There is provided a production method for an optical semiconductor device including a substrate having a silver plating layer formed on a surface and a light emitting diode bonded to the silver plating layer. The production method includes a film formation step of forming a clay film covering the silver plating layer and a connection step of electrically connecting the light emitting diode and the silver plating layer covered with the clay film by wire bonding, after the film formation step.

An LED die (26) conformally coated with phosphor (28) is mounted at the base (24) of a shallow, square reflector cup (16). The cup has flat reflective walls (20) that slope upward from its base to its rim at a shallow angle of approximately 33 degrees. A clear encapsulant (30) completely fills the cup to form a smooth flat top surface. Any emissions from the LED die or phosphor at a low angle (48, 50) are totally internally reflected at the flat air-encapsulant interface toward the cup walls. This combined LED/phosphor light is then reflected upward by the walls (20) and out of the package. Since a large percentage of the light emitted by the LED and phosphor is mixed by the TIR and the walls prior to exiting the package, the color and brightness of the reflected light is fairly uniform across the beam. The encapsulant is intentionally designed to enhance TIR to help mix the light.

A lighting device includes a body section; a substrate provided in the body section; a wiring pattern provided on a surface of the substrate and including wiring pads; and light emitting elements provided on the wiring pattern and including electrodes in the vicinity of a circumferential edge of a surface opposite to a side on which the wiring pattern is provided. The lighting device also includes wirings that respectively connect the wiring pads and a plurality of electrodes; a surrounding wall member provided to surround the light emitting elements and having an annular shape; and a sealing section provided to cover the inside of the surrounding wall member. At least a part of the light emitting elements is connected in series. The electrodes are respectively positioned on or inside a circumference passing through centers of the light emitting elements which are connected in series.

A method of manufacturing a light-emitting device includes providing a resin sheet that includes a lattice-patterned reflective material-containing portion and film-shaped phosphor-containing portions covering lattice openings of the reflective material-containing portion, placing the resin sheet on a substrate mounting a plurality of light-emitting elements such that each of the plurality of light-emitting elements is surrounded by the reflective material-containing portion and is covered on the top with the phosphor-containing portion, after placing the resin sheet on the substrate, softening the resin sheet by heating such that the phosphor-containing portions are adhered to the respective upper surfaces of the plurality of light-emitting elements and the reflective material-containing portion or the phosphor-containing portions is/are adhered to the side surfaces of the plurality of light-emitting elements, and curing the resin sheet and then cutting the substrate and the resin sheet to singulate individual light-emitting devices.

A solution for packaging a two terminal device, such as a light emitting diode, is provided. In one embodiment, a method of packaging a two terminal device includes: patterning a metal sheet to include a plurality of openings; bonding at least one two terminal device to the metal sheet, wherein a first opening corresponds to a distance between a first contact and a second contact of the at least one two terminal device; and cutting the metal sheet around each of the least one two terminal device, wherein the metal sheet forms a first electrode to the first contact and a second electrode to the second contact.

A method of fabricating a substrate free light emitting diode (LED), includes arranging LED dies on a tape to form an LED wafer assembly, molding an encapsulation structure over at least one of the LED dies on a first side of the LED wafer assembly, removing the tape, forming a dielectric layer on a second side of the LED wafer assembly, forming an oversized contact region on the dielectric layer to form a virtual LED wafer assembly, and singulating the virtual LED wafer assembly into predetermined regions including at least one LED. The tape can be a carrier tape or a saw tape. Several LED dies can also be electrically coupled before the virtual LED wafer assembly is singulated into predetermined regions including at the electrically coupled LED dies.

In one embodiment, an apparatus for optical communication is disclosed. An optical sub-assembly and optical platform may form the apparatus. Lasers contained in the hermetically sealed optical sub-assembly can be coupled to a modulator on the optical platform. The optical modulator can access an optical network using beams of light sent from the laser.

A method of manufacturing a light-emitting device includes forming a separation layer on an upper surface of a supporting substrate; forming a plurality of external electrode layers on the separation layer; mounting a plurality of light-emitting elements on the external electrode layers; forming a plurality of resin layers between the supporting substrate and each of the light-emitting elements after mounting the light-emitting elements, the resin layers being formed such that the resin layers are separated from one another, and each resin layer underlies at least one light-emitting element; and applying laser light to the separation layer from a lower surface side of the supporting substrate, and separating the supporting substrate and the light-emitting elements from each other.

Disclosed are a light emitting device and a lighting system having the same. The light emitting device includes a body including first and second lateral side parts, third and fourth lateral side parts, and a cavity, a first lead frame extending in a direction of the first lateral side part of the body, a second lead frame extending in a direction of the second lateral side part of the body, a light emitting chip disposed on the first lead frame in the cavity, and a gap part between the first and second lead frames. The first lead frame includes a first recess part having a first depth, and a second recess part recessed at a second depth, and the first recess part and the second recess part have a step structure with a curved surface.

An exemplary lead frame includes a substrate and a bonding electrode, a first connecting electrode, and a second connecting electrode embedded in the substrate. A top surface of the bonding electrode includes a first bonding surface and a second bonding surface spaced from the first bonding surface. A top surface of the first connecting electrode includes a first connecting surface and a second connecting surface spaced from the first connecting surface. Top surfaces of the bonding electrode, the first connecting electrode and the second connecting electrode are exposed out of the substrate to support and electrically connect with light emitting chips. Light emitting chips can be mounted on the lead frame and electrically connect with each other in parallel or in series; thus, the light emitting chips can be connected with each in a versatile way.