Probabilistic Modeling and Inference for Sequential Space-Varying Blur Identification

Huang, Yunshi; Chouzenoux, Émilie; Elvira, Vı́ctor

doi:10.1109/tci.2021.3081059

Cited by 6 publications

(3 citation statements)

References 70 publications

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“…As figure 3 demonstrates, the estimated FWHM and angles are consistent across the four beads, validating the assumption of a stationary PSF in the observed field. Moreover, the average FWHM values are close to the theoretical expectations computed with (45) and (46), equal to 0.34 µm along the axial axes, and 1.43 µm in the depth direction, which validates our approach.…”

Section: Experiments On Real Beads In Homogeneous Mediumsupporting

confidence: 85%

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A novel variational approach for multiphoton microscopy image restoration: from PSF estimation to 3D deconvolution

Ajdenbaum,

Chouzenoux,

Lefort

et al. 2024

Inverse Problems

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In multi-photon microscopy (MPM), a recent in-vivo fluorescence microscopy system, the task of image restoration can be decomposed into two interlinked inverse problems: firstly, the characterization of the Point Spread Function (PSF) and subsequently, the deconvolution (i.e., deblurring) to remove the PSF effect, and reduce noise. The acquired MPM image quality is critically affected by PSF blurring and intense noise. The PSF in MPM is highly spread in 3D and is not well characterized, presenting high variability with respect to the observed objects. This makes the restoration of MPM images challenging. Common PSF estimation methods in fluorescence microscopy, including MPM, involve capturing images of sub-resolution beads, followed by quantifying the resulting ellipsoidal 3D spot. In this work, we revisit this approach, coping with its inherent limitations in terms of accuracy and practicality.We estimate the PSF from the observation of relatively large beads (approximately 1μm in diameter). This goes through the formulation and resolution of an original non-convex minimization problem, for which we propose a proximal alternating method along with convergence guarantees.Following the PSF estimation step, we then introduce an innovative strategyto deal with the high level multiplicative noise degrading the acquisitions. We rely on a heteroscedastic noise model for which we estimate the parameters. We then solve a constrained optimization problem to restore the image, accounting for the estimated PSF and noise, while allowing a minimal hyper-parameter tuning. Theoretical guarantees are given for the restoration algorithm.These algorithmic contributions lead to an end-to-end pipeline for 3D image restoration in MPM, that we share as a publicly available Python software. We demonstrate its effectiveness through several experiments on both simulated and real data.

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Section: Experiments On Real Beads In Homogeneous Mediumsupporting

confidence: 85%

“…Another strategy is to break down the problem into two successive inverse problems. In this two-step approach, one first performs a calibration step [37,44,46,52,65], providing an estimate of the PSF h in a controlled situation where x is a known (i.e. calibrated) entity.…”

Section: Introductionmentioning

confidence: 99%

A novel variational approach for multiphoton microscopy image restoration: from PSF estimation to 3D deconvolution

Ajdenbaum,

Chouzenoux,

Lefort

et al. 2024

Inverse Problems

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“…The goal is to retrieve an estimation of x from the pair of images (z, y). This inverse problem typically arises in the calibration of optical instruments [5,43]. The observation model (110) can be expressed equivalently as…”

Section: Application To Robust Blur Kernel Identificationmentioning

confidence: 99%

SABRINA: A Stochastic Subspace Majorization-Minimization Algorithm

Chouzenoux

Jean-Baptiste

2022

J Optim Theory Appl

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A wide class of problems involves the minimization of a coercive and differentiable function F on R N whose gradient cannot be evaluated in an exact manner. In such context, many existing convergence results from standard gradientbased optimization literature cannot be directly applied and robustness to errors in the gradient is not necessarily guaranteed. This work is dedicated to investigating the convergence of Majorization-Minimization (MM) schemes when stochastic errors affect the gradient terms. We introduce a general stochastic optimization framework, called SABRINA (StochAstic suBspace majoRIzation-miNimization Algorithm) that encompasses MM quadratic schemes possibly enhanced with a subspace acceleration strategy. New asymptotical results are built for the stochastic process generated by SABRINA. Two sets of numerical experiments in the field of machine learning and image processing are presented to support our theoretical results and illustrate the good performance of SABRINA with respect to state-of-the-art gradient-based stochastic optimization methods.

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Image enhancement and blur pixel identification with optimization-enabled deep learning for image restoration

Premnath,

Gowr,

Ananth

et al. 2024

SIViP

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Probabilistic Modeling and Inference for Sequential Space-Varying Blur Identification

Cited by 6 publications

References 70 publications

A novel variational approach for multiphoton microscopy image restoration: from PSF estimation to 3D deconvolution

A novel variational approach for multiphoton microscopy image restoration: from PSF estimation to 3D deconvolution

SABRINA: A Stochastic Subspace Majorization-Minimization Algorithm

Image enhancement and blur pixel identification with optimization-enabled deep learning for image restoration

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