Power amplifier electronics for controlling application of radio frequency (RF) energy generated using solid state electronic components may further be configured to control application of RF energy in cycles between high and low powers. The power amplifier electronics may include a semiconductor die on which one or more RF power transistors are fabricated, an output matching network configured to provide impedance matching between the semiconductor die and external components operably coupled to an output tab, and bonding ribbon bonded at terminal ends thereof to operably couple the one or more RF power transistors of the semiconductor die to the output matching network. The bonding ribbon may have a width of greater than about five times a thickness of the bonding ribbon.

A low parasitic inductance power module featuring staggered interleaving conductive members, including: at least one base extending in a length direction; a substrate on which at least one input bus bar and at least one output bus bar are provided; a first unit including a first circuit base portion disposed on the base in a width direction, a plurality of first power devices being disposed on the first circuit base portion, each first power device having a first current input end and a first current output end which are parallel connected, the first current input end or the first current output end being conducted to the first circuit base portion; and a second unit. The units are serially-connected to the bus bars via input conductive members and output conductive members arrayed in a staggered interleaving mode, whereby to create individual inductances counteracting with each other, reducing overall parasitic inductance.

There are provided a semiconductor module capable of preventing the peeling of a sealing resin on the side where a connection section used for the connection to a semiconductor element is arranged and a manufacturing method for a semiconductor module. A semiconductor module includes: an outer frame; sealing resins; gate signal output terminals, and partition sections laid across the outer flame to partition a space into a plurality of housing sections, in the partition sections which the gate signal output terminals with connection sections exposed are arranged. The partition sections have through holes where sealing resins are formed, the sealing resins connecting adjacent housing sections and the sealing resin formed in the through hole being continuous with the sealing resins formed in the housing sections.

A semiconductor device includes first and second conductive parts, a first bonding wire connecting the first and second conductive parts and having a non-flat portion between opposite ends thereof so that a portion between the opposite ends is away from the first and second conductive parts, a case having a housing space to accommodate the first and second conductive parts, including a sidewall having first to fourth lateral faces surrounding the housing space to form a rectangular shape in a plan view, and a cover disposed on the sidewall, a sealing member filling the case to seal the first bonding wire, and a first stress relaxer for relieving a stress in the first bonding wire. The first bonding wire extends from the second lateral face toward the fourth lateral face, and the first stress relaxer is positioned between the first bonding wire and the first lateral face.

The present disclosure relates to a package capable of handling high radio frequency (RF) power, which includes a carrier, a ring structure attached to a top surface of the carrier, an RF die attached to the top surface of the carrier within an opening of the ring structure and electrically connected to the ring structure, a heat spreader attached to a top surface of the ring structure, and an output signal lead configured to send out RF output signals generated by the RF die. Herein, the heat spreader covers a portion of the top surface of the ring structure at an output side of the package, and the output signal lead is attached to a top surface of the heat spreader. As such, the RF output signals are capable of being transmitted from the RF die to the output signal lead through the ring structure and the heat spreader.

A power semiconductor module includes an insulating substrate, a first conductive circuit pattern, a second conductive circuit pattern, a first semiconductor device, a second semiconductor device, a sealing member, and a first barrier layer. The sealing member seals the first semiconductor device, the second semiconductor device, the first conductive circuit pattern, and the second conductive circuit pattern. At least one of the first barrier layer and the sealing member includes a first stress relaxation portion. This configuration improves the reliability of the power semiconductor module.

Provided is a semiconductor module having a P-side arm circuit and an N-side arm circuit. The semiconductor module comprises: a P terminal on a high-voltage side; an N terminal on a low-voltage side; a plurality of wiring patterns separated from each other; and a transistor and a diode connected in parallel in each of the circuits, wherein the plurality of wiring patterns include a first wiring pattern, a second wiring pattern, and a third wiring pattern, the P terminal is connected to the first wiring pattern, the N terminal is connected to the second wiring pattern, an anode electrode of the diode of the N-side arm circuit is arranged above the second wiring pattern and is connected to the second wiring pattern, and an anode electrode of the diode of the P-side arm circuit is arranged above the third wiring pattern and is connected to the third wiring pattern.

A semiconductor device, including a circuit pattern, a contact part and an external connection terminal. The contact part has a cylindrical through-hole and first and second opening ends opposite to each other, the second opening end being joined to the circuit pattern. The external connection terminal has a prismatic main body portion and first and second end portions, the second end portion being inserted into the through-hole from the first opening end of the contact part. The main body portion of the external connection terminal has an insertion prevented portion formed thereon. The contact part includes an insertion preventing portion formed on an inner circumferential surface of the through-hole, the insertion preventing portion being so positioned as to be substantially downstream, with respect to an insertion direction of the external connection terminal, from the main body portion of the external connection terminal inserted into the through-hole.

A ceramic encapsulating casing and a mounting structure thereof are provided. The ceramic encapsulating casing includes a ceramic substrate, a ceramic insulator, a cover plate and a pad structure. The ceramic substrate is provided with a cavity with an upward opening. The ceramic insulator is disposed on the ceramic substrate and provided with a radio frequency transmission structure. The pad structure is arranged on a bottom surface of the ceramic substrate. and includes a plurality of second pads that are arranged for transmitting signals and arranged in an array manner. A plurality of solder balls are attached to the plurality of second pads in one-to-one correspondence.

A semiconductor device includes: a package having a top surface and a bottom surface; a semiconductor element arranged in the package; and a base which is arranged in the package and on which the semiconductor element is mounted. A top surface of the base is exposed to the top surface of the package, and a bottom surface of the base is exposed to the bottom surface of the package.