Patent application number | Description | Published |
20130093871 | OMNIDIRECTIONAL SUPER-RESOLUTION MICROSCOPY - A microscopy method and apparatus includes placing a specimen to be observed adjacent to a reflective holographic optical element (RDOE). A beam of light that is at least partially coherent is focused on a region of the specimen. The beam forward propagates through the specimen and is at least partially reflected backward through the specimen. The backward reflected light interferes with the forward propagating light to provide a three dimensional interference pattern that is at least partially within the specimen. A specimen region illuminated by the interference pattern is imaged at an image detector. Computational reconstruction is used to generate a microscopic image in all three spatial dimensions (X,Y,Z), simultaneously with resolution greater than conventional microscopy. | 04-18-2013 |
20130106782 | OPTICAL TABLET STYLUS AND INDOOR NAVIGATION SYSTEM | 05-02-2013 |
20130120830 | LOW NOISE PHOTO-PARAMETRIC SOLID STATE AMPLIFIER - A solid state detection system includes a degenerate photo-parametric amplifier (PPA), wherein the PPA comprises a photo diode, and a periodically pulsed light source, wherein the photo-parametric amplifier (PPA) is synchronized to the pulsed light source with a phase locked loop that generates a pump waveform for the PPA at twice the frequency of the excitation pulse rate. | 05-16-2013 |
20130187950 | TRANSPARENT DISPLAY FOR MOBILE DEVICE - A projection-type display device is connectively coupled to a mobile device (such as a smartphone) where the light generated by a small projection device is directed at a relatively transparent holographic optical element (HOE) to provide a display to an operator of the mobile device or a viewer. The projector and HOE may be configured to produce and magnify a virtual image that is perceived as being displayed at a large distance from the operator who views the image through the HOE. The HOE may comprise a volume grating effective at only the narrow wavelengths of the projection device to maximize transparency while also maximizing the light reflected from the display projector to the eyes of the operator. | 07-25-2013 |
20130188486 | DATA CENTER NETWORK USING CIRCUIT SWITCHING - A circuit-based digital communications network is provided for a large data center environment that utilizes circuit switching in lieu of packet switching in order to lower the cost of the network and to gain performance efficiencies. A method for transmitting data in such a network comprises sending a setup request for a path for transmitting the data to a destination node and then speculatively sending the data to the destination node before the setup request is completed. | 07-25-2013 |
20130207964 | IMAGING STRUCTURE WITH EMBEDDED LIGHT SOURCES - In embodiments of an imaging structure with embedded light sources, an imaging structure includes a silicon backplane with a driver pad array. The embedded light sources are formed on the driver pad array in an emitter material layer, and the embedded light sources can be individually controlled at the driver pad array to generate and emit light. A conductive material layer over the embedded light sources forms a p-n junction between the emitter material layer and the conductive material layer. Micro lens optics can be positioned over the conductive material layer to direct the light that is emitted from the embedded light sources. Further, the micro lens optics may be implemented as parabolic optics to concentrate the light that is emitted from the embedded light sources. | 08-15-2013 |
20130208482 | IMAGING STRUCTURE COLOR CONVERSION - In embodiments of imaging structure color conversion, an imaging structure includes a silicon backplane with a driver pad array. An embedded light source is formed on the driver pad array in an emitter material layer, and the embedded light source emits light in a first color. A conductive material layer over the embedded light source forms a p-n junction between the emitter material layer and the conductive material layer. A color conversion layer can then convert a portion of the first color to at least a second color. Further, micro lens optics can be implemented to direct the light that is emitted through the color conversion layer. | 08-15-2013 |
20130285885 | HEAD-MOUNTED LIGHT-FIELD DISPLAY - A head-mounted light-field display system (HMD) includes two light-field projectors (LFPs), one per eye, each comprising a solid-state LED emitter array (SLEA) operatively coupled to a microlens array (MLA). The SLEA and the MLA are positioned so that light emitted from an LED of the SLEA reaches the eye through at most one microlens from the MLA. The HMD's LFP comprises a moveable solid-state LED emitter array coupled to a microlens array for close placement in front of an eye—without the need for any additional relay or coupling optics—wherein the LED emitter array physically moves with respect to the microlens array to mechanically multiplex the LED emitters to achieve resolution via mechanically multiplexing. | 10-31-2013 |
20130286053 | DIRECT VIEW AUGMENTED REALITY EYEGLASS-TYPE DISPLAY - A low-power, high-resolution, see-through (i.e., “transparent”) augmented reality (AR) display without projectors with relay optics separate from the display surface but instead feature a small size, low power consumption, and/or high quality images (high contrast ratio). The AR display comprises sparse integrated light-emitting diode (iLED) array configurations, transparent drive solutions, and polarizing optics or time multiplexed lenses to combine virtual iLED projection images with a user's real world view. The AR display may also feature full eye-tracking support in order to selectively utilize only the portions of the display(s) that will produce only projection light that will enter the user's eye(s) (based on the position of the user's eyes at any given moment of time) in order to achieve power conservation. | 10-31-2013 |
20130335671 | ACTIVE REFLECTIVE SURFACES - In embodiments of active reflective surfaces, an imaging structure includes a circuit control layer that controls pixel activation to emit light. A reflective layer of the imaging structure reflects input light from an illumination source. An active color conversion material that is formed on the reflective layer converts the input light to the emitted light. The active color conversion material can be implemented as a phosphorus material or quantum dot material that converts the input light to the emitted light, and in embodiments, the active color conversion material is laminated directly on the reflective layer. | 12-19-2013 |
20140267176 | SYSTEMS AND METHODS FOR PARALLAX COMPENSATION - An electronic device may include a touch screen electronic display configured to offset and/or shift the contact locations of touch implements and/or displayed content based on one or more calculated parallax values. The parallax values may be associated with the viewing angle of an operator relative to the display of the electronic device. In various embodiments, the parallax value(s) may be calculated using three-dimensional location sensors, an angle of inclination of a touch implement, and/or one or more displayed calibration objects. Parallax values may be utilized to remap contact locations by a touch implement, shift and/or offset displayed content, and/or perform other transformations as described herein. A stereoscopically displayed content may be offset such that a default display plane is coplanar with a touch surface rather than a display surface. Contacts by a finger may be remapped using portions of the contact region and/or a centroid of the contact region. | 09-18-2014 |
20140267177 | SYSTEMS AND METHODS FOR PARALLAX COMPENSATION - An electronic device may include a touch screen electronic display configured to offset and/or shift the contact locations of touch implements and/or displayed content based on one or more calculated parallax values. The parallax values may be associated with the viewing angle of an operator relative to the display of the electronic device. In various embodiments, the parallax value(s) may be calculated using three-dimensional location sensors, an angle of inclination of a touch implement, and/or one or more displayed calibration objects. Parallax values may be utilized to remap contact locations by a touch implement, shift and/or offset displayed content, and/or perform other transformations as described herein. A stereoscopically displayed content may be offset such that a default display plane is coplanar with a touch surface rather than a display surface. Contacts by a finger may be remapped using portions of the contact region and/or a centroid of the contact region. | 09-18-2014 |
20140267178 | SYSTEMS AND METHODS FOR PARALLAX COMPENSATION - An electronic device may include a touch screen electronic display configured to offset and/or shift the contact locations of touch implements and/or displayed content based on one or more calculated parallax values. The parallax values may be associated with the viewing angle of an operator relative to the display of the electronic device. In various embodiments, the parallax value(s) may be calculated using three-dimensional location sensors, an angle of inclination of a touch implement, and/or one or more displayed calibration objects. Parallax values may be utilized to remap contact locations by a touch implement, shift and/or offset displayed content, and/or perform other transformations as described herein. A stereoscopically displayed content may be offset such that a default display plane is coplanar with a touch surface rather than a display surface. Contacts by a finger may be remapped using portions of the contact region and/or a centroid of the contact region. | 09-18-2014 |
20140267179 | SYSTEMS AND METHODS FOR PARALLAX COMPENSATION - An electronic device may include a touch screen electronic display configured to offset and/or shift the contact locations of touch implements and/or displayed content based on one or more calculated parallax values. The parallax values may be associated with the viewing angle of an operator relative to the display of the electronic device. In various embodiments, the parallax value(s) may be calculated using three-dimensional location sensors, an angle of inclination of a touch implement, and/or one or more displayed calibration objects. Parallax values may be utilized to remap contact locations by a touch implement, shift and/or offset displayed content, and/or perform other transformations as described herein. A stereoscopically displayed content may be offset such that a default display plane is coplanar with a touch surface rather than a display surface. Contacts by a finger may be remapped using portions of the contact region and/or a centroid of the contact region. | 09-18-2014 |
20140267184 | Multimode Stylus - A stylus for use as an input device automatically switches its mode of operation. | 09-18-2014 |