Litcius/Paper detail

Independent state and measurement characterization for quantum computers

Junan Lin, Joel J. Wallman, Ian Hincks, Raymond Laflamme

2021Physical Review Research28 citationsDOIOpen Access PDF

Abstract

Correctly characterizing state preparation and measurement (SPAM) processes is a necessary step towards building reliable quantum processing units (QPUs). In this work, we discuss the subtleties behind separately measuring SPAM errors. We propose a protocol that can separately estimate SPAM errors, in the case where quantum gates are ideal. In the case where the quantum gates are imperfect, we derive bounds on the estimated SPAM error rates, based on gate error measures, which can be estimated independently of SPAM processes. Our method shows that the gauge ambiguity in characterizing SPAM operations can be resolved by assuming that there exists one qubit whose initial state is uncorrelated with other qubits in a QPU. We test the protocol on a publicly available five-qubit QPU and demonstrate its validity by comparing our results with simulations.

Topics & Concepts

QubitAmbiguityQuantum error correctionProtocol (science)State (computer science)Quantum gateComputer scienceQuantum computerQuantumCharacterization (materials science)AlgorithmUncorrelatedQuantum algorithmQuantum stateScheme (mathematics)Quantum circuitQuantum mechanicsMathematicsQuantum measurementQuantum information processingTask (project management)Gauge (firearms)Theoretical computer scienceMeasure (data warehouse)Quantum informationMeasurement deviceQuantum operationPhysicsQuantum logicOne-way quantum computerDimension (graph theory)Coin flippingQuantum networkStatistical physicsControlled NOT gateQuantum phase estimation algorithmObservational errorError detection and correctionTopology (electrical circuits)Weak measurementQuantum Computing Algorithms and ArchitectureQuantum Information and CryptographyQuantum-Dot Cellular Automata