Abstract: The present invention provides an infection prevention device and an infection prevention method including a light source 11 for radiating light in specific wavelength range, and a beam-firming optical element 12 for forming the light radiated from the light source 11 on a radiant film 20 having a predetermined width, wherein pathogenic microorganism which levitates together with airborne droplets or particles or which levitates alone is inactivated or killed by the radiant film 20 formed in air, or moisture of the airborne droplets or the particles is evaporated. According to this, pathogenic microorganism which levitates in air can be inactivated or killed in air.

Abstract: One aspect example is a system for photogrammetry of a building. A memory stores design data and physical material data. The design data includes virtual material information on attributes for each of virtual materials of a virtual building. The physical material data is on the attributes for each of physical materials and generated based on measured data acquired from a physical building constructed on the basis of the design data. A material associating processor is configured to generate pairs of virtual and physical materials by determining an association between the virtual materials and the physical materials based on the virtual material information and the physical material data. An attribute associating processor is configured to determine an association between the virtual material information and the physical material data in accordance with the attributes for each of the pairs.

Abstract: To provide a gas analysis device comprising: a cell; a light source; and a detector, wherein two or more types of gaseous components contained in the gas are measurement targets, a mid-infrared light with a wavelength that is caused to match the absorption spectrum of the measurement target gaseous components is output from the light source, and concentrations of the gaseous components are obtained based on light intensity detected by the detector. The gas analysis device sets a cumulative measurement time for the mid-infrared lights with the wavelengths for respective ones of the measurement target gaseous components; and controls at least one of an output time of the light source and a detection time of the detector in accordance with the cumulative measurement times, thereby efficiently measuring the plurality of types of gaseous components contained in the gas by using the mid-infrared lights with the plurality of wavelengths.

Abstract: To provide a gas analysis device comprising: a cell; a light source; and a detector, wherein two or more types of gaseous components contained in the gas are measurement targets, a mid-infrared light with a wavelength that is caused to match the absorption spectrum of the measurement target gaseous components is output from the light source, and concentrations of the gaseous components are obtained based on light intensity detected by the detector. The gas analysis device sets a cumulative measurement time for the mid-infrared lights with the wavelengths for respective ones of the measurement target gaseous components; and controls at least one of an output time of the light source and a detection time of the detector in accordance with the cumulative measurement times, thereby efficiently measuring the plurality of types of gaseous components contained in the gas by using the mid-infrared lights with the plurality of wavelengths.

Abstract: A saturable absorber functioning as a Q-switch is disposed on a path of a light in a laser resonator provided with a laser medium, the saturable absorber disposed in the laser resonator is transferred relatively toward the path of the light, and an initial transmittance of the saturable absorber in the case when the light passes through the saturable absorber is changed in order to achieve such effect that a scale of the whole equipment is not upsized, it is in excellent in workability and convenient, besides there is no fear of decreasing stability in a pulsed laser oscillation.

Abstract: To provide a laser oscillation method and a laser device, which use a laser medium such as an Nd:GdVO4 crystal to which neodymium is doped in high concentration exceeding 1% in atomicity ratio, the laser medium comprised of the gadolinium-vanadate crystal to which neodymium as laser active ion is doped by a floating zone method such that concentration becomes exceeding 1% in atomicity ratio.

Abstract: To provide a laser oscillation method and a laser device, which use a laser medium such as an Nd:GdVO4 crystal to which neodymium is doped in high concentration exceeding 1% in atomicity ratio, the laser medium comprised of the gadolinium-vanadate crystal to which neodymium as laser active ion is doped by a floating zone method such that concentration becomes exceeding 1% in atomicity ratio.