Abstract: Optoelectronic modules and methods of manufacturing the same are disclosed. Some of the disclosed modules employ a tape automated bonding substrate (TAB) which is surface mounted with circuit elements. In some examples, the TAB is mounted to a rigid substrate after a fiber submount is passively positioned on the substrate. This modular manufacturing technique limits the value of yield loss. In some example modules, only one active alignment is employed to manufacture the module. Some of the disclosed modules include an optically pluggable connector.

Abstract: Described herein is a hermetic fiber optic package that may have a wide bandwidth radio frequency (e.g., between 9 kHz and 300 GHz) interface and a multilayer substrate provides a platform to integrated various components such as, for example, integrated circuits having electronic components, optoelectronic components, or optics. In one embodiment, the substrate has a wide bandwidth surface mountable interface that may be a single ended or a differential that allows for an electrical signal to pass from the exterior of the package to the interior. The interior of the package contains a “riser” that is used to bring an electrical signal from the plane of the substrate to the plane close to the optical axis. This riser includes a transmission line to achieve the change in height. The transmission line can be single ended or differential. Also within the package is a “submount” upon which electrical/optical/electro-optic components can be integrated.

Abstract: A method and apparatus for a backsided and recessed optical package connection is described. The method includes the formation of a substrate having a top surface layer and an opposed layer, including one or more recessed portions. Following formation of the substrate, leads of a lead unit are coupled to one or more of the recessed portions of the substrate. Next, one or more optical electronic components are mounted onto the top surface of the substrate. Once the optoelectric components are mounted to the lop surface of the substrate, a cap is attached to the top surface of the substrate to encapsulate the one or more optical electronic components and form an optoelectronic package.

Abstract: A low profile ringframe used in electro-optical module packaging, for being hermetically sealed, e.g., by a solder joint, to a metalized ceramic substrate base, and to which a deep cover is later hermetically sealed, e.g., by a laser weld, the ringframe's side walls being of sufficiently low height to permit computer-aided viewing from the side, as well as top, of the critical optical fiber end-to-laser diode alignment. The ringframe can be mounted so as to be set back from, be flush with, or be extending exteriorly over the outer end wall of the ceramic substrate, and may also be formed so as to help physically separate the ringframe-to-substrate solder joint from the ringframe-to-laser weld seam. The ringframe, along the side where it is sealed to the adjacent substrate, can be notched with one or more cutout areas to allow a space for wicking of reflowed solder to prevent a built-up solder fillet from forming exteriorly of the ringframe.

Abstract: A package is described. In one embodiment, the package includes multiple optical elements and multiple flexures, with at least one optical element attached to each flexure. The optical elements may be in alignment with each other. In an alternative embodiment, multiple optical elements are attached to a single flexure.

Abstract: A package is described. In one embodiment, the package includes multiple optical elements and multiple flexures, with at least one optical element attached to each flexure. The optical elements may be in alignment with each other. In an alternative embodiment, multiple optical elements are attached to a single flexure.

Abstract: A method for aligning optical components includes positioning a flexure having an attached first optical component with respect to a substrate having a second optical component attached thereto. The flexure has at least two legs, and each leg has a foot portion. The method further includes coupling at least one leg of the two legs to the substrate at a point of contact between the foot portion of the at least one leg and the substrate. The method further includes adjusting the alignment of the optical components by spot welding a location on the leg. Spot welding on the substrate may also be used to adjust the alignment of the optical components.

Abstract: A flexure and package including the same are provided. In one embodiment, the flexure is coupled to a second optical element and a substrate to maintain the second optical element in alignment with a first optical element. The flexure comprises a body, a pair of front and back legs. The attachment of the rear legs to the substrate causes the flexure to move from a first flexure position to a second flexure position, the distance between the first flexure position and the second flexure position equaling an offset distance. A specified length of the body is chosen such that the offset distance causes a second offset distance of the second optical component held by the flexure, and this second offset distance is within a specified range. The second offset distance is equal to the difference between a primary second optical component position and a secondary second optical component position.

Abstract: A package for optical components and a method for making the package are disclosed. The package comprises a quasi-planar substrate having a positioning floor, a platform and an optional ring frame of precisely determined height. Optical components picked and placed on a substrate floor, a raised platform and frame. A flexure assembly allows fine positioning of components requiring critical optical alignment.

Abstract: A method for aligning optical components includes positioning a flexure having an attached first optical component with respect to a substrate having a second optical component attached thereto. The flexure has at least two legs, and each leg has a foot portion. The method further includes coupling at least one leg of the two legs to the substrate at a point of contact between the foot portion of the at least one leg and the substrate. The method further includes adjusting the alignment of the optical components by spot welding a location on the leg. Spot welding on the substrate may also be used to adjust the alignment of the optical components.

Abstract: A package for optical components and a method for making the package are disclosed. The package comprises a quasi-planar substrate having a positioning floor, a platform and an optional ring frame of precisely determined height. Optical components picked and placed on a substrate floor, a raised platform and frame. A flexure assembly allows fine positioning of components requiring critical optical alignment.

Abstract: An optoelectronic assembly having an insulating substrate with a planar surface and a metal layer bonded to the planar surface such that selected regions of the substrate are exposed and a step is produced between the substrate and a top surface of the metal layer. An active optical device is mounted on the metal layer and a passive optical device is aligned with the active device using the step as a fiduciary for positioning the former. The metal layer provides an electrical path to the active device. The thickness of the metal layer is selected such that the heat generated by the active device is dissipated, the substrate does not interfere with the propagation of light along the first optical axis, and such that the in-plane coefficient of thermal expansion (CTE) of the metal layer is constrained by the substrate. The optoelectronic assembly is also suitable for mounting active devices provided with submounts or without.

Abstract: An optoelectronic assembly having an insulating substrate with a planar surface and a metal layer bonded to the planar surface such that selected regions of the substrate are exposed and a step is produced between the substrate and a top surface of the metal layer. An active optical device is mounted on the metal layer and a passive optical device is aligned with the active device using the step as a fiduciary for positioning the former. The metal layer provides an electrical path to the active device. The thickness of the metal layer is selected such that the heat generated by the active device is dissipated, the substrate does not interfere with the propagation of light along the first optical axis, and such that the in-plane coefficient of thermal expansion (CTE) of the metal layer is constrained by the substrate. The optoelectronic assembly is also suitable for mounting active devices provided with submounts or without.

Abstract: A flexure and package including the same are provided. In one embodiment, the flexure is coupled to a second optical element and a substrate to maintain the second optical element in alignment with a first optical element. The flexure comprises a body, a pair of front and back legs. The attachment of the rear legs to the substrate causes the flexure to move from a first flexure position to a second flexure position, the distance between the first flexure position and the second flexure position equaling an offset distance. A specified length of the body is chosen such that the offset distance causes a second offset distance of the second optical component held by the flexure, and this second offset distance is within a specified range. The second offset distance is equal to the difference between a primary second optical component position and a secondary second optical component position.

Abstract: A package for optical components and a method for making the package are disclosed. The package comprises a quasi-planar substrate having a positioning floor, a platform and an optional ring frame of precisely determined height. Optical components picked and placed on a substrate floor, a raised platform and frame. A flexure assembly allows fine positioning of components requiring critical optical alignment.

Abstract: A package for housing optical components where the enclosure has two enclosures. The first enclosure for the optical components (the optical enclosure) provides necessary alignment and hermeticity as well as a heat pipe to dissipate heat generated by the optical component. The second enclosure for the electronic components (the electronic enclosure) provides proper hermeticity and heat dissipation devices (e.g., a Peltier cooling device). The first enclosure can sit atop the second enclosure or vice versa. In an embodiment, a heat sink can be attached to the top of the dual-enclosure assembly.

Abstract: A package for optical components and a method for making the package are disclosed. The package comprises a quasi-planar substrate having a positioning floor, a platform and an optional ring frame of precisely determined height. Optical components are picked and placed on a substrate floor, a raised platform and frame. A flexure assembly allows fine positioning of components requiring critical optical alignment.

Abstract: A package for optical components and a method for making the package are disclosed. The package comprises a quasi-planar substrate having a positioning floor, a platform and an optional ring frame of precisely determined height. Optical components picked and placed on a substrate floor, a raised platform and frame. A flexure assembly allows fine positioning of components requiring critical optical alignment.

Abstract: A method for fabricating a high power laser diode device with an output emission with a nearly circular mode profile for efficient coupling into an optical fiber. A vertical taper waveguide and a window tolerance region are formed in a base structure of the device employing successive etching steps. Further regrowth completes the device structure. The resultant laser device has a vertical and lateral tapered waveguide that adiabatically transforms the highly elliptical mode profile in an active gain section of the device into a substantially circular mode profile in a passive waveguide section of the device.

Abstract: A device and method for fabricating a high power laser diode device with an output emission with a nearly circular mode profile for efficient coupling into an optical fiber. A vertical taper waveguide and a window tolerance region are formed in a base structure of the device employing successive etching steps. Further regowth completes the device structure. The resultant laser device has a vertical and lateral tapered waveguide that adiabatically transforms the highly elliptical mode profile in an active gain section of the device into a substantially circular mode profile in a passive waveguide section of the device.