A method for on-line monitoring an electrolytic capacitor condition comprising: measuring a voltage ripple across the electrolytic capacitor and the current ripple flowing through the electrolytic capacitor; measuring the temperature of the electrolytic capacitor; emulating the monitored electrolytic capacitor using a capacitor model comprising a capacitor and a solid state adjustable resistor, applying one of the measured ripple to the capacitor model, adjusting the solid state adjustable resistor to minimize the error between an estimated ripple provided by the capacitor model and the other measured ripple not applied to the capacitor model, and estimating an equivalent series resistance of the monitored electrolytic capacitor using value of the solid state adjustable resistor.

A method for on-line monitoring an electrolytic capacitor condition comprising: measuring a voltage ripple across the electrolytic capacitor and the current ripple flowing through the electrolytic capacitor; measuring the temperature of the electrolytic capacitor; emulating the monitored electrolytic capacitor using a capacitor model comprising a capacitor and a solid state adjustable resistor, applying one of the measured ripple to the capacitor model, adjusting the solid state adjustable resistor to minimize the error between an estimated ripple provided by the capacitor model and the other measured ripple not applied to the capacitor model, and estimating an equivalent series resistance of the monitored electrolytic capacitor using value of the solid state adjustable resistor.

The present disclosure relates to circuitry for determining a temperature coefficient value of a resistor. The circuitry comprises circuitry for supplying an AC current signal to the resistor, circuitry for measuring a first voltage across the resistor when the AC current signal is supplied; and processing circuitry configured to determine the temperature coefficient value based on the first voltage.

The present disclosure relates to circuitry for determining a temperature coefficient value of a resistor. The circuitry comprises circuitry for supplying an AC current signal to the resistor, circuitry for measuring a first voltage across the resistor when the AC current signal is supplied; and processing circuitry configured to determine the temperature coefficient value based on the first voltage.

A sensor device configured to accurately identify a volatile compound from water vapor even at high humidity, and a method for manufacturing the sensor device are provided. The sensor device includes a measuring transducer including a pixel array on which volatile compounds and water vapor are condensed and a sensitive porous dielectric layer provided in a form of a plurality of spheres constituting the pixel array, a temperature controller provided around the pixel array, and configured to control temperature of each of pixels constituting the pixel array and temperature of the pixel array, a detection device connected to the measuring transducer, and configured to detect a response pattern of the volatile compounds through the pixel array, an analyzer configured to process, classify, and store the response pattern, a stimulating source connected to the measuring transducer, and configured to stimulate the measuring transducer, and at least one processor.

A sensor device configured to accurately identify a volatile compound from water vapor even at high humidity, and a method for manufacturing the sensor device are provided. The sensor device includes a measuring transducer including a pixel array on which volatile compounds and water vapor are condensed and a sensitive porous dielectric layer provided in a form of a plurality of spheres constituting the pixel array, a temperature controller provided around the pixel array, and configured to control temperature of each of pixels constituting the pixel array and temperature of the pixel array, a detection device connected to the measuring transducer, and configured to detect a response pattern of the volatile compounds through the pixel array, an analyzer configured to process, classify, and store the response pattern, a stimulating source connected to the measuring transducer, and configured to stimulate the measuring transducer, and at least one processor.

A fluid state detection apparatus which can detect a short failure in which a constituent Wheatstone bridge circuit is shorted to a power supply. A combustible gas detection apparatus (1) judges that a short failure has occurred in a constant temperature control circuit (231) (S240) when a top potential V21 is equal to or greater than a first judgment value Vth1 and a difference D1 (=V11−V31) is equal to or greater than a second judgment value Vth2. As a result, apparatus (1) can distinguish “a state in which a bridge circuit (210) is shorted to a DC power supply (40) (where the constant temperature control circuit 231 is in a short failure state)” from “a state in which the resistance of the heat generation resistor (15) deceases due to a combustible gas (hydrogen)” based on the top potential V21 and the difference D1.

Disclosed here is a method for sensing temperature-dependent electrical switching response, comprising: exposing a polymer-carbon composite to a temperature change, wherein the polymer-carbon composite comprises (a) a semi-conductive or conductive carbon network intercalated with (b) a polymer matrix, wherein the carbon network comprises at least one covalently bonded carbon material, and wherein the polymer matrix comprises at least one polymer having a net electron withdrawing character and adapted to apply a gating effect on the conductive carbon; and detecting a change in electrical conductivity of the polymer-carbon composite of at least three orders of magnitude. Also disclosed is a smart switching device comprising the polymer-carbon composite and a switch triggerable by an increase or decrease in electrical conductivity of the polymer-carbon composite of at least three orders or magnitude.

Assessing material strength for additive manufacturing is provided. The method comprises calibrating a baseline electrical resistivity of a multi-phase additive material for a set dislocation density as a function of phase fraction and phase composition, wherein individual phases of the material have different electrical resistivity values. After the additive material has undergone a number of heating and cooling cycles during additive manufacturing the additive material is characterized for phase fraction, phase composition, and electrical resistivity. Dislocation density of the additive material is then determined according to electrical resistivity after additive manufacturing, accounting for effects of phase fraction and phase composition determined by characterization.

Assessing material strength for additive manufacturing is provided. The method comprises calibrating a baseline electrical resistivity of a multi-phase additive material for a set dislocation density as a function of phase fraction and phase composition, wherein individual phases of the material have different electrical resistivity values. After the additive material has undergone a number of heating and cooling cycles during additive manufacturing the additive material is characterized for phase fraction, phase composition, and electrical resistivity. Dislocation density of the additive material is then determined according to electrical resistivity after additive manufacturing, accounting for effects of phase fraction and phase composition determined by characterization.