English

Exact Quantum Circuit Optimization is co-NQP-hard

Quantum Physics 2026-02-27 v2 Computational Complexity

Abstract

As quantum computing resources remain scarce and error rates high, minimizing the resource consumption of quantum circuits is essential for achieving practical quantum advantage. Here we consider the natural problem of, given a circuit CC, computing a circuit CC' which behaves equivalently on a desired subspace, and that minimizes a quantum resource type, expressed as the count or depth of (i) arbitrary gates, or (ii) non-Clifford gates, or (iii) superposition gates, or (iv) entanglement gates. We show that, when CC is expressed over any gate set that can implement the H and TOF gates exactly, each of the above optimization problems is hard for co-NQP\text{co-NQP}, and hence outside the Polynomial Hierarchy, unless the Polynomial Hierarchy collapses. This complements recent results in the literature which established an NP\text{NP}-hardness lower bound when equivalence is over the full state space, and tightens the gap to the corresponding NPNQP\text{NP}^{\text{NQP}} upper bound known for cases (i)-(iii) over Clifford+T and (i)-(iv) over H+TOF circuits.

Keywords

Cite

@article{arxiv.2510.16420,
  title  = {Exact Quantum Circuit Optimization is co-NQP-hard},
  author = {Adam Husted Kjelstrøm and Andreas Pavlogiannis and Jaco van de Pol},
  journal= {arXiv preprint arXiv:2510.16420},
  year   = {2026}
}

Comments

12 pages, 3 figures

R2 v1 2026-07-01T06:44:49.863Z