A package for a use in a package-on-package (PoP) device and a method of forming is provided. The package includes a substrate, a polymer layer formed on the substrate, a first via formed in the polymer layer, and a material disposed in the first via to form a first passive device. The material may be a high dielectric constant dielectric material in order to form a capacitor or a resistive material to form a resistor.

The object is to provide a technology for enabling detection of the voltage resistance in an assembled snubber substrate. A semiconductor device includes: a snubber substrate fixed to a base while being spaced from a p electrode and an n electrode; a snubber circuit disposed on the snubber substrate and electrically connected to the p electrode and the n electrode; and a semiconductor element electrically connected to the snubber circuit. The base includes an insulating component insulating the p electrode, the n electrode, and the snubber substrate from one another.

A logic cell including a fixed assembly including a first electrode, a mobile assembly including a second electrode, and third, fourth, and fifth electrodes, wherein: the first, second, third, fourth, and fifth electrodes are insulated from one another; the first and second electrodes define a capacitor variable according to the position of the mobile assembly relative to the fixed assembly; the third electrode is connected to a node of application of a first logic input signal; the fourth electrode is connected to a node of application of a second logic input signal; the fifth electrode is connected to a reference node; and the position of the second electrode relative to the first electrode is a function of a combination of the first and second logic input signals.

A semiconductor device is disclosed. In one example, the semiconductor device includes: an electronic component having a top surface, a bottom surface, and two end portions; a plurality of contacts disposed on the top surface; and a plurality of metal nodes disposed on the plurality of contacts. The plurality of contacts includes two end contacts disposed at the two end portions respectively and at least one intermediate contact disposed between the two end contacts. The plurality of metal nodes includes two end metal nodes disposed on the two end contacts respectively and at least one intermediate metal node disposed on the at least one intermediate contact.

The object is to provide a technology for enabling detection of the voltage resistance in an assembled snubber substrate. A semiconductor device includes: a snubber substrate fixed to a base while being spaced from a p electrode and an n electrode; a snubber circuit disposed on the snubber substrate and electrically connected to the p electrode and the n electrode; and a semiconductor element electrically connected to the snubber circuit. The base includes an insulating component insulating the p electrode, the n electrode, and the snubber substrate from one another.

Embodiments include package substrates and a method of forming the package substrates. A package substrate includes a dielectric having a cavity that has a footprint, a resistor embedded in the cavity of the dielectric, and a plurality of traces on the resistor, where a plurality of surfaces of the resistor are activated surfaces. The resistor may also have a plurality of sidewalls which may be activated sidewalls and tapered. The dielectric may include metallization particles/ions. The resistor may include resistive materials, such as nickel-phosphorus (NiP), aluminum-nitride (AlN), and/or titanium-nitride (TiN). The package substrate may further include a first resistor embedded adjacently to the resistor. The first resistor may have a first footprint of a first cavity that is different than the footprint of the cavity of the resistor. The resistor may have a resistance value that is thus different than a first resistance value of the first resistor.

A semiconductor integrated circuit device includes a chip main circuit, a damper and a passive component. The chip main circuit is coupled to a power source and performs a predetermined function. The damper is coupled to an output terminal of the chip main circuit. The passive component is coupled to the chip main circuit via the damper.

A semiconductor power conversion device includes a plurality of device cells in different portions of the active area, each including a respective gate electrode. The device includes a gate pad having a plurality of integrated resistors, each having a respective resistance. The device includes a first gate bus extending between the gate pad and the plurality of gate electrodes in a first portion of the active area. The plurality of gate electrodes in the first area is electrically connected to an external gate connection via a first integrated resistor and the first gate bus, and wherein the plurality of gate electrodes in a second portion of the active area is electrically connected to the external gate connection via a second integrated resistor, wherein the first and second integrated resistors have substantially different respective resistance values.

A current sensing resistor including: a first terminal and a second terminal which are made from an electrically conductive metal material; and a resistive element disposed between the first terminal and the second terminal. The resistive element, the first terminal, and the second terminal constitute a laminate in a thickness direction. The laminate has a size less than or equal to 5 mm.

A first conductive routing structure is electrically connected to a first electronic component. A second conductive routing structure is electrically connected to a second electronic component. An additive deposition process deposits a material over a surface of a processed wafer to form a conductive or resistive structure, which extends from a portion of the first conductive routing structure to a portion of the second conductive routing structure, to configure a circuit including the first and second electronic components.