Photonic quantum metrology with variational quantum optical non-linearities
ORAL
Abstract
Photonic quantum metrology harnesses quantum states of light to measure unknown parameters beyond classical precision limits. Current protocols suffer from two severe limitations that preclude their scalability: the exponential decrease in fidelities when generating states with large photon numbers due to gate errors, and the increased sensitivity of such states to noise. Here, we develop a deterministic protocol combining quantum optical non-linearities and variational quantum algorithms that provides a substantial improvement on both fronts. The key idea of such hybrid algorithm is to use a classical optimizer to find the set of parameters of a parametrized quantum circuit implemented on the hardware such that it generates states maximizing the quantum Fisher information. Our main result is the generation of metrologically-relevant states with a small number of operations which does not depend on photon-number, resulting in exponential improvements in fidelities when gate errors are considered. On top of that, we show that such states offer a better robustness to noise compared to other states considered noise-resilient.
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Publication: A. Muñoz de las Heras, C. Tabares, J. T. Schneider, L. Tagliacozzo, D. Porras, and A. González-Tudela, Photonic quantum metrology with variational quantum optical nonlinearities, Phys. Rev. Research 6, 013299 (2024).
Presenters
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Alberto Muñoz de las Heras
Instituto de Física Fundamental IFF-CSIC
Authors
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Alberto Muñoz de las Heras
Instituto de Física Fundamental IFF-CSIC
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Cristian Tabares
Consejo Superior de Investigaciones Cientificas (CSIC)
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Jan T Schneider
Instituto de Física Fundamental IFF-CSIC
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Luca Tagliacozzo
Instituto de Física Fundamental IFF-CSIC
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Diego Porras
Institute of Fundamental Physics, CSIC, Consejo Superior de Investigaciones Cientificas (CSIC)
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Alejandro Gonzalez-Tudela
CSIC - Madrid