A gas sensor is described for measuring a concentration of an analysis gas based on a thermal conductivity principle, including at least one analysis heating element situated on a first diaphragm for heating the analysis gas, a reference heating element situated on a second diaphragm for heating a reference gas, at least one evaluation electronics unit for measuring a resistance change of the analysis heating element caused by the analysis gas in relation to an electrical resistance of the reference heating element, the first diaphragm and the second diaphragm being situated adjacent to one another in a sensor substrate, due to a base substrate situated on one side on the sensor substrate, a measuring volume is formable between the first diaphragm and the base substrate and a reference volume is formable between the second diaphragm and the base substrate.

A gas sensor for detecting a gas in an environment is disclosed. The gas sensor comprises a housing having a cavity and a vent hole within the housing and a distributed element resonator within the cavity. The cavity includes a bottom surface and a top surface, and the housing is configured to receive the gas from the environment into the cavity through the vent hole. The distributed element resonator has an input terminal configured to receive a radio frequency input signal and an output terminal configured to produce an output signal.

A gas sensor for detecting a gas in an environment is disclosed. The gas sensor comprises a housing having a cavity and a vent hole within the housing and a distributed element resonator within the cavity. The cavity includes a bottom surface and a top surface, and the housing is configured to receive the gas from the environment into the cavity through the vent hole. The distributed element resonator has an input terminal configured to receive a radio frequency input signal and an output terminal configured to produce an output signal.

In one aspect, an example method includes (a) determining, via a thermal conductivity sensor of an automobile damage detection device, one or more thermal conductivities at one or more locations on an automobile; (b) transmitting, via a network interface of the automobile damage detection device, a request for anticipated thermal conductivity data from an automobile claims system, wherein the anticipated thermal conductivity data corresponds to anticipated thermal conductivities at the one or more locations on the automobile; (c) in response to transmitting the request, receiving, via the network interface from the automobile claims system, the anticipated thermal conductivity data; and (d) in response to receiving, from the automobile claims system, the anticipated thermal conductivity data, displaying, via a graphical user interface, a graphical representation of the determined one or more thermal conductivities and the anticipated thermal conductivity data.

In one aspect, an example method includes (a) determining, via a thermal conductivity sensor of an automobile damage detection device, one or more thermal conductivities at one or more locations on an automobile; (b) transmitting, via a network interface of the automobile damage detection device, a request for anticipated thermal conductivity data from an automobile claims system, wherein the anticipated thermal conductivity data corresponds to anticipated thermal conductivities at the one or more locations on the automobile; (c) in response to transmitting the request, receiving, via the network interface from the automobile claims system, the anticipated thermal conductivity data; and (d) in response to receiving, from the automobile claims system, the anticipated thermal conductivity data, displaying, via a graphical user interface, a graphical representation of the determined one or more thermal conductivities and the anticipated thermal conductivity data.

A sensor for detecting at least one property of a fluid medium in at least one measuring chamber, for detecting an H.sub.2 fraction in a measuring gas. The sensor includes at least a first sensor element to detect a heat conductivity of the fluid medium and output a first measuring signal, a second sensor element including a semiconducting metal oxide and designed to output a second measuring signal, a third sensor element for detecting a physical property of the fluid medium, the third sensor element differing from the first sensor element and the second sensor element with regard to the detected physical property and being designed to output a third measuring signal, and an electronic evaluation unit for evaluating the first, second, and third measuring signal. The electronic evaluation unit is designed to change operating parameters of the first and/or second and/or third sensor element.

A sensor for detecting at least one property of a fluid medium in at least one measuring chamber, for detecting an H.sub.2 fraction in a measuring gas. The sensor includes at least a first sensor element to detect a heat conductivity of the fluid medium and output a first measuring signal, a second sensor element including a semiconducting metal oxide and designed to output a second measuring signal, a third sensor element for detecting a physical property of the fluid medium, the third sensor element differing from the first sensor element and the second sensor element with regard to the detected physical property and being designed to output a third measuring signal, and an electronic evaluation unit for evaluating the first, second, and third measuring signal. The electronic evaluation unit is designed to change operating parameters of the first and/or second and/or third sensor element.

A gas sensor device includes a sensing element including a heating element and electronic circuitry in connection with the heating element. The sensing element forms resistive element in a circuit of the electronic circuitry. The electronic circuity operates the sensing element in a trigger mode via a pulsed energy input to the heating element at a first duty cycle and in a primary mode via a pulsed energy input to the heating element at a second duty cycle, which is greater than the first duty cycle. The electronic circuitry is further configured to measure a response of the sensing element over time during each pulse of a plurality of pulses of the pulsed energy input. The primary mode is entered upon measurement of a value of a response at or above a threshold value in the trigger mode of operation.

A gas sensor device includes a sensing element including a heating element and electronic circuitry in connection with the heating element. The sensing element forms resistive element in a circuit of the electronic circuitry. The electronic circuity operates the sensing element in a trigger mode via a pulsed energy input to the heating element at a first duty cycle and in a primary mode via a pulsed energy input to the heating element at a second duty cycle, which is greater than the first duty cycle. The electronic circuitry is further configured to measure a response of the sensing element over time during each pulse of a plurality of pulses of the pulsed energy input. The primary mode is entered upon measurement of a value of a response at or above a threshold value in the trigger mode of operation.

A method for surface characterization of a porous solid or powder sample using flowing gas includes a controller that controls mass flow of a carrier gas and an adsorptive gas to form a mixture having a target concentration of the adsorptive gas over the sample, determining adsorptive gas concentration based on signals from a detector disposed downstream of the sample, automatically repeating the controlling and determining steps for a plurality of different target concentrations, and generating an isotherm for the sample based on the adsorptive gas concentration for the plurality of different target concentrations. The method may include immersing the sample in liquid nitrogen to cool the sample for all, or at least a portion of each of the different target concentrations. The target concentrations may vary from less than 5% to greater than 95%, and may vary in a stepwise manner.