A flip-chip semiconductor-on-insulator die includes a substrate layer, an active layer, an insulator layer between the substrate layer and the active layer, a first metal layer, and a first via layer between the active layer and the first metal layer. The die at least first and second contact pads and a transistor including a first terminal formed within the active layer. A first portion of the first terminal falls within a footprint of the first contact pad and a second portion of the first terminal falls within a footprint of the second contact pad.

An electronic circuit module includes a substrate, a first electronic component mounted on one principal surface of the substrate, a substrate electrode provided on the one principal surface, a second electronic component supported by a support surface opposite to a surface of the first electronic component facing the one principal surface, a component electrode provided on a surface of the second electronic component, and a conductor including a connection part connecting the substrate electrode and the component electrode. The second electronic component includes a conductive portion electrically connected to the component electrode. The conductive portion is separated from a support surface of the first electronic component.

The present disclosure relates to a microelectronics package with a self-aligned stacked-die assembly and a process for making the same. The disclosed microelectronics package includes a module substrate, a first die with a first coupling component, a second die with a second coupling component, and a first mold compound. The first die is attached to the module substrate. The first mold compound resides over the module substrate, surrounds the first die, and extends above an upper surface of the first die to define a first opening. Herein, the first mold compound provides vertical walls of the first opening, which are aligned with edges of the first die in X-direction and Y-direction. The second die is stacked with the first die and in the first opening, such that the second coupling component is mirrored to the first coupling component.

An integrated circuit is provided including a first substrate with a first thermal conductivity. An active layer is deposited on the first substrate. At least one native device is fabricated on the active layer. A window is formed in the active layer, which exposes a portion of the first substrate. A non-native device is fabricated on a second substrate with a second thermal conductivity lower than the first thermal conductivity. The non-native device is flip-chip mounted in the widow on the first substrate and electrically connected to the at least one native device. The non-native device is also thermally connected to the first substrate such that heat generated by the non-native device is removed through the first substrate.

One aspect of this disclosure is a power amplifier module that includes a power amplifier on a substrate and a semiconductor resistor on the substrate. The power amplifier includes a bipolar transistor having a collector, a base, and an emitter. The collector has a doping concentration of at least 310.sup.16 cm.sup.3 at an interface with the base. The collector also has at least a first grading in which doping concentration increases away from the base. The semiconductor resistor includes a resistive layer that that includes the same material as a layer of the bipolar transistor. Other embodiments of the module are provided along with related methods and components thereof.

A microwave module includes an RF device and a multilayer resin substrate. The device includes a metal cover covering at least an internal circuit. The substrate includes a first end face on a side of the device, a second end face on a side opposite to the first end face, a signal through-holes surrounding the circuit and connected to the circuit, ground through-holes surrounding the signal through-holes and connected to the cover, a first surface ground provided on the first end face and connected to the cover, an inner layer surface ground connected to ground through-holes, and an RF transmission line surrounded by the ground through-holes, the first surface ground, and the inner layer surface ground, and connected to the signal through-hole.

A radio-frequency module includes: a transmitting circuit disposed on a mounting substrate to process a radio-frequency signal input from a transmission terminal and to output a resultant signal to a common terminal; a receiving circuit disposed on the mounting substrate to process a radio-frequency signal input from the common terminal and to output a resultant signal to a reception terminal; a first inductor included in a first transmitting circuit; and a bonding wire connected to the ground and bridging over the first inductor.

The present disclosure is directed to an electronic component package including: a wiring board including a first principal surface and a second principal surface facing each other; an electronic component mounted on the first principal surface; a sealing member provided on the first principal surface for covering the electronic component; and a shield film provided on a surface of the sealing member, wherein the wiring board is provided with a plurality of through holes between the first principal surface and the second principal surface, an electronic component including a columnar terminal is mounted on the first principal surface, and the columnar terminal is inserted into at least one of the through holes from the first principal surface and is exposed on a side of the second principal surface, thereby reducing the size and height of the package.

A high-frequency module includes a module substrate including major surfaces opposite to each other; a module substrate including major surfaces opposite to each other, the major surface being disposed facing the major surface; a first electronic component including a filter coupled to a power amplifier; a second electronic component including a filter coupled to a low-noise amplifier; and a third electronic component (an integrated circuit) including the low-noise amplifier. The first electronic component is disposed one of between the major surfaces, on the major surface, and on the major surface. The second electronic component is disposed another one of between the major surface surfaces, on the major surface, and on the major surface. The third electronic component is disposed other one of between the major surfaces, on the major surface, and on the major surface.

A radio-frequency module includes a module substrate having major surfaces opposite to each other; a module substrate having major surfaces opposite to each other, the major surface being disposed facing the major surface; a first electronic component including a filter coupled to a power amplifier via a switch; a second electronic component including a filter coupled to the power amplifier via the switch; and a third electronic component including the switch. The first electronic component is disposed one of between the major surfaces, on the major surface, and on the major surface. The second electronic component is disposed another one of between the major surfaces, on the major surface, and on the major surface. The third electronic component is disposed other one of between the major surfaces, on the major surface, and on the major surface.