A package includes an integrated circuit that includes at least one active area and at least one secondary device area, a support configured to support the integrated circuit, and a die attach material. The integrated circuit being mounted on the support using the die attach material and the die attach material including at least one channel configured to allow gases generated during curing of the die attach material to be released from the die attach material.

A package includes an integrated circuit that includes at least one active area and at least one secondary device area, a support configured to support the integrated circuit, and a die attach material. The integrated circuit being mounted on the support using the die attach material and the die attach material including at least one channel configured to allow gases generated during curing of the die attach material to be released from the die attach material.

A method for producing a printed circuit board structure comprising at least one insulation layer, at least one conductor layer, and at least one embedded component having a contact pad that has an outer barrier layer, in which structure at least two conductor paths/conductor layer are connected to at least two connections using vias, and each via runs from a conductor path/conductor layer directly to the barrier contact layer of the corresponding connection of the component.

A die includes a semiconductor layer, an electrical contact on a first side of the semiconductor layer, a backside electrical contact layer on second side of the semiconductor layer. The die further includes a zinc layer over at least one of the electrical contact or the backside electrical contact layer of the die, and a conversion coating over the zinc layer. The conversion coating includes at least one of zirconium and vanadium. As part of an embedded die package including the die, at least a portion of the conversion coating may adjacent to an electrically insulating substrate of the embedded die package.

A die includes a semiconductor layer, an electrical contact on a first side of the semiconductor layer, a backside electrical contact layer on second side of the semiconductor layer. The die further includes a zinc layer over at least one of the electrical contact or the backside electrical contact layer of the die, and a conversion coating over the zinc layer. The conversion coating includes at least one of zirconium and vanadium. As part of an embedded die package including the die, at least a portion of the conversion coating may adjacent to an electrically insulating substrate of the embedded die package.

A method of manufacturing a high-frequency device includes mounting a first chip having a first pillar on an upper surface thereof on a metal base, forming an insulator layer covering the first chip on the metal base, exposing an upper surface of the first pillar from the insulator layer, and forming a first wiring connected to the first pillar on the insulator layer and transmitting a high-frequency signal.

A light-emitting assembly with higher connection tolerances in manufacture includes a substrate, a light-emitting diode on the substrate, a transparent electrode, and a wire connected to the transparent electrode. The substrate includes a driving circuit connected to the light-emitting diode. The light-emitting diode includes a first electrode, a second electrode, and a light-emitting layer between the first electrode and the second electrode, the first electrode receiving the first driving signal. transparent electrode is connected to the second electrode. An orthographic projection area of the transparent electrode on the substrate is larger than an orthographic projection area of the second electrode on the substrate allowing less criticality in the alignment of signal wires for receiving the second driving signal. The light-emitting diode is configured to emit source light according to the first driving signal and the second driving signal.

A light emitting module including a circuit board and a lighting emitting device thereon and including first, second, and third LED stacks each including first and second conductivity type semiconductor layers, a first bonding layer between the second and third LED stacks, a second bonding layer between the first and second LED stacks, a first planarization layer between the second bonding layer and the third LED stack, a second planarization layer on the first LED stack, a lower conductive material extending along sides of the first planarization layer, the second LED stack, the first bonding layer, and electrically connected to the first conductivity type semiconductor layers of each LED stack, respectively, and an upper conductive material between the circuit board and the lower conductive material, in which a width of an upper end of the upper conductive material is greater than a width of the corresponding upper conductive material.

A light emitting module including a circuit board and a lighting emitting device thereon and including first, second, and third LED stacks each including first and second conductivity type semiconductor layers, a first bonding layer between the second and third LED stacks, a second bonding layer between the first and second LED stacks, a first planarization layer between the second bonding layer and the third LED stack, a second planarization layer on the first LED stack, a lower conductive material extending along sides of the first planarization layer, the second LED stack, the first bonding layer, and electrically connected to the first conductivity type semiconductor layers of each LED stack, respectively, and an upper conductive material between the circuit board and the lower conductive material, in which a width of an upper end of the upper conductive material is greater than a width of the corresponding upper conductive material.

The present disclosure provides a fan-out chip packaging structure and a method to fabricate the fan-out chip package. The fan-out chip packaging structure includes a first redistribution layer, a second redistribution layer, metal connecting posts, a semiconductor chip, a first packaging layer, a stacked chip package, a passive element, a filling layer, a metal bumps, and a second packaging layer. By means of the present disclosure, various chips having different functions can be integrated into one package structure, thereby improving the integration level of the fan-out packaging structure. By means of the first redistribution layer, the second redistribution layer, and the metal connecting posts, a three-dimensional vertically stacked package is achieved. In this way, the integration level of the packaging structure can be effectively improved, and the conduction path can be effectively shortened, thereby reducing power consumption, increasing the transmission speed, and increasing the data processing capacity.