English

Epsilon-nets, unitary designs and random quantum circuits

Quantum Physics 2021-11-02 v3 Mathematical Physics math.MP

Abstract

Epsilon-nets and approximate unitary tt-designs are natural notions that capture properties of unitary operations relevant for numerous applications in quantum information and quantum computing. The former constitute subsets of unitary channels that are epsilon-close to any unitary channel in the diamond norm. The latter are ensembles of unitaries that (approximately) recover Haar averages of polynomials in entries of unitary channels up to order tt. In this work we establish quantitative connections between these two notions. Specifically, we prove that, for a fixed dimension dd of the Hilbert space, unitaries constituting δ\delta-approximate tt-expanders form ϵ\epsilon-nets for td5/2ϵt\simeq\frac{d^{5/2}}{\epsilon} and δ=(ϵ3/2d)d2\delta=\left(\frac{\epsilon^{3/2}}{d}\right)^{d^2}. We also show that ϵ\epsilon-nets can be used to construct δ\delta-approximate unitary tt-designs for δ=ϵt\delta= \epsilon t. Finally, we prove that the degree of an exact unitary tt-design necessary to obtain an ϵ\epsilon-net must grow at least fast as 1ϵ\frac1\epsilon (for fixed dd) and not slower than d2d^2 (for fixed ϵ\epsilon). This shows near optimality of our result connecting tt-designs and ϵ\epsilon-nets. We apply our findings in the context of quantum computing. First, we show that that approximate t-designs can be generated by shallow random circuits formed from a set of universal two-qudit gates in the parallel and sequential local architectures. Our gate sets need not to be symmetric (i.e. contain gates together with their inverses) or consist of gates with algebraic entries. We also show a non-constructive version of the Solovay-Kitaev theorem for general universal gate sets. Our main technical contribution is a new construction of efficient polynomial approximations to the Dirac delta in the space of quantum channels, which can be of independent interest.

Cite

@article{arxiv.2007.10885,
  title  = {Epsilon-nets, unitary designs and random quantum circuits},
  author = {Michał Oszmaniec and Adam Sawicki and Michał Horodecki},
  journal= {arXiv preprint arXiv:2007.10885},
  year   = {2021}
}

Comments

26 pages + 17 pages of appendix, 3 figures, accepted in IEEE: Transactions in Information Theory, Important changes in ver 3: (i) Corrected estimates for volumes of balls in projective unitary group, (ii) bounds on the L1 of the approximation to the Dirac delta given. (iii) updated references

R2 v1 2026-06-23T17:17:17.662Z