Abstract: A scanning system and method scan an area of interest. The scanning system may include a first scanner that deflects a light signal. The light signal that is deflected by the first scanner is output as an initially-deflected light signal. A second scanner receives the initially-deflected light signal and deflects the initially-deflected light signal. The initially-deflected signal that is deflected by the second scanner is output as a subsequently-deflected light signal.

Abstract: An apparatus and methods for compensating for spatial non-uniformities in solar simulators. This is accomplished in part by acquiring a spatial map of the intensity distribution that the solar simulator produces across the illumination plane using a reference cell, identifying an area of an arbitrary solar cell within the illuminated area, and then calculating the expected illumination levels for that solar cell in that specific location based on the spatial mapping. The results of that process can then be used to determine the efficiency of the arbitrary solar cell during a test in which the reference cell (of known efficiency), located in a different part of the illuminating beam, simultaneously measures the illumination in one area of the illumination beam.

Abstract: A semiconductor device is disclosed, and includes a first sub-cell generating a first electrical current, a second sub-cell generating a second electrical current, and at least one power converter. The first sub-cell and the second sub-cell are electrically coupled to one another in series. The power converter is electrically coupled to both the first sub-cell and the second sub-cell. The power converter introduces a compensating current into at least one of the first sub-cell and the second sub-cell to balance the first electrical current and the second electrical current to be substantially equal to one another.

Abstract: A rigidly mountable solar panel includes lenses supported above a movable panel to focus sunlight onto photovoltaic material carried on the movable panel. Flexible supports space the movable panel at the focal points of the lenses, and a servo-mechanism enables movement of the movable panel to adjust position as the focal point moves with the sun. A light detector on the movable panel, sensing movement of the focal point signals the servo-mechanism to adjust the position of the movable panel automatically, thereby tracking the sun's movement. Concentrating sunlight on photovoltaic material selected to have higher conversion efficiency increases output. Segmenting the photovoltaic material so the output of the segments can be combined in a series-parallel relationship and using mirrors on the ends of the movable panel to reflect sunlight onto the segments allows electricity that is generated by the photovoltaic material to be more uniform during daylight.

Abstract: A contactless energy transfer system has a first stationary platform and a second movable platform. The first platform has at least one light source coupled to a power source. The second separate platform has at least one photovoltaic module mounted thereon. The at least one photovoltaic module is coupled to an energy storage system mounted on the second platform such that any light received at the photovoltaic module is converted to electrical energy stored in the energy storage system. The second platform is configured to move in close proximity to the first platform along a predetermined pathway. The predetermined pathway may be linear or rotary. The light sources are positioned and configured to direct light at the photovoltaic modules during a predetermined interval when the second platform is in close proximity to the first platform (for the linear pathway) or constantly or at predetermined intervals (for the rotatory pathway).

Abstract: An optical star tracker system including a single common aperture, a single light-redirecting element, a single imaging sensor and an image processor, wherein the light-redirecting element receives incident light rays from a plurality of objects and forms images of the objects distorted at angles indicative of the multiple directions of the incident light rays from the objects depending on an orientation at which the incident light rays originated from the objects.

Abstract: An apparatus and methods for retrofitting known solar simulator systems to allow the exit beam to be changed in size and location without changing the other fundamental functions of the main optical elements. The solar simulator system is provided with means for de-magnifying the exit beam to provide higher power densities at the illumination plane. By adding or replacing one final optical element, the system user can change the location of the illumination plane and the size of the illumination area. This change in size can increase or decrease the power density of the exit beam.

Abstract: A light assembly may include a reflector having a focal point in space, and a first light source configured to generate a first light at a first wavelength proximate to the focal point during a first illumination mode. The first light reflects off the reflector as a first collimated beam at the first wavelength. One or more second light sources are configured to direct one or more second light beams at one or more different wavelengths towards the focal point during a second illumination mode. The different wavelength(s) differ from the first wavelength. At least a portion of the second light beam(s) reflects off the reflector as one or more second collimated beams at the different wavelength(s).

Abstract: A solar simulator including an array of lamp modules, wherein each lamp module of the array includes a lamp configured to generate light, a homogenizer having an input end and an output end, a beam divergence lens positioned to focus the light onto the input end of the homogenizer, and an imaging lens positioned to receive the light from the output end of the homogenizer and image the light onto a target plane.

Abstract: Systems, methods, and apparatus for improving illumination from a searchlight are disclosed. In one or more embodiments, the disclosed method involves radiating, from the searchlight, light to produce an illuminated beam. The method further involves passing, through at least one diffuser, the light, thereby diffusing the illuminated beam. In one or more embodiments, at least one diffuser is located in front of a reflector of the searchlight. In at least one embodiment, the reflector is a parabolic reflector or a non-parabolic reflector. In one or more embodiments, the non-parabolic reflector is a converging reflector or a diverging reflector.

Abstract: A system includes a light detection and ranging (LIDAR) device. The system further includes a LIDAR target. The LIDAR device is configured to direct a light beam at the LIDAR target. The system also includes a retro-reflective material in contact with the LIDAR target.

Abstract: Methods, apparatuses, and systems are disclosed for manufacturing a structure having layers that may operate in low pressure or vacuum environments. More particularly, methods, apparatuses, and systems are disclosed for minimizing the effects of voids by eliminating their contents in layers of bonded structures. In some implementations, a method for improving bonding within a layered structure comprises applying a bonding material layer to a substrate layer; disposing a wicking material in the bonding material layer, said wicking material having an outer surface; applying a surface material layer to the bonding material layer to form a layered structure; and curing the layered structure.

Abstract: A laser range finder including a laser configured to project a laser beam onto a target object thereby causing a target beam to be reflected from the target object, wherein the laser beam has a frequency, and wherein the frequency is modulated at a known rate, a first beam splitter positioned to split a reference beam from the laser beam, a second beam splitter positioned to receive the target beam and the reference beam, wherein the target beam and the reference beam are coherently combined, the coherently combined beams establishing a difference frequency, and a detector configured to measure the difference frequency.

Abstract: A method for monitoring degradation of a flashlamp including triggering the flashlamp to produce a light pulse, monitoring at least one parameter as a function of time to obtain a pulse waveform of the light pulse, comparing the pulse waveform to at least one reference pulse waveform to determine a difference therebetween, and flagging an end-of-lamp-life condition when the difference exceeds a predetermined threshold.

Abstract: A lamp assembly including a housing defining an internal volume and a lamp positioned in the internal volume, the lamp including a first electrode and a second electrode, wherein the first electrode is both thermally and electrically coupled to the housing, and wherein the second electrode is thermally coupled to the housing by way of a thermally conductive, electrically insulative material and a heat transfer element.

Abstract: A light assembly may include a reflector having a reflective surface that defines an internal volume. A focal point is within the internal volume. A light source may be positioned outside of the internal volume of the reflector. The light source is configured to generate at least one light beam. A light guide may include an input end proximate to the light source and an output end proximate to the reflective surface. The light guide is configured to receive the light beam(s) at the input end and direct the light beam(s) out of the output end toward the reflective surface.

Abstract: Systems, methods, and apparatus for determining an electromagnetic (EM) spectrum scattered from a surface are disclosed. The disclosed method involves scanning an EM source to at least one EM source position. The method further involves illuminating, with the EM source, spectral energy to at least one target area on the surface for each of the EM source positions. Also, the method involves scanning a detector to a plurality of detector positions for each of the EM source positions. Additionally, the method involves detecting, with the detector, the EM spectrum scattered from at least one target area on the surface at each of the plurality of the detector positions for each of the EM source positions. Further, the method involves processing the EM spectrum detected at each of the plurality of the detector positions for each of the EM source positions to characterize the surface.

Abstract: A solar simulator including a support structure, two or more lighting modules connected to the support structure, wherein each lighting module includes a mounting structure and at least one multi-lamp assembly connected to the mounting structure, and a mobile sensor platform configured to sense light intensity and/or light spectrum.

Abstract: A laser detection and warning system and associated methods of warning a pilot of an aircraft of incoming laser radiation and determining a location of a source of laser radiation including a detector configured to be mounted to an aircraft, the detector having an optical subsystem, a detector subsystem, and a processor subsystem to determine characteristics of incoming laser radiation and transmit a laser warning output signal, wherein the laser warning output signal may include wavelength characteristics of the laser radiation, corresponding protective eyewear type, and location of the source of the laser radiation.

Abstract: An apparatus may have a light source configured to generate light, a reflector configured to collect the light and direct the light in a desired direction, a spectral filter assembly configured to receive the light from the reflector. The spectral filter assembly may have a stationary frame and a plurality of filter elements supported by the stationary frame. Filter elements of the plurality of filter elements may simultaneously filter a desired quantity of light within wavelength band to provide a filtered output light beam. A homogenizer may be configured to receive the filtered output light beam and produce a homogenized light beam having a substantially uniform irradiance distribution across a cross-section of the homogenized light beam.