A light-emitting device includes first and second light-emitting elements, first and second support members bonded to the first and second light-emitting elements, respectively, first and second protective elements, and a plurality of wirings including: a first wiring with one end being bonded to the first light-emitting element or the first support member; a second wiring with one end being bonded to the first light-emitting element or the first support member and the other end being bonded to the second light-emitting element or the second support member; a third wiring with one end being bonded to the first protective element or a support member equipped with the first protective element; and a fourth wiring with one end being bonded to the second protective element or a support member equipped with the second protective element.

A light emitting device includes: a resin package including: a resin part, and a plurality of leads including a first lead and a second lead, wherein the resin package has a concave portion having a bottom face at which a part of an upper surface of the first lead and a part of an upper surface of the second lead are exposed from the resin part; a light emitting element mounted on the bottom face of the concave portion; and a sealing member covering the light emitting element in the concave portion. The plurality of leads comprise a plurality of notch parts including a first notch part on a first side corresponding to a first outer side surface of the resin package and a second notch part on a second side corresponding to a second outer side surface of the resin package.

A light emitting device includes: a resin package including: a resin part, and a plurality of leads including a first lead and a second lead, wherein the resin package has a concave portion having a bottom face at which a part of an upper surface of the first lead and a part of an upper surface of the second lead are exposed from the resin part; a light emitting element mounted on the bottom face of the concave portion; and a sealing member covering the light emitting element in the concave portion. The plurality of leads comprise a plurality of notch parts including a first notch part on a first side corresponding to a first outer side surface of the resin package and a second notch part on a second side corresponding to a second outer side surface of the resin package.

An electronic power conversion component includes an electrically conductive package base comprising a source terminal, a drain terminal, at least one I/O terminal and a die-attach pad wherein the source terminal is electrically isolated from the die-attach pad. A GaN-based semiconductor die is secured to the die attach pad and includes a power transistor having a source and a drain, wherein the source is electrically coupled to the source terminal and the drain is electrically coupled to the drain terminal. A plurality of wirebonds electrically couple the source to the source terminal and the drain to the drain terminal. An encapsulant is formed over the GaN-based semiconductor die, the plurality of wirebonds and at least a top surface of the package base.

An optical component package includes a main substrate including a plurality of metal bodies, and a vertical insulation part provided between the metal bodies; a cavity provided in an upper surface of the main substrate; a sub-substrate provided in the cavity of the main substrate, the sub-substrate including an insulating body, a plurality of via holes vertically passing through the insulating body and filled with a metal material being electrically connected to each of the metal bodies, and a plurality of metal pads mounted on the insulating body and electrically connected to the plurality of via holes; a plurality of optical components mounted on the plurality of metal pads and electrically connected to the plurality of metal pads; and a light transmitting member provided above the main substrate.

A method of manufacturing a light emitting device having a resin package which provides an optical reflectivity equal to or more than 70% at a wavelength between 350 nm and 800 nm after thermal curing, and in which a resin part and a lead are formed in a substantially same plane in an outer side surface, includes a step of sandwiching a lead frame provided with a notch part, by means or an upper mold and a lower mold, a step of transfer-molding a thermosetting resin containing a light reflecting material in a mold sandwiched by the upper mold and the lower mold to form a resin-molded body in the lead frame and a step of cutting the resin-molded body and the lead frame along the notch part.

A method of manufacturing a light emitting device having a resin package which provides an optical reflectivity equal to or more than 70% at a wavelength between 350 nm and 800 nm after thermal curing, and in which a resin part and a lead are formed in a substantially same plane in an outer side surface, includes a step of sandwiching a lead frame provided with a notch part, by means or an upper mold and a lower mold, a step of transfer-molding a thermosetting resin containing a light reflecting material in a mold sandwiched by the upper mold and the lower mold to form a resin-molded body in the lead frame and a step of cutting the resin-molded body and the lead frame along the notch part.

Disclosed is an optical component package. The optical component package according to the present invention includes: a main substrate including a plurality of metal bodies, and a vertical insulation part provided between the metal bodies; a sub-substrate provided in a cavity of the main substrate, and electrically connected to each of the metal bodies with the vertical insulation part interposed therebetween; an optical component mounted on the sub-substrate; and a light transmitting member provided above the optical component, wherein the sub-substrate includes: an insulating body; a via hole vertically passing through the insulating body, and filled with a metal material; and a metal pad connected to the optical component.

A light-emitting device package includes a lead frame, a light-emitting device chip, a molding structure, and a plurality of slots. The lead frame includes a first lead and a second lead including metal and spaced apart from each other. The light-emitting device chip is mounted on a first area of the lead frame, which includes a part of the first lead and a part of the second lead. The molding structure includes an outer barrier surrounding an outside of the lead frame and an inner barrier. The plurality of slots are formed in each of the first lead and the second lead. The inner barrier divides the lead from into the first area and a second area. The inner barrier fills between the first lead in the second lead. The second area is located outside of the first area. The plurality of slots are filled by the molding structure.

The present invention provides a surface mounted light emitting apparatus which has long service life and favorable property for mass production, and a molding used in the surface mounted light emitting apparatus. The surface mounted light emitting apparatus comprises the light emitting device 10 based on GaN which emits blue light, the first resin molding 40 which integrally molds the first lead 20 whereon the light emitting device 10 is mounted and the second lead 30 which is electrically connected to the light emitting device 10, and the second resin molding 50 which contains YAG fluorescent material and covers the light emitting device 10. The first resin molding 40 has the recess 40c comprising the bottom surface 40a and the side surface 40b formed therein, and the second resin molding 50 is placed in the recess 40c. The first resin molding 40 is formed from a thermosetting resin such as epoxy resin by the transfer molding process, and the second resin molding 50 is formed from a thermosetting resin such as silicone resin.