A pixelated filter intended to rest on a support and including, in a stacking direction: first filter pixels each including a first interference filter covered with a first dielectric block; and second filter pixels each including a second dielectric block, having a thickness greater than or equal to the thickness of the first interference filter, covered with a second interference filter, having a thickness smaller than or equal to the thickness of the first dielectric block, wherein, for at least one of the second filter pixels, the second dielectric block of the second filter pixel is interposed between the first interference filters of two first filter pixels and the second interference filter of the second filter pixel is interposed between the first dielectric blocks of the first two filter pixels.

A lighting device includes a light permeable body which has an aperture through which light enters the body. A light source is moveable relative to the body to enable the lighting device to adopt selectively one of a first configuration and a second configuration. In the first configuration, the light source is positioned over the aperture so that light emitted by the light source passes through the body before illuminating the room. In the second configuration, the light source is spaced laterally from the aperture so that the room is illuminated directly by light emitted from the light source.

A light source device that includes a light device assembly and a monolithic lens. The light device assembly includes a first substrate with opposing top and bottom surfaces and a plurality of cavities formed into the top surface, a plurality of light source chips each disposed at least partially in one of the plurality of cavities and each including a light emitting device and electrical contacts, and a plurality of electrodes each extending between the top and bottom surfaces and each electrically connected to one of the electrical contacts. The monolithic lens is disposed over the top surface of the first substrate, and includes a unitary substrate with a plurality of lens segments each disposed over one of the light source chips.

A light source device that includes a light device assembly and a monolithic lens. The light device assembly includes a first substrate with opposing top and bottom surfaces and a plurality of cavities formed into the top surface, a plurality of light source chips each disposed at least partially in one of the plurality of cavities and each including a light emitting device and electrical contacts, and a plurality of electrodes each extending between the top and bottom surfaces and each electrically connected to one of the electrical contacts. The monolithic lens is disposed over the top surface of the first substrate, and includes a unitary substrate with a plurality of lens segments each disposed over one of the light source chips.

A solar simulator has an array of light sources including LED light sources and at least one non-LED light source. At least a portion of the infrared-light wavelength range covered by the solar simulator is covered only by the non-LED light source More than 50% of the irradiance provided by the solar simulator is provided by the LED light sources. Application to artificially recreate sunlight in a solar testing device for the testing of solar cells, sun screens, and other products.

A solar simulator has an array of light sources including LED light sources and at least one non-LED light source. At least a portion of the infrared-light wavelength range covered by the solar simulator is covered only by the non-LED light source More than 50% of the irradiance provided by the solar simulator is provided by the LED light sources. Application to artificially recreate sunlight in a solar testing device for the testing of solar cells, sun screens, and other products.

This disclosure relates to a surgical lighting device for generating a spot of light on a surgical site for use in combination with a fluorescence imaging device. The lighting device comprises a support structure, a subsurface which may be coupled to the support structure to seal the lower surface of the device while allowing light to pass through and a plurality of light sources emitting white light and placed between the support structure and the subsurface. The device further includes a plurality of NIR (near infrared) filters, each NIR filter being associated with a light source and being configured to substantially prevent the transmission of wavelengths within a wavelength band from 680 nm to 900 nm, while minimizing the change in the color temperature of the light spot.

This disclosure relates to a surgical lighting device for generating a spot of light on a surgical site for use in combination with a fluorescence imaging device. The lighting device comprises a support structure, a subsurface which may be coupled to the support structure to seal the lower surface of the device while allowing light to pass through and a plurality of light sources emitting white light and placed between the support structure and the subsurface. The device further includes a plurality of NIR (near infrared) filters, each NIR filter being associated with a light source and being configured to substantially prevent the transmission of wavelengths within a wavelength band from 680 nm to 900 nm, while minimizing the change in the color temperature of the light spot.

The present disclosure relates to a lighting device for automatically switching between a visible light source and an infrared light source. The lighting device may include a light source, an infrared filter, and a driving module for driving the infrared filter.

A daylight redirecting window film formed by a flexible multi-layer film laminate with a total thickness of less than one millimeter and configured to be applied to an indoor-facing window surface of a building facade. The window film includes a pair of outer film substrates flanking a light redirecting core layer. The core layer includes a parallel array of channels defining total internal reflection (TIR) surfaces and linear optically transmissive structures protruding transversely thought the core layer and bonded to the outer film substrates. A light output surface of the outer film substrate which is disposed on an indoor-facing side of the laminate includes a two-dimensional pattern of light scattering microstructures which are configured to spread light at least in a plane that is perpendicular to the channels. The TIR surfaces intercept and reflect a portion of sunlight propagating through the core layer such that the window film redirects that portion of incident sunlight towards a plurality of divergent directions, forming relatively high bend angles.