Abstract: The present invention provides a micro-optical device which may be used as an optical pigtailing assembly for waveguides. In an exemplary configuration the assembly includes a first chip which includes an optoelectronic component and an optical fiber. The optical fiber and optoelectronic component are coupled with an optical component, such as one or more waveguides on an integrated optic chip.

Abstract: Provided are optoelectronic components which include an optoelectronic device and a structure for self-aligning the optoelectronic device. Also provided are optoelectronic modules and methods of forming optoelectronic components.

Abstract: An optical device package includes a substrate having an upper surface, a distal end, a proximal end, and distal and proximal longitudinally extending notches co-linearly aligned with each other. A structure is mounted to the substrate and has at least one recessed portion. The structure can be a lid or a frame to which a lid is bonded. An optical fiber is positioned within at least one of the proximal longitudinally extending notch and the distal longitudinally extending notch and within the recessed portion of the structure mounted to the substrate. The optical device package can also include conductive legs extending upwardly from bonding pads on the upper surface of the substrate to facilitate flip mounting of the optical device package onto a circuit board or other such platform.

Abstract: Photoresist compositions and methods suitable for depositing a very thick photoresist layer in a single coating process are provided. Such photoresist layers are particularly suitable for use in chip scale packaging.

Abstract: Provided are optoelectronic device packages. The packages include a base substrate having an optoelectronic device mounting region on a surface of the base substrate and a lid mounting region. An optoelectronic device is mounted on the optoelectronic device mounting region. A lid is mounted on the lid mounting region to form an enclosed volume between the base substrate and the lid. The optoelectronic device is in the enclosed volume. The lid has an optically transmissive region suitable for transmitting light of a given wavelength along an optical path to or from the optoelectronic device, wherein at least a portion of the lid mounting region is disposed along the optical path below the surface of the base substrate to a depth below the optical path. Also provided are wafer or grid level optoelectronic device packages, wafer- or grid-level optoelectronic device package lid and their methods of formation, and connectorized optoelectronic devices.

Abstract: The present invention concerns a design for an external cavity single mode laser wherein a short optical path length for the optical cavity (e.g., ˜3 to 25 mm) provides sufficient spacing of the longitudinal modes allowing a single wavelength selective element, such as a microfabricated etalon, to provide a single mode of operation, and optionally a selectable mode of operation.

Abstract: Disclosed are methods of manufacturing electronic devices, particularly integrated circuits. Such methods include the use of low dielectric constant material prepared by using a removable porogen material.

Abstract: An apparatus for passively aligning first and second substrates having micro-components disposed thereon when the substrates do not include patterned surfaces which face each other. The apparatus includes a first depression which cooperates with an alignment sphere to mechanically engage a corresponding depression disposed on the front surface of the first substrate and a second depression which cooperates with a second alignment sphere to mechanically engage a corresponding depression disposed on the front surface of the second substrate. The first and second depression of the alignment apparatus and the alignment spheres cooperate to passively align micro-components disposed on each of the substrates.

Abstract: Provided are optoelectronic components which include an optoelectronic device mounted on a silicon substrate and a flexible circuit electrically connected to the optoelectronic device.

Abstract: Optical interface assemblies are provided. The optical interface assemblies include a first portion having a plurality of optical waveguides. The first portion is configured for mating engagement with an optical fiber connector. A second portion is mated to the first portion. The second portion is configured for mating engagement with an electronic substrate that includes an embedded waveguide assembly. The first and second portions are further configured so as to align the plurality of optical waveguides, at a first end of the first portion, with a plurality of corresponding waveguide cores of the embedded waveguide assembly. The first and second portions are further configured so as to align the plurality of optical waveguides, at a second end of the first portion, with a plurality of corresponding optical fibers in the optical fiber connector. Also provided are electronic assemblies and methods for coupling optical fibers with electronic substrate embedded waveguides.

Abstract: Provided are optoelectronic components which include an optoelectronic device and a structure for self-aligning the optoelectronic device. Also provided are optoelectronic modules and methods of forming optoelectronic components.

Abstract: Provided are optoelectronic components which include an optoelectronic device and a substrate having a first surface, a second surface opposite the first surface and a trench in the first surface, the trench including a bottom surface. An optoelectronic device is in the trench mounted directly to the bottom surface. Structure for passively aligning the optoelectronic device in the trench is further included. Also provided are optoelectronic modules and methods of forming optoelectronic components.

Abstract: A method of fabricating optical filter is disclosed. The method includes providing the substrate and selectively etching the substrate to form a plurality of freestanding layers. A plurality of dielectric layers is disposed over an outer surface of each of the freestanding layers. The resultant optical filters may be used in a variety of applications including etalon applications.

Abstract: A method of forming air gaps within a solid structure is provided. In this method, a sacrificial material is covered by an overlayer. The sacrificial material is then removed through the overlayer to leave an air gap. Such air gaps are particularly useful as insulation between metal lines in an electronic device such as an electrical interconnect structure. Structures containing air gaps are also provided.

Abstract: A multi-level optical device includes a substrate having a baseline level. At least one feature is disposed at a level above the baseline level. At least one feature is disposed at a level below the baseline level, or in the feature above the baseline level is located at a distance apart from the feature below the baseline level. The distance has an accuracy inn the range of approximately ±0.05 ?m to less than approximately ±1.0 ?m. A method of fabricating an optical device includes forming at least one feature at a level of above a baseline level of a substrate; and forming at least one feature at a baseline level below the baseline level of the substrate, wherein the feature at a level above the baseline level and the feature at a level below the baseline level are patterned in a single-mask step using a multi-level mask.

Abstract: Provided is a dry-film suitable for use in forming an optical component. The dry-film includes a carrier substrate having a front surface and a back surface. A non-photoimageable, thermally curable polymeric layer is provided over the front surface of the carrier substrate. The polymeric layer includes a thermally active component and units of the formula (RSiO1.5), wherein R is a substituted or unsubstituted organic group. A protective cover layer is disposed over the front or back surface of the carrier substrate. Also provided are methods of forming optical devices with dry-films. The invention finds particular applicability in the optoelectronics industry.

Abstract: An optical device is disclosed which includes a single-mode waveguide (700) which supports a first optical mode in a first region and a second optical mode in a second region. The waveguide includes a guiding layer (703) having at least one wing (750) extended outwardly from the guiding layer (703). The guiding layer (703) may desirably have a rib waveguide (706, 707) cross sectional shape at the wings. The wings (750) decrease in width along the length of the guiding layer to convert a rib waveguide mode at the wings to a channel waveguide mode.

Abstract: Provided is a dry-film suitable for use in forming an optical component. The dry-film includes a carrier substrate having a front surface and a back surface. A negative-working photoimageable polymeric layer is disposed over the front surface of the carrier substrate, and includes a photoactive component and units of the formula (RSiO1.5), wherein R is a substituted or unsubstituted organic group. In each of the units, R is free of hydroxy groups. The units include units of the formula (R1SiO1.5) and (R2SiO1.5), wherein R1 is a substituted or unsubstituted aliphatic group and R2 is a substituted or unsubstituted aromatic group. A protective cover layer is disposed over the front surface or back surface of the carrier substrate. Also provided are methods of forming optical devices with dry-films. The invention finds particular applicability in the optoelectronics industry.

Abstract: An optical device package includes a substrate having a top portion with an a recess for receiving an optical semiconductor component and an elongated linear groove for receiving an optical fiber. The optical fiber is positioned within the groove in said substrate such that the top surface of the optical fiber is substantially at or below the upper surface of the substrate and the optical fiber is operatively aligned with the optical semiconductor component for the transfer of optical signals therebetween. A frame is hermetically sealed to the upper surface of the substrate.

Abstract: Provided are optoelectronic components which include a substrate having a front surface, a back surface and a trench in the front surface, an optoelectronic device in the trench, and an encapsulant filling the trench frush to the front surface, wherein the encapsulant provides an optical surface.