Abstract: Disclosed are interposer including an interposer coupling assemblies for communicating optical signals to an integrated circuit and other interposer structures having an optical interface for optical connections. In one embodiment, the interposer coupling assembly includes a connector attachment saddle having an optical alignment structure, an optical pathway that includes a GRIN lens, and an optical signal turning element adjacent to the GRIN lens. The interposer coupling assembly may be optically attached to an integrated circuit or a base that is attached to an integrated circuit to form an interposer structure that allows high-speed data transfer. Also disclosed are complimentary optical assemblies that may be optically connected to the interposer coupling assembly.

Abstract: An optical coupling device includes a multi-core fiber alignment station, a single-mode fiber alignment station, and a furcation lens assembly. The multi-core fiber alignment station and single-mode fiber alignment station include alignment hardware configured to position optical fibers at fixed positions relative to an optical axis of the furcation lens assembly. The furcation lens assembly includes a furcating and projecting axicon surfaces that are rotationally invariant and are configured such that optical modes of an optical fiber aligned in one of the fiber alignment stations are spatially separated and substantially telecentrically mapped to corresponding optical modes of optical fibers aligned in the other fiber alignment station.

Abstract: An organic light emitting diode (OLED) device having enhanced light extraction is disclosed. The OLED device includes an upper waveguide structure having an organic layer and supports first guided modes, and a lower waveguide structure with a light-extraction waveguide that supports second guided modes substantially matched to the first guided modes. The lower waveguide structure includes a light-extraction waveguide interfaced with a light-extraction matrix. The light-extraction waveguide includes one or more light-redirecting features. The upper and lower waveguide structures are configured to facilitate mode coupling from the first guided modes to the second guide modes while substantially avoiding coupling the first guided modes to surface plasmon polaritons. The light traveling in the second guided modes is redirected to exit the OLED device by light-redirecting features of the light-extraction waveguide.

Abstract: An optical fiber connector for coupling light to or from an input fiber is disclosed. The connector includes a first alignment member that holds an achromatic GRIN lens. The achromatic GRIN lens has a half-pitch axial length L, wherein 0.5 mm?L?5 mm. The optical fiber connector has a field fiber that interfaces with the achromatic GRIN lens. The connector is operable between operating wavelengths of 800 nm and 1600 nm with a coupling loss of less than 0.2 dB.

Abstract: An optical fiber connector for coupling light to or from an input fiber is disclosed. The connector includes a first alignment member that holds an achromatic GRIN lens. The achromatic GRIN lens has a half-pitch axial length L, wherein 0.5 mm?L?5 mm. The optical fiber connector has a field fiber that interfaces with the achromatic GRIN lens. The connector is operable between operating wavelengths of 800 nm and 1600 nm with a coupling loss of less than 0.2 dB.

Abstract: An expanded beam optical connector including a connector body, an optical element in the form of a waveguide or active device, a beam width altering optical lens, and a transmit/receive window. The optical element, the beam width altering optical lens, and the transmit/receive window are configured such that optical signals propagate between the optical element and the transmit/receive window via the beam width altering optical lens. The transmit/receive window includes an optical medium that forms an interior surface of the transmit/receive window, an optical transition layer between the interior surface formed by the optical medium, and a protective layer forming an exterior surface of the transmit/receive window. The connector body is configured to place the exterior surface of the transmit/receive window in close contact with a mating exterior surface of a mating transmit/receive window of a complementary optical device to define a close contact portion.

Abstract: A multi-grating resonant waveguide (RWG) biosensor for an optical reader system having a spatial resolution limit is disclosed. The multi-grating RWG biosensor includes one or more signal-grating regions and one or more reference-grating regions. The multi-grating RWG biosensor can also include a non-resonance region that spatially separates the one or more signal-grating regions, that spatially separates the one or more reference-grating regions, and that spatially separates the one or more reference-grating regions from the one or more signal-grating regions. The non-resonance region can have a minimum width greater than the optical reader system spatial resolution limit. The RWG biosensor can have an asymmetric split-grating configuration. Methods of measuring a signal resonant wavelength of a multi-grating RWG biosensor using an optical reader having a spatial resolution limit are also disclosed.

Abstract: A method and optical reader system for label-independent detection as defined herein. The reader system includes: a launch beam; a first lens; a receptacle for receiving at least one optical biosensor article, the article having a mask on one face, and the mask having at least one aperture there through for receiving and transmitting radiation from the collimated launch beam; an angular separator; and an imager to record the image of the optical biosensor article.

Abstract: A multi-wavelength reference microplate for a label-independent optical reader is disclosed. The microplate includes a support plate that supports a plurality of reference wells. At least one of the reference wells is configured as a multi-wavelength reference well having disposed therein two or more resonant waveguide grating sections that respectively reflect two or more different reference resonant wavelengths within the light source wavelength band. Methods for making and using the microplates are also disclosed.

Abstract: An optical reader system and method for label-independent detection having enhanced two-dimensional spatial resolution of the reader, as defined herein. The system includes a translatable slit-mask and microplate combination for selectively irradiating a biosensor on a microplate, as defined further herein.

Abstract: A multi-grating resonant waveguide (RWG) biosensor for an optical reader system having a spatial resolution limit is disclosed. The multi-grating RWG biosensor includes one or more signal-grating regions and one or more reference-grating regions. The multi-grating RWG biosensor can also include a non-resonance region that spatially separates the one or more signal-grating regions, that spatially separates the one or more reference-grating regions, and that spatially separates the one or more reference-grating regions from the one or more signal-grating regions. The non-resonance region can have a minimum width greater than the optical reader system spatial resolution limit. The RWG biosensor can have an asymmetric split-grating configuration. Methods of measuring a signal resonant wavelength of a multi-grating RWG biosensor using an optical reader having a spatial resolution limit are also disclosed.

Abstract: A method and optical reader system for label-independent detection as defined herein. The reader system includes: a launch beam; a first lens; a receptacle for receiving at least one optical biosensor article, the article having a mask on one face, and the mask having at least one aperture there through for receiving and transmitting radiation from the collimated launch beam; an angular separator; and an imager to record the image of the optical biosensor article.

Abstract: A length of oxynitride optical fiber is exposed to actinic radiation that is modulated by an interference technique to form a pattern of refractive index variations that functions as a reflective grating.

Abstract: A length of oxynitride optical fiber is exposed to actinic radiation that is modulated by an interference technique to form a pattern of refractive index variations that functions as a reflective grating.

Abstract: A length of oxynitride optical fiber is exposed to actinic radiation that is modulated by an interference technique to form a pattern of refractive index variations that functions as a reflective grating.

Abstract: A length of oxynitride optical fiber is exposed to actinic radiation that is modulated by an interference technique to form a pattern of refractive index variations that functions as a reflective grating.

Abstract: A length of oxynitride optical fiber is exposed to actinic radiation that is modulated by an interference technique to form a pattern of refractive index variations that functions as a reflective grating.

Abstract: Athermalized optical waveguide devices and methods of making the athermalized devices are described. Boron is incorporated into the composition of the optical waveguides in order to athermalize the waveguides by reducing spectral shifts caused by changes in temperature. The invention includes the utilization of boron dopants in the core and cladding of optical waveguide devices such as Mach-Zehnder coupler devices and long period fiber gratings.

Abstract: An optical coupler 10 has two fibers 20, 30 that are adjacent each other in a coupling region 12. One of the fibers has a clad doped with a photosensitive glass, such as germania. The photosensitive glass is exposed to suitable radiation to alter the index of refraction of fiber and tune the coupler 10 to the selected coupling frequency.