A system for real-time detection of airborne pathogens is disclosed. The system includes: an air intake unit defining an inlet and an air inflow channel; a fan configured to cause air in a sampling environment to flow into the air inflow channel via the inlet; a cooling unit for cooling air in the air inflow channel; a collection chamber for collecting liquid water condensed from air in the air inflow channel, the collection chamber including: an active target substrate having a surface that is coated with bioreceptors; and a reference target substrate that is not coated with bioreceptors, and an optical detection unit that is configured to independently illuminate the active target substrate and the reference target substrate with light for detecting presence of an airborne pathogen.

A system for real-time detection of airborne pathogens is disclosed. The system includes: an air intake unit defining an inlet and an air inflow channel; a fan configured to cause air in a sampling environment to flow into the air inflow channel via the inlet; a cooling unit for cooling air in the air inflow channel; a collection chamber for collecting liquid water condensed from air in the air inflow channel, the collection chamber including: an active target substrate having a surface that is coated with bioreceptors; and a reference target substrate that is not coated with bioreceptors, and an optical detection unit that is configured to independently illuminate the active target substrate and the reference target substrate with light for detecting presence of an airborne pathogen.

Various techniques are provided for increasing contrast of gas features in a scene. In one example, a method includes receiving a captured infrared image comprising a gas feature and a scene feature. The captured infrared image comprises a first range of pixel values associated with a first temperature range of the gas feature and the scene feature. The method also includes applying a spatial filter to the captured infrared image to provide a spatially filtered infrared image retaining the gas feature and removing the scene feature. The spatially filtered infrared image comprises a second range of pixel values associated with a second temperature range of the gas feature without the additional scene feature to exhibit increased gas contrast over the captured infrared image. Additional methods and systems are also provided.

Various techniques are provided for increasing contrast of gas features in a scene. In one example, a method includes receiving a captured infrared image comprising a gas feature and a scene feature. The captured infrared image comprises a first range of pixel values associated with a first temperature range of the gas feature and the scene feature. The method also includes applying a spatial filter to the captured infrared image to provide a spatially filtered infrared image retaining the gas feature and removing the scene feature. The spatially filtered infrared image comprises a second range of pixel values associated with a second temperature range of the gas feature without the additional scene feature to exhibit increased gas contrast over the captured infrared image. Additional methods and systems are also provided.

A gas supply and discharge adapter has an opening through which a gas flows into and out of a gas sensor, an inflow port through which the gas flows into the opening, and an outflow port through which the gas flows out of the opening. The inflow port and the outflow port are positioned independently of each other. When the inflow port and the opening are viewed in plan through the gas supply and discharge adapter, the inflow port partially overlaps the opening.

A gas supply and discharge adapter has an opening through which a gas flows into and out of a gas sensor, an inflow port through which the gas flows into the opening, and an outflow port through which the gas flows out of the opening. The inflow port and the outflow port are positioned independently of each other. When the inflow port and the opening are viewed in plan through the gas supply and discharge adapter, the inflow port partially overlaps the opening.

A sample analyzing apparatus analyzes a component to be measured securely while reducing a frequency of maintenance of the sample analyzing apparatus. The sample analyzing apparatus includes a heating furnace that heats a sample held by a sample holding body and a gas analysis section that analyzes a component to be measured contained in a gas generated by heating the sample, and the gas analysis section includes a laser light source that irradiates the gas with a laser light, and a photodetector that detects an intensity of a sample light as being the laser light that has transmitted through the gas.

A sample analyzing apparatus analyzes a component to be measured securely while reducing a frequency of maintenance of the sample analyzing apparatus. The sample analyzing apparatus includes a heating furnace that heats a sample held by a sample holding body and a gas analysis section that analyzes a component to be measured contained in a gas generated by heating the sample, and the gas analysis section includes a laser light source that irradiates the gas with a laser light, and a photodetector that detects an intensity of a sample light as being the laser light that has transmitted through the gas.

An apparatus for measuring vapor partial pressures of water and carbon dioxide includes a pair of infrared (IR) sources and a pair of quad filter detectors are placed opposite to one another such that the vapor partial pressures of water (H.sub.2O) and carbon dioxide (CO.sub.2) is measured and quantified in a short pathlength gas cell.

An apparatus for measuring vapor partial pressures of water and carbon dioxide includes a pair of infrared (IR) sources and a pair of quad filter detectors are placed opposite to one another such that the vapor partial pressures of water (H.sub.2O) and carbon dioxide (CO.sub.2) is measured and quantified in a short pathlength gas cell.