Abstract: Provided are coaxial waveguide microstructures. The microstructures include a substrate and a coaxial waveguide disposed above the substrate. The coaxial waveguide includes: a center conductor; an outer conductor including one or more walls, spaced apart from and disposed around the center conductor; one or more dielectric support members for supporting the center conductor in contact with the center conductor and enclosed within the outer conductor; and a core volume between the center conductor and the outer conductor, wherein the core volume is under vacuum or in a gas state. Also provided are methods of forming coaxial waveguide microstructures by a sequential build process and hermetic packages which include a coaxial waveguide microstructure.

Abstract: An optical device is disclosed which includes a waveguide that support a first optical mode in a first region and a second optical mode in a second region. The waveguide further includes single material guiding layer having a lower portion with a first taper and an upper portion with a second taper.

Abstract: A first waveguide holding member has a first transverse surface region and a first optical waveguide having an end terminating at the first transverse surface region. A second waveguide holding member has a second transverse surface region which confronts the first transverse surface region of the first waveguide holding member and a second optical waveguide having an end terminating at the second transverse surface region. A guide member is operatively coupled to the first and second waveguide holding members and guides the first waveguide holding member in a transverse direction relative to the second waveguide holding member so as to selectively optically couple and decouple the ends of the first and second optical waveguides.

Abstract: A micromachined structure, comprising: a substarte; a first wet etched pit disposed in the substrate; a second wet etched pit disposed in the substrate, the second pit extending into the substrate a greater depth than the first pit; and a dry pit disposed between, and adjacent to, the first and second pits. Also disclosed is a micromachined substrate comprising: a wet etched pit; and a dry-etched hole disposed in the wet etched pit, wherein the dry hole extends through the substrate.

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 the substrate such that the tap 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: A device including a first solder pad and a second solder pad comprised of a post-soldering alloy composition on a substrate is provided. The alloy composition comprises two or more elements, and the post soldering alloy composition of the first solder pad has different amounts of the two or more elements than the alloy composition of the second solder pad. A method of making a solder pad comprises masking a substrate comprising at least a first solder pad and a second solder pad, wherein the mask exposes a greater area of the first solder pad so that the deposited element becomes part of an alloy composition of the first solder pad upon soldering thereby changing the melting point of the first solder pad.

Abstract: An optoelectronic submount for providing optical connection and electrical connection to a vertically communicating optical device, such as a vertical cavity surface-emitting laser. The submount has a trench for holding the optoelectronic device on-edge, and electrical connection pits adjoining the trench. A metallization layer is disposed in the electrical connection pits. The electrical connection pits are aligned with the trench and optoelectronic device so that compact pads on the optoelectronic device can be soldered to the metallization layer. A groove can be provided in the submount for holding an optical fiber in alignment with an active area of the optoelectronic device.

Abstract: An optical fiber having an a core with a D-shape or an oval shape at an endface. The optical fiber tapers from a round, cylindrical section to the endface so that adiabatic mode transformation is provided. Preferably, the D-shape or oval shape is selected so that the optical fiber has a mode shape at its endface that matches the mode shape of a diffused waveguide.

Abstract: The present invention provides an optical microbench having intersecting structures etched into a substrate. In particular, microbenches in accordance with the present invention include structures having a planar surfaces formed along selected crystallographic planes of a single crystal substrate. Two of the structures provided are an etch-stop pit and an anisotropically etched feature disposed adjacent the etch-stop pit. At the point of intersection between the etch-stop pit and the anisotropically etched feature the orientation of the crystallographic planes is maintained. The present invention also provides a method for micromachining a substrate to form an optical microbench. The method comprises the steps of forming an etch-stop pit and forming an anisotropically etched feature adjacent the etch-stop pit. The method may also comprise coating the surfaces of the etch-stop pit with an etch-stop layer.

Abstract: An optical subassembly which positions an optical device is described. The optical device is mounted on a plurality of spheres or columns placed in predetermined positions in an upper surface of a substrate. The predetermined positions include pits formed in the upper surface of the substrate. The spheres may be the same size or may be of varying sizes. Pits or grooves also may be formed in the optical device. The optical device may be formed with flexure positions to assist in holding it in place on the spheres. Further, the optical device, spheres and substrate may be metallized or formed of metal and the surface tension forces of solder may be utilized to position the optical device.

Abstract: An optical device package includes a substrate; an optical fiber, a frame, and optionally a lid and an optical semiconductor component. The upper surface of the frame includes conductive visa extending vertically to solder balls on its upper surface. Conductive traces along the surface of the substrate provide electrical communication between the optical semiconductor component and the frame. The optical device package is adapted for flip-chip type mounting to a circuit board or other mounting surface.

Abstract: A novel micromachining method in which dry etching and anisotropic wet etching are combined.

Abstract: An optical fiber array having a V-groove chip with a front portion and a rear portion. The optical fibers are disposed in the V-grooves. The optical fibers are bnonded (e.g. glued) to the V-groove chip in the rear portion of the chip. The optical fibers are not bonded to the front portion of the chip. Preferably, the optical fibers have endfaces that are flush with a front face of the chip. The optical fibers extend from the rear portion. In use, the optical fiber array is pressed against V-grooves of an integrated optics chip or optoelectronic submount. Since the optical fibers are not bonded to the front portion, they can move slightly to fit precisely into V-grooves of the IO chip or submount. Hence, optical fiber alignment is improved. Also, there is no danger of residual adhesive preventing close contact between the optical fibers and IO chip.

Abstract: A waveguide array is provided for use in optical systems requiring a two-dimensional array of waveguides. The two-dimensional array comprises a first one-dimensional array which includes a plurality of optical waveguides and at least one registration feature. The two-dimensional array also comprises a second one-dimensional array having a plurality of optical waveguides and comprising at least one detent disposed in communication with the registration feature. The detent and registration feature are provided in respective locations of the first and second one-dimensional arrays so that the conjoined first and second one-dimensional arrays provide a two-dimensional array of waveguides. In a particular configuration of the two-dimensional array, the waveguides comprise optical fibers.

Abstract: Optoelectronic packages comprise both an optical array and base chip. The array and base chip are aligned and coupled using a combination of V-grooves, wick stops, and alignment spheres (e.g., presion ball bearings). The array and base chip are passively aligned by disposeing an optical fiber having an angled endface onto V-grooves in both the array and base chip. The base chip typically comprises an optical surface device, such as a vertical cavity, surface emitting laser or photodetector.

Abstract: An optical interconnect includes a waveguide holder having a first side and a second side. The first side has a first depression and the second side has a second depression. The waveguide holder has an opening in which a plurality of waveguides are disposed.

Abstract: Provided are photodefinable compositions suitable for use in forming an optical waveguide. The compositions include a silsesquioxane polymer having polymerized units of the formula (R1SiO1.5) and (R2SiO1.5), wherein R1 and R2 are different and are substituted or unsubstituted organic side chain groups and are free of hydroxy groups, and two or more functional end groups, and a photoactive component. The solubility of the silsesquioxane polymer is altered upon exposure to actinic radiation such that the composition is developable in an aqueous developer solution. Also provided are methods of forming an optical waveguide with the inventive compositions, optical waveguides, and electronic devices including one or more optical waveguide.

Abstract: An optical assembly which allows for passive alignment of the various elements is described. A substrate with a cut out portion and an upper surface is utilized as a mount for an optical array and an imaging assembly. The optical array, which preferably includes a plurality of optical fibers is positioned on V-grooves located on the upper surface. The imaging assembly, which preferably includes a plurality of lenses, such as GRIN lenses, is lowered at least partially into the cut-out portion. The optical fibers are optically coupled with said lenses. A waveguide, having a plurality of waveguide cores within a cladding, may further be optically coupled with the lenses, or alternatively, directly to the optical fibers. An integrated optic chip may also be affixed to the substrate or mounted on the substrate.

Abstract: An optical fiber switch having two coupled fiber arrays which move in a transverse direction to provide switching action. Each array has a front face and the front faces are nearly in contact. Optical fiber ends are located at the front faces. The front faces of the fiber arrays have transverse grooves in which rolling spheres are disposed. The fiber arrays move by rolling on the spheres. The spheres provide for smooth transverse motion and a fixed distance between optical fiber arrays. The spheres and front face grooves also provide for alignment between the optical fibers.

Abstract: An optical device package includes a substrate, optical semiconductor component, optical fiber, frame and lid. The substrate has a longitudinal notch for mounting the optical fiber and a lateral groove with a proximally facing stop surface. The frame includes at least one downwardly extending projection configured and dimensioned so as to engage a lateral end portion of the lateral groove. The frame is self-aligning and seats itself by being dropped into place.