about
Numerical multiplexing and demultiplexing of digital holographic information for remote reconstruction in amplitude and phaseInvestigation of angular multiplexing and de-multiplexing of digital holograms recorded in microscope configurationControlling depth of focus in 3D image reconstructions by flexible and adaptive deformation of digital holograms.All-optical microfluidic chips for reconfigurable dielectrophoretic trapping through SLM light induced patterning.Red blood cell as an adaptive optofluidic microlens.Holographic imaging of unlabelled sperm cells for semen analysis: a review.Biolens behavior of RBCs under optically-induced mechanical stress.Quantitative phase maps denoising of long holographic sequences by using SPADEDH algorithm.On the holographic 3D tracking of in vitro cells characterized by a highly-morphological change.Synthesis and display of dynamic holographic 3D scenes with real-world objects.Compression of digital holograms via adaptive-sparse representation.Automatic focusing in digital holography and its application to stretched holograms.Identification of bovine sperm head for morphometry analysis in quantitative phase-contrast holographic microscopy.Multi-wavelengths digital holography: reconstruction, synthesis and display of holograms using adaptive transformation.Microscopy imaging and quantitative phase contrast mapping in turbid microfluidic channels by digital holography.Random resampling masks: a non-Bayesian one-shot strategy for noise reduction in digital holography.Digital holography as a method for 3D imaging and estimating the biovolume of motile cells.Particle tracking by full-field complex wavefront subtraction in digital holography microscopy.Imaging adherent cells in the microfluidic channel hidden by flowing RBCs as occluding objects by a holographic method.Refocusing criterion via sparsity measurements in digital holography.3D morphometry of red blood cells by digital holography.Encoding multiple holograms for speckle-noise reduction in optical display.Improving holographic reconstruction by automatic Butterworth filtering for microelectromechanical systems characterization.Label-free analysis of mononuclear human blood cells in microfluidic flow by coherent imaging tools.On-speckle suppression in IR digital holography.Digital holography as 3D tracking tool for assessing acoustophoretic particle manipulation.Holographic tracking of living cells by three-dimensional reconstructed complex wavefronts alignment.Full-angle tomographic phase microscopy of flowing quasi-spherical cells.Investigation on dynamics of red blood cells through their behavior as biophotonic lenses.Optical signature of erythrocytes by light scattering in microfluidic flows.Strategies for reducing speckle noise in digital holographyTomographic flow cytometry by digital holographyRetrieving acoustic energy densities and local pressure amplitudes in microfluidics by holographic time-lapse imagingQuasi noise-free digital holographyAssembling and rotating erythrocyte aggregates by acoustofluidic pressure enabling full phase-contrast tomography
P50
Q28301215-D9072CFE-A983-4872-92AD-BF1825E5CD2FQ29037345-6ABC617B-4978-40CE-BD50-E8B914018E8BQ33503579-C5B427F0-C233-47F8-AC3E-7DAC81A98554Q34409258-4D07AF7F-6EB5-41EF-9972-E1EF1D785C74Q35574781-C821F43C-BE23-40B4-88E2-D2D4932C1091Q38285845-E8BDCC9A-EA46-4143-B6AC-05A16D063829Q38744821-4C1AABDF-8583-4818-9B0A-D93D7AE720B2Q39185645-1C2EA08B-B0CB-4DBB-BB87-4E58FDD4A177Q39221686-1F8FD46B-12CC-43B8-8BF7-3EDB339D056AQ39939844-9A365AA9-7C7D-4D69-8842-ED0368CF4E5EQ39961113-CA9FA7C7-1E27-4A02-AE88-28775CCCAA38Q39983713-5DAE63A0-3934-4D44-AA90-AF54963C8A21Q40008915-F603D726-7B57-497E-B6F3-D75BA17316F9Q40033834-1207CD3F-0E0C-4528-B9FF-81D846FC6F99Q40044535-A81C8044-C77A-45ED-A240-E62E5A2969B4Q40095490-6DB3A21D-C26C-400F-BB55-777CAAF8AA2EQ40143903-6C5B0004-687F-4D6F-809B-7009242418EEQ40166734-72D48F93-18B5-4292-988E-3C3700CC2798Q40193980-10C87B4D-B20A-436C-9968-6080F0E8DE76Q40214761-01361010-2312-419B-9F53-111C37CCCDE1Q40223666-404388BF-106C-4442-BC67-120976C9ABAFQ40235278-B829484E-C6FA-44A5-83F0-16AD4DF6CA7CQ40279789-B686F9C9-1256-4B90-AC66-9A4C3736DCB6Q40396245-3CDBE28A-D638-4FB0-BDB4-CC69FCE11075Q40420385-F08E8227-09A8-46E6-8991-5501217D5636Q40493976-BB074909-88EB-4348-B6A4-EB9AF5E386CEQ42803349-916BBDA8-2F6E-4698-B24F-00F30A1ED34AQ48592085-69BADCE7-C143-4EB9-9F9E-240925146FD2Q48593778-2E9F2217-A93D-4401-B451-EC5BBFA7EB63Q48661571-F6ECE36E-841B-4D08-AA64-3376782A0EAEQ58805476-B6A95593-ED19-43E2-9099-D3365635FDCBQ59306341-FDA134F4-BFE5-48DE-82D1-0F95D056C861Q62663416-DEC0BA51-E067-4449-A070-C5848A8EB17AQ91241638-3F2BF92A-CD55-4379-87BC-8451E4C4AA15Q92723919-CF1AC867-3323-4B04-9233-EDCA055460F9
P50
description
researcher, ORCID id # 0000-0002-9607-7728
@en
wetenschapper
@nl
name
Pasquale Memmolo
@ast
Pasquale Memmolo
@en
Pasquale Memmolo
@es
Pasquale Memmolo
@nl
type
label
Pasquale Memmolo
@ast
Pasquale Memmolo
@en
Pasquale Memmolo
@es
Pasquale Memmolo
@nl
prefLabel
Pasquale Memmolo
@ast
Pasquale Memmolo
@en
Pasquale Memmolo
@es
Pasquale Memmolo
@nl
P1053
K-8304-2013
P106
P1153
24478818300
P21
P31
P3829
P496
0000-0002-9607-7728