Compressed sensing enabled high-bandwidth and large dynamic range magnetic sensing

• URL: http://arxiv.org/abs/2502.06070v1
• Date: Sun, 09 Feb 2025 23:27:22 GMT
• Title: Compressed sensing enabled high-bandwidth and large dynamic range magnetic sensing
• Authors: Galya Haim, Chris Mullarkey, John Howell, Nir Bar-Gill,
• Abstract summary: The Nitrogen-Vacancy (NV) center in diamond is used for sensing magnetic and electric fields, strain and temperature. This study introduces a novel application of compressed sensing (CS) for magnetic sensing using NV centers.
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• Abstract: Electron Spin Resonance (ESR) is a widely common method in the field of quantum sensing. Specifically with the Nitrogen-Vacancy (NV) center in diamond, used for sensing magnetic and electric fields, strain and temperature. However, ESR measurements are limited in temporal resolution, primarily due to the large number of data points required especially in high dynamic range regimes and the need for extensive averaging caused by low signal-to-noise ratio (SNR). This study introduces a novel application of compressed sensing (CS) for magnetic sensing using NV centers. By comparing CS with conventional raster scanning, we demonstrate the potential of CS to enhance sensing applications. Experimental results, supported by simulations, show an improvement of factor 3 in measurement accuracy in low SNR data, which also translates to achieving the same accuracy with only 15% of the data points. Moreover, the proposed approach is not confined to NV centers but can be extended to ESR measurements in other systems, broadening its applicability in quantum sensing.

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