14:10 - 14:40
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Paper No. 2015-FRI-S0401-I001
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Invited Speaker: Myung K Kim
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Holographic Fluorescence Microscopy
Recent developments in digital holography, including self-interference incoherent digital holography (SIDH), provide highly versatile capabilities for 3D holographic imaging with incoherent light, that can remove the barrier between fluorescence and holography. Recent progress in holographic fluorescence microscopy techniques is presented, including aberrationa compensation, differential imaging, and compressive sensing.
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14:40 - 14:55
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Paper No. 2015-FRI-S0401-O001
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Yang-Kun Chew
Award Candidate
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Digital holographic microscopy with photorefractive self-pumped phase conjugation
Technique of optical phase conjugation is being adopted into in-line digital holographic microscopy to suppress scattering noise and compensate aberrations.
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14:55 - 15:10
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Paper No. 2015-FRI-S0401-O002
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Wei Jen Hsaio
Award Candidate
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Super-resolution imaging in reflective objects using synthetic aperture and up-sampled Fresnel holograms
An up-sampling method is proposed to perform super-resolution imaging in synthetic aperture Fresnel digital holographic microscopy. The up-sampling is employed in Fresnel digital hologram reconstruction to overcome the pixel pitch limitation of commercialized sensor to improve the reconstructed image resolution. The resolution of 176 nm is achieved in full-field measurement.
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15:10 - 15:25
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Paper No. 2015-FRI-S0401-O003
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Sheng-Yen Wang
Award Candidate
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Phase-Only Display Hologram Converted from Incoherent Scanning Hologram
Optical scanning holography (OSH) is able to
record an incoherent complex hologram of a three-dimensional
object without speckle noise. In this paper we use bidirectional
error diffusion method to convert the incoherent complex
hologram into a phase-only hologram for holographic display.
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15:25 - 15:40
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Paper No. 2015-FRI-S0401-O004
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Chen Yen Lin
Award Candidate
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Optically Sectioned volume holographic endoscopy
A wide field endoscope system incorporating a multiplexed volume holographic imaging grating with Talbot structured illumination to simultaneously acquire optically sectioned images at selective depths within a thick biological tissue is presented. The proposed endoscope system is configured such that several of Talbot-illumination planes occur inside a volumetric sample, and also serves as the in-focus input planes for the multiplex volume holographic imaging gratings. The performance of endoscope system is evaluated by the imaging quality of the fluorescent beads and mouse intestine.
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