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Literature DB >> 17491629

Reduction of speckle in digital holography by discrete Fourier filtering.

Jonathan Maycock¹, Bryan M Hennelly, John B McDonald, Yann Frauel, Albertina Castro, Bahram Javidi, Thomas J Naughton.

Abstract

We present a digital signal processing technique that reduces the speckle content in reconstructed digital holograms. The method is based on sequential sampling of the discrete Fourier transform of the reconstructed image field. Speckle reduction is achieved at the expense of a reduced intensity and resolution, but this trade-off is shown to be greatly superior to that imposed by the traditional mean and median filtering techniques. In particular, we show that the speckle can be reduced by half with no loss of resolution (according to standard definitions of both metrics).

Year: 2007 PMID： 17491629 DOI： 10.1364/josaa.24.001617

Source DB: PubMed Journal: J Opt Soc Am A Opt Image Sci Vis ISSN： 1084-7529 Impact factor: 2.129

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Cited

5 in total

1. Image-based analysis of living mammalian cells using label-free 3D refractive index maps reveals new organelle dynamics and dry mass flux.

Authors: Patrick A Sandoz; Christopher Tremblay; F Gisou van der Goot; Mathieu Frechin
Journal: PLoS Biol Date: 2019-12-19 Impact factor: 8.029

5. Polychromatic digital holographic microscopy: a quasicoherent-noise-free imaging technique to explore the connectivity of living neuronal networks.

Authors: Céline Larivière-Loiselle; Erik Bélanger; Pierre Marquet
Journal: Neurophotonics Date: 2020-10-16 Impact factor: 3.593

5 in total

Reduction of speckle in digital holography by discrete Fourier filtering.

1. Image-based analysis of living mammalian cells using label-free 3D refractive index maps reveals new organelle dynamics and dry mass flux.

2. Physical pupil manipulation for speckle reduction in digital holographic microscopy.

3. Quasi noise-free digital holography.

4. Strategies for reducing speckle noise in digital holography.

5. Polychromatic digital holographic microscopy: a quasicoherent-noise-free imaging technique to explore the connectivity of living neuronal networks.