Fast quantum measurement tomography with dimension-optimal error bounds

Abstract

We present a two-step protocol for quantum measurement tomography that is light on classical co-processing cost and still achieves optimal sample complexity in the system dimension. Given measurement data from a known probe state ensemble, we first apply least-squares estimation to produce an unconstrained approximation of the POVM, and then project this estimate onto the set of valid quantum measurements. For a POVM with L outcomes acting on a d-dimensional system, we show that the protocol requires O(d3 L (d)/ε2) samples to achieve error ε in worst-case distance, and O(d2 L2 (dL)/ε2) samples in average-case distance. We further establish two almost matching sample complexity lower bounds of (d3/ε2) and (d2 L/ε2) for any non-adaptive, single-copy POVM tomography protocol. Hence, our projected least squares POVM tomography is sample-optimal in dimension d up to logarithmic factors. Our method admits an analytic form when using global or local 2-designs as probe ensembles and enables rigorous non-asymptotic error guarantees. Finally, we also complement our findings with empirical performance studies carried out on a noisy superconducting quantum computer with flux-tunable transmon qubits.