English

Classical simulation of quantum circuits with partial and graphical stabiliser decompositions

Quantum Physics 2022-09-05 v1

Abstract

Recent developments in classical simulation of quantum circuits make use of clever decompositions of chunks of magic states into sums of efficiently simulable stabiliser states. We show here how, by considering certain non-stabiliser entangled states which have more favourable decompositions, we can speed up these simulations. This is made possible by using the ZX-calculus, which allows us to easily find instances of these entangled states in the simplified diagram representing the quantum circuit to be simulated. We additionally find a new technique of partial stabiliser decompositions that allow us to trade magic states for stabiliser terms. With this technique we require only 2αt2^{\alpha t} stabiliser terms, where α0.396\alpha\approx 0.396, to simulate a circuit with T-count tt. This matches the α\alpha found by Qassim et al., but whereas they only get this scaling in the asymptotic limit, ours applies for a circuit of any size. Our method builds upon a recently proposed scheme for simulation combining stabiliser decompositions and optimisation strategies implemented in the software QuiZX. With our techniques we manage to reliably simulate 50-qubit 1400 T-count hidden shift circuits in a couple of minutes on a consumer laptop.

Keywords

Cite

@article{arxiv.2202.09202,
  title  = {Classical simulation of quantum circuits with partial and graphical stabiliser decompositions},
  author = {Aleks Kissinger and John van de Wetering and Renaud Vilmart},
  journal= {arXiv preprint arXiv:2202.09202},
  year   = {2022}
}

Comments

10 pages, 4 figures

R2 v1 2026-06-24T09:44:27.914Z