English

Quantum circuit compilation and hybrid computation using Pauli-based computation

Quantum Physics 2023-10-04 v2

Abstract

Pauli-based computation (PBC) is driven by a sequence of adaptively chosen, non-destructive measurements of Pauli observables. Any quantum circuit written in terms of the Clifford+TT gate set and having tt TT gates can be compiled into a PBC on tt qubits. Here we propose practical ways of implementing PBC as adaptive quantum circuits and provide code to do the required classical side-processing. Our schemes reduce the number of quantum gates to O(t2)O(t^2) (from a previous O(t3/logt)O(t^3 / \log t) scaling) and space/time trade-offs are discussed which lead to a reduction of the depth from O(tlogt)O(t \log t) to O(t)O(t) within our schemes, at the cost of tt additional auxiliary qubits. We compile examples of random and hidden-shift quantum circuits into adaptive PBC circuits. We also simulate hybrid quantum computation, where a classical computer effectively extends the working memory of a small quantum computer by kk virtual qubits, at a cost exponential in kk. Our results demonstrate the practical advantage of PBC techniques for circuit compilation and hybrid computation.

Keywords

Cite

@article{arxiv.2203.01789,
  title  = {Quantum circuit compilation and hybrid computation using Pauli-based computation},
  author = {Filipa C. R. Peres and Ernesto F. Galvão},
  journal= {arXiv preprint arXiv:2203.01789},
  year   = {2023}
}

Comments

28 pages, 14 figures, includes links to a GitHub repository for Python software implementing all tasks discussed in the paper

R2 v1 2026-06-24T10:01:00.238Z