Patent application number | Description | Published |
20090060444 | Optical Fiber Holder And Heat Sink - An optical fiber holding device is disclosed having an optical fiber held therein. The device has a base with a spiral channel in an upper surface holding and housing the optical fiber. The channel has a first location where the fiber enters leading to a plurality of turnings for holding the optical fiber wrapped therearound at another end a second location where the fiber exits the channel wherein the bend radius of the optical fiber housed within the spiral channel is at least 2 cm. The dimensions are such that housing forms a heat sink allowing heat within the fiber to dissipate within the base. The spiral channel is preferably designed to keep the fiber within the channel and to prevent it from inadvertently springing out spring tension of the bent fiber holds the fiber within the groove or channel. | 03-05-2009 |
20090232453 | Tapered Fiber Retroreflector - An expanded-beam all-glass retroreflector for a fiber laser cavity. The retroreflector consists of a section of a tapered double-clad fiber for beam expansion, e.g. a tapered section of the laser fiber itself, or a piece of coreless fiber spliced to the laser fiber, and a reflective surface for reflection of the expanded beam back into laser cavity through the tapered fiber section. | 09-17-2009 |
20110032605 | PULSED OPTICAL SOURCE - The invention relates to pulsed optical sources formed of a source of seed optical radiation, a pulsed optical amplifier for pulsing the seed optical radiation, and an output optical port for outputting a pulsed optical signal produced by the pulsed optical amplifier. An optically isolating element such as an optical circulator is provided in the optical path between the optical seed source and the pulsed optical amplifier. | 02-10-2011 |
20110243161 | FREQUENCY CONVERSION OF A LASER BEAM USING A PARTIALLY PHASE-MISMATCHED NONLINEAR CRYSTAL - The invention relates to a laser system including a nonlinear crystal having a first length portion and a second length portion. The nonlinear crystal disposed to receive input light from the laser for converting the input light into frequency converted light; wherein the nonlinear crystal is configured so that the first length portion of the nonlinear crystal is phase matching for the input light and the frequency converted light, and the second length portion of the nonlinear crystal is phase mismatching for the input light and the frequency converted light. Phase mismatching means may include a temperature controlling board, a clamp, or electrodes. | 10-06-2011 |
20120320451 | LARGE MODE AREA OPTICAL WAVEGUIDE DEVICES - A very large more area active double clad optical waveguide doped with Nd | 12-20-2012 |
20130148925 | VARYING BEAM PARAMETER PRODUCT OF A LASER BEAM - An optical delivery waveguide for a material laser processing system includes a small lens at an output end of the delivery waveguide, transforming laser beam divergence inside the waveguide into a spot size after the lens. By varying the input convergence angle and/or launch angle of the laser beam launched into the waveguide, the output spot size can be continuously varied, thus enabling a continuous and real-time laser spot size adjustment on the workpiece, without having to replace the delivery waveguide or a process head. A divergence of the laser beam can also be adjusted dynamically and in concert with the spot size. | 06-13-2013 |
20130250979 | STABILIZING BEAM POINTING OF A FREQUENCY-CONVERTED LASER SYSTEM - A beam-stabilized laser system using optical frequency conversion in a nonlinear optical crystal is disclosed. An optimal phase-matching angle in the crystal depends on both wavelength and temperature. If the crystal temperature changes, the optimal phase-matching direction will change as well. A different wavelength can be selected so that the optimal phase-matching occurs along the original beam path and returns the output beam to the original direction. Thus, a central wavelength of the laser beam illuminating the nonlinear optical crystal can be slightly adjusted to compensate for the pointing drift. Since the illuminating wavelength can normally be tuned much faster than the crystal temperature, a more agile and responsive pointing stabilization can be achieved. | 09-26-2013 |
20130301116 | MASTER OSCILLATOR - POWER AMPLIFIER SYSTEMS - The invention provides fiber-optic light sources such as cladding-pumped master oscillator—power amplifier (MOPA) systems which use double-clad optical fibers (DCF). The inner cladding of the first DCF used in the master oscillator section has a circular cross-section in order to enable the formation of low loss optical splices in the integrated MOPA structure. The inner cladding of the second DCF in the output amplifier section has a shaped non-circular cross-section in order to enhance the absorption of the pump light in the doped core of the second DCF. | 11-14-2013 |
20140211818 | CLADDING LIGHT STRIPPER AND METHOD OF MANUFACTURING - A cladding stripper includes a plurality of transversal notches or grooves in the outer surface of an exposed inner cladding of a double clad optical fiber. Position and orientation of the notches can be selected to even out cladding light release along the cladding light stripper, enabling more even temperature distributions due to released cladding light. The notches on the optical fiber can be made with a laser ablation system. | 07-31-2014 |
20150139638 | SYSTEM AND METHOD OF ESTIMATING BEAM MODE CONTENT FOR WAVEGUIDE ALIGNMENT - Alignment of a multimode waveguide to a source of light or another waveguide is evaluated using a multi-wavelength light source and a modal decomposition processing of an intensity profile of a waveguide output beam, wherein inter-modal interference is averaged out over wavelength. Fitting a superposition of mode intensity profiles to a wavelength-averaged intensity profile of the output beam provides information about the modal composition of the output beam, which may be used to assess the alignment of the multimode waveguide with respect to the input light beam, and to provide a feedback for guiding a waveguide alignment process. | 05-21-2015 |
20150160468 | REDUCING OPTICAL ABERRATIONS WITH GRADED-INDEX OPTICS - An aberration corrector and a method to reducing a spherical aberration are disclosed. The aberration corrector has a radial, rotationally symmetric variation of refractive index including a term varying in proportion to a fourth degree of a distance from the optical axis. Since the spherical aberration causes a wavefront deviation proportional to the fourth degree of distance from the optical axis, the spherical aberration can be reduced by the aberration corrector when its thickness causes the exact amount of the phase delay corresponding to the wavefront deviation, but with an opposite sign. | 06-11-2015 |
20160111850 | WAVELENGTH COMBINED LASER SYSTEM - A beam combiner may include source elements, each configured to output a beam of light locked at a center wavelength different from center wavelengths of other source elements. The beam combiner may include a dispersive element configured to combine the beams of light into a combined beam, and a beam separator configured to separate the combined beam into an output beam and a locking beam. The beam combiner may include a spatial filter configured to prevent crosstalk within the locking beam, and to redirect the locking beam to the source elements. The dispersive element may be configured to disperse the locking beam into constituent wavelength beams. Each constituent wavelength beam may be directed to a respective one of the source elements for locking that source element at its center wavelength, and may correspond in wavelength to the center wavelength of the respective source element. | 04-21-2016 |
20160116679 | VARYING BEAM PARAMETER PRODUCT OF A LASER BEAM - An optical delivery waveguide for a material laser processing system includes a small lens at an output end of the delivery waveguide, transforming laser beam divergence inside the waveguide into a spot size after the lens. By varying the input convergence angle and/or launch angle of the laser beam launched into the waveguide, the output spot size can be continuously varied, thus enabling a continuous and real-time laser spot size adjustment on the workpiece, without having to replace the delivery waveguide or a process head. A divergence of the laser beam can also be adjusted dynamically and in concert with the spot size. | 04-28-2016 |
Patent application number | Description | Published |
20110216064 | SENDING A PARAMETER BASED ON SCREEN SIZE OR SCREEN RESOLUTION OF A MULTI-PANEL ELECTRONIC DEVICE TO A SERVER - In a particular embodiment, a method includes detecting a hardware configuration change at an electronic device. The electronic device includes at least a first panel having a first display surface and a second panel having a second display surface. An effective screen size or a screen resolution corresponding to a viewing area that includes the first display surface and the second display surface is modified in response to the hardware configuration change. The method also includes sending at least one parameter associated with or based on the modified effective screen size or the modified screen resolution to a server. | 09-08-2011 |
20120311165 | SELECTIVE ADMISSION INTO A NETWORK SHARING SESSION - A system and method provide for the selective authorization and admission of a client into a data sharing session with a host. A host may select one or more clients into the sharing session based on the proximity of the clients. When a client is selected, an identifier is provided from the client device to the host device, for example, utilizing an optical identifier such as a bar code or an audible identifier such as an encoded sound. The identifier is then utilized to establish a link between the client and the host. In this fashion any number of client devices may be selectively admitted into the sharing session in a quick and easy process enabling security for the host and anonymity for the client. | 12-06-2012 |
20150049001 | ENABLING REMOTE SCREEN SHARING IN OPTICAL SEE-THROUGH HEAD MOUNTED DISPLAY WITH AUGMENTED REALITY - A method, an apparatus, and a computer program product construct an augmented view as perceived by a user of an augmented reality (AR) device having an optical see-through head mounted display (HMD) with AR, for display at a remote device. An apparatus obtains scene data corresponding to a real-world scene visible through the optical see-through HMD, and screen data of at least one of a first augmented object displayed on the optical see-through HMD, and a second augmented object displayed on the optical see-through HMD. The apparatus determines to apply at least one of a first offset to the first augmented object relative to an origin of the real-world scene, and a second offset to the second augmented object relative to the origin. The apparatus then generates augmented-view screen data for displaying the augmented view on an HMD remote from the AR device. The augmented-view screen data is based on at least one of the first offset and the second offset. | 02-19-2015 |
20150049012 | VISUAL, AUDIBLE, AND/OR HAPTIC FEEDBACK FOR OPTICAL SEE-THROUGH HEAD MOUNTED DISPLAY WITH USER INTERACTION TRACKING - A method, an apparatus, and a computer program product provide feedback to a user of an augmented reality (AR) device having an optical see-through head mounted display (HMD). The apparatus obtains a location on the HMD corresponding to a user interaction with an object displayed on the HMD. The object may be an icon on the HMD and the user interaction may be an attempt by the user to select the icon through an eye gaze or gesture. The apparatus determines whether a spatial relationship between the location of user interaction and the object satisfies a criterion, and outputs a sensory indication, e.g., visual display, sound, vibration, when the criterion is satisfied. The apparatus may be configured to output a sensory indication when user interaction is successful, e.g., the icon was selected. Alternatively, the apparatus may be configured to output a sensory indication when the user interaction fails. | 02-19-2015 |
20150049013 | AUTOMATIC CALIBRATION OF EYE TRACKING FOR OPTICAL SEE-THROUGH HEAD MOUNTED DISPLAY - An apparatus for calibrating an eye tracking system of a head mounted display displays a moving object in a scene visible through the head mounted display. The object is displayed progressively at a plurality of different points (P) at corresponding different times (T). While the object is at a first point of the plurality of different points in time, the apparatus determines whether an offset between the point P and an eye gaze point (E) satisfies a threshold. The eye-gaze point (E) corresponds to a point where a user is determined to be gazing by the eye tracking system. If the threshold is not satisfied, the apparatus performs a calibration of the eye tracking system when the object is at a second point of the plurality of different points in time. The apparatus then repeats the determining step when the object is at a third point of the plurality of different points in time. | 02-19-2015 |
20150049112 | AUTOMATIC CUSTOMIZATION OF GRAPHICAL USER INTERFACE FOR OPTICAL SEE-THROUGH HEAD MOUNTED DISPLAY WITH USER INTERACTION TRACKING - A method, an apparatus, and a computer program product render a graphical user interface (GUI) on an optical see-through head mounted display (HMD). The apparatus obtains a location on the HMD corresponding to a user interaction with a GUI object displayed on the HMD. The GUI object may be an icon on the HMD and the user interaction may be an attempt by the user to select the icon through an eye gaze or gesture. The apparatus determines whether a spatial relationship between the location of user interaction and the GUI object satisfies a criterion, and adjusts a parameter of the GUI object when the criterion is not satisfied. The parameter may be one or more of a size of the GUI object, a size of a boundary associated with the GUI object or a location of the GUI object. | 02-19-2015 |
20150049113 | VISUAL SEARCH IN REAL WORLD USING OPTICAL SEE-THROUGH HEAD MOUNTED DISPLAY WITH AUGMENTED REALITY AND USER INTERACTION TRACKING - A method, an apparatus, and a computer program product conduct online visual searches through an augmented reality (AR) device having an optical see-through head mounted display (HMD). An apparatus identifies a portion of an object in a field of view of the HMD based on user interaction with the HMD. The portion includes searchable content, such as a barcode. The user interaction may be an eye gaze or a gesture. A user interaction point in relation to the HMD screen is tracked to locate a region of the object that includes the portion and the portion is detected within the region. The apparatus captures an image of the portion. The identified portion of the object does not encompass the entirety of the object. Accordingly, the size of the image is less than the size of the object in the field of view. The apparatus transmits the image to a visual search engine. | 02-19-2015 |
20150049201 | AUTOMATIC CALIBRATION OF SCENE CAMERA FOR OPTICAL SEE-THROUGH HEAD MOUNTED DISPLAY - An apparatus for calibrating an augmented reality (AR) device having an optical see-through head mounted display (HMD) obtains eye coordinates in an eye coordinate system corresponding to a location of an eye of a user of the AR device, and obtains object coordinates in a world coordinate system corresponding to a location of a real-world object in the field of view of the AR device, as captured by a scene camera having a scene camera coordinate system. The apparatus calculates screen coordinates in a screen coordinate system corresponding to a display point on the HMD, where the calculating is based on the obtained eye coordinates and the obtained object coordinates. The apparatus calculates calibration data based on the screen coordinates, the object coordinates and a transformation from the target coordinate system to the scene camera coordinate system. The apparatus then derives subsequent screen coordinates for the display of AR in relation to other real-world object points based on the calibration data. | 02-19-2015 |