English

Fast quantum circuit cutting with randomized measurements

Quantum Physics 2023-03-08 v2

Abstract

We propose a new method to extend the size of a quantum computation beyond the number of physical qubits available on a single device. This is accomplished by randomly inserting measure-and-prepare channels to express the output state of a large circuit as a separable state across distinct devices. Our method employs randomized measurements, resulting in a sample overhead that is O~(4k/ε2)\widetilde{O}(4^k / \varepsilon ^2), where ε\varepsilon is the accuracy of the computation and kk the number of parallel wires that are "cut" to obtain smaller sub-circuits. We also show an information-theoretic lower bound of Ω(2k/ε2)\Omega(2^k / \varepsilon ^2) for any comparable procedure. We use our techniques to show that circuits in the Quantum Approximate Optimization Algorithm (QAOA) with pp entangling layers can be simulated by circuits on a fraction of the original number of qubits with an overhead that is roughly 2O(pκ)2^{O(p\kappa)}, where κ\kappa is the size of a known balanced vertex separator of the graph which encodes the optimization problem. We obtain numerical evidence of practical speedups using our method applied to the QAOA, compared to prior work. Finally, we investigate the practical feasibility of applying the circuit cutting procedure to large-scale QAOA problems on clustered graphs by using a 3030-qubit simulator to evaluate the variational energy of a 129129-qubit problem as well as carry out a 6262-qubit optimization.

Keywords

Cite

@article{arxiv.2207.14734,
  title  = {Fast quantum circuit cutting with randomized measurements},
  author = {Angus Lowe and Matija Medvidović and Anthony Hayes and Lee J. O'Riordan and Thomas R. Bromley and Juan Miguel Arrazola and Nathan Killoran},
  journal= {arXiv preprint arXiv:2207.14734},
  year   = {2023}
}

Comments

9 pages, 6 figures

R2 v1 2026-06-25T01:20:09.570Z