English

Circuit connectivity boosts by quantum-classical-quantum interfaces

Quantum Physics 2023-03-21 v1

Abstract

High-connectivity circuits are a major roadblock for current quantum hardware. We propose a hybrid classical-quantum algorithm to simulate such circuits without swap-gate ladders. As main technical tool, we introduce quantum-classical-quantum interfaces. These replace an experimentally problematic gate (e.g. a long-range one) by single-qubit random measurements followed by state-preparations sampled according to a classical quasi-probability simulation of the noiseless gate. Each interface introduces a multiplicative statistical overhead which is remarkably independent of the on-chip qubit distance. Hence, by applying interfaces to the longest range gates in a target circuit, significant reductions in circuit depth and gate infidelity can be attained. We numerically show the efficacy of our method for a Bell-state circuit for two increasingly distant qubits and a variational ground-state solver for the transverse-field Ising model on a ring. Our findings provide a versatile toolbox for error-mitigation and circuit boosts tailored for noisy, intermediate-scale quantum computation.

Keywords

Cite

@article{arxiv.2203.04984,
  title  = {Circuit connectivity boosts by quantum-classical-quantum interfaces},
  author = {Roeland Wiersema and Leonardo Guerini and Juan Felipe Carrasquilla and Leandro Aolita},
  journal= {arXiv preprint arXiv:2203.04984},
  year   = {2023}
}
R2 v1 2026-06-24T10:07:51.565Z