A transistor includes a semiconductor substrate having first and second terminals. An interconnect structure, on an upper surface of the substrate, is formed of layers of dielectric material and electrically conductive material. The conductive material includes a first pillar connected with the first terminal, a second pillar connected with the second terminal, and a shield system between the first and second pillars. The shield system includes forked structures formed in at least two conductive layers of the interconnect structure and at least partially surrounding segments of the second pillar. The shield system may additionally include shield traces formed in a first conductive layer positioned between gate fingers and the first pillars and/or the shield system may include shield runners that are located in an electrically conductive layer that is below a topmost electrically conductive layer with the first pillar being connected to a runner in the topmost conductive layer.

A semiconductor device has a first wiring extending in a first direction on a nitride semiconductor layer. A source electrode is electrically connected to the first wiring and extends in a second direction. A drain electrode extends in the second direction and includes a first and second portion extending in the second direction, spaced from each other in the first direction. An element isolation region is in the second nitride semiconductor layer between the first and second portions. A third portion extends in the second direction on the first and second portions. A gate electrode extends in the second direction on the second nitride semiconductor layer between the source electrode and the drain electrode. The portion includes holes therein aligned with each other along the second direction with the spacing between adjacent holes in the second direction increasing with increasing distance in the second direction from the first wiring.

Packaged RF transistor amplifiers are provided that include a flat no-lead overmold package that includes a die pad, a plurality of terminal pads and an overmold encapsulation that at least partially covers the die pad and the terminal pads and an RF transistor amplifier die mounted on the die pad and at least partially covered by the overmold encapsulation. These packaged RF transistor amplifiers may have an output power density of at least 3.0 W/mm.sup.2.

A first interconnect on an interconnect level connects a first subset of PMOS drains together of a CMOS device. A second interconnect on the interconnect level connects a second subset of the PMOS drains together. The second subset of the PMOS drains is different than the first subset of the PMOS drains. The first interconnect and the second interconnect are disconnected on the interconnect level. A third interconnect on the interconnect level connects a first subset of NMOS drains together of the CMOS device. A fourth interconnect on the interconnect level connects a second subset of the NMOS drains together. The second subset of the NMOS drains is different than the first subset of the NMOS drains. The third interconnect and the fourth interconnect are disconnected on the interconnect level. The first, second, third, and fourth interconnects are coupled together though at least one other interconnect level.

A semiconductor device includes: a high-side transistor having a first gate electrode, first drain electrodes and first source electrodes; a low-side transistor having a second gate electrode, second drain electrodes and second source electrodes; a plurality of first drain pads that are disposed above the first drain electrodes and are electrically connected to the first drain electrodes; a plurality of first source pads that are disposed above the second source electrodes and are electrically connected to the second source electrodes; a plurality of first common interconnects that are disposed above the first source electrodes and above the second drain electrodes and are electrically connected to the first source electrodes and the second drain electrodes; and a plurality of second common interconnects that are connected to the first common interconnects, and extend in a direction that intersects with the first common interconnects.

When an ESD element is operated, for the purpose of suppressing heat generation and causing uniform current to flow through all channels of all transistors included in the ESD element, various substrate potentials existing in the transistors and the channels of a multi finger type ESD element are electrically connected via a low resistance substrate, and further, are set to a potential that is different from a Vss potential. In this manner, the current is uniformized and heat generation is suppressed through low voltage operation to improve an ESD tolerance.

There is provided a semiconductor device including a multi-gate transistor having a plurality of gates in a common active region, in which the multi-gate transistor has a comb-shaped metal structure in which a first metal is drawn out and bundled in a W length direction from contacts arranged in a single row in each of a source region and a drain region, and the multi-gate transistor has a wiring layout in which a root section of the first metal coincides immediately above an end of the source region and the drain region or is disposed inside the end of the source region and the drain region in the W length direction.

A semiconductor device includes: diffusion layers that are formed over a semiconductor substrate in a first direction, that are separated from one another by separation regions, and that serve as drain regions or source regions of respective transistors; a gate electrode of the transistors, which is formed in the first direction so as to straddle the diffusion layers; gate extraction wirings that are formed above the separation regions so as to sandwich therebetween the individual diffusion layers in the first direction, that are electrically coupled to the gate electrode above the separation regions, and that supply a gate signal to the gate electrode.

A chip package structure is provided. The chip package structure includes a first substrate. The chip package structure includes a conductive via structure passing through the first substrate. The chip package structure includes a chip over a first surface of the first substrate. The chip package structure includes a barrier layer over a second surface of the first substrate. The chip package structure includes an insulating layer over the barrier layer. The chip package structure includes a conductive pad over the insulating layer and passing through the insulating layer and the barrier layer to connect with the conductive via structure. The chip package structure includes a conductive bump over the conductive pad.

A semiconductor device comprising a switch and a method of making the same. The device has a layout that includes one or more rectangular unit cells. Each unit cell includes a gate that divides the unit cell into four corner regions. Each unit cell also includes a source comprising first and second source regions located in respective opposite corner regions of the unit cell. Each unit cell further includes a drain comprising first and second drain regions located in respective opposite corner regions of the unit cell. Each unit cell also includes a plurality of connection members extending over the gate, source and drain for providing electrical connections to the gate, source and drain.