Related papers: Machine-learning based high-bandwidth magnetic sensing

Machine-learning based high-bandwidth magnetic sensing

URL: http://arxiv.org/abs/2409.12820v2
Date: Mon, 23 Jun 2025 11:20:23 GMT
Title: Machine-learning based high-bandwidth magnetic sensing
Authors: Galya Haim, Stefano Martina, John Howell, Nir Bar-Gill, Filippo Caruso,
Abstract summary: Nitrogen-vacancy (NV) color centers in diamond provide versatile, high-sensitivity, and high-spatial-resolution magnetic sensing.<n>Current schemes for spin resonance magnetic sensing (as applied by NV quantum sensing) suffer from tradeoffs associated with sensitivity, dynamic range, and bandwidth.<n>We implement machine learning tools to enhance NV magnetic sensing in terms of the sensitivity/bandwidth tradeoff in large dynamic range scenarios.
Score: 1.3980986259786223
License: http://creativecommons.org/licenses/by/4.0/
Abstract: Recent years have seen significant growth of quantum technologies, and specifically quantum sensing, both in terms of the capabilities of advanced platforms and their applications. One of the leading platforms in this context is nitrogen-vacancy (NV) color centers in diamond, providing versatile, high-sensitivity, and high-spatial-resolution magnetic sensing. Nevertheless, current schemes for spin resonance magnetic sensing (as applied by NV quantum sensing) suffer from tradeoffs associated with sensitivity, dynamic range, and bandwidth. Here we address this issue, and implement machine learning tools to enhance NV magnetic sensing in terms of the sensitivity/bandwidth tradeoff in large dynamic range scenarios. Our results indicate a potential reduction of required data points by at least a factor of 3, while maintaining the current error level. Our results promote quantum machine learning protocols for sensing applications towards more feasible and efficient quantum technologies.

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