A beam reverser module for an optical power amplifier of a laser arrangement comprises at least one reflecting surface for receiving an incoming laser beam propagating in a first direction and reflecting the incoming laser beam into a second direction different from the first direction, wherein the at least one reflecting surface is a highly reflecting surface of at least one mirror.

A beam reverser module for an optical power amplifier of a laser arrangement comprises at least one reflecting surface for receiving an incoming laser beam propagating in a first direction and reflecting the incoming laser beam into a second direction different from the first direction, wherein the at least one reflecting surface is a highly reflecting surface of at least one mirror.

Spectroscopic probe light shields coupled to the end of an optical probe improve user safety, reduce unwanted stray light and enhance signal collection from a liquid or gaseous sample. Apertured inner and outer baffles with offset perforations allow a sample to flow through the baffles and past a counter-propagating focused or collimated excitation/collection beam. The spectroscopic probe may be a Raman or fluorescence probe, operating in the UV-visible or mid-IR region of the spectrum. The inner shield may include a retro-reflector to amplify light collection from the sample, or the inner shield may include a light absorber to reduce the intensity of a scattered excitation beam. One or both of the inner and outer shields may be cylindrical, and the apertures in the baffles may be slots, circles or other shapes. The baffle(s) may be adapted for temporary, permanent, or semi-permanent attachment to the distal end of the probe optic.

A reinforced multi-body optical device that in one embodiment includes a multi-body optical device having a thickness that is less than or equal to about 1.0 millimeter and a supporting plate bonded without epoxy to the multi-body optical device. In an embodiment the supporting plate has a coefficient of thermal expansion (CTE) that is within about 0.5 parts per million of the CTE of the multi-body optical device.

A reinforced multi-body optical device that in one embodiment includes a multi-body optical device having a thickness that is less than or equal to about 1.0 millimeter and a supporting plate bonded without epoxy to the multi-body optical device. In an embodiment the supporting plate has a coefficient of thermal expansion (CTE) that is within about 0.5 parts per million of the CTE of the multi-body optical device.

A portable inflator includes a housing having or including a compressor. The housing may also contain or include a handle and stand. The housing has an outer surface at least in part formed or constructed of a light reflective material. Suitable light reflective materials can include reflective plastic materials or the like.

A portable inflator includes a housing having or including a compressor. The housing may also contain or include a handle and stand. The housing has an outer surface at least in part formed or constructed of a light reflective material. Suitable light reflective materials can include reflective plastic materials or the like.

Electromagnetic wave absorbing particles are provided that include hexagonal tungsten bronze having oxygen deficiency, wherein the tungsten bronze is expressed by a general formula: M.sub.xWO.sub.3-y (where one or more elements M include at least one or more species selected from among K, Rb, and Cs, 0.15x0.33, and 0<y0.46), and wherein oxygen vacancy concentration N.sub.V in the electromagnetic wave absorbing particles is greater than or equal to 4.310.sup.14 cm.sup.3 and less than or equal to 8.010.sup.21 cm.sup.3.

Methods for quantifying pupil swim are disclosed in order to compensate for the same. A target image, in one embodiment, is displayed on a display of a head mounted display (HMD). Images of the target image are captured from a plurality of positions relative to an optical axis of an optics block of the HMD at an exit pupil of the HMD. The target image includes features and differences between observed locations of the features and their expected locations absent the optics block are determined. From these differences, a wavefront of the optics block is reconstructed and distortion corrections for the optics block are generated using the wavefront. The distortion corrections, when applied to a virtual scene, add pre-distortion that is canceled by the optical imperfections of the optics block as light of the virtual scene with the pre-distortion passes through the optics block.

A near-eye display device includes (a) a display unit for displaying a display image, (b) a viewing unit for presenting the display image to the eye and transmitting ambient light from an ambient scene toward the eye, and (c) an eye imaging unit including (i) an illumination module for generating at least three infrared light beams propagating along at least three different, non-coplanar directions, respectively, (ii) a first beamsplitter interface, disposed between the display unit and the viewing unit, for merging at least a portion of each of the infrared light beams with visible display light to direct each portion toward the eye via the viewing unit, and (iii) a camera for imaging, via the viewing unit and the first beamsplitter interface, pupil of the eye and reflections of the infrared light beams incident on the eye, to form one or more images indicative of gaze direction of the eye.