English

Optimal Two-Qubit Circuits for Universal Fault-Tolerant Quantum Computation

Quantum Physics 2021-06-21 v4

Abstract

We study two-qubit circuits over the Clifford+CS gate set, which consists of the Clifford gates together with the controlled-phase gate CS=diag(1,1,1,i). The Clifford+CS gate set is universal for quantum computation and its elements can be implemented fault-tolerantly in most error-correcting schemes through magic state distillation. Since non-Clifford gates are typically more expensive to perform in a fault-tolerant manner, it is often desirable to construct circuits that use few CS gates. In the present paper, we introduce an efficient and optimal synthesis algorithm for two-qubit Clifford+CS operators. Our algorithm inputs a Clifford+CS operator U and outputs a Clifford+CS circuit for U, which uses the least possible number of CS gates. Because the algorithm is deterministic, the circuit it associates to a Clifford+CS operator can be viewed as a normal form for that operator. We give an explicit description of these normal forms and use this description to derive a worst-case lower bound of 5log(1/epsilon)+O(1) on the number of CS gates required to epsilon-approximate elements of SU(4). Our work leverages a wide variety of mathematical tools that may find further applications in the study of fault-tolerant quantum circuits.

Keywords

Cite

@article{arxiv.2001.05997,
  title  = {Optimal Two-Qubit Circuits for Universal Fault-Tolerant Quantum Computation},
  author = {Andrew N. Glaudell and Neil J. Ross and Jacob M. Taylor},
  journal= {arXiv preprint arXiv:2001.05997},
  year   = {2021}
}

Comments

23 pages. Significant revisions to Sections 5 and 6. Updated introduction and conclusion. Link to open access implementation provided

R2 v1 2026-06-23T13:13:20.669Z