Computational multifocal microscopy

He, Kaijian; Wang, Zihao; Huang, Xiang; Wang, Xiaolei; Yoo, Seunghwan; Ruiz, Pablo; Gdor, Itay; Selewa, Alan; Ferrier, Nicola; Scherer, Norbert F.; Hereld, Mark; Katsaggelos, Aggelos K.; Cossairt, Oliver

doi:10.1364/boe.9.006477

Cited by 15 publications

(8 citation statements)

References 32 publications

(47 reference statements)

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“…Our multifocus imaging strategy offers several notable advantages over alternative strategies. Compared to techniques using a DOE [29][30][31] , our z-splitter prism is low cost, easy to design and assemble, does not require the addition of a chromatic corrector, and can be adapted to a variety of imaging modalities. Compared to techniques that also involve the use of beamsplitting optics 24,25,27,28 , our system requires only a single camera and enables significantly larger FOV while offering the flexibility of swapping in different z-splitters to accommodate different imaging speed or volume requirements.…”

Section: Discussionmentioning

confidence: 99%

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High-contrast multifocus microscopy with a single camera and z-splitter prism

Xiao¹,

Gritton²,

Tseng³

et al. 2020

Preprint

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We present a multifocus imaging strategy based on the use of a simple z-splitter prism that can be assembled from off-the-shelf components. Our technique enables a widefield image stack to be distributed onto a single camera and recorded simultaneously. We exploit the volumetric nature of our image acquisition by further introducing a novel extended-volume 3D deconvolution strategy to suppress far-out-of-focus fluorescence background to significantly improve the contrast of our recorded images, conferring to our system a capacity for quasi optical sectioning. By swapping in different z-splitter configurations, we can prioritize high speed or large 3D field-of-view imaging depending on the application of interest. Moreover, our system can be readily applied to a variety of imaging modalities in addition to fluorescence, such as phase-contrast and darkfield imaging. Because of its simplicity, versatility, and performance, we believe our system will be a useful tool for general biological or biomedical imaging applications.

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Section: Discussionmentioning

confidence: 99%

“…To date, examples of such devices include specially fabricated beam splitters (using two cameras 27,28 ) or diffractive optical elements (DOEs) [29][30][31][32] . These usually involve significant design and manufacturing challenges.…”

Section: Introductionmentioning

confidence: 99%

High-contrast multifocus microscopy with a single camera and z-splitter prism

Xiao¹,

Gritton²,

Tseng³

et al. 2020

Preprint

View full text Add to dashboard Cite

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“…This technique, termed "multifocus microscopy" (MFM), allows for a simpler optical configuration, employing just a single camera, but the MFG introduces chromatic aberration, which degrades performance and/or restricts spectral bandwidth, 42 although this can be mitigated using computational techniques. 43 A key benefit of MUM is that it can also be used to image extended objects, 41,44 whereas the emphasis for PSF-engineering has been on localization of PSFs that are the images of pointlike objects. 45,46 There is also the opportunity to use MUM/MFM in combination with engineered PSFs for even better localization precision, as has been done using an astigmatic PSF [47][48][49] and an Airy-beam-based PSF.…”

Section: A Multifocal-plane Microscopy (Mum)mentioning

confidence: 99%

Advances in 3D single particle localization microscopy

et al. 2019

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The spatial resolution of conventional optical microscopy is limited by diffraction to transverse and axial resolutions of about 250 nm, but localization of point sources, such as single molecules or fluorescent beads, can be achieved with a precision of 10 nm or better in each direction. Traditional approaches to localization microscopy in two dimensions enable high precision only for a thin in-focus layer that is typically much less than the depth of a cell. This precludes, for example, super-resolution microscopy of extended three-dimensional biological structures or mapping of blood velocity throughout a useful depth of vasculature. Several techniques have been reported recently for localization microscopy in three dimensions over an extended depth range. We describe the principles of operation and typical applications of the most promising 3D localization microscopy techniques and provide a comparison of the attainable precision for each technique in terms of the Cramér-Rao lower bound for high-resolution imaging.

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“…Our paper investigates the temporal upsampling problem. While previous approaches investigate in the framework of compressive sensing [1,14,17,26,35,38,41], we formulate our work as fusing event streams with intensity images to obtain a temporally dense video. Compared to existing literature [36] which integrates event counts per pixel across time, our differentiable model utilizes "tanh" functions as event activation units and imposes sparsity constraints on both spatial and temporal domain.…”

Section: Related Workmentioning

confidence: 99%

Event-Driven Video Frame Synthesis

Wang¹,

Jiang²,

He³

et al. 2019

2019 IEEE/CVF International Conference on Computer Vision Workshop (ICCVW)

Self Cite

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Temporal Video Frame Synthesis (TVFS) aims at synthesizing novel frames at timestamps different from existing frames, which has wide applications in video codec, editing and analysis. In this paper, we propose a high framerate TVFS framework which takes hybrid input data from a lowspeed frame-based sensor and a high-speed event-based sensor. Compared to frame-based sensors, event-based sensors report brightness changes at very high speed, which may well provide useful spatio-temoral information for high framerate TVFS. In our framework, we first introduce a differentiable forward model to approximate the physical sensing process, fusing the two different modes of data as well as unifying a variety of TVFS tasks, i.e., interpolation, prediction and motion deblur. We leverage autodifferentiation which propagates the gradients of a loss defined on the measured data back to the latent high framerate video. We show results with better performance compared to state-ofthe-art. Second, we develop a deep learning-based strategy to enhance the results from the first step, which we refer as a residual "denoising" process. Our trained "denoiser" is beyond Gaussian denoising and shows properties such as contrast enhancement and motion awareness. We show that our framework is capable of handling challenging scenes including both fast motion and strong occlusions. Supplementary material, demo and code are released at: https://github.com/winswang/int-event-fusion/tree/win10.

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Computational multifocal microscopy

Cited by 15 publications

References 32 publications

High-contrast multifocus microscopy with a single camera and z-splitter prism

High-contrast multifocus microscopy with a single camera and z-splitter prism

Advances in 3D single particle localization microscopy

Event-Driven Video Frame Synthesis

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