Image-based wavefront sensing for astronomy using neural networks

Andersen, Torben; Owner-Petersen, Mette; Enmark, Anita

doi:10.1117/1.jatis.6.3.034002

Cited by 23 publications

(15 citation statements)

References 24 publications

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“…Compared with other optimization approaches that rely on iterative methods, including prior information about the experimental setup additionally constrains the optimization process [12]. Compared to neural network approaches [33,34,35,36,37,38,39,40,24,41], differentiable model-based approaches have the advantage that they don't rely on a predetermined model of sample aberrations.…”

Section: Discussionmentioning

confidence: 99%

Differentiable model-based adaptive optics for two-photon microscopy

Vishniakou,

Seelig

2021

Preprint

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Aberrations limit scanning fluorescence microscopy when imaging in scattering materials such as biological tissue. Model-based approaches for adaptive optics take advantage of a computational model of the optical setup. Such models can be combined with the optimization techniques of machine learning frameworks to find aberration corrections, as was demonstrated for focusing a laser beam through aberrations onto a camera [1]. Here, we extend this approach to two-photon scanning microscopy. The developed sensorless technique finds corrections for aberrations in scattering samples and will be useful for a range of imaging application, for example in brain tissue.

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Section: Discussionmentioning

confidence: 99%

Differentiable model-based adaptive optics for two-photon microscopy

Vishniakou,

Seelig

2021

Preprint

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“…The calibration of instrumental aberrations, through phase diversity approaches, [30][31][32] focal plane sharpening 33 techniques, or even Deep-learning strategies, 34,35 is particularly challenging. First of all, sampling the instrumental aberrations across the fov is feasible by the use of internal fibers within the system, 36,37 but can be potentially time consuming and requires direct control of the system.…”

Section: Scope On Advanced Psf Models and Reconstruction Techniquesmentioning

confidence: 99%

Review of PSF reconstruction methods and application to post-processing

Beltramo-Martin

Ragland

Fétick

et al. 2020

Adaptive Optics Systems VII

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Determining the PSF remains a key challenge for post adaptive-optics (AO) observations regarding the spatial, temporal and spectral variabilities of the AO PSF, as well as itx complex structure. This paper aims to provide a non-exhaustive but classified list of techniques and references that address this issue of PSF determination, with a particular scope on PSF reconstruction, or more generally pupil-plane-based approaches. We have compiled a large amount of references to synthesize the main messages and kept them at a top level. We also present applications of PSF reconstruction/models to post-processing, more especially PSF-fitting and deconvolution for which there is a fast progress in the community.

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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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Image-based wavefront sensing for astronomy using neural networks

Cited by 23 publications

References 24 publications

Differentiable model-based adaptive optics for two-photon microscopy

Differentiable model-based adaptive optics for two-photon microscopy

Review of PSF reconstruction methods and application to post-processing

Differentiable model-based adaptive optics with transmitted and reflected light

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