English

A random matrix model for random approximate $t$-designs

Quantum Physics 2024-04-17 v3 Mathematical Physics math.MP Probability

Abstract

For a Haar random set SU(d)\mathcal{S}\subset U(d) of quantum gates we consider the uniform measure νS\nu_\mathcal{S} whose support is given by S\mathcal{S}. The measure νS\nu_\mathcal{S} can be regarded as a δ(νS,t)\delta(\nu_\mathcal{S},t)-approximate tt-design, tZ+t\in\mathbb{Z}_+. We propose a random matrix model that aims to describe the probability distribution of δ(νS,t)\delta(\nu_\mathcal{S},t) for any tt. Our model is given by a block diagonal matrix whose blocks are independent, given by Gaussian or Ginibre ensembles, and their number, size and type is determined by tt. We prove that, the operator norm of this matrix, δ(t)\delta({t}), is the random variable to which Sδ(νS,t)\sqrt{|\mathcal{S}|}\delta(\nu_\mathcal{S},t) converges in distribution when the number of elements in S\mathcal{S} grows to infinity. Moreover, we characterize our model giving explicit bounds on the tail probabilities P(δ(t)>2+ϵ)\mathbb{P}(\delta(t)>2+\epsilon), for any ϵ>0\epsilon>0. We also show that our model satisfies the so-called spectral gap conjecture, i.e. we prove that with the probability 11 there is tZ+t\in\mathbb{Z}_+ such that supkZ+δ(k)=δ(t)\sup_{k\in\mathbb{Z}_{+}}\delta(k)=\delta(t). Numerical simulations give convincing evidence that the proposed model is actually almost exact for any cardinality of S\mathcal{S}. The heuristic explanation of this phenomenon, that we provide, leads us to conjecture that the tail probabilities P(Sδ(νS,t)>2+ϵ)\mathbb{P}(\sqrt{\mathcal{S}}\delta(\nu_\mathcal{S},t)>2+\epsilon) are bounded from above by the tail probabilities P(δ(t)>2+ϵ)\mathbb{P}(\delta(t)>2+\epsilon) of our random matrix model. In particular our conjecture implies that a Haar random set SU(d)\mathcal{S}\subset U(d) satisfies the spectral gap conjecture with the probability 11.

Keywords

Cite

@article{arxiv.2210.07872,
  title  = {A random matrix model for random approximate $t$-designs},
  author = {Piotr Dulian and Adam Sawicki},
  journal= {arXiv preprint arXiv:2210.07872},
  year   = {2024}
}

Comments

41 pages, some references added, some changes in presentation in particular in Section 6

R2 v1 2026-06-28T03:39:33.246Z