A display device includes a plurality of bank patterns disposed on a substrate and spaced apart from each other, a plurality of electrodes disposed on the substrate and extended parallel to each other and spaced apart from each other, an insulating layer disposed on the plurality of electrodes and the plurality of bank patterns, and a plurality of light emitting elements disposed on the insulating layer, having both ends disposed on the plurality of electrodes, wherein the plurality of bank patterns include sides facing each other, and portions of the plurality of light emitting elements are disposed on the sides of the plurality of bank patterns.

Disclosed in one example is an apparatus including a substrate, a sensor over the substrate including an active surface and a sensor bond pad, a molding layer over the substrate and covering sides of the sensor, the molding layer having a molding height relative to a top surface of the substrate that is greater than a height of the active surface of the sensor relative to the top surface of the substrate, and a lidding layer over the molding layer and over the active surface. The lidding layer and the molding layer form a space over the active surface of the sensor that defines a flow channel.

A three-dimensional structure in which a wiring is provided on a surface is provided. At least a part of the surface of the three-dimensional structure includes an insulating layer containing filler. A recessed gutter for wiring is provided on the surface of the three-dimensional structure, and at least a part of a wiring conductor is embedded in the recessed gutter for wiring.

A method produces a plurality of optoelectronic modules, and includes: A) providing a metallic carrier assembly with a plurality of carrier units; B) applying a logic chip, each having at least one integrated circuit, to the carrier units; C) applying emitter regions that generate radiation, which can be individually electrically controlled; D) covering the emitter regions and the logic chips with a protective material; E) overmolding the emitter regions and the logic chips so that a cast body is formed, which joins the carrier units, the logic chips and the emitter regions to one another; F) removing the protective material and applying electrical conductor paths to the upper sides of the logic chips and to a cast body upper side; and G) dividing the carrier assembly into the modules.

A semiconductor package includes a plurality of stack modules which are vertically stacked. Each of the stack modules includes an interposing bridge, a semiconductor dies, and redistribution lines. The stack modules are provided by rotating each of the stack modules by different rotation angles corresponding to multiples of a reference angle and by vertically stacking the rotated stack modules. The interposing bridge includes a plurality of sets of through vias, and each set of through vias includes through vias arrayed in a plurality of columns. The plurality of sets of through vias are disposed in respective ones of divided regions of the interposing bridge. If the plurality of sets of through vias are rotated by the reference angle, then the rotated through vias overlap with the plurality of sets of through vias which are originally located. The redistribution lines connect the semiconductor dies to the plurality of sets of through vias.

A semiconductor device has a plurality of interconnected modular units to form a 3D semiconductor package. Each modular unit is implemented as a vertical component or a horizontal component. The modular units are interconnected through a vertical conduction path and lateral conduction path within the vertical component or horizontal component. The vertical component and horizontal component each have an interconnect interposer or semiconductor die. A first conductive via is formed vertically through the interconnect interposer. A second conductive via is formed laterally through the interconnect interposer. The interconnect interposer can be programmable. A plurality of protrusions and recesses are formed on the vertical component or horizontal component, and a plurality of recesses on the vertical component or horizontal component. The protrusions are inserted into the recesses to interlock the vertical component and horizontal component. The 3D semiconductor package can be formed with multiple tiers of vertical components and horizontal components.

A packaged semiconductor includes an electrically insulating encapsulant body having an upper surface, a first semiconductor die encapsulated within the encapsulant body, the first semiconductor die having a main surface with a first conductive pad that faces the upper surface of the encapsulant body, a second semiconductor die encapsulated within the encapsulant body and disposed laterally side by side with the first semiconductor die, the second semiconductor die having a main surface with a second conductive pad that faces the upper surface of the encapsulant body, and a first conductive track that is formed in the upper surface of the encapsulant body and electrically connects the first conductive pad to the second conductive pad. The encapsulant body includes a laser activatable mold compound.

The power on wafer assembly can include: a compliant connector, an integrated circuit, a printed circuit board (PCB), a power component, and a set of compliant connectors. The power on wafer assembly can optionally include: a compression element, a cooling system, a set of mechanical clamping components, and a power source. However, the power on wafer assembly can additionally or alternately include any other suitable components.

A semiconductor package includes a first sub-package on an interconnection layer. A second sub-package and a third sub-package are sequentially stacked on the first sub-package. Each of the first to third sub-packages includes a semiconductor chip and an interposing bridge. The interposing bridge includes a first through via and a second through via. The second sub-package further includes a first redistributed line electrically connecting the semiconductor chip of the second sub-package to the first through via. The third sub-package further includes a second redistributed line electrically connecting the semiconductor chip of the third sub-package to the second through via.

A semiconductor device includes a support substrate with leads arranged therearound, a semiconductor die on the support substrate, and a layer of laser-activatable material molded onto the die and the leads. The leads include proximal portions facing towards the support substrate and distal portions facing away from the support substrate. The semiconductor die includes bonding pads at a front surface thereof which is opposed to the support substrate, and is arranged onto the proximal portions of the leads. The semiconductor device has electrically-conductive formations laser-structured at selected locations of the laser-activatable material. The electrically-conductive formations include first vias extending between the bonding pads and a front surface of the laser-activatable material, second vias extending between the distal portions of the leads and the front surface of the laser-activatable material, and lines extending at the front surface of the laser-activatable material and connecting selected first vias to selected second vias.