Mitigation of Crosstalk Errors in a Quantum Measurement and Its Applications

Abstract: In practical realizations of quantum information processing, there may exist noise in a measurement readout stage where errors appear not only on individual qubits but also on multiple ones collectively, the latter of which is called crosstalk errors. In this work, we present a framework for mitigating measurement errors, for both individual and crosstalk errors. The mitigation protocol consists of two steps, firstly quantum pre-processing, which applies local unitary transformations before a measurement, and classical post-processing that manipulates measurement outcomes to recover noiseless data. The local unitaries in quantum pre-processing can be constructed by characterizing a noisy measurement via quantum detector tomography. We show that the mitigation protocol can maintain a measurement error on multiple qubits as much as that in a single-qubit readout, i.e., the error rates for measurements on multiple qubits are suppressed up to a percent level. The mitigation protocol is realized in IBMQ Sydney and applied to the certification of entanglement-generating circuits. It is demonstrated that the mitigation protocol can successfully eliminate measurement errors so that entanglement-generation circuits can be efficiently certified.