Embodiments are described herein for a sensor device created for determining and monitoring quality and strength developments in concrete and other materials using temperature and electrical resistivity parameters. The embodiments described herein may be utilized in the construction industry for real-time monitoring of concrete and cement structures or for monitoring the strength and quality of soils, polymers, and liquid additives as well. According to various embodiments, alternating current (AC) electrical and temperature measurements may be performed to correlate to the quality and performance of the concrete, polymers, treated soils, and other materials. These measurements may be made by compact sensor devices that are configured to read both temperature and AC electrical measurements continuously to quantify the performance of materials.

A nanomaterial-based gas sensor system comprising a low voltage circuitry which includes a transducer to detect changes in electrical properties of a multi-channel gas sensor array, analog signal conditioning, and an A/D conversion to provide a signal to a digital back-end.

A processing apparatus is configured to receive a sense signal from a capacitive fluid sensor having a first electrode and a second electrode with a sensing region between the electrodes. The processing apparatus is configured to receive an alternating drive signal applied to the capacitive fluid sensor. The processing apparatus is configured to determine a complex impedance of the fluid sensor based on the sense signal and the drive signal. The complex impedance includes an in-phase component indicative of a conductivity quantity of a fluid in the sensing region and a quadrature component indicative of a capacitance quantity of the fluid sensor. The processing apparatus is configured to determine a temperature of the fluid in dependence on at least the determined capacitance quantity of the fluid sensor.

A novel approach, based on hybrid nanostructure gas sensors, to correlate metrics related to specific medical conditions to a signature created by the sensor's response to the Volatile Organic Compounds (VOCs) contained in human breath.

A sensor device includes a detection resistor having a resistance value changing according to a physical quantity and a reference resistor compared with the detection resistor, the reference resistor is configured by electrically connecting a first resistance circuit and a second resistance circuit. The first resistance circuit includes a first and a second resistive element having positive and negative resistance temperature coefficients, respectively, which are electrically connected. The second resistance circuit includes a third and a fourth resistive elements having a positive and a negative resistance temperature coefficient, respectively, which are electrically connected. The first resistance circuit is configured to generate a first deviation to either the positive or negative side with respect to a temperature change, and the second resistance circuit is configured to generate a second deviation to the side opposite to the positive or negative side where the first deviation is generated.

A method of enhancing judgment of a gas detector contains: dividing a voltage difference between an output signal voltage and an environmental detection voltage of the gas detector into several parts. Each of multiple detecting processes of the gas detector is captured by a microprocessor at the environmental detection voltage for ten times in each microsecond, and a predetermined detection time of each detecting process is 10 seconds. When the environmental detection voltage changes linearly, the predetermined detection time of each detecting process is shorten to 1/10 second/per time. After three successive detection processes change linearly, a warning device is started. Otherwise, the microprocessor compensates the output signal voltage and recovers the predetermined detection time when the environmental detection voltage changes so as to maintain the voltage difference at a certain value.

The present disclosure relates to a concept for checking at least one solder joint between a printed circuit board and a current sensor, including: measuring, by means of the current sensor, an electric current through the solder joint; measuring at least one temperature of the current sensor as a function of the electric current; and ascertaining a quality of the solder joint based on the temperature and the electric current.

A particulate matter detection device includes a sensor element and a detection control unit. The sensor element includes a particulate matter detection unit and a temperature compensation unit. The particulate matter detection unit includes a pair of detection electrodes on a deposition surface of a detection conductive layer. The temperature compensation unit includes a pair of temperature compensation electrodes on a non-deposition surface of a temperature compensation conductive layer. The detection electrodes and the temperature compensation electrodes are connected to a common ground terminal. The detection control unit detects a first output signal based on an electrical resistance between the detection electrodes and detects a second output signal based on an electrical resistance between the temperature compensation electrodes, and calculates a deposition amount of particulate matter on the basis of a differential output between the first output signal and the second output signal.

An electronic sensing system located on a printed circuit board is provided. The electronic sensing system including: a target gas sensor configured to detect a resistance of the target gas sensor; a reference sensor configured to detect a resistance of the reference sensor; a resistance comparator including a digital potentiometer, the resistance comparator being electrically connected to the target gas sensor and the reference sensor, wherein the digital potentiometer is configured to be adjusted to determine a first resistance in response to the resistance of the target gas sensor and a second resistance in response to the resistance of the reference sensor; and a system on a chip in electronic communication with the resistance comparator, the system on a chip being configured to determine a target gas concentration in response to the first resistance and the second resistance.

A method of enhancing judgment of a gas detector contains: dividing a voltage difference between an output signal voltage and an environmental detection voltage of the gas detector into several parts. Each of multiple detecting processes of the gas detector is captured by a microprocessor at the environmental detection voltage for ten times in each microsecond, and a predetermined detection time of each detecting process is 10 seconds. When the environmental detection voltage changes linearly, the predetermined detection time of each detecting process is shorten to 1/10 second/per time. After three successive detection processes change linearly, a warning device is started. Otherwise, the microprocessor compensates the output signal voltage and recovers the predetermined detection time when the environmental detection voltage changes so as to maintain the voltage difference at a certain value.