Zhihan Zhang, Senrui Chen, Yunchao Liu, Liang Jiang (Jun 06 2024).
Abstract: Mid-circuit measurement (MCM) is a crucial ingredient in the development of fault-tolerant quantum computation. While there have been rapid experimental progresses in realizing MCM, a systematic method for characterizing noisy MCM is still under exploration. In this work we develop an algorithm to characterize noisy MCM, via a generalization of cycle benchmarking – a standard approach for characterizing the Pauli noise channel of Clifford gates. The key idea is to use a joint Fourier transform on the classical and quantum registers and then estimate parameters in the Fourier space, analogous to Pauli fidelities used in cycle benchmarking. Furthermore, we develop a theory of the noise learnability of MCM, which determines what information can be learned about the noise model (in the presence of state preparation and measurement noise) and what cannot, which shows that all learnable information can be learned using our algorithm. As an application, we show how to use the learned information to test the independence between measurement noise and state preparation noise in a MCM. Finally, we conduct numerical simulations to illustrate the practical applicability of the algorithm. Similar to cycle benchmarking, we expect the algorithm to provide a useful toolkit that is of experimental interest.