Litcius/Paper detail

Variational Principle for Optimal Quantum Controls in Quantum Metrology

Jing Yang, Shengshi Pang, Zekai Chen, Andrew N. Jordan, Adolfo del Campo

2022Physical Review Letters47 citationsDOIOpen Access PDF

Abstract

We develop a variational principle to determine the quantum controls and initial state that optimizes the quantum Fisher information, the quantity characterizing the precision in quantum metrology. When the set of available controls is limited, the exact optimal initial state and the optimal controls are, in general, dependent on the probe time, a feature missing in the unrestricted case. Yet, for time-independent Hamiltonians with restricted controls, the problem can be approximately reduced to the unconstrained case via Floquet engineering. In particular, we find for magnetometry with a time-independent spin chain containing three-body interactions, even when the controls are restricted to one- and two-body interaction, that the Heisenberg scaling can still be approximately achieved. Our results open the door to investigate quantum metrology under a limited set of available controls, of relevance to many-body quantum metrology in realistic scenarios.

Topics & Concepts

Quantum metrologyPhysicsHeisenberg limitQuantumQuantum mechanicsMetrologyUncertainty principleQuantum stateScalingVariational principleQuantum sensorFloquet theoryStatistical physicsSet (abstract data type)State (computer science)Spin (aerodynamics)Quantization (signal processing)Quantum algorithmQuantum systemQuantum limitCoherent statesQuantum error correctionMagnetometerOpen quantum systemQuantum operationQuantum processMeasure (data warehouse)Quantum technologyCoherence (philosophical gambling strategy)Quantum opticsQuantum Information and CryptographyQuantum Computing Algorithms and ArchitectureQuantum many-body systems