Patent application number | Description | Published |
20100108133 | Thin Film Semiconductor Photovoltaic Device - A substantially transparent substrate having first and second major surfaces and a plurality of side surfaces; a thin-film semiconductor layer coupled to the first major surface of the substrate and including first and second major surfaces and at least one photo-sensitive p-n junction therein; and a light directing feature operable to cause incident light to propagate through the substrate and into the semiconductor layer in a waveguide mode such that the light reflects a plurality of times between the first and second major surfaces of the semiconductor layer and impinges upon the p-n junction a plurality of times | 05-06-2010 |
20100129647 | Method of Weldbonding and a Device Comprising Weldbonded Components - A method of assembling optoelectronic and/or photonic components, said method comprising: (i) providing at least two optoelectronic and/or photonic components; (ii) aligning and situating these components relative to one another and in close proximity with one another so as to: (a) provide optical coupling between these components; and (b) maintain the distance d between the adjacent parts of these components, where d is 0 to 100 μm; (iii) adhering these components to one another with while maintaining optical coupling therebetween; and (iv) laser welding these components together while maintaining optical coupling therebetween. | 05-27-2010 |
20100154877 | Semiconductor Core, Integrated Fibrous Photovoltaic Device - A cane having optical properties includes: a core formed of a semiconductor material; and a transparent cladding formed of glass, glass-ceramic, or polymer coaxially oriented about the core, the cane may be used to produce a photovoltaic device, including: a semiconductor core including at least one p-n junction, defined by respective n-type and p-type regions; a substantially transparent cladding in coaxial relationship with the semiconductor core, forming a longitudinally oriented cane; and first and second electrodes, each being electrically coupled to a respective one of the n-type and p-type regions. | 06-24-2010 |
20100159242 | Semiconductor Core, Integrated Fibrous Photovoltaic Device - A cane having optical properties includes: a core formed of a semiconductor material; and a transparent cladding formed of glass, glass-ceramic, or polymer coaxially oriented about the core, the cane may be used to produce a photovoltaic device, including: a semiconductor core including at least one p-n junction, defined by respective n-type and p-type regions; a substantially transparent cladding in coaxial relationship with the semiconductor core, forming a longitudinally oriented cane; and first and second electrodes, each being electrically coupled to a respective one of the n-type and p-type regions. | 06-24-2010 |
20100303109 | Proximity Coupled Athermal Optical Package Comprising Laser Source And Compound Facet Wavelength Conversion Device - Particular embodiments of the present disclosure bring an SHG crystal, or other type of wavelength conversion device, into close proximity with a laser source to eliminate the need for coupling optics, reduce the number of package components, and reduce package volume. According to one embodiment of the present disclosure, an optical package is provided comprising a laser source and a wavelength conversion device. The laser source is positioned such that the output face of the laser source is proximity-coupled to a waveguide portion of the input face of the wavelength conversion device. The input face of the wavelength conversion device comprises an α-cut facet and β-cut facet. The α-cut facet of the input face is oriented at a horizontal angle α, relative to the waveguide of the wavelength conversion device to permit proximity coupling of the output face of the laser source and the input face of the wavelength conversion device. The β-cut facet of the input face is oriented at a horizontal angle β, relative to the waveguide of the wavelength conversion device to cooperate with the horizontal tilt angle of the device to reduce back reflections from the input face of the wavelength conversion device into the laser source. Additional embodiments are disclosed. | 12-02-2010 |
20100303110 | Edge Bonded Optical Packages - Particular embodiments of the present disclosure bring an SHG crystal, or other type of wavelength conversion device, into close proximity with a laser source to eliminate the need for coupling optics, reduce the number of package components, and reduce package volume. According to one embodiment of the present disclosure, an optical package is provided comprising a laser source subassembly comprising a laser base and a wavelength conversion device subassembly comprising a converter base. The bonding interface of the laser base is bonded the complementary bonding interface of the converter base such that the laser output face can be proximity-coupled to the converter input face at an predetermined interfacial spacing x. Additional embodiments are disclosed and claimed. | 12-02-2010 |
20110069929 | Methods for Passively Aligning Opto-Electronic Component Assemblies on Substrates - A method for aligning an opto-electronic component assembly (OECA) on a substrate includes positioning a substrate on an assembly surface and positioning an OECA on the substrate such that a first OECA alignment face projects from a first substrate alignment face. The substrate and the OECA are advanced towards a contact face of a first assembly alignment mechanism such that the first substrate alignment face contacts the contact face of the first assembly alignment mechanism after the first OECA alignment face contacts the contact face. The OECA is displaced relative to the first substrate alignment face when the first OECA alignment face contacts the contact face and the substrate continues to move towards the contact face thereby aligning the OECA on the substrate relative to the first substrate alignment face. | 03-24-2011 |
20110129189 | CLAD METAL SUBSTRATES IN OPTICAL PACKAGES - Embodiments of the present disclosure bring a wavelength conversion device into close proximity with a laser source to eliminate the need for coupling optics, reduce the number of package components, and reduce package volume. According to one embodiment of the present disclosure, an optical package is provided comprising a laser diode chip and a clad metal substrate. The clad metal substrate comprises a clad metal region that is mechanically coupled to a base metal region. The laser diode chip is coupled to the clad metal region. The clad metal region comprises a clad metal material having a thermal conductivity that is greater than a thermal conductivity of the base metal material. The clad metal region further comprises a coefficient of thermal expansion that is approximately equal to a coefficient of thermal expansion of the base metal material and is greater than a coefficient of thermal expansion of the laser diode chip. | 06-02-2011 |
20120189252 | RECEPTACLE FERRULE ASSEMBLIES WITH GRADIENT INDEX LENSES AND FIBER OPTIC CONNECTORS USING SAME - A receptacle ferrule assembly for a fiber optic receptacle connector. The receptacle ferrule assembly comprises a first lens with first second optical surfaces and a receptacle ferrule body having first and second ends. At least one monolithic optical system is formed in a monolithic receptacle ferrule body and includes a lens formed at the second end of monolithic receptacle ferrule body and an optical surface formed at the first end of monolithic receptacle ferrule body. The optical surface is situated adjacent to, and mated to the second optical surface of the first lens The monolithic optical system is configured, in conjunction with the first lens, to define a receptacle optical pathway from the second end of the monolithic optical system to the first surface of the first lens. According to some embodiments the first lens is a gradient index lens. | 07-26-2012 |
20130044773 | OPTICAL SOURCES HAVING PROXIMITY COUPLED LASER SOURCE AND WAVEGUIDE - An optical source including a laser source and a waveguide is provided. The laser source includes a laser cavity having a laser optical path length extending from a DBR grating to a reflective laser output facet, and emits an output beam at a fundamental wavelength. The waveguide has an input facet and an output facet, and extends along a waveguide optical length from the input facet of the waveguide to the output facet of the waveguide. The input facet and the output facet of the waveguide are approximately normal with respect to an optical path of the output beam. The waveguide and the laser source are proximity coupled, and the waveguide optical length is an integer multiple of the laser optical path length. | 02-21-2013 |
20130219969 | METHODS OF MAKING A STUB LENS ELEMENT AND ASSEMBLIES USING SAME FOR OPTICAL COHERENCE TOMOGRAPHY APPLICATIONS - Methods of making a stub lens element and assemblies for coherence tomography (OCT) applications are disclosed. The method of making the stub lens element includes drawing a rod of optical material and processing the drawn rod to form a lens integrally connected to a stub section. The methods also include operably supporting an optical fiber and a stub lens element in a cooperative optical relationship to form a stub lens sub-assembly. The methods also include operably supporting the stub lens sub-assembly and a light-deflecting member in a cooperative optical relationship to form a probe optical assembly that has a folded optical path. | 08-29-2013 |
20130223787 | PROBE OPTICAL ASSEMBLIES AND PROBES FOR OPTICAL COHERENCE TOMOGRAPHY - Probes optical assemblies and probes for optical coherence tomography (OCT) applications are disclosed. The probe assembly includes an optical fiber, a stub lens and a light-deflecting member arranged in a cooperative optical relationship to define an optical path between the optical fiber end and an image plane that is folded by the light-deflecting member. The optical probe includes a transparent jacket that contains the optical probe assembly. | 08-29-2013 |
20130223801 | STUB LENS ASSEMBLIES FOR USE IN OPTICAL COHERENCE TOMOGRAPHY SYSTEMS - Stub lens assemblies for use in optical coherence tomography. The stub lens assembly has an optical fiber having an end, and an optical fiber ferrule that supports the optical fiber. The stub lens assembly also has a sleeve having a central channel with first and second ends, with the optical fiber ferrule supported within the central channel at the first end. The stub lens assembly further includes a stub lens element having a stub section with a proximal end that resides adjacent the optical fiber end within the central channel of the sleeve. The stub section is formed integral with a lens, which has a lens surface. The sleeve supports the optical fiber end and the proximal end of the stub section in a cooperative optical relationship. | 08-29-2013 |
20130266259 | MONOLITHIC BEAM-SHAPING OPTICAL SYSTEMS AND METHODS FOR AN OCT PROBE - Monolithic beam-shaping optical systems and methods are disclosed for an optical coherence tomography (OCT) probe that includes a transparent cylindrical housing having asymmetric optical power. The system includes a transparent monolithic body having a folded optical axis and at least one alignment feature that supports the end of an optical fiber adjacent an angled planar end wall. The monolithic body also includes a total-internal reflection surface and a lens surface that define object and image planes. Light from the optical fiber end traverses the optical path, which includes the cylindrical housing residing between the lens surface and the image plane. Either the lens surface by itself or the lens surface and the reflective (eg, TIR) surface in combination are configured to substantially correct for the asymmetric optical power of the cylindrical housing, thereby forming a substantially rotationally symmetric image spot at the image plane. | 10-10-2013 |
20140143996 | METHODS OF FORMING GRADIENT INDEX (GRIN) LENS CHIPS FOR OPTICAL CONNECTIONS AND RELATED FIBER OPTIC CONNECTORS - Gradient index (GRIN) lens chips for optical connections, and related methods of creating GRIN lens chips are disclosed. Each GRIN lens chip may include at least one GRIN lens and a GRIN lens holder for aligning the GRIN lens in an optical connection. When creating a GRIN lens chip, a shaped substrate may be provided including a GRIN lens holder and at least one GRIN groove for securing and aligning the GRIN lens relative to the GRIN lens holder. The GRIN lens may be part of a GRIN lens rod. By freeing the GRIN lens holder from the shaped substrate, the GRIN lens holder may include a fiber mating surface and a terminal mating surface. The fiber mating surface and the terminal mating surface may be used to align the GRIN lens holder in the optical connection. | 05-29-2014 |
20140147078 | GRADIENT INDEX (GRIN) LENS CHIPS AND ASSOCIATED SMALL FORM FACTOR OPTICAL ARRAYS FOR OPTICAL CONNECTIONS, RELATED FIBER OPTIC CONNECTORS - Gradient index (GRIN) lens chips and associated small form factor optical arrays for optical connections, and related fiber optic connectors are disclosed. By aligning GRIN lenses within a GRIN lens chip, a more precise and reliable alignment may be achieved with respect to optical fibers than if a single conventional ferrule is utilized to align and secure both GRIN lenses and optical fibers. The GRIN lens chip may include a GRIN lens received and thereby aligned within a groove disposed between a fiber end and a terminal end of a GRIN lens holder body. The optical fibers may also be received and thereby aligned within a groove of a ferrule body. In this manner, when the GRIN lens chip containing the GRIN lenses is aligned with a ferrule body containing the optical fibers, then the GRIN lenses may be precisely located relative to the optical fibers. | 05-29-2014 |
20140169742 | OPTICAL PORT HAVING ONE OR MORE ALIGNMENT FEATURES - Disclosed are optical ports and devices using the optical ports. The optical port includes a mounting body having a first pocket and at least one mounting surface for securing the optical port, one or more optical elements, and a first alignment feature disposed in the pocket, wherein the alignment feature includes a piston that is translatable during mating. The one or more optical elements may be an integral portion of the mounting body or a discrete lens. In other embodiments, the mounting body may include a plurality of pockets and one of the pockets may include a magnet for securing a plug to the optical port. The optical port may optionally have a minimalist optical port footprint so that the complimentary mating optical plug engages a portion of the frame during mating. | 06-19-2014 |
20140247454 | POWER TRANSMISSION AND SENSING DEVICE - A torque transmission assembly comprising: (i) an optical fiber coupled to an optical sensing component and capable of rotating and translating the optical sensing component and of transmitting light to and from the optical sensing component; and (b) an annular structure surrounding the optical fiber, the annular structure in conjunction with said optical fiber transmits torque from a rotating component to the optical sensing component, wherein the annular structure does not include a steel wire torque spring. | 09-04-2014 |
20140247455 | OPTICAL COHERENCE TOMOGRAPHY ASSEMBLY - An OCT assembly comprising: (a) a light transmissive rod having a first end, a second end, and a central axis; and a refractive surface adjacent to the second end; (b) a housing surrounding the OCT probe component; the housing having a tubular body with the window situated over the refractive surface, said tubular body having a surface wherein said surface of said tubular body has a coefficient of friction being less than 0.3; (c) an optical fiber connected to the OCT probe component; (d) an annular structure surrounding said optical fiber and capable of translating and rotating the OCT probe component. | 09-04-2014 |
20140376865 | FIBER OPTIC CONNECTORS HAVING A TRANSLATING TRAY ALONG WITH CABLE ASSEMBLIES USING THE CONNECTORS - Embodiments disclosed herein include fiber optic connectors that include a tray that translates from a retracted position to an extended position along with cable assemblies using the connector and methods for making the same. In one embodiment, the connector includes a housing, a fiber optic body having an optical interface with at least one optical channel, at least one optical fiber in optical communication with the at least one optical channel of the optical interface, a tray that is movable between a first position that retracts the tray into the housing and a second position where the tray extends from the housing, wherein the fiber optic body is essentially stationary with respect to the tray, and an actuator for moving the tray between the first position and the second position. | 12-25-2014 |
20150025369 | HOUSING FOR THE OCT PROBE, OCT PROBE ASSEMBLY, AND A METHOD OF MAKING SUCH ASSEMBLY - According to some embodiments a housing for the OCT comprises: (a) a tubular body with an inner diameter of less than 5 mm (for example less than 2 mm, and in some embodiments not greater than 1.5 mm), a first end, a second end; and a window formed in the tubular body closer to the second end than to the first end, displaced from the second end, and framed by a portion of the tubular body, wherein the window has a width w. According to some embodiments, 0.05 mm01-22-2015 | |
20150063765 | DEVICE-TO-DEVICE OPTICAL CONNECTORS - A device-to-device optical connector assembly is configured to provide an optical signal as an expanded beam to an expanded beam plug cable. The connector assembly includes an active receptacle having a lead-in portion that receives a light beam from an opto-electronic device, a lead-out portion and a turn portion that turns the light beam and delivers a collimated light beam to the lead-out portion. A waveguide rod is optically coupled to the lead-out portion of the active receptacle that receives the collimated light beam and carries the collimated light beam from the active receptacle to the expanded beam plug cable. In one embodiment, the waveguide rod has a step index core waveguide profile with its fundamental mode generally matching the coupling optics of a complementary cable assembly or the like within a predetermined value. | 03-05-2015 |