Disclosed are a quantum chip test structure and a fabrication method therefor, and a test method and a fabrication method for a quantum chip. The quantum chip test structure includes: a superconducting Josephson junction and a connection structure of the superconducting Josephson junction that are located on a substrate; a first isolation layer located on the connection structure, where a connection window penetrating through the first isolation layer is formed in the first isolation layer; a second isolation layer located on the first isolation layer, where a deposition window is formed in the second isolation layer; and an electrical connection portion located in the connection window and an electrical connection layer located in the deposition window, and the electrical connection layer is configured to implement electrical contact with a test device.

A semiconductor device includes a signal processing circuit configured to generate an output signal, an output pad, an output line connecting the signal processing circuit to the output pad, the output signal from the signal processing circuit being output from the output pad through the output line, a shorting pad formed in the output line, a switch connected between the shorting pad and the output pad, and configured to connect the signal processing circuit to the output pad when the switch is on, and disconnect the signal processing circuit from the output pad when the switch is off, and a wiring line connecting the shorting pad to the output pad.

A semiconductor device includes first and second contact parts that are disposed close to each other with an interval therebetween and form a screw hole (connection area) to which an external connection terminal is connected. The first contact part extends from a side of a case via a first linkage part that extends from the side, and the second contact part extends from the side via a second linkage part that extends from the side. The first and second linkage parts are disposed away from each other by at least a certain interval. In this way, the semiconductor device is allowed to have first and second semiconductor chips connected in parallel with each other and function as a semiconductor device. In addition, electrical characteristics of the first and second semiconductor chips of the semiconductor device are individually measured.

The present disclosure provides an RF power device including: a single RF power transistor; a pad spaced apart from the single RF power transistor and configured to transmit a temperature and RF characteristic information of the single RF power transistor to an outside; and a temperature and RF characteristic detector connected between the pad and the ground and configured to detect the temperature and the RF characteristics of the single RF power transistor, and is characterized in that the ground is connected to the single RF power transistor, and the single RF power transistor, the pad, and the temperature and RF characteristic detector are manufactured on the same wafer.

An image sensor includes a pixel array and a test region adjacent to the pixel array. Each of the pixel array and the test region include a plurality of pixels, and each of the pixels in the test region include: a substrate including a photoelectric conversion element; and a transparent layer formed over the substrate and having an inclined top surface.

The disclosed technology relates generally to semiconductor devices, and more particularly to semiconductor devices including a metal-oxide-semiconductor (MOS) transistor and are configured for accelerating and monitoring degradation of the gate dielectric of the MOS transistor. In one aspect, a semiconductor device configured with gate dielectric monitoring capability comprises a metal-oxide-semiconductor (MOS) transistor including a source, a drain, a gate, and a backgate region formed in a semiconductor substrate. The semiconductor device additionally comprises a bipolar junction transistor (BJT) including a collector, a base, and an emitter formed in the semiconductor substrate, wherein the backgate region of the MOS transistor serves as the base of the BJT and is independently accessible for activating the BJT. The MOS transistor and the BJT are configured to be concurrently activated by biasing the backgate region independently from the source of the MOS transistor, such that the base of the BJT injects carriers of a first charge type into the backgate region of the MOS transistor, where the first charge type is opposite charge type to channel current carriers.

A computer-implemented method may determine a sheet resistance of a base layer of a bipolar junction transistor (BJT). A computer-implemented method may estimate a quiescent current based on the sheet resistance of the base layer. A computer-implemented method may reject a power amplifier die based on the quiescent current not satisfying a threshold level.

A purpose of the present invention is to provide a technique capable of suppressing an electric discharge during evaluation. A semiconductor device includes: a semiconductor base body having an element region and a terminal region; a plurality of electrode pads disposed in an area that is in the element region of the semiconductor base body and is separated from the terminal region, an insulating protection film having an opening provided above each of the electrode pads; and a plurality of conductive layers disposed on the protection film and electrically connected to the plurality of electrode pads, respectively, through the opening. In a planar view, each of the conductive layers is extended to the terminal region or the vicinity of the terminal region.

A semiconductor device includes a signal processing circuit configured to generate an output signal, an output pad, an output line connecting the signal processing circuit to the output pad, the output signal from the signal processing circuit being output from the output pad through the output line, a shorting pad formed in the output line, a switch connected between the shorting pad and the output pad, and configured to connect the signal processing circuit to the output pad when the switch is on, and disconnect the signal processing circuit from the output pad when the switch is off, and a wiring line connecting the shorting pad to the output pad.

A purpose of the present invention is to provide a semiconductor device that can restrain occurrence of partial discharge in evaluation of electric characteristics and can carry out failure analysis from the upper side of a measurement object. A semiconductor device according to the present invention includes: at least one electrode; a protective layer having at least one opening part provided such that a portion of the electrode is exposed at the opening part, and being formed to cover the other portion of the electrode excluding the portion of the electrode exposed at the opening part, the protective layer being insulative; and a conductive layer formed so as to cover the protective layer and the opening part and be directly connected to the electrode at the opening part.