A determining unit 31 determines an image region of a foreign material in an imaged image generated by an imaging unit 22 by using an imaging optical system 21. A setting unit 32 sets a pressure, injection time, an injection direction of air injected to the foreign material, an injection pattern obtained by combining them and the like based on a determination result. A foreign material removal processing unit 33 adjusts air injection by an air injection adjusting unit 331 based on the setting by the setting unit 32 and injects from an air injecting unit 332 to the imaging optical system 21 to remove the foreign material adhering to the imaging optical system 21. The air is injected according to an adhesion condition of the foreign material, so that the foreign material adhering to the imaging optical system may be optimally removed.

A determining unit 31 determines an image region of a foreign material in an imaged image generated by an imaging unit 22 by using an imaging optical system 21. A setting unit 32 sets a pressure, injection time, an injection direction of air injected to the foreign material, an injection pattern obtained by combining them and the like based on a determination result. A foreign material removal processing unit 33 adjusts air injection by an air injection adjusting unit 331 based on the setting by the setting unit 32 and injects from an air injecting unit 332 to the imaging optical system 21 to remove the foreign material adhering to the imaging optical system 21. The air is injected according to an adhesion condition of the foreign material, so that the foreign material adhering to the imaging optical system may be optimally removed.

The invention provides a sensor device which comprises an input flow channel (10) for receiving a gas flow with entrained matter to be sensed. A thermophoretic arrangement (14a, 14b) is used to induce a thermophoretic particle movement from a first, warmer, region (16) of the input flow channel to a second, cooler, region (18) of the input flow channel (10). A sensor (24) comprises a particle sensor component at or downstream of the first region (16) of the input flow channel (10). The invention provides the benefit of pre-filtering (e.g. removal of most suspended solids/liquids) without the need for a physical filter that can become blocked.

An apparatus and method for analyzing a flow of material having an inlet region, a measurement range and an outlet region, and having a first diverter and a second diverter, and a deflection area, wherein in a first state of operation, the two diverters form a continuous first material flow space from the inlet region via the first diverter through the measurement range, via the second diverter to the outlet region, and in a second state of operation, form a continuous second material flow space from the inlet region via the first diverter through the deflection area, via the second diverter to the outlet region.

The invention provides a sensor device which comprises an input flow channel (10) for receiving a gas flow with entrained matter to be sensed. A thermophoretic arrangement (14a, 14b) is used to induce a thermophoretic particle movement from a first, warmer, region (16) of the input flow channel to a second, cooler, region (18) of the input flow channel (10). A sensor (24) comprises a particle sensor component at or downstream of the first region (16) of the input flow channel (10). The invention provides the benefit of pre-filtering (e.g. removal of most suspended solids/liquids) without the need for a physical filter that can become blocked.

An apparatus and method for analyzing a flow of material having an inlet region, a measurement range and an outlet region, and having a first diverter and a second diverter, and a deflection area, wherein in a first state of operation, the two diverters form a continuous first material flow space from the inlet region via the first diverter through the measurement range, via the second diverter to the outlet region, and in a second state of operation, form a continuous second material flow space from the inlet region via the first diverter through the deflection area, via the second diverter to the outlet region.

Condensation mitigation devices and condensation prediction/detection techniques configured to prevent window condensation with reduced power consumption are disclosed. A condensation mitigation device is configured to predict and/or detect a window condensation event. The condensation mitigation device is powered on only during such an event, and the condensation mitigation device is powered off afterwards to conserve power.

Systems, devices, and methods including an optical cell assembly, comprising: an optical core based trace gas sensor configured to measure trace gas concentrations; and an optical cell sub assembly including: a housing configured to house the optical core based trace gas sensor; and a field-replaceable filter media configured to be detachably attached to a portion of the housing and allow ambient trace gas to enter into the optical cell sub assembly.

A system for automated collection of Raman spectra from ex-vivo tissue samples is provided. The system may comprise a cartesian robot that moves a detachable Raman probe to points on the ex-vivo tissue sample that have been predetermined through a 3D image of the sample. Accordingly, methods of rapid acquisition of multiple Raman spectra from a heterogeneous tissue sample are provided. The inventive methods consider variable contours of the sample to provide Raman spectra from multiple points while generating optimal coverage of the sample. The inventive methods include cleaning the Raman probe between acquisitions of Raman spectra from the multiple points.

A sensor assembly includes a passageway for a process fluid, an optical window, an optical sensor, and a nozzle. The optical sensor configured to detect an optical property of the process fluid. The optical window includes an inner surface. The nozzle configured discharge an atomized fluid in a discharge direction that intersects the inner surface of the optical window. A sensor system includes a sensor assembly and conduits for supplying a gas and a liquid to a nozzle of the sensor assembly. A method of cleaning an optical window in a sensor assembly includes forming an atomized fluid and discharging the atomized fluid in a discharge direction that intersects the optical window.