An array of light emitting devices is mounted on a support surface with the transparent growth substrate (e.g., sapphire) facing up. A photoresist layer is then deposited over the top surface of the growth substrate, followed by depositing a reflective material over the top and side surfaces of the light emitting devices to encapsulate the light emitting devices. The top surfaces of the light emitting devices are then ground down to remove the reflective material over the top surface of the photoresist. The photoresist is then dissolved to leave a cavity over the growth substrate having reflective walls. The cavity is then filled with a phosphor. The phosphor-converted light emitting devices are then singulated to form packaged light emitting devices. All side light is reflected back into the light emitting device by the reflective material and eventually exits the light emitting device toward the phosphor. The packaged light emitting devices, when energized, appear as a white dot with no side emission (e.g., no blue halo).

To prevent deterioration of light incident/emission environment in a semiconductor device in which a transmissive material is laminated on an optical element forming surface via an adhesive. The semiconductor device includes a semiconductor element manufactured by chip size packaging, a transmissive material which is bonded with an adhesive to cover an optical element forming surface of the semiconductor element, and a side surface protective resin which covers an entire side surface where a layer structure of the semiconductor element and the transmissive material is exposed.

In an embodiment a composite semiconductor component includes a carrier substrate having a plurality of projecting elements projecting from a first main surface of the carrier substrate, an electrically conductive material electrically conductively connected to a contact region of the carrier substrate and located on at least one of the projecting elements, some of the projecting elements not being covered with the electrically conductive material and a semiconductor chip arranged on the carrier substrate and having at a first surface at least one contact pad electrically connected to the electrically conductive material on at least one element, wherein, at a position at which the contact pad and the electrically conductive material on the projecting element are in each case in contact with one another, the contact pad has a larger lateral extent than the projecting element in each case.

Disclosed in an embodiment is a semiconductor device package comprising: a body comprising a cavity; a semiconductor device disposed within the cavity; and a light transmission member disposed on an upper portion of the cavity, wherein the body comprises a first conductive part and a second conductive part disposed to be spaced apart from each other in a first direction, a first insulating part disposed between the first conductive part and the second conductive part, and a second insulating part disclosed in an edge region where a lower surface and side surfaces of the body meet, wherein the cavity comprises a stepped portion on which the light transmission member is disposed, and wherein the second insulating part overlaps with the stepped portion in a vertical direction of the body.

An electronic device including a plurality of light-emitting units, a driving circuit, and a controlling circuit is provided. The driving circuit is configured to drive at least one of the light-emitting units. The controlling circuit is configured to control the driving circuit. The plurality of light-emitting units, the driving circuit, and the controlling circuit are respectively disposed on different substrates.

The invention relates to a timepiece including, in addition to a crystal (34), the following external elements: a back (2), a middle (1), a dial (3) and two bracelet strands (30), at least one of these external elements comprising at least one part made of an at least partially transparent or translucent ceramic material, the timepiece further including at least two point light sources (10) releasing heat, each light source (10) being capable of being separately switched on/off and being disposed in or directly beneath said at least one external element comprising the ceramic material, each light source (10) producing light that passes through the ceramic material of said external element, and wherein each light source (10) is configured to produce localised light on a point or quasi-point area (40) of the ceramic material of the external element concerned, so as to produce localised illumination on said external element.

A package structure with a wettable side surface and a manufacturing method thereof, and a vertical package module are disclosed. The package structure includes a first dielectric layer, a chip and a circuit layer. The first dielectric layer is provided with a package cavity, side wall bonding pads are arranged on a side wall of the first dielectric layer and located outside the package cavity. The chip is packaged inside the package cavity, pins of the chip face first surface of the first dielectric layer. The circuit layer is arranged on the first surface of the first dielectric layer, and the circuit layer is directly or indirectly connected to the side wall bonding pads and the pins of the chip.

A cap is mounted to a support substrate, the cap including a cap body and an optical shutter. The cap and support substrate define a housing. An electronic chip is disposed in the housing above the support substrate. A face of the electronic chip supports an optical device that is optically coupled with the optical shutter. The cap body is thermally conductive. Within the housing, a thermally conductive linking structure is coupled in a thermally conductive manner between the cap body and the electronic chip. The thermally conductive linking structure surrounds the electronic chip. A thermal interface material fills a portion of the housing between the thermally conductive linking structure and the cap body.

A light-emitting device package includes a frame including one side on which a first electrode is formed and the other side on which a second electrode is formed, an LED chip including a first conductive connection pad electrically connected to the first electrode and a second conductive connection pad electrically connected to the second electrode, a reflective member disposed on the frame, forming a cavity for accommodating the LED chip therein, and reflecting light emitted from the LED chip, and a wavelength conversion member filled in the cavity to cover the LED chip, wherein the reflective member includes a first side and a second side different from the first side, and a first height of the first side and a second height of the second side are formed to be different from each other.

A micro LED structure includes a first micro LED chip having opposite first and second sides, a second micro LED chip adjacent to the first side of the second micro LED chip, a third micro LED chip adjacent to the first side of the first micro LED chip, and optical structures respectively over the first micro LED chip, the second micro LED chip and the third micro LED chip. Each of the first, second and third micro LED chip includes a semiconductor stack, a metal pad and a reflective coating layer. The semiconductor stack includes a first semiconductor layer, an active layer in contact with the first semiconductor layer, and a second semiconductor layer in contact with the active layer. The metal pad is in contact with the first semiconductor layer, and the reflective coating layer is disposed around sidewalls of the semiconductor stack.