Nonasymptotic bounds for quantum purity amplification

Abstract

In quantum purity amplification, one is given n copies of a noisy quantum state ρ∈ Cd × d and asked to prepare k copies of its principal eigenstate |vd. Several prior works have derived information-theoretically optimal algorithms for this problem, but the bounds they prove are only shown in the asymptotic regime as the number of samples n tends to infinity. In this paper, we establish the following nonasymptotic guarantee: if ρ's eigenvalues are sorted p1 ≤ ·s ≤ pd and pd-1 < pd, then equation* n = O(k + kδ · 1-pd(pd-pd-1)2) equation* copies suffice to output a state with fidelity at least 1-δ with |vd k. Our bound holds for arbitrary spectra, and is independent of the dimension d. In the case of depolarizing noise, our finite-sample guarantee matches the optimal asymptotic scaling. Our proof is based on the combinatorics of random Young diagrams.