Patent application number | Description | Published |
20090129487 | METHODS AND APPARATUS FOR GENERATING AND PROCESSING TRANSMITTER SIGNALS - Transmitter signals are modulated with one or more codes which may represent a pulse even though the code(s) are not shaped as pulses. The code(s) may be generated by defining a pulse by its Fourier components, and then adding random phases to the Fourier components. A time-domain signal may then be created, which may serve as the code to be modulated on a carrier wave. Upon reflection of the transmitter signal, the received signal may be processed by a receiver to recover the pulse. The time-of-flight of the transmitter signal can then be determined, enabling distance measurements to be made. | 05-21-2009 |
20090135714 | METHODS AND APPARATUS FOR GENERATING AND PROCESSING TRANSMITTER SIGNALS - Transmitter signals are modulated with one or more codes which may represent a pulse even though the code(s) are not shaped as pulses. The code(s) may be generated by defining a pulse by its Fourier components, and then adding random phases to the Fourier components. A time-domain signal may then be created, which may serve as the code to be modulated on a carrier wave. Upon reflection of the transmitter signal, the received signal may be processed by a receiver to recover the pulse. The time-of-flight of the transmitter signal can then be determined, enabling distance measurements to be made. | 05-28-2009 |
20090154935 | BIDIRECTIONAL OPTICAL LINK OVER A SINGLE MULTIMODE FIBER OR WAVEGUIDE - A transceiver for use in a bidirectional optical communication link over a multimode channel is provided. The transceiver includes a single transverse mode light source in a transmitter. A waveguide or fiber based bidirectional coupler projects the transmitter mode to the high modes of the multimode channel. A detector coupled to predominantly all the modes of the channel via the waveguide or fiber based bidirectional coupler. | 06-18-2009 |
20090278030 | METHOD OF LOCATING AN OBJECT IN 3-D - Methods and devices for calculating the position of a movable device are disclosed. The device may include multiple optical detectors (ODs) and the movable device may include light sources. Optics may be above the ODs. A controller may calculate the position of the light source based on data from the ODs and properties of the optics. The device may be a game console, and the light source may be a game controller. The roles of the OD and light sources may be interchanged. The rotation of the movable device may be determined using multiple light sources and/or multiple ODs on the movable device. The movable device may calculate its position and transmit it to a console. The light sources may be modulated by time or frequency to distinguish between the light sources. There may be two or more movable devices. There may be two or more consoles. | 11-12-2009 |
20090278800 | METHOD OF LOCATING AN OBJECT IN 3D - Methods and devices for calculating the position of a movable device are disclosed. The device may include multiple optical detectors (ODs) and the movable device may include light sources. Optics may be above the ODs. A controller may calculate the position of the light source based on data from the ODs and properties of the optics. The device may be a game console, and the light source may be a game controller. The roles of the OD and light sources may be interchanged. The rotation of the movable device may be determined using multiple light sources and/or multiple ODs on the movable device. The movable device may calculate its position and transmit it to a console. The light sources may be modulated by time or frequency to distinguish between the light sources. There may be two or more movable devices. There may be two or more consoles. | 11-12-2009 |
20090279104 | METHOD OF LOCATING AN OBJECT IN 3D - Methods and devices for calculating the position of a movable device are disclosed. The device may include multiple optical detectors (ODs) and the movable device may include light sources. Optics may be above the ODs. A controller may calculate the position of the light source based on data from the ODs and properties of the optics. The device may be a game console, and the light source may be a game controller. The roles of the OD and light sources may be interchanged. The rotation of the movable device may be determined using multiple light sources and/or multiple ODs on the movable device. The movable device may calculate its position and transmit it to a console. The light sources may be modulated by time or frequency to distinguish between the light sources. There may be two or more movable devices. There may be two or more consoles. | 11-12-2009 |
20090279105 | METHOD OF LOCATING AN OBJECT IN 3-D - Methods and devices for calculating the position of a movable device are disclosed. The device may include multiple optical detectors (ODs) and the movable device may include light sources. Optics may be above the ODs. A controller may calculate the position of the light source based on data from the ODs and properties of the optics. The device may be a game console, and the light source may be a game controller. The roles of the OD and light sources may be interchanged. The rotation of the movable device may be determined using multiple light sources and/or multiple ODs on the movable device. The movable device may calculate its position and transmit it to a console. The light sources may be modulated by time or frequency to distinguish between the light sources. There may be two or more movable devices. There may be two or more consoles. | 11-12-2009 |
20090279106 | METHOD OF LOCATING AN OBJECT IN 3-D - Methods and devices for calculating the position of a movable device are disclosed. The device may include multiple optical detectors (ODs) and the movable device may include light sources. Optics may be above the ODs. A controller may calculate the position of the light source based on data from the ODs and properties of the optics. The device may be a game console, and the light source may be a game controller. The roles of the OD and light sources may be interchanged. The rotation of the movable device may be determined using multiple light sources and/or multiple ODs on the movable device. The movable device may calculate its position and transmit it to a console. The light sources may be modulated by time or frequency to distinguish between the light sources. There may be two or more movable devices. There may be two or more consoles. | 11-12-2009 |
20090279107 | OPTICAL DISTANCE MEASUREMENT BY TRIANGULATION OF AN ACTIVE TRANSPONDER - Methods and devices for calculating the position of a movable device are disclosed. A console and movable device may include light detector(s) and light sources. A light source of the console may emit light that is detected by light detector(s) of the movable device. The moveable device may respond by emitting light synchronous with the received light. The console may calculate the position of the movable device by calculating the time for the light emitted from the movable device to strike the light detector(s) of the console. The rotation of the movable device may be calculated using multiple light sources and/or multiple light detector(s). The movable device may calculate its position and transmit it to a console. Multiple light sources may be distinguished using encoding or modulation of time and/or frequency. The roles of the light detectors(s) and light sources may be switched. | 11-12-2009 |
20090281765 | METHOD OF LOCATING AN OBJECT IN 3D - Methods and devices for calculating the position of a movable device are disclosed. The device may include multiple optical detectors (ODs) and the movable device may include light sources. Optics may be above the ODs. A controller may calculate the position of the light source based on data from the ODs and properties of the optics. The device may be a game console, and the light source may be a game controller. The roles of the OD and light sources may be interchanged. The rotation of the movable device may be determined using multiple light sources and/or multiple ODs on the movable device. The movable device may calculate its position and transmit it to a console. The light sources may be modulated by time or frequency to distinguish between the light sources. There may be two or more movable devices. There may be two or more consoles. | 11-12-2009 |
20090309036 | SILICON DETECTOR AND METHOD FOR CONSTRUCTING SILICON DETECTORS - Disclosed is a die having photodetectors provided on a first surface thereof. The die includes an insulative shell member, a conductive shell member and a photodetector conductor. The insulative shell member extends around a periphery of the photodetector receptors and extending through a depth of the semiconductor die. The conductive shell member bridges the insulative shell member and extends through the depth of the semiconductor die. The photodetector conductors are provided on the first surface of the semiconductor die and electrically couple respective photodetectors with a corresponding conductive shell member. Also disclosed is a process for making a semiconductor die and an integrated circuit structure. | 12-17-2009 |
20100231513 | POSITION MEASUREMENT SYSTEMS USING POSITION SENSITIVE DETECTORS - Methods and devices for a remote control device for a display device are disclosed. In one embodiment, the remote control device may comprise a plurality of light sources that each has a light profile angled in a predetermined degree different from other light sources. In another embodiment, the remote control device may comprise a controller; and a plurality of optical detectors coupled to the controller. Each optical detector may generate a pair of electrical signals in response to incident light from a plurality of light sources located on a display device and the controller may calculate the position of the remote control device based on the electrical signals. | 09-16-2010 |
20100284699 | BIDIRECTIONAL OPTICAL LINK OVER A SINGLE MULTIMODE FIBER OR WAVEGUIDE - A transceiver for use in a bidirectional optical communication link over a multimode channel is provided. The transceiver includes a single transverse mode light source in a transmitter. A waveguide or fiber based bidirectional coupler projects the transmitter mode to the high modes of the multimode channel. A detector coupled to predominantly all the modes of the channel via the waveguide or fiber based bidirectional coupler. | 11-11-2010 |
20100305418 | MULTIUSE OPTICAL SENSOR - One or more electromagnetic radiation sources, such as a light emitting diode, may emit electromagnetic waves into a volume of space. When an object enters the volume of space, the electromagnetic waves may reflect off the object and strike one or more position sensitive detectors after passing through an imaging optical system such as glass, plastic lens, or a pinhole located at known distances from the sources. Mixed signal electronics may process detected signals at the position sensitive detectors to calculate position information as well as total reflected light intensity, which may be used in medical and other applications. A transparent barrier may separate the sources and detectors from the objects entering the volume of space and reflecting emitted waves. Methods and devices are provided. | 12-02-2010 |
20110286690 | OPTICAL PACKAGE AND RELATED METHODS - A package for an electronic chip including an optical component protects the chip and the component, while allowing for an optical connection of the component with another optical device. This is achieved, in various embodiments, by forming a well in a protective material deposited over the chip to expose the optical component, and by providing alignment features in the protective material to align and connect the optical component with another optical device. | 11-24-2011 |
20120249475 | 3D USER INTERFACE CONTROL - Techniques to provide a three-dimensional (“3D”) user interface (“UI”) processing system for a device that may include at least one sensor, a 3D display, and a controller. The controller may include a memory, which may store instructional information, and a processor. The processor may be configured to receive sensor data from the sensor(s) and to interpret sensor data according to the instructional information. The processor may generate a user interface command(s) and transmit the command(s) to the 3D display to control and/or manipulate the 3D display. The processor may also generate host commands to control and/or execute applications within a host system of the device. | 10-04-2012 |
20130128263 | Angle measurement by use of multiple oriented light sources - Embodiments of the present invention may provide a relative angular motion measurement system that includes a remote device used to control operations of a host device. The remote may include a plurality of light sources with predetermined light distribution patterns and angles of orientation with respect to a major axis of the remote. The host device may include a sensor and a controller. The sensor may detect light emitted from the remote (via the light sources) and generate output signals that may be interpreted by the controller. The controller may interpret the output signals from the sensor to estimate received intensity from each light source and calculate the orientation of the remote device based on data representing the light sources' light distribution patterns with fixed angles of orientation. | 05-23-2013 |
20130155396 | OPTICAL MEASURING SENSOR - An optical detector may include an aperture, at least two photodetectors, and a measuring arrangement to quantify light detected at the photodetectors after passing through the aperture without the need for a lens. The aperture may be positioned between a light source and the two photodetectors to allow light from a light source to pass through the aperture to the photodetectors. The photodetectors may include PIN junction photodiodes and may be electrically isolated from each other, positioned next to each other in a side-by-side configuration, and then aligned with the aperture so that a proportion of the quantified light detected at the photodetectors changes as an angle of light from the light source incident to the aperture changes. Optical detectors and methods are provided. | 06-20-2013 |
20140323844 | CIRCUIT ARCHITECTURE FOR PHOTODIODES - An electrical circuit includes a photodiode that receives a light signal from a light source and generates a photocurrent signal, a trans-impedance amplifier that amplifies the photocurrent signal and generates a low noise signal, and a high pass filter that converts the low noise signal into an alternating current (AC) signal having a positive amplitude, a negative amplitude, and a zero cross-over point between the positive amplitude and the negative amplitude. The electrical circuit also includes a positive integrating amplifier that receives the positive amplitude of the AC signal and generates a positive integrated value over an integration period, and a negative integrating amplifier that receives the negative amplitude of the AC signal and generates a negative integrated value over the integration period. The electrical circuit further includes at least one analog-to-digital converter that receives the positive and negative integrated values. | 10-30-2014 |
20140334772 | SYSTEMS AND METHODS FOR PASSIVE ALIGNMENT OF OPTO-ELECTRONIC COMPONENTS - A method for aligning an opto-electronic component in an IC die with an optical port is disclosed. This is achieved, in various embodiments, by forming alignment features in the IC die that can mate with complementary alignment features of the optical port. The formation of alignment features can be performed at the wafer level during fabrication of the IC die. An optical signal carrier may be optically coupled to the optical port such that the signal carrier may communicate optically with the opto-electronic component. | 11-13-2014 |
20140340302 | INTEGRATED GESTURE SENSOR MODULE - An integrated gesture sensor module includes an optical sensor die, an application-specific integrated circuit (ASIC) die, and an optical emitter die disposed in a single package. The optical sensor die and ASIC die can be disposed in a first cavity of the package, and the optical emitter die can be disposed in a second cavity of the package. The second cavity can be conical or step-shaped so that the opening defining the cavity increases with distance from the upper surface of the optical emitter die. The upper surface of the optical emitter die may be higher than the upper surface of the optical sensor die. An optical barrier positioned between the first and second cavities can include a portion of a pre-molded, laminate, or ceramic package, molding compound, and/or metallized vias. | 11-20-2014 |
20140375978 | OPTICAL TIME-OF-FLIGHT SYSTEM - Time-of-flight technology may be combined with optical detection technology identifying an angle of a light pulse emitted from a transmitter and reflected off an object based on a proportion of the reflected light pulse detected at each of at least two light sensors. The optical detection technology may include a light detector with two or more light sensors arranged at different orientations with respect to an aperture in the detector so that each sensor is able to detect a different subset of the light passing through the aperture. The effective angle of the light passing through aperture may then be calculated from the proportion of light detected at the each of the sensors. The effective angle information may be combined with a calculated time-of-flight of the light pulse to accurately identify a position of the object relative to the detector in two or three dimensions. | 12-25-2014 |
20140375985 | OPTICAL ANGLE MEASUREMENT - An optical detector may include an epitaxial layer having a continuous surface provided on a surface of a substrate. Two or more electrodes may be arranged at different positions in the epitaxial layer so that the electron-hole pairs generated in the epitaxial layer from incident light passing through the aperture and reaching the epitaxial layer have a varying probability of being collected by each of the electrodes as the angle of the incident light changes. The electrodes may be arranged at different depths in the epitaxial layer. The epitaxial layer may be continuous and have a continuous aperture-facing surface between each of the electrodes associated with a particular aperture to ensure that more light passing through the aperture is absorbable in the epitaxial layer and subsequently detectable by the electrodes. This may result in improved light detection capabilities. | 12-25-2014 |