A gas sensor device includes gas sensors and switches. The switches are connected to the respective gas sensors in series. The gas sensors each include: a first conductive layer; a second conductive layer; a metal oxide layer disposed between the first conductive layer and the second conductive layer; and an insulation layer covering the first conductive layer, the second conductive layer, and the metal oxide layer and having an opening from which a portion of the second conductive layer is exposed. The resistance of the gas sensor is decreased when a gas containing a hydrogen atom comes into contact with the second conductive layer.

The invention relates to a non-contact printing method and system as well as to a printed sensor. The method includes the steps of disposing a substrate (130) between a discharge electrode (110) and a printing material (140) such that the substrate (130) is spaced apart from the printing material (140); and activating the discharge electrode (110) to generate an electric field between the substrate (130) and the printing material (140), wherein the printing material (140) moves onto a surface (132) of the substrate (130) when the electric field attracts the printing material (140) to the surface (132) of the substrate (130). A corresponding printing system and printed sensor are also provided.

The present application is directed to a multi-sensor gas sampling detection system and method for detecting and measuring the radicals in a radical gas stream and includes at least one radical gas generator in communication with at least one gas source. The radical gas generator may be configured to generate at least one radical gas stream which may be used within a processing chamber. As such, the processing chamber is in fluid communication with the radical gas generator. At least one analysis circuit in fluid communication with the radical gas generator may be used in the detection and measurement system. The analysis may be configured to receive a defined volume and/or flow rate of the radical gas stream. In one embodiment, the analysis circuit may be configured to react at least one reagent with radicals within the defined volume of the radical gas stream thereby forming at least one chemical species within at least one compound stream. At least one sensor module within the analysis circuit may be configured to measure a concentration of the chemical species within the compound stream. One or more flow measurement modules may be in fluid communication with the sensor module. During use, the flow measurement module may be configured to measure the volume of at least one of the compound stream and radical gas stream.

A gas sensor includes a chemiresistor having responsive to a specific gas vapor to be sensed such that a resistance of the chemiresistor changes responsive to exposure to the specific gas vapor. A data collection circuit is coupled to the chemiresistor to sense the change in resistance responsive to the specific gas vapor. An antenna is coupled to the data collection circuit to receive power from an RF interrogation signal, power the data collection circuit with the received power, and transmit a signal from the data collection circuit representative of the resistance of the chemiresistor.

This document provides methods, devices, and systems for detecting the presence, absence, or amount of one or more analytes. For example, this document provides methods for using graphene-based sensors to detect one or more analytes (e.g., proteins, nucleic acids, intact cells, intact viruses, intact microorganisms, and/or chemicals).

A portable electronic device and related methods are described using an integrated chemical sensor linked to a chemical sensor processing unit and being sensitive to the concentration of a component in a sample of air and further including an operating system providing instructions for the control of the portable device, wherein the chemical processing unit uses under operating conditions a first set of instructions and a second set of instructions stored within the portable device, wherein the first set of instructions is part of the operating system level of instructions and the second set of instructions is part of a user of instructions with the second set of instructions being linked to the operating system via a plugin interface and wherein the second set of instructions is communicated to the portable device from a remote computing system based on access to measurements and/or operating conditions of the chemical sensor.

A circuit arrangement comprises a first branch comprising a resistor of variable resistance and a diode-connected bipolar transistor and a second branch comprising a resistor of fixed resistance and another diode-connected bipolar transistor. A control loop reproduces a voltage drop at the resistor of variable resistance to a voltage drop at the resistor of fixed resistance. Output terminals are connected to the bipolar transistors to supply a differential voltage. The circuit arrangement may be used as an analog frontend circuit in a gas sensor or a temperature sensor arrangement.

A gas sensing device includes one or more chemo-resistive gas sensors; one or more heating elements for heating each of the gas sensors; a preprocessing block for filtering signal samples in order to generate filtered signal samples for each of the gas sensors; an information extraction block for generating representations for the filtered signal samples for each of the gas sensors based on dynamic characteristics of the received filtered signal samples of the respective gas sensor; and a decision making block for receiving the representations, wherein the decision making block includes a trained model based algorithm stage having an input layer and an output layer, wherein the decision making block includes trained models, wherein the decision making block creates sensing results based on output values of the output layer of the algorithm stage, and wherein the output values are created by using the trained models.

The invention relates to a hydrogen sensor (8) and a method for its production, a measuring device (2), and a method for measuring a hydrogen concentration. The hydrogen sensor (8) for measuring a hydrogen concentration in an environment (4) includes a substrate (10) on which a hydrogen-absorbing sensor medium (14) is applied as a thin film in a sensor region (12) communicating with the environment. The sensor medium (14) changes its volume depending on a hydrogen concentration in the sensor medium (14), and said change of the volume causes a variation of a mechanical strain introduced by the sensor medium (14) in the substrate (10). In a preferred embodiment, the substrate (10) of the hydrogen sensor (8) is a piezoresistive semiconductor, at least within the sensor region (12).

A wireless chemical sensor includes an electrical conductor and a material separated therefrom by an electric insulator. The electrical conductor is an unconnected open-circuit shaped for storage of an electric field and a magnetic field. In the presence of a time-varying magnetic field, the first electrical conductor resonates to generate harmonic electric and magnetic field responses. The material is positioned at a location lying within at least one of the electric and magnetic field responses so-generated. The material changes in electrical conductivity in the presence of a chemical-of-interest.