Abstract: A method, system, and apparatus of sterilizing or disinfecting a space or surface with UV light from a laser that produces UV or other light energy with germicidal effect, at least like UVGI. The light can be controlled in terms of power to be effective for germicidal effect on a given biological organism or agent. In cases where humans might be present and represent a risk of interaction with the laser, techniques are used to remove those risks. The laser can be directed to a single relatively small area, aimed to multiple areas, or scanned to cover larger areas. It allows either human operation at stand-off distances from the relevant spaces, volumes, areas, surfaces (e.g., at least inches and typically feet or tens of feet). It has an indefinite useful operation life.

Abstract: A method and system for interrogating a target for one or more chemical species of interest using Raman microscopy and spectroscopy. A feature includes the ability to precisely electro-mechanically move and orient a Raman microscope relative to the target with multiple degrees of freedom of movement, including targets with 3-D form factors. This promotes effective detection of minute quantities of chemical species of interest. It also allows effective detection of minute quantities whether the target is static or moving. The method and system can include enhancements. Examples include alternative imaging spectrometers, alternative Raman microscope optical set-ups, and alternative focusing techniques. Others include control of the excitation energy and user controls and options to allow highly adjustable, flexible, and effective detection for a variety of detection applications.

Abstract: The present invention relates to a novel stand-off distance chemical detector system such as can be used, for example, for standoff detection of explosives. Instead of a conventional lasing medium, a Pr:YAG or Pr:BYF based UV laser is used which can be advantageously implemented in Raman spectroscopy.

Abstract: The present invention relates to a highly portable, highly flexible standard of distance chemical detector such as can be used, for example, for standoff detection of explosives. Aspects of the invention include techniques for portability compactness and ways to diminish influence of fluorescence on Raman spectroscopy. Additional features can include a compact imaging spectrometer, a wirelessly connected smart device for user interface, and an auto-focus/range finder.

Abstract: The present invention relates to a novel stand-off distance chemical detector system such as can be used, for example, for standoff detection of explosives. Instead of a conventional lasing medium, a Pr:YAG or Pr:BYF based UV laser is used which can be advantageously implemented in Raman spectroscopy.

Abstract: A system comprises a processing system, a laser system, a telescope system, a detector system and optical systems operatively arranged such that the laser system may be capable of outputting multiple wavelengths to a common telescope system, and the detector system is capable of receiving signatures from the same telescope system, under the control of a control system. The processor system processes signals received from the detector system to determine substances identified by known signatures. For example, a plurality of detectors in the detector system each receive a range of wavelengths of the signatures received by the telescope system. For example, a variable beam diverger and variable beam expander operatively control expansion and divergence of the output the laser system. For example, a beam reducer and lenslet array may operatively transmit signatures via optical fiber bundle to one or more of the detectors.

Abstract: A system comprises a processing system, a laser system, a telescope system, a detector system and optical systems operatively arranged such that the laser system may be capable of outputting multiple wavelengths to a common telescope system, and the detector system is capable of receiving signatures from the same telescope system, under the control of a control system. The processor system processes signals received from the detector system to determine substances identified by known signatures. For example, a plurality of detectors in the detector system each receive a range of wavelengths of the signatures received by the telescope system. For example, a variable beam diverger and variable beam expander operatively control expansion and divergence of the output the laser system. For example, a beam reducer and lenslet array may operatively transmit signatures via optical fiber bundle to one or more of the detectors.

Abstract: A spectroscopy system including first and second lasers. The first laser is triggered to induce a plasma, such as on a surface of a target at a stand-off distance from the target. The second laser stimulates amplified emissions from the plasma detected by one or more spectroscopes. The gain induced by the second laser detects traces of explosives and other substances on surfaces at stand-off distances. The spectroscopy systems use the same telescopic optics to collect emissions from the detection surface and activated at or just before the peak emission intensity useful for detecting element signatures and intensity ratios from the trace elements in the plasma.

Abstract: A spectroscopy system including first and second lasers. The first laser is triggered to induce a plasma, such as on a surface of a target at a stand-off distance from the target. The second laser stimulates amplified emissions from the plasma detected by one or more spectroscopes. The gain induced by the second laser detects traces of explosives and other substances on surfaces at stand-off distances. The spectroscopy systems use the same telescopic optics to collect emissions from the detection surface and activated at or just before the peak emission intensity useful for detecting element signatures and intensity ratios from the trace elements in the plasma.