A 2nd signal line has impedance lower than impedance of a 1st signal line. A capacitor includes a 1st extension part and a 2nd extension part, a 1st ground part and a 2nd ground part. The 1st extension part and the 2nd extension part are connected to a 2nd signal line and are provided on an insulation substrate to extend along a longitudinal direction of the 2nd signal line. The 1st ground part and the 2nd ground part are at least a part of a ground pattern, and are provided between the 1st extension part and the 2nd extension part and the 2nd signal line, and between the 1st extension part and the 2nd extension part and an end part of the insulation substrate, to be electrically coupled with the 1st extension part and the 2nd extension part.

A semiconductor package includes: an insulating substrate; a first semiconductor chip; a second semiconductor chip with a thickness smaller than a thickness of the first semiconductor chip; a heat radiation member in which a main surface located on an opposite side of an active surface of the first semiconductor chip and an active surface of the second semiconductor chip, respectively, are bonded to a lower surface; and a sealing resin having contact with at least part of a side wall of the heat radiation member without being raised over an upper surface of the heat radiation member to seal the first and second semiconductor chips on the insulating substrate, wherein in the heat radiation member, a thickness of a first bonding part to which the first semiconductor chip is bonded is smaller than a thickness of a second bonding part to which the second semiconductor chip is bonded.

Embodiments disclosed herein include semiconductor devices and methods of forming such devices. In an embodiment the semiconductor device comprises a first semiconductor layer, where first transistors are fabricated in the first semiconductor layer, and a back end stack over the first transistors. In an embodiment the back end stack comprises conductive traces and vias electrically coupled to the first transistors. In an embodiment, the semiconductor device further comprises a second semiconductor layer over the back end stack, where the second semiconductor layer is a different semiconductor than the first semiconductor layer. In an embodiment, second transistors are fabricated in the second semiconductor layer.

A manufacturing method of a chip-attached substrate includes preparing a stacked substrate including multiple chips, a first substrate to which the multiple chips are temporarily bonded, and a second substrate bonded to the first substrate with the multiple chips therebetween; and separating the multiple chips bonded to the first substrate and the second substrate from the first substrate to bond the multiple chips to one surface of a third substrate including a device layer.

A radio frequency module includes a module substrate, a power amplifier that amplifies a transmission signal in a middle band group, a low noise amplifier that amplifies a reception signal in the middle band group, and a conductive component that transmits a radio frequency signal in a high band group, wherein the power amplifier is mounted on a main surface of the module substrate, the low noise amplifier is mounted on a main surface of the module substrate, and the conductive component is mounted between the power amplifier and the low noise amplifier on the main surface when the module substrate is viewed in plan.

An electronic device includes a plurality of light emitting units mounted on a substrate, and an opening that is provided so as to correspond to each of the light emitting units and guides light emitted from the light emitting units to an outside.

A method includes forming a set of through-vias in a substrate, the set of through-vias partially penetrating a thickness of the substrate. First connectors are formed over the set of through-vias on a first side of the substrate. The substrate is singulated to form dies. The first side of the dies are attached to a carrier. The dies are thinned from the second side to expose the set of through-vias. Second connectors are formed over the set of through-vias on the second side of the dies. A device die is bonded to the second connectors. The dies and device dies are singulated into multiple packages. Corresponding structures result from these methods.

A photonic device manufacturing method, including a step of transfer, onto a same surface of a photonic circuit previously formed inside and on top of a first substrate, of at least a first die made up of a III-V semiconductor material and of at least a second die made up of silicon nitride, the method further including a step of forming of photonic components in said at least one first and at least one second dies.

Micro light-emitting diode displays having colloidal or graded index quantum dot films and methods of fabricating micro light-emitting diode displays having colloidal or graded index quantum dot films are described. In an example, a micro light emitting diode pixel structure includes a plurality of micro light emitting diode devices in a dielectric layer. A transparent conducting oxide layer is above the dielectric layer. A material layer is on the transparent conducting oxide layer, the material layer having a portion with a hydrophilic surface and a portion with a hydrophobic surface, the hydrophilic surface over one of the plurality of micro light emitting diode devices. A color conversion film is on the hydrophilic surface of the material layer and over the one of the plurality of micro light emitting diode devices.

Semiconductor devices laterally surrounded by at least one dielectric material portion are formed over a substrate. At least one edge seal ring structure is formed around the semiconductor devices and the at least one dielectric material portion. One or more of the at least one edge seal ring structure has a horizontal cross-sectional profile that includes laterally-extending regions that extend laterally with a uniform width between an inner sidewall and an outer sidewall, and notch regions connecting neighboring pairs of the laterally-extending regions and having a greater width than the uniform width. Cavities in the laterally-extending regions are connected to cavities in the notch regions to allow outgassing from the material of the at least one edge seal ring structure.