A power amplifier circuit includes a substrate and a semiconductor chip disposed on or above the substrate. The semiconductor chip includes a power amplifier unit that amplifies an RF signal, a ground terminal to which a ground of the power amplifier unit is coupled, and a first circuit element having a first end electrically coupled to the ground terminal without any portion outside the semiconductor chip interposed therebetween, and having a second end. The substrate includes a second circuit element having a first end electrically coupled to an output of the power amplifier unit and a second end electrically coupled to the second end of the first circuit element. The first and second circuit elements constitute a harmonic wave termination circuit. The harmonic wave termination circuit reflects, to the power amplifier unit, a harmonic wave component of the amplified RF signal output from the power amplifier unit.

A printed wiring board includes a resin insulating layer, a metal post formed in the insulating layer and protruding from first surface of the insulating layer, a conductor layer formed on second surface of the insulating layer, and a via conductor penetrating through the insulating layer and connecting the metal post and conductor layer. The metal post has a protruding portion protruding from the first surface of the insulating layer and an embedded portion connected to the protruding portion and embedded in the insulating layer such that the protruding portion does not extend onto the insulating layer, and the metal post has upper and side surfaces such that the side surface has unevenness including a first unevenness on side surface of the protruding portion and a second unevenness formed on side surface of the embedded portion and having a size that is larger than a size of the first unevenness.

A circuit board includes an insulating layer having a protrusion on a surface, and a connection pad formed on an upper surface of the protrusion. A peripheral portion of a lower surface of the connection pad is exposed from the protrusion.

A multilayer substrate includes a flexible element assembly including a principal surface, a first to an n-th external electrode disposed on the principal surface, and at least one first dummy conductor disposed inside the element assembly and being in a floating state. When the element assembly is viewed from a normal direction that is normal to the principal surface, a distance between an m-th external electrode and a nearest external electrode therefrom among the first to the n-th external electrodes is defined as a distance Dm, an average of distances D1 to Dn is defined as an average Dave, and when the element assembly is viewed from the normal direction, an area within a circle with a center on the m-th external electrode and with a radius of Dm is defined as an area Am. The first dummy conductor is located in at least one area Am with a radius of Dm smaller than the average Dave when viewed from the normal direction.

A semiconductor substrate and a manufacturing method thereof are provided. The semiconductor substrate includes a dielectric layer, a circuit layer, a first protection layer and a plurality of conductive posts. The dielectric layer has a first surface and a second surface that are opposite to each other. The circuit layer is embedded in the dielectric layer and is exposed from the first surface. The first protection layer covers a portion of the first circuit layer and defines a plurality of holes that expose a remaining portion of the first circuit layer. The conductive posts are formed in the holes.

The present disclosure relates to a printed circuit board and a method of manufacturing the same. The printed circuit board includes: an insulating layer; a plurality of pads disposed on the insulating layer; and a plurality of insulating walls that are disposed on the insulating layer and cover side surfaces of the plurality of pads, respectively, but are not disposed on upper surfaces of the plurality of pads. The plurality of insulating walls are disposed to be spaced apart from each other on the first insulating layer.

A wiring board of the present invention includes an insulating board including a core insulating plate and an insulating layer laminated on at least one surface of the insulating plate. A plurality of code information reading pads formed of a conductor layer are disposed on a surface of the insulating layer formed uppermost. A common conductor is disposed oppositely to the code information reading pads by interposing therebetween the insulating layer formed uppermost. At least one of the code information reading pads and the common conductor are electrically connected to each other through a via conductor penetrating through the insulating layer formed uppermost.

An integrated circuit (IC) device may include a first substrate having an inductor ground plane in a conductive layer of the first substrate. The integrated circuit may also include a first inductor in a passive device layer of a second substrate that is supported by the first substrate. A shape of the inductor ground plane may substantially correspond to a silhouette of the first inductor.

Semiconductor assemblies including thermal layers and associated systems and methods are disclosed herein. In some embodiments, the semiconductor assemblies comprise one or more semiconductor devices over a substrate. The substrate includes a thermal layer configured to transfer thermal energy across the substrate. The thermal energy is transferred from the semiconductor device to the graphene layer using one or more thermal connectors.

A package structure includes a substrate, a sensor, a base, a lead frame, conductive vias and patterned circuit layer. The substrate includes a component-disposing region and electrode contacts. The sensor is disposed at the component-disposing region and electrically connected to the electrode contacts. The base covers the substrate with its bonding surface and includes a receiving cavity, a slanted surface extended between a bottom surface of the receiving cavity and the bonding surface, and electrodes disposed on the bonding surface and electrically connected to the electrode contacts respectively. The sensor is located in the receiving cavity. The lead frame is disposed at the base. The conductive vias penetrates the base and electrically connected to the lead frame. The patterned circuit layer is disposed on the slanted surface and electrically connected to the conductive vias and the electrodes.