Tomography of quantum states with bounded extent

Abstract

We give a general framework for tomography of states that have bounded-extent with respect to a structured class of states. Let C be a family of n-qubit states such that: (i) C is succinctly representable and (ii) there is a weak agnostic learner of C. We give a tomography protocol for an unknown state |ψ that is promised to admit a decomposition of the form |ψ = Σi ci |ϕi, where |ϕi ∈ C with bounded 1-norm of the coefficients (which we call extent). Our main contribution is to show that a weak agnostic learner for C can be boosted into a tomography algorithm for states with bounded extent with respect to C. Our reduction is black-box and applies broadly across model classes. As an application, when C is the class of stabilizer states, we obtain tomography algorithms for states with stabilizer extent ξ up to trace distance , in time poly(n,(ξ/)(ξ/)), which is improvable to poly(n,ξ,1/) assuming the algorithmic polynomial Freiman-Ruzsa conjecture in the high-doubling regime. When the unknown state |ψ is arbitrary, we give an algorithmic decomposition result in the spirit of a weak regularity lemma for quantum states with respect to C and show that the structure in |ψ that is explainable by C can be efficiently learned. Our main conceptual message is that agnostic learning of a structured base class automatically yields learnability of its low-complexity linear span.