拉盖尔-高斯模式实验三维超定位

Chenyu Hu, Liang Xu, Ben Wang, Zhiwen Li, Yipeng Zhang, Yong Zhang, Lijian Zhang
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摘要

提高三维定位精度对超分辨率成像至关重要。通过合理设计点扩散函数(PSF),如利用Laguerre-Gaussian (LG)模式及其叠加,可以提高三维定位精度的极限。然而,实现这些限制是具有挑战性的,因为它通常涉及复杂的检测策略和实际限制。在这项工作中,我们严格推导了LG模式及其叠加的最终三维定位极限,特别是旋转模式,在多参数估计框架中。我们的研究结果表明,实现LG模式的3D超定位所需的大部分信息可以通过可行的强度检测获得。当方位角指数l为零时,可以达到三维极限精度。为了提供原理证明演示,我们开发了一种迭代最大似然估计(MLE)算法,该算法在考虑像素化和检测器噪声的情况下收敛到点源的三维位置。实验实现表明,与高斯模式相比,LG模式的横向定位精度提高了两倍,轴向定位精度提高了20倍。我们还展示了旋转模式在近焦区域内优越的轴向定位能力,有效地克服了单一LG模式遇到的局限性。值得注意的是,在存在现实像差的情况下,该算法鲁棒地实现了cram - rao下界。我们的研究结果为评估和优化可实现的3D定位精度提供了有价值的见解,这将促进超分辨率显微镜的发展。
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Experimental 3D super-localization with Laguerre–Gaussian modes

Improving three-dimensional (3D) localization precision is of paramount importance for super-resolution imaging. By properly engineering the point spread function (PSF), such as utilizing Laguerre–Gaussian (LG) modes and their superposition, the ultimate limits of 3D localization precision can be enhanced. However, achieving these limits is challenging, as it often involves complicated detection strategies and practical limitations. In this work, we rigorously derive the ultimate 3D localization limits of LG modes and their superposition, specifically rotation modes, in the multi-parameter estimation framework. Our findings reveal that a significant portion of the information required for achieving 3D super-localization of LG modes can be obtained through feasible intensity detection. Moreover, the 3D ultimate precision can be achieved when the azimuthal index l is zero. To provide a proof-of-principle demonstration, we develop an iterative maximum likelihood estimation (MLE) algorithm that converges to the 3D position of a point source, considering the pixelation and detector noise. The experimental implementation exhibits an improvement of up to two-fold in lateral localization precision and up to twenty-fold in axial localization precision when using LG modes compared to Gaussian mode. We also showcase the superior axial localization capability of the rotation mode within the near-focus region, effectively overcoming the limitations encountered by single LG modes. Notably, in the presence of realistic aberration, the algorithm robustly achieves the Cramér-Rao lower bound. Our findings provide valuable insights for evaluating and optimizing the achievable 3D localization precision, which will facilitate the advancements in super-resolution microscopy.

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