Rigorous measurement error correction
Michael R Geller
Abstract
Abstract We review an experimental technique used to correct state preparation and measurement errors on gate-based quantum computers, and discuss its rigorous justification. Within a specific biased quantum measurement model, we prove that nonideal measurement of an arbitrary n -qubit state is equivalent to ideal projective measurement followed by a classical Markov process Γ acting on the output probability distribution. Measurement errors can be removed, with rigorous justification, if Γ can be learned and inverted. We show how to obtain Γ from gate set tomography (Blume-Kohout et al arXiv:1310.4492) and apply the rigorous correction technique to single IBM Q superconducting qubits.
Topics & Concepts
AlgorithmError detection and correctionIdeal (ethics)Set (abstract data type)Observational errorQuantum error correctionMarkov processState (computer science)Computer scienceMathematicsMarkov chainQuantumProcess (computing)Measurement uncertaintyQuantum tomographySystematic errorCalculus (dental)Quantum processQuantum computerQuantum measurementMeasure (data warehouse)Quantum systemQuantum stateDiscrete mathematicsError analysisQuantum algorithmQuantum Computing Algorithms and ArchitectureQuantum Information and CryptographyQuantum Mechanics and Applications