Full-counting statistics and quantum information of dispersive readout with a squeezed environment
- URL: http://arxiv.org/abs/2512.02531v1
- Date: Tue, 02 Dec 2025 08:54:33 GMT
- Title: Full-counting statistics and quantum information of dispersive readout with a squeezed environment
- Authors: Ming Li, JunYan Luo, Gloria Platero, Georg Engelhardt,
- Abstract summary: We study a prototypical dispersive readout setup that is probed by a squeezed vacuum in a time-reversal-symmetric fashion.<n>We develop a full-counting-statistics framework for dispersive readout and analyze its measurement information.
- Score: 4.443295371060434
- License: http://creativecommons.org/licenses/by/4.0/
- Abstract: Motivated by the importance of dispersive readout in quantum technology, we study a prototypical dispersive readout setup that is probed by a squeezed vacuum in a time-reversal-symmetric fashion. To this end, we develop a full-counting-statistics framework for dispersive readout and analyze its measurement information, accompanied by a generalized mean-field approach suitable to deal with non-unitary dynamics. Distinct from conventional input-output theory, our full-counting-statistics approach enables the direct calculation of arbitrary-order cumulants for the measured cumulative (i.e., time-integrated) photonic distribution while maintaining applicability to nonlinear systems. The corresponding Fisher information exhibits an exponential dependence on the squeezing parameter and a robustness against residual nonlinearity, which can even approach the quantum Fisher information, setting an upper limit. This work introduces a conceptually streamlined and computationally efficient framework for continuous quantum measurements, making it well suited for widespread adoption in quantum technologies.
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