A semiconductor component is provided in the present invention. The semiconductor component includes a substrate, a semiconductor working layer disposed on the substrate, an insulating layer disposed on an upper surface of the semiconductor working layer, plural conducting electrodes, and at least a metal layer floated on the upper surface of the semiconductor working layer and within the insulating layer. The conducting electrodes include plural working electrodes disposed within the insulating layer and plural connecting electrodes disposed over the upper surface of the semiconductor working layer. By floating the at least a metal layer on the semiconductor working layer and controlling occupied area of the metal layer and the conducting electrodes on the upper surface of the semiconductor working layer, heat dissipation performance of the semiconductor component can be effectively increased.

A face-down mountable chip-size package semiconductor device includes a semiconductor layer and N (N is an integer greater than or equal to three) vertical MOS transistors in the semiconductor layer. Each of the N vertical MOS transistors includes, on an upper surface of the semiconductor layer, a gate pad electrically connected to a gate electrode of the vertical MOS transistor and one or more source pads electrically connected to a source electrode of the vertical MOS transistor. The semiconductor layer includes a semiconductor substrate. The semiconductor substrate functions as a common drain region for the N vertical MOS transistors. For each of the N vertical MOS transistors, a surface area of the vertical MOS transistor in a plan view of the semiconductor layer increases with an increase in a maximum specified current of the vertical MOS transistor.

A high-frequency transistor includes a source electrode, a drain electrode, a gate electrode, and a gate drive line that applies a voltage to the gate electrode. An impedance adjustment circuit is connected between the gate electrode and the gate drive line. A characteristic impedance of the gate electrode is Z1, when a connecting point between the impedance adjustment circuit and the gate electrode is viewed from the impedance adjustment circuit. A characteristic impedance of the gate drive line is Z2, when a connecting point between the impedance adjustment circuit and the gate drive line is viewed from the impedance adjustment circuit. X that denotes a characteristic impedance of the impedance adjustment circuit is a value between Z1 and Z2.

A chip-on-film package includes a base substrate on which a first pad region, a second pad region, and a third region located between the first pad region and the second pad region are defined, a dummy pad disposed on the first pad region, input pads disposed on the first pad region, output pads disposed on the second region, a first detection line disposed on the base substrate, and a second detection line disposed on the base substrate. The first detection line is connected to a first input pad and a second input pad via the second pad region to form a first loop between the first input pad and the second input pad, and the second detection line is connected to the dummy pad and the first detection line via the third region to form a second loop between the dummy pad and the first input pad.

A semiconductor device includes a substrate and a metallization layer. The substrate has an active region that includes opposite first and second edges. The metallization layer is disposed above the substrate, and includes a pair of metal lines and a metal plate. The metal lines extend from an outer periphery of the active region into the active region and toward the second edge of the active region. The metal plate interconnects the metal lines and at least a portion of which is disposed at the outer periphery of the active region.

According to example configurations herein, a leadframe includes a first conductive strip, a second conductive strip, and a third conductive strip disposed substantially adjacent and substantially parallel to each other. A semiconductor chip substrate includes a first array of switch circuits disposed adjacent and parallel to a second array of switch circuits. Source nodes in switch circuits of the first array are disposed substantially adjacent and substantially parallel to source nodes in switch circuits of the second array. When the semiconductor chip and the leadframe device are combined to form a circuit package, a connectivity interface between the semiconductor chip and conductive strips in the circuit package couples each of the source nodes in switch circuits of the first array and each of the multiple source nodes in switch circuits of the second array to a common conductive strip in the leadframe device.

A print head substrate includes: a substrate surface including a plurality of printing elements and a plurality of pads disposed along a first side and electrically connected to the printing elements, the substrate surface having an acute angle portion formed by the first side and a second side; and a test element group (TEG) area including a TEG not electrically connected to the printing elements, at least a part of the TEG area being located between the second side and a pad closest to a vertex of the acute angle portion among the pads.

A transistor device includes a semiconductor structure, a plurality of gate fingers extending on the semiconductor structure in a first direction, a plurality of gate interconnects that each have a first end and a second end extending on the semiconductor structure in the first direction, wherein each gate interconnect is connected to a respective gate finger by a plurality of first conductive vias, and a plurality of gate runners extending on the semiconductor structure in the first direction. At least one gate interconnect of the gate interconnects is connected to one of the gate runners by a second conductive via at an interior position of the at least one gate interconnect that is remote from the first end and the second end of the at least one gate interconnect.

A semiconductor device assembly includes a substrate and a die coupled to the substrate, the die including a first contact pad electrically coupled to a first circuit on the die including an active circuit element, a first TSV electrically coupling the first contact pad to a first backside contact pad, and a second contact pad electrically coupled to a second circuit including only passive circuit elements. The substrate includes a substrate contact electrically coupled to the first and second contact pads. The assembly can further include a second die including a third contact pad electrically coupled to a third circuit including a second active circuit element, and a fourth contact pad electrically coupled to a fourth circuit on the second die including only passive circuit elements. The substrate contact can be electrically coupled to the third contact pad, but electrically disconnected from the fourth contact pad.

The present invention discloses a modularized circuit for isolated circuit, wherein the isolated circuit includes at least two circuit components connecting in parallel and/or series, the circuit components, according to a circuit connection configuration, weld corresponding pins of the components directly, forming an integrated module in accordance with a desired connection method of the circuit, and saving circuit boards and wires; the circuit components are designed as a parallelepiped, and a plurality of bonding pads are arranged on part of an area on a surface of the parallelepiped. Due to constructing a circuit unit by welding connections in a way of building blocks, welding directly between components in a 3D space, comparing to the circuits limited in a circuit board plane as a PCB, it owns a wider design space.