Class / Patent application number | Description | Number of patent applications / Date published |
385008000 |
Electro-optic
| 74 |
385006000 |
Magneto-optic
| 9 |
385005000 |
Light intensity dependent (e.g., nonlinear effects)
| 6 |
385007000 |
Acousto-optic | 4 |
20090162002 | ACOUSTO-OPTIC FILTER - Optical waveguides are provided on a substrate, a thin film whose refractive index is optically less than the refractive indices of the optical waveguides is provided on the surface of the substrate, and a surface-acoustic-wave waveguide is arranged on the thin film so as to cross the optical waveguides in a direction oblique thereto. The optical waveguides are not directly influenced by the location of the SAW waveguide and the phase matching condition of the optical waveguides is not changed, whereby the sidelobe characteristic of an optical filter is not degraded by assigning weights to the SAW intensity. | 06-25-2009 |
20130202245 | WAVELENGTH CONVERSION APPARATUS, LIGHT SOURCE APPARATUS, AND WAVELENGTH CONVERSION METHOD - In order to create a stable non-linear optical effect with high efficiency for a plurality of input lights having different wavelengths, according to a first aspect of the present invention, provided is a wavelength conversion apparatus comprising an input section into which input light is input; a wavelength converting section that includes a polarity inverting structure whose polarity inverts periodically and that, in response to the input of light having a wavelength corresponding to the period with which the polarity inverts, converts the wavelength of the light; and a direction changing section that changes a progression direction in which the input light passes through the polarity inverting structure, according to the wavelength of the input light, without changing relative positions of the input section and the polarity inverting structure. Also provided are a light source apparatus and a wavelength converting method. | 08-08-2013 |
20140254975 | SYSTEMS AND METHODS FOR MINIMALLY-INVASIVE OPTICAL-ACOUSTIC IMAGING - An imaging guidewire can include one or more optical fibers communicating light along the guidewire. At or near its distal end, one or more blazed or other fiber Bragg gratings (FBGs) directs light to a photoacoustic transducer material that provides ultrasonic imaging energy. Returned ultrasound is sensed by an FBG sensor. A responsive signal is optically communicated to the proximal end of the guidewire, and processed to develop a 2D or 3D image. In one example, the guidewire outer diameter is small enough such that an intravascular catheter can be passed over the guidewire. Techniques for improving ultrasound reception include using a high compliance material, resonating the ultrasound sensing transducer, using an attenuation-reducing coating and/or thickness, and/or using optical wavelength discrimination. Techniques for improving the ultrasound generating transducer include using a blazed FBG, designing the photoacoustic material thickness to enhance optical absorption. Techniques for distinguishing plaque or vulnerable plaque may be used to enhance the displayed image. | 09-11-2014 |
20160377954 | NANOSTRUCTURED ACOUSTO-OPTIC DEVICE, AND OPTICAL SCANNER, OPTICAL MODULATOR, AND HOLOGRAPHIC DISPLAY APPARATUS USING THE NANOSTRUCTURED ACOUSTO-OPTIC DEVICE - An acousto-optic device capable of increasing a range of a diffraction angle of output light by using a nanostructured acousto-optic medium, and an optical scanner, an optical modulator, a two-dimensional/three-dimensional (2D/3D) conversion stereoscopic image display apparatus, and a holographic display apparatus using the acousto-optic device. The acousto-optic device may include a nanostructured acousto-optic medium formed by at least two different mediums repeatedly alternating with each other, wherein at least one of the at least two different mediums includes an acousto-optic medium. The acousto-optic device having the aforementioned structure may increase the range of a diffraction angle of output light. Thus, various systems such as the optical scanner, the optical modulator, the 2D/3D conversion stereoscopic image display apparatus, and the holographic display apparatus may not require a separate optical system to increase an operational angle range, thereby decreasing a size of the system and/or improving a resolution of the system. | 12-29-2016 |
Entries |
Document | Title | Date |
20080279497 | METHODS TO REDUCE POLARIZATION DEPENDENT LOSS IN PLANAR LIGHTWAVE CIRCUITS - Polarization dependent loss may be reduced by providing at least one dummy waveguide or at least one dummy metal structure. Polarization dependent loss may also be reduced by imposing a mechanical force on the OIC to exert mechanical stress thereby changing at least one of the birefringence and the optical axes of at least one waveguide. And polarization dependent loss may be reduced by forming a metal heater using a first set of metal deposition parameters; forming a conductive metal structure contacting the metal heater using a second set of metal deposition parameters; and selecting the first set of metal deposition parameters and the second set of metal deposition parameters to reduce stress. | 11-13-2008 |
20090129720 | Efficient transfer of light signals between optical devices - An optical device includes a waveguide immobilized on a base. The device includes a port configured to receive light signals from the waveguide such that the light signals travel through the port. The light signals enter the port traveling in a first direction. The port is configured to change the direction of the light signals from the first direction to a second direction that is toward a location above the device or below the device. The device also includes a wedge configured to receive the light signals from the port such that the light signals travel through the wedge and then exit the wedge traveling in a direction that is at an angle in a range of 88° to 92° relative to the device and that is toward a location above or below the device. | 05-21-2009 |
20100215310 | Photonic band gap router - An arrangement includes a photonic band-gap assembly comprising at least one input wave guide and at least one output wave guides, and at least one routing element responsive to signals to selectively route a signal from the input wave guide to one or more of the output wave guides. | 08-26-2010 |
20110002576 | Silicide Thermal Heaters for Silicon-on-Insulator Nanophotonic Devices - A thermally switched Silicon-On-Insulator (SOI) photo electronic device includes a silicon layer including an optical waveguide and a silicide heating element horizontally adjacent to the waveguide. The waveguide has a refractive index that changes with heat applied to the waveguide. | 01-06-2011 |
20110002577 | Backside Reflection Optical Display - The disclosure generally involves an optical (perhaps flat panel) display utilizing backside reflection for time-multiplexed optical shuttering. One display comprises a side-illuminated light guide associated with conditions for total internal reflection. A first surface of the light guide is elastomeric. Disposed against this elastomeric surface is an active layer that selectively deforms the elastomeric surface in locations that can correspond to display pixels. This resulting change in the geometry of the elastomeric surface can be sufficient to defeat the conditions for total internal reflection. When appropriate, light is reflected by the particular deformation and is ejected from another surface of the light guide. In this case, each location that allows light to exit could represent an activated display pixel. In certain situations, color flat panel displays of varying sizes may further implement field sequential color and time-multiplexed optical shuttering. | 01-06-2011 |
20140233879 | Luminescent Stacked Waveguide Display - A display includes at least two stacked waveguides ( | 08-21-2014 |
20150147019 | FLAT PANEL WAVEGUIDE DISPLAY AND SYSTEM - The invention provides a flat panel waveguide display, including: a fan out region, configured to allow light to experiences total internal reflection therein; a screen region, which comprises a front surface, a back surface and several side surfaces, the front surface is opposite to the back surface, wherein one side surface of the screen region optically connects to one side surface of the fan out region; and a first dielectric layer, coated on entire surface of the front surface of the screen region, wherein both of the fan out region and the screen region are made of waveguide material; wherein the first dielectric layer is divided into a first group of sections along direction of light path of light entering from the fan out region into the screen region, refractive index of each section of the first group is different from one another. Accordingly, the invention further provides a flat panel waveguide display system. | 05-28-2015 |
20160170287 | OPTICAL BEAMS | 06-16-2016 |