Machine learning guided rapid focusing with sensor-less aberration corrections

Jin, Yinying; Zhang, Yiye; Hu, Ling; Huang, Haiyang; Xu, Qiaoqi; Zhu, Xinpei; Huang, Linjian; Zheng, Yao; Shen, Hui-Liang; Gong, Wei; Si, Ke

doi:10.1364/oe.26.030162

Cited by 58 publications

(30 citation statements)

References 21 publications

(11 reference statements)

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“…Over the last years, deep learning-based approaches using convolutional neural networks (CNNs) have proven to be powerful and computationally efficient for image-based classification and regression tasks for microscopy images [18,19]. Recently, several studies demonstrated that deep learning-based phase retrieval can produce accurate results at fast processing speeds [20][21][22][23][24][25], however they fall short regarding their practical applicability. Some of these approaches [22][23][24] used purely simulated synthetic data, where generalizability to real microscopy images is unclear.…”

Section: Introductionmentioning

confidence: 99%

“…Some of these approaches [22][23][24] used purely simulated synthetic data, where generalizability to real microscopy images is unclear. Others focused on specific microscopy acquisition modes (such as using biplanar PSFs [20]) or microscopy setups that allow to collect large sets of experimental ground truth data for training and prediction [21,25], thus limiting this approach in practice. Moreover, most studies lack comparison against strong classical phase retrieval methods that are used in practice.…”

Section: Introductionmentioning

confidence: 99%

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Practical sensorless aberration estimation for 3D microscopy with deep learning

et al. 2020

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Estimation of optical aberrations from volumetric intensity images is a key step in sensorless adaptive optics for 3D microscopy. Recent approaches based on deep learning promise accurate results at fast processing speeds. However, collecting ground truth microscopy data for training the network is typically very difficult or even impossible thereby limiting this approach in practice. Here, we demonstrate that neural networks trained only on simulated data yield accurate predictions for real experimental images. We validate our approach on simulated and experimental datasets acquired with two different microscopy modalities and also compare the results to non-learned methods. Additionally, we study the predictability of individual aberrations with respect to their data requirements and find that the symmetry of the wavefront plays a crucial role. Finally, we make our implementation freely available as open source software in Python.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Practical sensorless aberration estimation for 3D microscopy with deep learning

et al. 2020

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“…Machine learning offers novel approaches to correct for aberrations encountered when imaging though scattering materials, [1][2][3][4] from astronomy [5][6][7][8][9] to microscopy with transmitted (for example [10][11][12]) and reflected light [13]. To find aberration corrections in these situations, machine learning typically relies on large synthetic datasets.…”

Section: Introductionmentioning

confidence: 99%

“…In practice, training datasets are often based on combinations of Zernike polynomials [5][6][7][8][9][10][11][12][13] which might however not accurately capture all aspects of experimentally encountered aberrations. Additionally, for more strongly scattering samples, which require increasingly higher orders of Zernike modes, covering all potential scattering situations by sampling a sufficient number of different mode combinations eventually results in very large datasets.…”

Section: Introductionmentioning

confidence: 99%

Differentiable model-based adaptive optics with transmitted and reflected light

Vishniakou¹,

Seelig²

2020

Opt. Express

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Aberrations limit optical systems in many situations, for example when imaging in biological tissue. Machine learning offers novel ways to improve imaging under such conditions by learning inverse models of aberrations. Learning requires datasets that cover a wide range of possible aberrations, which however becomes limiting for more strongly scattering samples, and does not take advantage of prior information about the imaging process. Here, we show that combining model-based adaptive optics with the optimization techniques of machine learning frameworks can find aberration corrections with a small number of measurements. Corrections are determined in a transmission configuration through a single aberrating layer and in a reflection configuration through two different layers at the same time. Additionally, corrections are not limited by a predetermined model of aberrations (such as combinations of Zernike modes). Focusing in transmission can be achieved based only on reflected light, compatible with an epidetection imaging configuration.

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“…Currently, adaptive optics (AO) is used to correct the wavefront aberrations, taking advantages of an active element such as a deformable mirror or a SLM . Nowadays, several methods based on AO were reported to successfully correct the phase patterns for doughnut beams.…”

Section: Introductionmentioning

confidence: 99%

Aberration corrections of doughnut beam by adaptive optics in the turbid medium

Chen

et al. 2019

Journal of Biophotonics

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The doughnut beam is a spatially structured beam which has been widely used in super-resolution microscopy, laser trapping and so on. However, when it passes through thick scattering medium, aberrations will seriously affect its performance. Currently, adaptive optics (AO) has become one of the most powerful tools to compensate aberrations. However, conventional AO always suffers from limited corrected field of view (FOV). Here, we propose a method with conjugate AO system based on coherent optical adaptive technique. The results show that the corrected FOV can be improved effectively. For a wide range of the optical applications with doughnut beam, our method has potentials in correcting aberrations with high speed in turbid media.(A) Mouse brain slice, (B) the distribution of r PAO , (C) the distribution of r CAO . The vortex beam focus of the blue point in (B) and (C) among a 137.5 × 137.5 μm FOV (D1) ideally, (D2) with scattering, (D3) in pupil AO system and (D4) in conjugate AO system. K E Y W O R D S aberration correction, adaptive optics, doughnut beam, turbid medium

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Machine learning guided rapid focusing with sensor-less aberration corrections

Cited by 58 publications

References 21 publications

Practical sensorless aberration estimation for 3D microscopy with deep learning

Practical sensorless aberration estimation for 3D microscopy with deep learning

Differentiable model-based adaptive optics with transmitted and reflected light

Aberration corrections of doughnut beam by adaptive optics in the turbid medium

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