English

Negative Quasi-Probability as a Resource for Quantum Computation

Quantum Physics 2012-11-30 v4

Abstract

A central problem in quantum information is to determine the minimal physical resources that are required for quantum computational speedup and, in particular, for fault-tolerant quantum computation. We establish a remarkable connection between the potential for quantum speed-up and the onset of negative values in a distinguished quasi-probability representation, a discrete analog of the Wigner function for quantum systems of odd dimension. This connection allows us to resolve an open question on the existence of bound states for magic-state distillation: we prove that there exist mixed states outside the convex hull of stabilizer states that cannot be distilled to non-stabilizer target states using stabilizer operations. We also provide an efficient simulation protocol for Clifford circuits that extends to a large class of mixed states, including bound universal states.

Keywords

Cite

@article{arxiv.1201.1256,
  title  = {Negative Quasi-Probability as a Resource for Quantum Computation},
  author = {Victor Veitch and Christopher Ferrie and David Gross and Joseph Emerson},
  journal= {arXiv preprint arXiv:1201.1256},
  year   = {2012}
}

Comments

15 pages v4: This is a major revision. In particular, we have added a new section detailing an explicit extension of the Gottesman-Knill simulation protocol to deal with positively represented states and measurement (even when these are non-stabilizer). This paper also includes significant elaboration on the two main results of the previous version

R2 v1 2026-06-21T20:00:55.492Z