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Measurement error mitigation in quantum computers through classical bit-flip correction

Lena Funcke, Tobias Hartung, Karl Jansen, Stefan Kühn, Paolo Stornati, Xiaoyang Wang

2022Physical review. A/Physical review, A66 citationsDOIOpen Access PDF

Abstract

We develop a classical bit-flip correction method to mitigate measurement errors on quantum computers. This method can be applied to any operator, any number of qubits, and any realistic bit-flip probability. We first demonstrate the successful performance of this method by correcting the noisy measurements of the ground-state energy of the longitudinal Ising model. We then generalize our results to arbitrary operators and test our method both numerically and experimentally on IBM quantum hardware. As a result, our correction method reduces the measurement error on the quantum hardware by up to one order of magnitude. We finally discuss how to preprocess the method and extend it to other error sources beyond measurement errors. For local Hamiltonians, the overhead costs are polynomial in the number of qubits, even if multiqubit correlations are included.

Topics & Concepts

QubitError detection and correctionComputer scienceQuantum computerOverhead (engineering)Quantum error correctionOperator (biology)AlgorithmQuantumQuantum mechanicsPhysicsGeneBiochemistryOperating systemChemistryRepressorTranscription factorQuantum Computing Algorithms and ArchitectureQuantum Information and CryptographyQuantum and electron transport phenomena
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