Class / Patent application number | Description | Number of patent applications / Date published |
351215000 | Including light polarizing means | 9 |
20080231807 | High Resolution Laterial and Axial Tomography - An in-vivo high resolution lateral and axial tomography system of the retina, is provided, including a Michelson interferometer, generating a tomographical image by full field OCT interference with Z sweeping, adaptive optical correction apparatus, correcting the wave fronts coming from and going to the eye, including a reference source, a deformable mirror and wave surface analysis apparatus, detection apparatus producing an image from an interferometric measurement using the OCT principle and apparatus for focussing the wave surface analyser. The apparatus for focussing are embodied and controlled, synchronously with the Z sweeping to force the deformable mirror to adopt an additional curvature, such as to combine the input light source and detection apparatus at a given depth in the retina. | 09-25-2008 |
20090310083 | Method and Apparatus for Improved Fundus Imaging Through Choice of Light Polarisation - The present invention provides a method and device to image the fundus of the eye using polarized light which includes circular polarization. The invention is most broadly comprised of a device to generate polarization states of light, including circularly polarized light (i.e. potentially combinations of elliptically polarized light and depolarized light combined, elliptically polarized light alone, or circularly polarized light with depolarised light or circularly polarized light alone). This light can be used with any fundus imaging device including but not limited to fundus cameras, scanning laser ophthalmoscopes, confocal scanning laser ophthalmoscopes, optical coherence tomography instruments, with or without some form of wavefront correction. This is a change from common fundus imaging systems which use randomly polarized light or linearly polarized light. The simplest implementation of this is a quarter wave plate (or equivalent retarder) combined with a linear polarizer located after the light source and before the eye. The QWP can be rotated to produce differing circular and elliptical polarizations of light which are ideal for imaging differing structures at the rear of the eye for different people. | 12-17-2009 |
20100245768 | VIEWING DEVICE TO MINIMIZE PARALLAX - A viewing device usable by a surgeon to make an accurate corneal mark during an eye surgery procedure may be a face or head-mounted device to free the surgeon's hands. The device incorporates a light producing apparatus, such as an LED, that may be positioned to be coaxial or otherwise substantially co-aligned with a line-of-sight of the surgeon's dominant eye, and thus match the patient's line of sight with the surgeon's line of sight. The device include polarizing filters that cooperate with the light to minimize or even eliminate parallax viewing of a corneal light reflex by the surgeon's non-dominant or other eye. Further, the device may also include magnification lenses to enhance the view of the eye as seen by the surgeon. | 09-30-2010 |
20110149245 | OPTICAL COHERENCE REFLECTOMETRY WITH DEPTH RESOLUTION - A device for performing distance measurements on an eye. The device includes an interferometer, focuses at least one measurement beam records backscattered radiation and interferometrically generates a measurement signal displaying structures of the eye by time-domain, spectral-domain or Fourier-domain coherence reflectometry, has an adjustment apparatus for laterally and/or axially displacing the focus in the eye or for varying a polarization state of the measurement beam and has a control apparatus which actuates the interferometer, wherein the control apparatus generates a plurality of A-scan individual signals from the backscattered radiation, combines these to an A-scan measurement signal and actuates the adjustment apparatus for displacing the position of the focus or for varying the polarization while recording the backscattered radiation from which the control apparatus generates the A-scan individual signals is being recorded. | 06-23-2011 |
20120162604 | BINOCULAR INDIRECT OPHTHALMOSCOPE - A binocular indirect ophthalmoscope that is adapted to be worn on a wearer's head includes a headband and illumination housing having an illumination source and a viewer module wherein the viewer module is moveable between an in-use and an out-of-use position. A mounting assembly is provided for allowing the viewer module to be pivoted between the in-use and the out-of-use positions and also allows adjustment and locking to the wearer's face in the in-use position. The mounting assembly includes a magnetic securement of the viewer module in both the in-use and out-of-use positions. Part of the magnetic securement operates as an electrical contact to automatically provide power to the illumination source in the in-use position. An optical polarizer provides intensity adjustment of the light energy transmitted to the eye being examined. Preferably the illumination source is a light emitting diode. | 06-28-2012 |
20120229768 | METHOD AND APPARATUS FOR DETECTING FIXATION OF AT LEAST ONE EYE OF A SUBJECT ON A TARGET - An apparatus for detecting fixation of at least one eye of a subject on a target includes an optical illumination system, an optical detection system, and a signal processing system adapted to communicate with the optical detection system. The signal processing system is configured to calculate at least one of a time-frequency distribution or an Auto-Regressive spectral estimation of the detection signal to provide a frequency distribution of the detection signal at a plurality of times for use in determining periods in which the subject's eye is fixed on the target based on the first and second frequency signatures. | 09-13-2012 |
20130182222 | SYSTEMS AND METHODS FOR OCULAR FUNDUS EXAMINATION REFLECTION REDUCTION - Various embodiments include systems and methods for ocular fundus examination reflection reduction. An illumination polarizer assembly can be configured to be user-attachable to an ophthalmological device and can be configured to position a first optical polarizer in an illumination portion of a light path associated with the ophthalmological device. An observation polarizer assembly can be configured to be user-attachable to the ophthalmological device and can also configured to position a second optical polarizer in an observation portion of the light path. | 07-18-2013 |
20150335241 | APPARATUS FOR OBTAINING STATUS INFORMATION OF CRYSTALLINE LENS AND EQUIPMENT INCLUDING THE SAME - In one example embodiment, an apparatus for obtaining status information of a crystalline lens of an eye includes a light projector configured to project a reference light to the crystalline lens; an intensity detector configured to detect an intensity of scattered light that is generated from the reference light by being scattered at the crystalline lens; and a calculator configured to calculate thickness information of the crystalline lens based on the intensity of scattered light. | 11-26-2015 |
20160038025 | APPARATUS AND METHOD FOR MINIMIZING THE INFLUENCE OF CORNEAL BIREFRINGENCE ON THE ANALYSIS OF EYE FIXATION AND FOCUS USING RETINAL BIREFRINGENCE SCANNING - The present invention provides apparatus and methods for detecting fixation of an eye of a subject on a target. The methods provide for optimization of parameters of the spinning half wave plate and the fixed wave plate in the retinal birefringence scanning (RBS) design to enable uses of the “spinning artifact” frequency component. Frequency of the “spinning artifact” component is determined by half wave plate rotation speed and direction, and amplitude is determined by interaction of the spinning half wave plate with any retardance encountered in the double-pass optics such as the fixed wave plate, the corneal birefringence, and the small amount of retinal birefringence. With optimum selection of the fractional spinning frequency of the half wave plate, and the orientation/retardance of the fixed wave plate, the “spinning artifact” frequency component is essentially independent of the fixation direction and is also essentially independent of the normal range of corneal birefringence. | 02-11-2016 |