Instance-optimal high-precision shadow tomography with few-copy measurements: A metrological approach

Abstract

We study the sample complexity of shadow tomography in the high-precision regime under realistic measurement constraints. Given an unknown d-dimensional quantum state and a known set of observables \Oi\i=1m, the goal is to estimate expectation values \tr(Oi)\i=1m to accuracy ε in Lp-norm, using possibly adaptive measurements that act on O(polylog(d)) number of copies of at a time. We focus on the regime where ε is below an instance-dependent threshold. Our main contribution is an instance-optimal characterization of the sample complexity as (p/ε2), where p is a function of \Oi\i=1m defined via an optimization formula involving the inverse Fisher information matrix. Previously, tight bounds were known only in special cases, e.g. Pauli shadow tomography with L∞-norm error. Concretely, we first analyze a simpler oblivious variant where the goal is to estimate an observable of the form Σi=1m αi Oi with \|α\|q = 1 (where q is dual to p) revealed after the measurement. For single-copy measurements, we obtain a sample complexity of (obp/ε2). We then show (p/ε2) is necessary and sufficient for the original problem, with the lower bound applying to unbiased, bounded estimators. Our upper bounds rely on a two-step algorithm combining coarse tomography with local estimation. Notably, ob∞ = ∞. In both cases, allowing c-copy measurements improves the sample complexity by at most (1/c). Our results establish a quantitative correspondence between quantum learning and metrology, unifying asymptotic metrological limits with finite-sample learning guarantees.