A wafer-level chip-size package includes a semiconductor structure. A bonding pad is formed over the semiconductor structure, including a plurality of conductive segments. A conductive component is formed over the semiconductor structure, being adjacent to the bonding pad. A passivation layer is formed, exposing a portions of the conductive segments of the first bonding pad. A conductive redistribution layer is formed over the portions of the conductive segments of the first bonding pad exposed by the passivation layer. A planarization layer is formed over the passivation layer and the conductive redistribution layer, exposing a portion of the conductive redistribution layer. A UBM layer is formed over the planarization layer and the portion of the conductive redistribution layer exposed by the planarization layer. A conductive bump is formed over the UBM layer.

To provide a semiconductor device less affected by noise without making a manufacturing process more complicated and increasing a chip area. The device has a semiconductor substrate having first and second surfaces, a first-conductivity-type drain region on the second surface side in the semiconductor substrate, a first-conductivity-type drift region on the first surface side of a substrate region, a second-conductivity-type base region on the first surface side of the drift region, a first-conductivity-type source region on the first surface of the semiconductor substrate sandwiching a base region between the source and drift regions, a gate electrode opposite to and insulated from the base region, a wiring on the first main surface electrically coupled to the source region, and a first conductive film on the first main surface, opposite to and insulated from the wiring, and electrically coupled to the substrate region.

A wide bandgap semiconductor device with an adjustable voltage level includes a wide bandgap semiconductor power unit and a level adjusting unit. The wide bandgap semiconductor power unit includes a source terminal, to which the level adjusting unit is electrically connected. The level adjusting unit provides a level shift voltage via the source terminal to adjust a driving voltage level of the wide bandgap semiconductor power unit. By adjusting the driving voltage level of the wide bandgap semiconductor power unit using the level adjusting unit, the wide bandgap semiconductor device may serve as a high-voltage enhancement-mode transistor to achieve reduced costs and an increased switching speed.

A semiconductor device package may include a leadframe having a first portion with first extended portions and a second portion with second extended portions. Mold material may encapsulate a portion of the leadframe and a portion of a semiconductor die mounted to the leadframe. A first set of contacts of the semiconductor die may be connected to a first surface of the first extended portions, while a second set of contacts may be connected to a first surface of the second extended portions. A mold-locking cavity having the mold material included therein may be disposed in contact with a second surface of the first extended portions opposed to the first surface of the first extended portions, a second surface of the second extended portions opposed to the first surface of the second extended portions, the first portion of the leadframe, and the second portion of the leadframe.

RF transistor amplifiers include an RF transistor amplifier die having a Group III nitride-based semiconductor layer structure and a plurality of gate terminals, a plurality of drain terminals, and at least one source terminal that are each on an upper surface of the semiconductor layer structure, an interconnect structure on an upper surface of the RF transistor amplifier die, and a coupling element between the RF transistor amplifier die and the interconnect structure that electrically connects the gate terminals, the drain terminals and the source terminal to the interconnect structure.

A packaged power device includes a ceramic package body having a top drain pad having a first area, a top source pad having a second area smaller than the first area, and a top gate pad having a third area smaller than the second area; a power device having a bottom surface affixed to a top drain pad, a die source pad coupled to the top source pad, and a die gate pad coupled to the top gate pad; and a ceramic lid affixed to the ceramic package body to form the packaged power device.

A packaged radio frequency transistor amplifier includes a package housing, an RF transistor amplifier die that is mounted within the package housing, a first capacitor die that is mounted within the package housing, an input leadframe that extends through the package housing to electrically connect to a gate terminal of the RF transistor amplifier die, and an output leadframe that extends through the package housing to electrically connect to a drain terminal of the RF transistor amplifier die. The output leadframe includes an output pad region, an output lead that extends outside of the package housing, and a first arm that extends from one of the output pad region and the output lead to be adjacent the first capacitor die.

A package structure is provided. The package structure includes a leadframe, a device, first protrusions, second protrusions, a conductive unit, and an encapsulation material. The device includes a substrate, an active layer, first electrodes, second electrodes and a third electrode. The first electrodes have different potentials than the second electrodes. The first electrodes and the second electrodes are arranged so that they alternate with each other. The first protrusions are disposed on each of the first electrodes. The second protrusions are disposed on each of the second electrodes. The first protrusions and the second protrusions are connected to the leadframe. The first side of the conductive unit is connected to the substrate of the device. The conductive unit is connected to the leadframe. The encapsulation material covers the device and the leadframe. The second side of the conductive unit is exposed from the encapsulation material.

Examples of integrated semiconductor devices are described. In one example, an integrated device includes first and second transistors formed on a substrate, where the transistors share a terminal metal feature to reduce a size of the integrated device. The terminal metal feature can include a shared source electrode metalization, for example, although other electrode metalizations can be shared. In other aspects, a first width of a gate of the first transistor can be greater than a second width of a gate of the second transistor, and the shared metalization can taper from the first width to the second width. The integrated device can also include a metal ground plane on a backside of the substrate, and the terminal metal feature can also include an in-source via for the shared source electrode metalization. The in-source via can electrically couple the shared source electrode metalization to the metal ground plane.

A semiconductor device includes an integrated circuit that is disposed at a first face side of a semiconductor substrate, the semiconductor substrate having a first face and a second face, the second face opposing the first face, the semiconductor substrate having a through hole from the first face to the second face; an external connection terminal that is disposed at the first face side; a conductive portion that is disposed in the through hole, the conductive portion being electrically connected to the external connection terminal; and an electronic element that is disposed at a second face side.