English

Quantum Coupon Collector

Quantum Physics 2020-07-06 v1 Emerging Technologies

Abstract

We study how efficiently a kk-element set S[n]S\subseteq[n] can be learned from a uniform superposition S|S\rangle of its elements. One can think of S=iSi/S|S\rangle=\sum_{i\in S}|i\rangle/\sqrt{|S|} as the quantum version of a uniformly random sample over SS, as in the classical analysis of the ``coupon collector problem.'' We show that if kk is close to nn, then we can learn SS using asymptotically fewer quantum samples than random samples. In particular, if there are nk=O(1)n-k=O(1) missing elements then O(k)O(k) copies of S|S\rangle suffice, in contrast to the Θ(klogk)\Theta(k\log k) random samples needed by a classical coupon collector. On the other hand, if nk=Ω(k)n-k=\Omega(k), then Ω(klogk)\Omega(k\log k) quantum samples are~necessary. More generally, we give tight bounds on the number of quantum samples needed for every kk and nn, and we give efficient quantum learning algorithms. We also give tight bounds in the model where we can additionally reflect through S|S\rangle. Finally, we relate coupon collection to a known example separating proper and improper PAC learning that turns out to show no separation in the quantum case.

Keywords

Cite

@article{arxiv.2002.07688,
  title  = {Quantum Coupon Collector},
  author = {Srinivasan Arunachalam and Aleksandrs Belovs and Andrew M. Childs and Robin Kothari and Ansis Rosmanis and Ronald de Wolf},
  journal= {arXiv preprint arXiv:2002.07688},
  year   = {2020}
}

Comments

17 pages LaTeX

R2 v1 2026-06-23T13:45:37.036Z