A semiconductor light emitting device includes a substrate, a first epitaxial structure and a second epitaxial structure, a connecting layer, a first electrode structure, a second electrode structure, and a third electrode structure. The first epitaxial structure and the second epitaxial structure are on the substrate side by side. The connecting layer is between the first epitaxial structure and the substrate, between the second epitaxial structure and the substrate, and between the first epitaxial structure and the second epitaxial structure. The first electrode structure is on the first epitaxial structure away from the substrate. The second electrode structure is on the second epitaxial structure away from the substrate. The third electrode structure is connected to the connecting layer.

Apparatuses, systems, and associated methods are described that provide an optical device with sealed optoelectronic component(s) without impacting effective optical performance of the optical device. An example optical device includes a substrate that defines a first surface and a second surface opposite the first surface. The optical device further includes an optoelectronic component supported by the first surface of the substrate where the optoelectronic component operates with optical signals. The optical device further includes a conformal coating applied to the first surface of the substrate such that at least a portion of the conformal coating is disposed on the optoelectronic component. The conformal coating substantially seals the optoelectronic component from an external environment of the optical device without impacting effective optical performance of the optical device. A thickness of the conformal coating may be determined based upon one or more operating parameters of the optoelectronic component.

A light-emitting module includes a substrate, a surface light-emitting element, and an optical waveguide. The surface light-emitting element includes light sources and is attached to the substrate. The optical waveguide is attached to the surface light-emitting element in a state in which the optical waveguide covers the light sources. The optical waveguide extends in an axial direction with a refractive index distribution in a radial direction. The optical waveguide condenses light beams emitted from the surface light-emitting element.

A light-emitting device includes: a plurality of semiconductor laser elements; a package having a hermetically sealed space, with the plurality of semiconductor laser elements arranged in the space; an optical member fixed to the package; and a plurality of adhesives including a first adhesive and a second adhesive fixing the optical member to the package. The plurality of adhesives are bonded to the optical member between an emission surface of the package and an incidence surface or a lower surface of the optical member. In the optical member, one or more first bonding regions to which the first adhesive is bonded and one or more second bonding regions to which the second adhesive is bonded are located at positions that are closer to the incidence surface of the optical member than to an emission surface of the optical member.

A light-emitting device includes: a plurality of semiconductor laser elements; a package having a hermetically sealed space, with the plurality of semiconductor laser elements arranged in the space; an optical member fixed to the package; and a plurality of adhesives including a first adhesive and a second adhesive fixing the optical member to the package. The plurality of adhesives are bonded to the optical member between an emission surface of the package and an incidence surface or a lower surface of the optical member. In the optical member, one or more first bonding regions to which the first adhesive is bonded and one or more second bonding regions to which the second adhesive is bonded are located at positions that are closer to the incidence surface of the optical member than to an emission surface of the optical member.

At least one embodiment of the invention provides a photonic subsystem for integrating onto a photonic platform. The subsystem comprises a laser source and a plurality of optical components for focusing and directing a laser beam emitted from the laser source into a photonic platform. The laser source and plurality of optical components are mounted to a substrate and encapsulated.

At least one embodiment of the invention provides a photonic subsystem for integrating onto a photonic platform. The subsystem comprises a laser source and a plurality of optical components for focusing and directing a laser beam emitted from the laser source into a photonic platform. The laser source and plurality of optical components are mounted to a substrate and encapsulated.

This semiconductor laser device comprises: a semiconductor laser element; a switching element connected in series to the semiconductor laser element, the switching element having a gate electrode, a drain electrode, and a source electrode; capacitors connected in parallel to the semiconductor laser element and the switching element; first drive electroconductive parts to which first terminals of the capacitors are connected; a second drive electroconductive part positioned apart from the first drive electroconductive parts; first drive connection members that connect the first drive electroconductive parts and the source electrode; and a second drive connection member that connects the second drive electroconductive part and the source electrode.

An object of the present technique is to reduce a wiring inductance between a semiconductor laser and a laser driver in a semiconductor laser driving apparatus.

A semiconductor laser driving apparatus includes a substrate, a laser driver, and a semiconductor laser. The substrate incorporates the laser driver. The semiconductor laser is mounted on one surface of the substrate of the semiconductor laser driving apparatus. Connection wiring electrically connects the laser driver and the semiconductor laser to each other with a wiring inductance of 0.5 nanohenries or less. A sealing portion seals a connection terminal portion of the semiconductor laser for the substrate.

An embodiment of a semiconductor package includes a leadframe having leads, a mold compound partly encasing the leadframe so that the leads protrude from the mold compound, a power transistor die attached to the leadframe at a first side of the leadframe, and a driver die attached to the leadframe at a second side of the leadframe opposite the first side so that the power transistor die and the driver die are disposed in a stacked arrangement. The driver die is configured to control the power transistor die. The driver die is in direct electrical communication with the power transistor die only through the leadframe and any interconnects which attach the power transistor die and the driver die to the leadframe. Corresponding methods of manufacturing the semiconductor package are also described.