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Extending Matchgate Simulation Methods to Universal Quantum Circuits

Quantum Physics 2024-06-18 v2

Abstract

Matchgates are a family of parity-preserving two-qubit gates, nearest-neighbour circuits of which are known to be classically simulable in polynomial time. In this work, we present a simulation method to classically simulate an n\boldsymbol{n}-qubit circuit containing N\boldsymbol{N} gates, m\boldsymbol{m} of which are universality-enabling gates and Nm\boldsymbol{N-m} of which are matchgates, in the setting of single-qubit Pauli measurements and product state inputs. The universality-enabling gates we consider include the SWAP, CZ, and CPhase gates. For fixed m\boldsymbol{m} as n\boldsymbol{n} \rightarrow \boldsymbol{\infty}, the resource cost, T\boldsymbol{T}, scales as O((enm+1)2m+2)\boldsymbol{\mathcal{O}\left(\left(\frac{en}{m+1}\right)^{2m+2}\right)}. For m\boldsymbol{m} scaling as a linear function of n\boldsymbol{n}, however, T\boldsymbol{T} scale as O(22nH(m+1n))\boldsymbol{\mathcal{O}\left(2^{2nH\left(\frac{m+1}{n}\right)}\right)}, where H(λ)\boldsymbol{H}(\lambda) is the binary entropy function.

Keywords

Cite

@article{arxiv.2302.02654,
  title  = {Extending Matchgate Simulation Methods to Universal Quantum Circuits},
  author = {Avinash Mocherla and Lingling Lao and Dan E. Browne},
  journal= {arXiv preprint arXiv:2302.02654},
  year   = {2024}
}
R2 v1 2026-06-28T08:32:47.291Z