English

Shorter quantum circuits via single-qubit gate approximation

Quantum Physics 2023-12-20 v2

Abstract

We give a novel procedure for approximating general single-qubit unitaries from a finite universal gate set by reducing the problem to a novel magnitude approximation problem, achieving an immediate improvement in sequence length by a factor of 7/9. Extending the works arXiv:1612.01011 and arXiv:1612.02689, we show that taking probabilistic mixtures of channels to solve fallback (arXiv:1409.3552) and magnitude approximation problems saves factor of two in approximation costs. In particular, over the Clifford+T\sqrt{\mathrm{T}} gate set we achieve an average non-Clifford gate count of 0.23log2(1/ε)+2.130.23\log_2(1/\varepsilon)+2.13 and T-count 0.56log2(1/ε)+5.30.56\log_2(1/\varepsilon)+5.3 with mixed fallback approximations for diamond norm accuracy ε\varepsilon. This paper provides a holistic overview of gate approximation, in addition to these new insights. We give an end-to-end procedure for gate approximation for general gate sets related to some quaternion algebras, providing pedagogical examples using common fault-tolerant gate sets (V, Clifford+T and Clifford+T\sqrt{\mathrm{T}}). We also provide detailed numerical results for Clifford+T and Clifford+T\sqrt{\mathrm{T}} gate sets. In an effort to keep the paper self-contained, we include an overview of the relevant algorithms for integer point enumeration and relative norm equation solving. We provide a number of further applications of the magnitude approximation problems, as well as improved algorithms for exact synthesis, in the Appendices.

Keywords

Cite

@article{arxiv.2203.10064,
  title  = {Shorter quantum circuits via single-qubit gate approximation},
  author = {Vadym Kliuchnikov and Kristin Lauter and Romy Minko and Adam Paetznick and Christophe Petit},
  journal= {arXiv preprint arXiv:2203.10064},
  year   = {2023}
}

Comments

88 pages

R2 v1 2026-06-24T10:18:38.394Z