Estimating gate-set properties from random sequences

With quantum devices for computing and simulation increasing in scale and complexity, there is a growing need for tools that obtain precise diagnostic information about quantum operations.

In this work, we show that by measuring random gate sequences, one can accurately and efficiently estimate a wealth of different properties of noisy implementations of gate sets. This simple experimental protocol is independent of the properties one intends to estimate. It generates `sequence  shadows' from which gate-set properties can be extracted, through classical post-processing, in a state preparation and measurement error robust way. Our schemes include protocols to extract many average gate fidelities with respect to arbitrary unitary channels. This - as a special case - emulates (interleaved) randomized benchmarking, but is vastly more general in its applicability. We establish that the sequence estimation scheme can be used as a primitive for partial, compressive and full process tomography, and the learning of Pauli noise. This gives rise to channel variants of shadow estimation with close-to optimal performance guarantees. Finally, we discuss applications to the engineering cycle for the optimization of quantum gates, for instance as a novel method to diagnose crosstalk.