A resistor is provided with a resistance body and a pair of electrodes connected to the resistance body (a first electrode body, a second electrode body), the resistance body being arranged so as to be at least separated away from a substrate board (a circuit board) when mounted on the substrate board (the circuit board), wherein the resistor has the oxide film on at least one of the resistance body and each of the electrodes (the first electrode body, the second electrode body) at a boundary portion (a bonded portion, a bonded portion) between the resistance body and each of the electrodes (the first electrode body, the second electrode body) on the mounting surface of the resistor.

The present invention relates to a shunt resistor for current detection. The shunt resistor (1) includes: a resistance element (5) having a plate shape; and electrodes (6, 7) connected to both end surfaces (5a, 5b) of the resistance element (5), wherein the electrodes (6, 7) have cut portions (11, 12), respectively, the cut portions (11, 12) extending parallel to joint portions (8, 9) of the resistance element (5) and the electrodes (6, 7), and each of the cut portions (11, 12) is located at a position where a relationship Y0.80X-1.36 holds, where Y is a distance from each joint portion (6, 7) to each cut portion (11, 12), and X is a length of the joint portions (6, 7) in a width direction of the electrodes (6, 7).

The present invention relates to a shunt resistor for current detection. The shunt resistor (1) includes: a resistance element (5) having a plate shape; and electrodes (6, 7) connected to both end surfaces (5a, 5b) of the resistance element (5), wherein the electrodes (6, 7) have cut portions (11, 12), respectively, the cut portions (11, 12) extending parallel to joint portions (8, 9) of the resistance element (5) and the electrodes (6, 7), and each of the cut portions (11, 12) is located at a position where a relationship Y0.80X-1.36 holds, where Y is a distance from each joint portion (6, 7) to each cut portion (11, 12), and X is a length of the joint portions (6, 7) in a width direction of the electrodes (6, 7).

The present application relates generally to programmable impedances and employs an auxiliary impedance in parallel to a primary programmable impedance to augment the performance of the primary programmable impedance at lower impedance values.

The present application relates generally to programmable impedances and employs an auxiliary impedance in parallel to a primary programmable impedance to augment the performance of the primary programmable impedance at lower impedance values.

The shunt resistor includes: the resistance body; and the electrode joined to the resistance body and made of aluminum as a main component. In addition, the shunt resistor includes the plated portion configured to cover at least the joined portions between the resistance body and the electrode the plated portion being configured of a plating having higher specific resistance than the resistance body.

The shunt resistor includes: the resistance body; and the electrode joined to the resistance body and made of aluminum as a main component. In addition, the shunt resistor includes the plated portion configured to cover at least the joined portions between the resistance body and the electrode the plated portion being configured of a plating having higher specific resistance than the resistance body.

A multifunctional assembly having a resistive element a conductive element in electrical communication with the resistive element, the conductive element defining at least one of a plurality of multifunctional zones of the resistive element, wherein the conductive element is configured to direct a flow of electricity across at least one of the plurality of multifunctional zones of the resistive element in a preselected manner.

A multifunctional assembly having a resistive element a conductive element in electrical communication with the resistive element, the conductive element defining at least one of a plurality of multifunctional zones of the resistive element, wherein the conductive element is configured to direct a flow of electricity across at least one of the plurality of multifunctional zones of the resistive element in a preselected manner.

The composite piezo resistive sensor device is a sensor device with high sensitivity, as well as unique and novel properties. More specifically, the device has a combination of a 3-D structure and a graphene mesh. The device has a cantilever structure that can be used to detect impulses in the surrounding environment to identify characteristics such as kinetic energy, resonant frequency, mass, density, shape, surface features, and inertial moments to infer the presence and prevalence of impulse sources. The composite silicon and graphene structure creates a mechanical moment of inertia that amplifies localized deformation and induces unique harmonic modes in the piezo resistor. The composite piezo resistor is much more sensitive and produces richer, continuous signal outputs without requiring surface functionalization, and it therefore has the ability to assay a wide range of micro and nano particles, as well inferring more generally the presence of impulse sources.