Abstract: The present disclosure includes sensing device embodiments. One sensing device includes a heater layer, a resistance detector layer, constructed and arranged to indicate a temperature value based upon a correlation to a detected resistance value, an electrode layer, and a sensing layer.

Abstract: A system automatically and continuously finds and aggregates the most relevant and current information about the people and things that a user cares about. The information gathering is based on current context (e.g., where the user is, what the user is doing, what the user is saying/typing, etc.). The result of the context based information gathering is presented ubiquitously on user interfaces of any of the various physical devices operated by the user.

Abstract: Embodiments of the present invention relate to a gas sensor comprising a flow channel, a concentration modulator positioned in the flow channel, a gas generator in contact with the flow channel, one or more gas detectors positioned downstream of the concentration modulator and gas generator and a pump.

Abstract: Embodiments of the present invention relate a gas sensor system comprising a gas generating device adapted to generate a test gas, a target gas sensor positioned near the gas generating device, a test gas sensor positioned near the gas generating device and in communication with the target gas sensor and wherein the test gas sensor is sensitive to the test gas.

Abstract: A system and method include generating at least one bubble in tissue using ultrasound. The at least one bubble generated is detected and correlated to gas saturation of the tissue.

Abstract: A sensor system for detection of gas with a modified ion selection FET. The FET may have a gate of low conductivity material for detection of a species in a fluid. A component such as a capacitor may be connected to an electrode of the FET, such as a source, in conjunction with the FET to reduce noise of the detection signal of the species. One or more current sources may provide a current through the FET, and through a resistor to provide a constant source-to-drain voltage. The system may have a bulk voltage selection of either that of a voltage approximately equal to the FET source voltage or greater than the FET source voltage. Also, a guard ring may be implemented in the FET for preventing leakage currents relative to the source or drain.

Abstract: A photoacoustic gas sensor includes a photoacoustic cell configured to receive a gas mixture having a first gas component and a second gas component. The photoacoustic gas sensor also includes a light source configured to provide light to the photoacoustic cell. The photoacoustic gas sensor further includes a photoacoustic cell controller configured to measure a concentration of the second gas component using a speed of sound through the gas mixture, where the speed of sound is determined based on an absorption associated with the first gas component. In addition, the photoacoustic gas sensor could include a temperature sensor configured to measure a temperature of the gas mixture, where the photoacoustic cell controller is configured to determine the concentration of the second gas component using the speed of sound and the temperature.

Abstract: A system for testing and calibrating gas sensors with gas stored in a strip of packets. The strip may be fed into a chamber having a defined volume of air. A packet may be punctured with a mechanism to release one or more gases into the volume of air to result in an air-gas mixture. New air may be moved into the chamber to push the mixture out of the chamber to a sensor for testing and/or calibration. Then another packet may be punctured to release one or more gases into the volume of new air in the chamber for another air-gas mixture. This mixture may be moved out of the chamber, in the same manner as the previous mixture, to another sensor for testing and/or calibration. This procedure may be repeated with additional packets on the strip.

Abstract: Embodiments of the present invention relate a gas sensor comprising a gas detector and a hydrocarbon gas generating device, wherein the hydrocarbon gas generating device is positioned to provide an amount of hydrocarbon gas to the gas detector for testing. The hydrocarbon gas generating device comprises a heater and a gas releasing material.

Abstract: A sensing system having a zeroing mechanism incorporating a micropump. The micropump may be connected to a gas conditioner for providing zeroing gas to a sensor downstream. The micropump and sensor may be connected to a processor or computer for pump control and receipt of information from the sensor. Upon zeroing and/or baseline correction of the sensor, the pump may be stopped and a sample gas may be fed into the sensor for detection and analysis. Alternatively, the pump may situated downstream of the sensor to draw conditioned gas through the sensor. A valve may be added having a conditioned gas input connected to the conditioner and having a sample input. The valve may have an output connected to the sensor. When the valve is open to the conditioned gas input, it will be closed to the sample input, and vice versa. The system may be for zeroing and/or calibration.

Abstract: A sensor system for detection of gas with a modified ion selection FET. The FET may have a gate of low conductivity material for detection of a species in a fluid. A component such as a capacitor may be connected to an electrode of the FET, such as a source, in conjunction with the FET to reduce noise of the detection signal of the species. One or more current sources may provide a current through the FET, and through a resistor to provide a constant source-to-drain voltage. The system may have a bulk voltage selection of either that of a voltage approximately equal to the FET source voltage or greater than the FET source voltage. Also, a guard ring may be implemented in the FET for preventing leakage currents relative to the source or drain.

Abstract: A system for testing and calibrating gas sensors with gas stored in a strip of packets. The strip may be fed into a chamber having a defined volume of air. A packet may be punctured with a mechanism to release one or more gases into the volume of air to result in an air-gas mixture. New air may be moved into the chamber to push the mixture out of the chamber to a sensor for testing and/or calibration. Then another packet may be punctured to release one or more gases into the volume of new air in the chamber for another air-gas mixture. This mixture may be moved out of the chamber, in the same manner as the previous mixture, to another sensor for testing and/or calibration. This procedure may be repeated with additional packets on the strip.

Abstract: Embodiments of the present invention relate to a gas sensor comprising a flow channel, a concentration modulator positioned in the flow channel, a gas generator in contact with the flow channel, one or more gas detectors positioned downstream of the concentration modulator and gas generator and a pump.

Abstract: The electronic device comprises an organic semiconductor material in a monodomain structure on a substrate. Said semiconductor material is preferably part of a transistor, wherein the monodomain extends on the channel, i.e. from a source to a drain electrode. The material comprises a mesogenic unit with spacer groups and end groups. The end groups are preferably reactive, i.e. dienes, acrylates, oxetanes or the like. The mesogenic unit contains a central oligothiophenyl-group, rigid spacer groups, particularly acetylenes, and additional groups, for instance thiophenyl or phenyl.

Abstract: Embodiments of the present invention relate a gas sensor comprising a gas detector and a hydrocarbon gas generating device, wherein the hydrocarbon gas generating device is positioned to provide an amount of hydrocarbon gas to the gas detector for testing. The hydrocarbon gas generating device comprises a heater and a gas releasing material.

Abstract: Embodiments of the present invention relate to a gas sensor system comprising a gas sensor, a fluid reservoir enclosing a fluid and in proximity to the gas sensor and a membrane positioned between the gas sensor and fluid reservoir, wherein the membrane allows a sufficient amount of a test gas generated from the fluid to contact the gas sensor for testing. Embodiments also relate to a method of testing a gas sensor, the method comprises contacting reagents within a fluid reservoir, generating a test gas and contacting a gas sensor with the test gas sufficient to test the gas sensor.

Abstract: Embodiments of the present invention relate a gas sensor system comprising a gas generating device adapted to generate a test gas, a target gas sensor positioned near the gas generating device, a test gas sensor positioned near the gas generating device and in communication with the target gas sensor and wherein the test gas sensor is sensitive to the test gas.

Abstract: A polymer comprising structural units of the formula I is prepared according to a novel method, in which the starting compound R1 ‘S—(CHR’2)—Ar—(CHR2)—SR1 is polymerized with a base, preferably in an aprotic solvent. The polymer comprises 50 to 1000 structural units of the formula I. The solution comprising the polymer thus prepared has a lower viscosity than a solution of a similar polymer with a greater chain length. The solution comprising the polymer thus prepared may be applied as a layer on a substrate. Electronic components with layers prepared with the polymer of the invention show better properties.

Abstract: A sensor is disclosed that includes an electrolyte pump in fluid communication with an electrochemical cell and an ion selective electrode. The electrochemical cell may include a gold cathode and a platinum anode. The sensor may include an electrolyte reservoir as well as an optional electrolyte waste reservoir. Methods of sensing chlorine dioxide are also disclosed.

Abstract: A self-calibration device and method for a FFET sensor having a thin functional film positioned to detect the presence of at least one specific component in a fluid, a current driven source, a gate and a voltage source applied to said gate, a tub and a drain. An input signal is applied to the gate to produce a measured output signal that is compared to an expected output reference signal. The input signal is selected from controlled voltage pulses to the gate, or the source bias current can be changed. Alternatively, the signal can be a known concentration pulse of the specific component applied to the FFET or a heat source pulse for changing the temperature of the FFET by a small amount.