The following is an apparatus and a method that enables the automated collection and identification of airborne particulate matter comprising dust, pollen grains, mold spores, bacterial cells, and soot from a gaseous medium comprising the ambient air. Once ambient air is inducted into the apparatus, aerosol particulates are acquired and imaged under a novel lighting environment that is used to highlight diagnostic features of the acquired airborne particulate matter. Identity determinations of acquired airborne particulate matter are made based on captured images. Abundance quantifications can be made using identity classifications. Raw and summary information are communicated across a data network for review or further analysis by a user. Other than routine maintenance or subsequent analyses, the basic operations of the apparatus may use, but do not require the active participation of a human operator.

An aircraft air quality testing system includes a portable housing unit to be removably placed within an aircraft; an air testing unit secured inside the portable housing unit and including: a sensor to receive an air sample during a plurality of oxygen generation system cycles and engine thrust settings of the aircraft; a removable collection media to receive the air sample from the sensor and filter targeted chemicals from the air sample; and a plurality of analyzers to perform a real-time chemical analysis of the air sample and the filtered targeted chemicals. A first computer is operatively connected to the portable housing unit and includes: a processor to receive the real-time chemical analysis and generate real-time chemical analysis and flow rate data; a memory device to store the real-time chemical analysis and flow rate data; and a display device operatively connected to the portable housing unit.

This method comprises: obtaining first data representative of amounts of a first gas and second data representative of amounts of a second tracer gas emitted by the source together with the first gas, calculating at least one coefficient of correlation between the amounts of the first gas and the amounts of the second gas from the first representative data and the second representative data; obtaining a measured or computed flow of the second gas emitted by the source; computing a flow of the first gas emitted by the source on the basis of the measured or computed flow of the second gas emitted by the source and the correlation coefficient.

A system and approach for catalyst model parameter identification with modeling accomplished by an identification procedure that may incorporate a catalyst parameter identification procedure which may include determination of parameters for a catalyst device, specification of values for parameters and component level identification. Component level identification may be of a thermal model, adsorption and desorption, and chemistry. There may then be system level identification to get a final estimate of catalyst parameters.

Provided is a gas sensor and methods of monitoring the same. The gas sensor may detect gas restrictions within the gas sensor. The gas sensor may include a test gas diffusion path allowing for monitoring of restrictions within the gas sensor. A pulse of test gas may be electrochemically generated into a void disposed between the membrane and capillary of the gas sensor. The resulting transient signal on the sensing electrode may be analyzed to determine the degree of restriction present in the gas sensor.

A gas concentration monitoring system (100) is provided. The system (100) includes a radiation source (104) having one or more emitting elements and a radiation sensor (106) having one or more sensing elements configured to detect radiation received at the radiation sensor (106). A reactive material (108) is located between the radiation source (104) and the radiation sensor (106) and is configured to react to the presence of a gas such as carbon dioxide, wherein the reaction of the reactive material (108) impacts an amount of radiation detected at the radiation sensor (106).

In accordance with an example embodiment, a system and method for obscurant mitigation is disclosed. The system comprises an obscurant assessor configured to characterize one or more characteristics of a detected obscurant and generate an obscurant model; an obscurant mitigator configured to perform one or more mitigation operations; and a controller communicatively coupled to each of the obscurant assessor and the obscurant mitigator. The controller is configured to receive an output signal from a vehicle sensor corresponding to a detected obscurant level and determine if the detected obscurant level exceeds a predetermined threshold. The controller generates an obscurant mitigation plan if the detected obscurant level exceeds the predetermined threshold based on the obscurant model generated by the obscurant assessor; and controls operations of an obscurant mitigator based on the obscurant mitigation plan to reduce the detected obscurant level.

The present disclosure provides, method, a system, and apparatus for identifying odorants. For example, the apparatus performs sensing an odorant using an olfactory sensor, encoding the sensed odorant to an electrical signal using an input processor, determining an identity representation of the odorant based on the encoded electrical signal, and determining odorant information using a time-dependent hash code based on the identity representation of the odorant.

A portable hand-held oxygen monitor for monitoring oxygen in a weld zone includes a user interface having an alphanumeric display and one or more user interface buttons. An audiovisual alarm includes an indicator light and an audio output device, the indicator light being separate and distinct from the alphanumeric display. The oxygen monitor implements an oxygen monitoring mode responsive to activation of one or more of the user interface buttons, wherein (1) a gas sample is obtained, (2) a digital gas sample oxygen level value is generated, and (3) the gas sample oxygen level value is compared to a stored oxygen level alarm value, and the audiovisual alarm is activated if the gas sample oxygen level value is less than the oxygen level alarm value. The activating includes illuminating the indicator light and generating sound from the audio output device to alert a monitor user that is safe to weld.

Systems and methods presented herein generally relate to greenhouse gas emission management and, more particularly, to greenhouse gas emission management systems and methods for performing greenhouse gas detection sensor placement planning, leakage source tracing, and quantification of leakage source detections for oil and gas production facilities.