TOM 1 - Silicon Photonics and Guided-Wave Optics
TOM 2 - Computational, Adaptive and Freeform Optics
TOM 3 - Optical System Design, Tolerancing and Manufacturing
TOM 4 - Bio-Medical Optics
TOM 5 - Resonant Nanophotonics
TOM 6 - Optical Materials: crystals, thin films, organic molecules & polymers, syntheses, characterization and applications
TOM 7 - Thermal radiation and energy management
TOM 8 - Non-linear and Quantum Optics
TOM 9 - Opto-electronic Nanotechnologies and Complex Systems
TOM 10 - Frontiers in Optical Metrology
TOM 11 - Tapered optical fibers, from fundamental to applications
TOM 12 - Optofluidics
TOM 13 - Advances and Applications of Optics and Photonics
EU Project Session
Early Stage Researcher Session
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Please note that all times are shown in the time zone of the conference. The current conference time is: 1st Dec 2022, 05:34:18pm WET
TOM2 S02: Computational, Adaptive and Freeform Optics - focus on Illumination, AR/VR and information driven systems: Computational
2:30pm - 4:00pm
Session Chair: Juergen Czarske, Technische Universität Dresden, Germany
1st floor, 70 seats
2:30pm - 3:00pm Invited ID: 325 / TOM2 S02: 1 TOM 2 Computational, Adaptive and Freeform Optics - focus on Illumination, AR/VR and information driven systems
Imaging beyond the limits of diffraction and aberrations with computational microscopy
Andrew Robert Harvey, Guillem Carles, Michael Handley, Daniel Olesker, Jonathan Taylor, Conall Thompson, Paul Zammit, Yongzhuang Zhou, Tomas Aidukas
School of Physics and Astronomy, University of Glasgow, United Kingdom
A common requirement for microscopy of biological samples is to image with sub-cellular resolution throughout extended volumes up to 100um thick and across a field of view that may excess 1cm^2. The fundamental limits of diffraction and the practical limits of optical aberrations means that no traditional microscopy technique can achieve these goals without resorting to mechanical scanning. We report two computational microscopy techniques that define the state of the art in 3D high-resolution imaging.
We describe (1) imaging with engineering PSFs to enable three-dimensional localisation microscopy with a spatial resolution approaching one-hundredth of a wavelength throughout a volume that is more than 15 times greater than with conventional localisation microscopy and (2) a new multi-objective Fourier ptychography that enables an arbitrary scaleable increase in the speed of acquisition of gigapixel images.
3:00pm - 3:15pm ID: 121 / TOM2 S02: 2 TOM 2 Computational, Adaptive and Freeform Optics - focus on Illumination, AR/VR and information driven systems
Computation of aberration coefficients for plane-symmetric reflective optical systems using Lie algebraic methods
Antonio Barion1, Martijn Anthonissen1, Jan ten Thije Boonkkamp1, Wilbert IJzerman1,2
1Eindhoven University of Technology, Netherlands, The; 2Signify, Netherlands, The
The Lie algebraic method offers a systematic way to find aberration coefficients of any order for plane-symmetric reflective optical systems. The coefficients derived from the Lie method are in closed form and solely depend on the geometry of the optical system. We investigate and verify the results for a single reflector. The concatenation of multiple mirrors follows from the mathematical framework.
3:15pm - 3:30pm ID: 320 / TOM2 S02: 3 TOM 2 Computational, Adaptive and Freeform Optics - focus on Illumination, AR/VR and information driven systems
Is trans-scleral illumination the future of retinal imaging?
Joel Terry1, Daniel Martin Geddes1, Victor Ochoa-Gutierrez1, Zhiyuan Yang2, Kenneth J. Smith2, Andy R. Harvey1
1University of Glasgow, United Kingdom; 2University College London, United Kingdom
Retinal imaging is an essential tool for monitoring eye and systemic health. Traditional approaches illuminate the retina through the pupil, requiring careful real-time alignment to separate the illumination and imaging paths and prevent the faint retinal image from being swamped by Fresnel reflections, ocular scatter and fluorescence. Somewhat surprisingly, the sclera is sufficiently transmissive to enable efficient trans-scleral illumination of the retina, which prevents overlap of the illumination and imaging light paths. We discuss how this enables and enhances three emerging retinal imaging approaches based on computational imaging.
We will discuss the opportunities for employing trans-scleral illumination for: (a) ultra-widefield aberration correction using the concepts of multi-scale, multi-camera imaging, for which transscleral illumination enables reflex-free imaging for fields of view approaching 200°; for (b) phasor-spectral-fluorescence lifetime imaging with enhanced quantification and discrimination of retinal fluorophores devoid of the lens autofluorescence that plagues conventional illumination; and for (c) spectral retinal oximetry for which reduced intraocular scatter provides improved measurement of vascular contrast and more reliable oximetry.
3:30pm - 3:45pm ID: 337 / TOM2 S02: 4 TOM 2 Computational, Adaptive and Freeform Optics - focus on Illumination, AR/VR and information driven systems
Utilizing adaptive optics to build an inverted lattice lightsheet microscope
Lars-Christian Wittig1, Marco Pretorius1, Thomas Kalkbrenner2, Jörg Siebenmorgen2
Lightsheet microscopy has become an inevitable tool for low photodamage imaging in developmental biology. Dedicated beamshapes (lattice lightsheets) have extended this unrivalled sample preservation to live cell imaging with high spatio-temporal resolution. With the Lattice Lightsheet 7 Zeiss has made this method widely available and we want to show, that the optical configuration of this microscope is defined by only three key requirements: 1. High SNR at low photodamage, 2. Diffraction limited resolution and sectioning, 3. Consumable type sample carrier. Especially, one can conclude from these demands that an adaptive optical element is essential for the imaging path to achieve high-end performance. In order to account for tolerances of the cover glass we developed a generalised Alvarez lens which fully compensates for associated wavefront errors and thereby ensures highest imaging quality.
3:45pm - 4:00pm ID: 392 / TOM2 S02: 5 TOM 2 Computational, Adaptive and Freeform Optics - focus on Illumination, AR/VR and information driven systems
Design and realization of a miniaturized high resolution computed tomography imaging spectrometer
Simon Amann1, Tobias Haist1, Alexander Gatto2, Markus Kamm2, Alois Herkommer1
1University of Stuttgart, Institut für Technische Optik, Germany; 2Sony Europe B.V, Stuttgart Technology Center, Germany
The computed tomography imaging spectrometer (CTIS) is a relatively unknown snapshot hyperspectral camera. It utilizes computational imaging approaches to gain the hyperspectral image from a spatio-spectral smeared sensor image. We present a strongly miniaturized system with a dimension of only 36 mm x 40.5 mm x 52.8 mm and a diagonal field of view of 29°. We achieve this using a Galilean beam expander and a combination of off-the-shelf lenses, a highly aspherical imaging system from a commercial smartphone and a 13 MP monochrome smartphone image sensor. The reconstructed hyperspectral image has a spatial resolution of 400 x 300 pixel with 39 spectral channels.