A semiconductor device includes a gate electrode embedded in each of a plurality of first trenches through an insulating film. The gate electrode includes a first gate electrode electrically connected to a first gate pad and a second gate electrode electrically connected to a second gate pad. A charge period and a discharge period of gate capacitance parasitic on the second gate electrode are shorter than a charge period and a discharge period of gate capacitance parasitic on the first gate electrode, respectively.

A semiconductor device according to an embodiment includes a plurality of circuit units each including a substrate, a first electrode on a first side of the substrate, a second electrode aligned with the first electrode on the first side of the substrate, a third electrode on a second side of the substrate, and a first switching element and a second switching element. The switching elements are aligned on the substrate between the first electrode, second electrode and third electrode, electrically connected in series between the first electrode and the second electrode, and having the third electrode electrically connected therebetween. In two of the adjacent circuit units, the first side of one circuit unit and the first side of the other circuit unit are adjacent to each other, and the second side of the one and the second side of the other are adjacent to each other.

A semiconductor device includes a semiconductor body including a drift zone that forms a pn junction with an emitter region. A first load electrode is at a front side of the semiconductor body. A second load electrode is at a rear side of the semiconductor body opposite to the front side. One or more variable resistive elements are electrically connected in a controlled path between the drift zone and one of the first and second load electrodes. The variable resistive elements activate and deactivate electronic elements of the semiconductor device in response to a change of the operational state of the semiconductor device.

The disclosure provides an electronic device. The electronic device includes a substrate, a transistor, and a variable capacitor. The transistor is disposed on the substrate. The variable capacitor is disposed on the substrate and adjacent to the transistor. A material of the transistor and a material of the variable capacitor both a include a III-V semiconductor material. The electronic device of an embodiment of the disclosure may simplify manufacturing process, reduce costs, or reduce dimensions.

Metal pillars are placed adjacent to NPN transistor arrays that are used in the power amplifier for RF power generation. By placing the metal pillars in intimate contact with the silicon substrate, the heat generated by the NPN transistor arrays flows down into the silicon substrate and out the metal pillar. The metal pillar also forms an electrical ground connection in close proximity to the NPN transistors to function as a grounding point for emitter ballast resistors, which form an optimum electrothermal configuration for a linear SiGe power amplifier.

Metal pillars are placed adjacent to NPN transistor arrays that are used in the power amplifier for RF power generation. By placing the metal pillars in intimate contact with the silicon substrate, the heat generated by the NPN transistor arrays flows down into the silicon substrate and out the metal pillar. The metal pillar also forms an electrical ground connection in close proximity to the NPN transistors to function as a grounding point for emitter ballast resistors, which form an optimum electrothermal configuration for a linear SiGe power amplifier.

Solder bumps are placed in direct contact with the silicon substrate of an amplifier integrated circuit having a flip chip configuration. A plurality of amplifier transistor arrays generate waste heat that promotes thermal run away of the amplifier if not directed out of the integrated circuit. The waste heat flows through the thermally conductive silicon substrate and out the solder bump to a heat-sinking plane of an interposer connected to the amplifier integrated circuit via the solder bumps.

Metal pillars are placed adjacent to NPN transistor arrays that are used in the power amplifier for RF power generation. By placing the metal pillars in intimate contact with the silicon substrate, the heat generated by the NPN transistor arrays flows down into the silicon substrate and out the metal pillar. The metal pillar also forms an electrical ground connection in close proximity to the NPN transistors to function as a grounding point for emitter ballast resistors, which form an optimum electrothermal configuration for a linear SiGe power amplifier.

Improve the reliability of a semiconductor device. A resistive element Rg is filled in a trench TR formed in a well region PW of a semiconductor substrate. The resistive element Rg and the trench TR have an endless shape in plan view. The resistive element Rg is connected to a first contact member PG that is electrically connected to a gate pad GP, and a second contact member PG that is electrically connected to a gate wiring GW. Furthermore, a third contact member PG, which electrically connects an emitter electrode EE to the well region PW, is positioned in an area surrounded by an endless shape of the resistive element Rg, between the first and second contact members PG in a Y direction.

The present disclosure relates to a system for biasing a power amplifier. The system can include a first die that includes a power amplifier circuit and a passive component having an electrical property that depends on one or more conditions of the first die. Further, the system can include a second die including a bias signal generating circuit that is configured to generate a bias signal based at least in part on measurement of the electrical property of the passive component of the first die.