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Improving the dynamics of quantum sensors with reinforcement learning

Jonas Schuff, Lukas J Fiderer, Daniel Braun

2020New Journal of Physics49 citationsDOIOpen Access PDF

Abstract

Abstract Recently proposed quantum-chaotic sensors achieve quantum enhancements in measurement precision by applying nonlinear control pulses to the dynamics of the quantum sensor while using classical initial states that are easy to prepare. Here, we use the cross-entropy method of reinforcement learning (RL) to optimize the strength and position of control pulses. Compared to the quantum-chaotic sensors with periodic control pulses in the presence of superradiant damping, we find that decoherence can be fought even better and measurement precision can be enhanced further by optimizing the control. In some examples, we find enhancements in sensitivity by more than an order of magnitude. By visualizing the evolution of the quantum state, the mechanism exploited by the RL method is identified as a kind of spin-squeezing strategy that is adapted to the superradiant damping.

Topics & Concepts

PhysicsQuantum decoherenceQuantumReinforcement learningSensitivity (control systems)Position (finance)Nonlinear systemQuantum sensorDynamics (music)Quantum dynamicsStatistical physicsQuantum systemControl (management)Mechanism (biology)Quantum controlCoherent controlQuantum mechanicsSimple (philosophy)Quantum measurementOpen quantum systemMeasurement deviceClassical mechanicsMechanical and Optical ResonatorsNeural Networks and Reservoir ComputingQuantum Information and Cryptography
Improving the dynamics of quantum sensors with reinforcement learning | Litcius