English

Trading classical and quantum computational resources

Quantum Physics 2016-07-06 v1

Abstract

We propose examples of a hybrid quantum-classical simulation where a classical computer assisted by a small quantum processor can efficiently simulate a larger quantum system. First we consider sparse quantum circuits such that each qubit participates in O(1) two-qubit gates. It is shown that any sparse circuit on n+k qubits can be simulated by sparse circuits on n qubits and a classical processing that takes time 2O(k)poly(n)2^{O(k)} poly(n). Secondly, we study Pauli-based computation (PBC) where allowed operations are non-destructive eigenvalue measurements of n-qubit Pauli operators. The computation begins by initializing each qubit in the so-called magic state. This model is known to be equivalent to the universal quantum computer. We show that any PBC on n+k qubits can be simulated by PBCs on n qubits and a classical processing that takes time 2O(k)poly(n)2^{O(k)} poly(n). Finally, we propose a purely classical algorithm that can simulate a PBC on n qubits in a time 2cnpoly(n)2^{c n} poly(n) where c0.94c\approx 0.94. This improves upon the brute-force simulation method which takes time 2npoly(n)2^n poly(n). Our algorithm exploits the fact that n-fold tensor products of magic states admit a low-rank decomposition into n-qubit stabilizer states.

Keywords

Cite

@article{arxiv.1506.01396,
  title  = {Trading classical and quantum computational resources},
  author = {Sergey Bravyi and Graeme Smith and John Smolin},
  journal= {arXiv preprint arXiv:1506.01396},
  year   = {2016}
}

Comments

14 pages, 4 figures

R2 v1 2026-06-22T09:46:54.367Z