about
Numerical wave propagation in ImageJDiffractive digital lensless holographic microscopy with fine spectral tuning.Immersion digital in-line holographic microscopy.Numerical evaluation of the limit of concentration of colloidal samples for their study with digital lensless holographic microscopy.Shift-variant digital holographic microscopy: inaccuracies in quantitative phase imaging.Enhancing spatial resolution in digital holographic microscopy by biprism structured illumination.Accurate single-shot quantitative phase imaging of biological specimens with telecentric digital holographic microscopy.Off-axis digital holographic microscopy: practical design parameters for operating at diffraction limit.Physical compensation of phase curvature in digital holographic microscopy by use of programmable liquid lens.Color digital lensless holographic microscopy: laser versus LED illumination.Automatic full compensation of quantitative phase imaging in off-axis digital holographic microscopy.Three-dimensional surface contouring of macroscopic objects by means of phase-difference images.Comment on "Reconstruction algorithm for high-numerical-aperture holograms with diffraction-limited resolution".Lensless microscopy technique for static and dynamic colloidal systems.Magnified reconstruction of digitally recorded holograms by Fresnel-Bluestein transform.Aberration compensation for objective phase curvature in phase holographic microscopy: comment.Automatic method for focusing biological specimens in digital lensless holographic microscopy.Comparative analysis of the modified enclosed energy metric for self-focusing holograms from digital lensless holographic microscopy.Diabetes screening by telecentric digital holographic microscopy.Second-harmonic illumination to enhance multispectral digital lensless holographic microscopy.Phase-shifting by means of an electronically tunable lens: quantitative phase imaging of biological specimens with digital holographic microscopy.Reduction of speckle noise in holographic images using spatial jittering in numerical reconstructions.High resolution Talbot self-imaging applied to structural characterization of self-assembled monolayers of microspheres.FIMic: design for ultimate 3D-integral microscopy of in-vivo biological samples.Single-shot 3D topography of reflective samples with digital holographic microscopy.Chromatic aberration compensation in numerical reconstruction of digital holograms by Fresnel-Bluestein propagation.Phase-shifting digital holographic microscopy by using a multi-camera setup.Cooperative execution of auto-focusing metrics in digital lensless holographic microscopy for internal-structured samples.Accelerated numerical processing of electronically recorded holograms with reduced speckle noise.Diffraction-based modeling of high-numerical-aperture in-line lensless holograms.Numerical dark field illumination applied to experimental digital lensless holographic microscopy for reconstructions with enhanced contrastYoung's experiment with electromagnetic spatial coherence waveletsWavemeter based on moiré effectElectromagnetic spatial coherence waveletsRadiant, virtual, and dual sources of optical fields in any state of spatial coherenceDefinition and invariance properties of the complex degree of spatial coherenceSingle-shot speckle reduction in numerical reconstruction of digitally recorded holograms
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P50
description
hulumtues
@sq
onderzoeker
@nl
researcher
@en
հետազոտող
@hy
name
Jorge Garcia-Sucerquia
@ast
Jorge Garcia-Sucerquia
@en
Jorge Garcia-Sucerquia
@es
Jorge Garcia-Sucerquia
@sl
type
label
Jorge Garcia-Sucerquia
@ast
Jorge Garcia-Sucerquia
@en
Jorge Garcia-Sucerquia
@es
Jorge Garcia-Sucerquia
@sl
altLabel
Jorge García-Sucerquia
@en
Jorge Garcĩa-Sucerquia
@en
Jorge I. Garcia-Sucerquia
@en
Jorge I. García-Sucerquia
@en
Jorge Ivan García-Sucerquia
@en
Jorge Iván García-Sucerquia
@en
prefLabel
Jorge Garcia-Sucerquia
@ast
Jorge Garcia-Sucerquia
@en
Jorge Garcia-Sucerquia
@es
Jorge Garcia-Sucerquia
@sl
P106
P1153
55912359300
P21
P31
P496
0000-0003-3449-6094