A sensor device, a method for operating a sensor device and an electronic assembly comprising a sensor device are disclosed. In an embodiment a sensor device includes a first sensor unit and a second sensor unit in a common housing, wherein each of the first and second sensor units comprises a heater element and a temperature sensor element, wherein the housing comprises a cover element having an opening, the cover element covering the first sensor unit, and wherein the opening is arranged over the second sensor unit.

A combustion analyzer system includes an analyzer unit, a primary analysis probe and one or more remote probes. The analyzer unit includes a condensation removal unit and two or more electrochemical sensors to detect at least oxygen and carbon monoxide. The analyzer unit also includes a means for sealing or isolating the electrochemical sensor inputs to prevent oxidation of the reactive elements when the unit is not in use.

An artificial olfactory sensing system includes a sensor unit. The sensor unit includes a semiconductor device equipped with a transistor and a sensor cell in which an olfactory receptor is manifested on a lipid film. A proton adsorption film is formed on a gate electrode of the transistor. A physiological aqueous solution is disposed on the proton adsorption film. Then, the sensor cell is disposed in the physiological aqueous solution. A proton is adsorbed onto the proton adsorption film. When the olfactory receptor recognizes an odor molecule, the positive ions in the physiological aqueous solution flow from an ion channel of the olfactory receptor into the sensor cell. As a result, the proton is dissociated from the proton adsorption film into the physiological aqueous solution, and the potential of the gate electrode is changed.

A gas detecting device is disclosed and comprises a main body, a suspended particle sensing module and a gas sensing module, wherein the main body includes a first sensing area and a second sensing area. A suspended particle sensing module disposed within the first sensing area includes an irradiating mechanism, a first gas transporting actuator, a laser device and a light sensing device. The first gas transporting actuator transmits air to the first sensing area, the suspended particles in the air is irradiated by the laser beam emitted from the laser device to generate scattered light spots for the light sensing device to detect the suspended particles. The gas sensing module disposed within the second sensing area includes a gas sensor and a second gas transporting actuator. The second gas transporting actuator transmits air to the second sensing area, and the gas sensing device detects a gas composition contained in the air.

Infrared gas detection system comprising a gas inlet, an infrared gas analyzer connected to the gas inlet and a secondary gas sensor connected to the gas inlet, and an evaluation device evaluating the measurement signals from both the infrared gas analyzer and from the secondary gas sensor, such that a gas is identified only if both the infrared measurement signal and the secondary measurement signal coincide in time.

According to one embodiment, a sensor includes a base including a first region and a second region; and a first sensor section. The first sensor section includes a first support portion fixed to the first region, a first structure, and a first film portion. The first structure is supported by the first support portion. The first structure includes a first resistance member. A first direction from the second region to the first structure crosses a second direction from the first region to the second region. The first film portion is fixed to the first region. A first gap is provided between the second region and the first film portion. A second gap is provided between the first film portion and the first structure.

Provided is a hydrogen concentration measuring device capable of measuring with high accuracy a hydrogen concentration over an extensive range by a simple configuration. The device includes: a sensor chip which detects the electric resistance of a sensing film; an optical measurement unit which detects the transmitted light intensity of the film; and a controller. The controller performs measurement processing such that a hydrogen concentration in the gas atmosphere is measured based on the detected electric resistance in a first measurement range and based on the detected transmitted light intensity in a second measurement range and is determined so as to reduce a difference between the hydrogen concentration based on the detected electric resistance and the hydrogen concentration based on the detected transmitted light intensity in the overlap of the first measurement range and the second measurement range.

Apparatus for determining concentration of a targeted gas in environmental air, the apparatus includes a non-dispersive infrared (NDIR) sensor, a pressure sensor coupled in fluid communication with an interior of the NDIR sensor; and a processor. The processor is configured to receive pressure data from the pressure sensor based on gas pressure within an interior of the NDIR sensor, receive a target-gas concentration signal from the NDIR sensor, and produce a pressure-compensated concentration signal based on the target-gas concentration signal, a predetermined reference pressure and the pressure data from the pressure sensor.

Embodiments of a gas detector with a first gas sensor having a first gas specificity and a first response time and a second gas sensor having a second gas specificity and a second response time. The first gas specificity is different than the second gas specificity, the first response time is different than the second response time, or both the first gas specificity and the first response time are different than the second gas specificity and the second response time. A readout and analysis circuit is coupled to the first and second gas sensors to read and analyze data from the first and second gas sensors, and a control circuit is coupled to the readout and analysis circuit and to the first and second gas sensors to execute logic that operates the first gas sensor, the second gas sensor, or both the first and second gas sensors.

Apparatus and associated methods relate to height-differentiated gas detection sensors attached to one or more tethers suspended from an unmanned air vehicle (UAV) platform. In an illustrative example, each of the gas sensors, for example, may communicate gas detection signal information to a signal processing module onboard the UAV platform. Each of the tethers, for example, may provide a data channel from the sensor to the signal processing module. Some tethers, for example, may supply operating power to one or more of the gas detection sensors. The UAV platform may advantageously deploy one or more low-cost, disposable, tethered gas detection sensors into vertically confined spaces (e.g., chimneys, vents), or along a length of pipeline, for example. The sensors may be deployed at a minimum predetermined height providing separation from the UAV to attenuate prop-wash with respect to the sensors.