Coherent randomized benchmarking

TL;DR

This paper introduces a coherent randomized benchmarking protocol that uses superpositions of sequences, offering advantages in efficiency, scalability, and the ability to benchmark diverse quantum gate sets.

Contribution

It proposes a novel coherent approach to randomized benchmarking that improves efficiency and can benchmark a wide range of quantum gates using auxiliary degrees of freedom.

Findings

Efficient benchmarking of universal gate sets and multi-qudit operations.

Coherent protocol offers simplicity and scalability benefits.

Auxiliary degrees of freedom enable control without affecting the tested gates.

Abstract

Randomized benchmarking is a powerful technique to efficiently estimate the performance and reliability of quantum gates, circuits and devices. Here we propose to perform randomized benchmarking in a coherent way, where superpositions of different random sequences rather than independent samples are used. We show that this leads to a uniform and simple protocol with significant advantages with respect to gates that can be benchmarked, and in terms of efficiency and scalability. We show that e.g. universal gate sets, the set of $n-$qudit Pauli operators or more general sets including arbitrary unitaries, as well as a particular $n-$qudit Clifford gate using only the Pauli set, can be efficiently benchmarked. The price to pay is an additional complexity to add control to the involved quantum operations. However we demonstrate that this can be done by using auxiliary degrees of freedom that are naturally available in basically any physical realization, and are independent of the gates to be tested.