Instance-optimal high-precision shadow tomography with few-copy measurementsConfirmed

by Sisi Zhou (Perimeter Institute for Theoretical Physics)

Wednesday Apr 15, 2026, 1:00 PM → 2:30 PM America/Toronto

PI/4-405 - Bob Room (Perimeter Institute for Theoretical Physics)

We give the first instance-optimal sample complexity bounds for shadow tomography using few-copy measurements in the high-precision regime. More concretely, we study the problem of learning expectation values of a given set of observables of an unknown quantum state to precision $\epsilon$ in $L_p$-norm, using (possibly adaptive) measurements that act on one or a few copies at a time, and we are interested in the regime that $\epsilon$ is below some concrete and potentially dimension-dependent threshold. In this setup, we prove the necessary and sufficient number of copies, for any given set of observables, is characterized by a simple optimization formula involving a quadratic form of the inverse Fisher information matrix up to a logarithmic factor. Our results establish a rigorous correspondence between quantum learning and quantum metrology.