Related papers: Superresolution for two incoherent optical sources with arbitrary intensities in two dimensions

Superresolution for two incoherent optical sources with arbitrary intensities in two dimensions

URL: http://arxiv.org/abs/2508.08049v1
Date: Mon, 11 Aug 2025 14:50:07 GMT
Title: Superresolution for two incoherent optical sources with arbitrary intensities in two dimensions
Authors: Junyan Li, Shengshi Pang,
Abstract summary: The Rayleigh criterion has long served as a fundamental limit for the resolution of classical optical imaging.<n>Advances in quantum metrology have led to the quantum superresolution technique that can estimate the separation between a pair of incoherent point sources with nonvanishing precision.<n>For two-dimensional optical systems, the precision limit of estimating the whole separation remains unknown.
Score: 0.825651323214656
License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
Abstract: The Rayleigh criterion has long served as a fundamental limit for the resolution of classical optical imaging. However, recent advances in quantum metrology have led to the quantum superresolution technique that can break Rayleigh's curse and estimate the separation between a pair of incoherent point sources with nonvanishing precision. For two-dimensional optical systems, the precision limit of estimating the whole separation, i.e., the distance, between two point sources remains unknown so far. In this paper, we investigate the estimation precision of the distance between two incoherent point sources with arbitrary intensities in a two-dimensional imaging system. Through the multiparameter quantum estimation theory, we obtain the ultimate estimation precision of the distance and show that it remains nonzero when the distance approaches zero, which surpasses the Rayleigh criterion. We further show that the precision can be enhanced by aligning the two point sources along specific directions if the point-spread functions of the two sources are not circularly symmetric, and find the optimial relative azimuth between the two point sources and the highest estimation precision of the distance. In addition to the distance estimation, we also consider the quantum estimation of the relative azimuth between two incoherent point sources. A surprising result is that the precision limit of the azimuth decays quadratically with the distance, which suggests that the azimuth cannot be resolved when the two point sources get sufficiently close to each other and is therefore inaccessible by the quantum superresolution technique in this case. This reveals a new and fundamental limitation on the resolvability of two incoherent point sources in multi-dimensional quantum imaging which cannot be addressed by optimizing the quantum measurements.

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