterministic, ancilla-free decompositions over the Clifford+TT gate set. In this work, we introduce a more general and conceptually simpler circuit decomposition method that allows for synthesis into protocols that probabilistically implement quantum circuits over several universal gate sets including, but not restricted to, the Clifford+TT gate set. The protocol, which we call Probabilistic Quantum Circuits with Fallback (PQF), implements a walk on a discrete Markov chain in which the target unitary is an absorbing state and in which transitions are induced by multi-qubit unitaries followed by measurements. In contrast to RUS protocols, the presented PQF protocols terminate after a finite number of steps. Specifically, we apply our method to the Clifford+TT, Clifford+VV, and Clifford+π/12\pi/12 gate sets to achieve decompositions with expected gate counts of logb(1/ε)+O(log(log(1/ε)))\log_b(1/\varepsilon)+O(\log(\log(1/\varepsilon))), where bb is a quantity related to the expansion property of the underlying universal gate set.

Keywords

Cite

@article{arxiv.1409.3552,
  title  = {Efficient synthesis of probabilistic quantum circuits with fallback},
  author = {Alex Bocharov and Martin Roetteler and Krysta M. Svore},
  journal= {arXiv preprint arXiv:1409.3552},
  year   = {2015}
}

Comments

17 pages, 7 figures; added Appendix F on the runtime performance of the synthesis algorithm

R2 v1 2026-06-22T05:54:48.525Z