A light emitting device including a first light emitting element and an optical member disposed over the first light emitting element. The optical member includes a light transmissive member and a ceramic component. The light transmissive member has a first upper surface, a second upper surface, and a lower surface opposing to the first upper surface and a second upper surface. The ceramic component is disposed on the second upper surface of the light transmissive member. The light transmissive member and the ceramic component each has a portion that overlaps with the first light emitting element when viewed in plan view.

A semiconductor device package includes a resin unit having a first through hole and a second through hole, a conductive body disposed on the resin unit and having a cavity that is concave in a first direction from a top surface of the conductive body toward a bottom surface thereof, and a light-emitting device disposed in the cavity, wherein the conductive body includes a first protrusion and a second protrusion, which protrude in the first direction from the bottom surface of the conductive body, and the first protrusion is disposed inside the first through hole, the second protrusion is disposed inside the second through hole, and a top surface of the resin unit is in contact with the bottom surface of the conductive body.

A light-emitting element package according to an embodiment comprises: a body comprising a cavity; the cavity; a first frame and a second frame arranged on the bottom surface of the cavity; a first metal layer disposed on the first frame; an ultraviolet light-emitting element disposed on the first metal layer; and a second metal layer disposed on the second frame and electrically connected to the second frame, wherein the body comprises a separation portion between the first frame and the second frame, the second metal layer extends over the sloping surface of the cavity and the separation portion of the body, and the second metal layer is spaced apart from the first metal layer in the cavity and surrounds the first metal layer.

A method of manufacturing a light source device includes: disposing bumps containing a first metal on a first substrate which is thermally conductive; disposing a bonding member on the bumps, the bonding member containing Au—Sn alloy; disposing a light emitting element on the bumps and the bonding member; and heating the first substrate equipped with the bumps, the bonding member, and the light emitting element.

A method of manufacturing a light emitting device includes: providing a light emitting element including a light extraction surface, an electrode-formed surface on a side opposite to the light extraction surface, lateral surfaces positioned between the light extraction surface and the electrode-formed surface, and a pair of electrodes on the electrode-formed surface; providing a covering member including a lens portion and a first recess on a side different from the lens portion; disposing the light emitting element on a bottom surface of the first recess, with the light extraction surface and the bottom surface of the first recess facing each other; and forming a reflective member in the first recess to cover the lateral surfaces of the light emitting element while at least a part of the pair of electrodes is exposed from the reflective member.

A semiconductor light-emitting element includes: a semiconductor stack including an n-type layer and a p-type layer and having at least one n exposure portion being a recess where the n-type layer is exposed; a p wiring electrode layer on the p-type layer; an insulating layer (i) continuously covering inner lateral surfaces of at least one n exposure portion and part of a top surface of the p wiring electrode layer and (ii) having an opening portion that exposes the n-type layer; an n wiring electrode layer disposed above the p-type layer and the p wiring electrode layer and in contact with the n-type layer in the opening portion; and at least one first n connecting member connected to the n wiring electrode layer in at least one first n terminal region. The n wiring electrode layer and the p-type layer are disposed below at least one first n terminal region.

A display device and a manufacturing method thereof are provided. The display device includes a circuit substrate, multiple light-emitting elements and a packaging material. The circuit substrate includes a first surface, a second surface opposite the first surface, and multiple through slots penetrating through the first and second surfaces. The through slots each are in a stepped form, and the circuit substrate is divided into a chip mounting area, multiple anodes, and a common cathode. The light-emitting elements include multiple light-emitting elements mounted on the circuit substrate along a straight line and electrically connected with the anodes respectively through wires. The packaging material covers the circuit substrate, the light-emitting elements and the wires. The display device has an excellent performance while achieving a small size.

Provided is a LED backlight module, display screen and detection method of a LED backlight module. The LED backlight module includes a substrate and multiple LED chips arranged on the substrate, one first detection group is arranged on the substrate for each LED chip of more than one LED chip arranged at an interval of N LED chips connected in series, where N is greater than or equal to 0, the first detection group includes a first positive electrode detection point and a first negative electrode detection point, the first positive electrode detection point and the first negative electrode detection point of the first detection group are respectively connected to a positive electrode and a negative electrode of the each LED chip.

Solid-state lighting devices including light-emitting diodes (LEDs) and LED packages are disclosed. LED packages are provided with improved thermal and/or electrical coupling between LED chips and submounts or lead frames. Various configurations of submounts with via arrangements are disclosed to provide improved coupling between LED chips and submounts. LED chip contacts are disclosed with one or more openings that are registered with vias to provide more uniform mounting. Multiple LED chips may be arranged around a thermally conductive element on a submount, and a via in the submount may be registered with the thermally conductive element. Subassemblies are provided between LED chips and lead frames to improve electrical and thermal coupling. Underfill materials may be arranged between LED chips and lead frames to provide improved mechanical support.

A new method, system and apparatus for mounting mechanically, thermally and electrically light emitting diode (LED), crystals, arrays or packages. The above provides an LED assembly having reduced number of components and costs, superior heat dissipation, mechanical properties and a compact structure. The use of a grid or mesh allows for more efficient and inexpensive removal of heat from one or more LEDs within an LED fixture.