Abstract
Randomized benchmarking (RB) is a powerful method for determining the error rate of experimental quantum gates. Traditional RB, however, is restricted to gatesets, such as the Clifford group, that form a unitary 2-design. The recently introduced character RB can benchmark more general gates using techniques from representation theory; up to now, however, this method has only been applied to "multiplicity-free" groups, a mathematical restriction on these groups. In this paper, we extend the original character RB derivation to explicitly treat non-multiplicity-free groups, and derive several applications. First, we derive a rigorous version of the recently introduced subspace RB, which seeks to characterize a set of one- and two-qubit gates that are symmetric under SWAP. Second, we develop a new leakage RB protocol that applies to more general groups of gates. Finally, we derive a scalable RB protocol for the matchgate group, a group that like the Clifford group is non-universal but becomes universal with the addition of one additional gate. This example provides one of the few examples of a scalable non-Clifford RB protocol. In all three cases, compared to existing theories, our method requires similar resources, but either provides a more accurate estimate of gate fidelity, or applies to a more general group of gates. In conclusion, we discuss the potential, and challenges, of using non-multiplicity-free character RB to develop new classes of scalable RB protocols and methods of characterizing specific gates.
Highlights
Advances in accurate and scalable methods for characterizing the performance of quantum gates are critical for the realization of large-scale reliable quantum computers
We provide a generalization of character Randomized benchmarking (RB) that applies to groups with multiplicity, which we underpin with rigorous derivations
Our main contributions include: (a) We provide a derivation of character RB for nonmultiplicity-free groups G
Summary
Advances in accurate and scalable methods for characterizing the performance of quantum gates are critical for the realization of large-scale reliable quantum computers. (a) We provide a derivation of character RB for nonmultiplicity-free groups G This RB method allows us to directly predict the average fidelity of the gates in G as in Ref. [23], the method can be applied directly to other gates with the same SWAP symmetry as the UZZ gate It provides grounding for benchmarking gates with other subspace-preserving symmetries, though creativity will be required to determine when and how these gates can be combined with single-qubit gates to obtain a group with the properties that yield a practical character RB protocol. Non-multiplicity-free character RB is a general framework for benchmarking groups of quantum gates It provides a method for characterizing individual gates when the gates can be combined into operations that form a group, as we illustrate in the case of subspace RB.
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