Hsieh, Hsien-Yi scite author profile

We experimentally reconstruct Wigner's quantum phase current for the first time. Using an optical parametric oscillator, coupled to the environment, at varying pump powers, allows us to directly observe signatures of quantum phase space dynamics for the creation of squeezed states. Our approach allows identifying pure squeezing dynamics as well as dissipation and decoherence currents. The central stagnation point of the current shows a topological charge of -1, this is generic for the dynamics of squeezer setups. This work establishes a novel experimental paradigm for measuring quantumness and non-classicality of the dynamics of a quantum system.

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Direct Parameter Estimations from Machine Learning-Enhanced Quantum State Tomography

Hsien-Yi

Ning

Chen

et al. 2022

Symmetry

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With the power to find the best fit to arbitrarily complicated symmetry, machine-learning (ML)-enhanced quantum state tomography (QST) has demonstrated its advantages in extracting complete information about the quantum states. Instead of using the reconstruction model in training a truncated density matrix, we develop a high-performance, lightweight, and easy-to-install supervised characteristic model by generating the target parameters directly. Such a characteristic model-based ML-QST can avoid the problem of dealing with a large Hilbert space, but cab keep feature extractions with high precision, capturing the underlying symmetry in data. With the experimentally measured data generated from the balanced homodyne detectors, we compare the degradation information about quantum noise squeezed states predicted by the reconstruction and characteristic models; both are in agreement with the empirically fitting curves obtained from the covariance method. Such a ML-QST with direct parameter estimations illustrates a crucial diagnostic toolbox for applications with squeezed states, from quantum information process, quantum metrology, advanced gravitational wave detectors, to macroscopic quantum state generation.

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Direct parameter estimations from machine-learning enhanced quantum state tomography

Hsien-Yi¹,

Ning²,

Chen³

et al. 2022

Preprint

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With the capability to find the best fit to arbitrarily complicated data patterns, machine-learning (ML) enhanced quantum state tomography (QST) has demonstrated its advantages in extracting complete information about the quantum states. Instead of using the reconstruction model in training a truncated density matrix, we develop a high-performance, lightweight, and easy-to-install supervised characteristic model by generating the target parameters directly. Such a characteristic model-based ML-QST can avoid the problem of dealing with large Hilbert space, but keep feature extractions with high precision. With the experimentally measured data generated from the balanced homodyne detectors, we compare the degradation information about quantum noise squeezed states predicted by the reconstruction and characteristic models, both give agreement to the empirically fitting curves obtained from the covariance method. Such a ML-QST with direct parameter estimations illustrates a crucial diagnostic toolbox for applications with squeezed states, including advanced gravitational wave detectors, quantum metrology, macroscopic quantum state generation, and quantum information process.

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Hsieh, Hsien-Yi

Extract the Degradation Information in Squeezed States with Machine Learning

Experimental Demonstration of Topological Charge Protection in Wigner Current

Direct Parameter Estimations from Machine Learning-Enhanced Quantum State Tomography

Direct parameter estimations from machine-learning enhanced quantum state tomography

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