Provided is a lighting device that can be easily attached to and removed from a panel. The lighting device includes a lighting film including a prism layer configured to emit incident light toward a prescribed direction as emitted light and a double-sided adhesive adhering to at least a part of an outer periphery of the lighting film and including both surfaces having adhesiveness on a side of the incident light and a side of the emitted light, wherein at least one of a peeling strength and a shear bonding strength on the side of the incident light is less than that on the side of the emitted light.

An optical article for illuminating building interiors including a reflective grid and a light diffusing element positioned between the reflective grid and a light source. The reflective grid includes one or more arrays of transverse reflective surfaces and is configured to partially transmit and partially redirect incident light over a broad angular range.

In one example, a mobile solar system includes a solar refraction device comprising a lens array assembly having a plurality of lens array sub-assemblies. The lens array assembly is configured to refract solar energy impinging on the lens array assembly to focus refracted solar energy at a plurality of focal points of the plurality of lens array sub-assemblies. Each focal point of the plurality of focal points corresponds to a corresponding lens array sub-assembly of the solar refraction device. The solar system further includes a frame supporting the solar refraction device above an underlying surface, and a mobility system coupled to the frame to provide for movement of the solar refraction device above and across the underlying surface.

A skylight for a building includes a solar panel arranged within the skylight, the solar panel comprising one or more photovoltaic cells to collect direct radiation from rays of sunlight for conversion to electrical power, and an optical element to receive the direct radiation and refract it to the solar panel, and to receive the direct radiation and diffuse radiation scattered from the rays of sunlight and refract the direct radiation and the diffuse radiation through the skylight, bypassing the solar panel, to provide daylighting in the building.

The present invention, in an aspect thereof, is directed to a daylighting device including: a daylighting sheet including: a transparent base member; and a plurality of transparent daylighting sections on a first face of the base member; and at least one hollow structural body composed of a resin provided on a second face of the base member opposite the first face, the at least one hollow structural body including: a transparent, first plate section; a transparent, second plate section opposing the first plate section; a plurality of structural bodies extending in a direction of alignment of the daylighting sections between the first plate section and the second plate section and arranged at prescribed intervals in a direction of extension of the daylighting sections; and hollow portions between the structural bodies.

A system for diagnosing pathogenic infection of a person, the system comprising a processor configured for: receiving a trigger comprising data indicative of a possible pathogenic infection; determining, using a risk classifier and medical information about the patient, a risk score for the patient comprising a likelihood that one or more body systems is infected; determining, using a likelihood classifier and the medical information, a likelihood score for the patient comprising an identification of one or more pathogens or pathogen categories that could be causing an infection; determining a relevance score using a relevance classifier and the determined risk and likelihood scores, the relevance score comprising one or more clinical tests relevant to confirming or rejecting the possible pathogenic infection of the person; and reporting, via a user interface, the determined relevance score.

A light harvester or collector collects solar radiation from an unshaded location adjacent a growing plant. The light harvester can be either imaging (e.g., parabolic reflectors) or non-imaging (e.g., compound parabolic concentrator). The concentrated solar radiation is projected into a light transmitter that conducts the light through the plant's outer canopy and into the inner canopy to a diffuser which disperses and reradiates the light into the inner canopy. The diffused light transforms a non-productive, potentially leafless zone of the plant into a productive zone so that more fruit can be produced per volume of land surface. The system can prevent transmission of infrared into the inner canopy so that the inner canopy zone is not heated and the amount of water lost to transpiration is reduced. The system can also modify other spectral components to affect plant development and to control pests and diseases.

The solar illumination distribution system (10) uses a series of parabolic reflectors (12, 14, 42, 44, 46) and other optical components to direct and distribute solar radiation onto a desired surface (G), such as for illuminating a stadium or arena as well as providing light for the growth of natural turf in desired locations within the stadium or arena. A primary parabolic reflector (12) and a secondary parabolic reflector (14) focus solar radiation onto one end of a fiber optic bundle (24), which transmits the solar radiation to a desired location. At the desired location, the light transmitted through the fiber optic bundle (24) is distributed through a plurality of fiber optic cables (36, 38, 40) to a plurality of tertiary parabolic reflectors (42, 44, 46) to illuminate the desired surface (G).

A light collector (1), a plurality of densely distributed light collecting protrusions (11) protruding upward from the light collector (1), and a light collecting curved surface (111) is provided on the light collecting protrusions (11) in a curved manner; a plurality of densely distributed Fresnel lenses (12) protruding downward from the light collector (1), and a light emitting curved surface (121) being provided underneath the Fresnel lenses (12) in a curved manner. The light collector (1) of the present invention has low production cost and an effect of increasing light usage rate.

An optical device and systems using an optical device are provided, where the optical device may be configured for collimating incoming light rays. The optical device may include a host medium substantially comprised of a transparent material and an array of substantially transparent structures embedded within the host medium. The structures of the array each include a convex side presented to the incoming light rays and a concave side that passes light rays through toward the output face of the host medium, collimating the rays. Multiple stages of arrays may be provided in the optical device, typically with lengthening aspect ratios and increasing indexes of refraction in a direction from the input face toward the output face. The systems may use the optical device for using an exterior light to illuminate an interior space in a building or to generate power.