An integrated optically functional multilayer structure includes a flexible, substrate film arranged with a circuit design including at least a number of electrical conductors on the substrate film; and a plurality of top-emitting, bottom-installed light sources provided upon a first side of the substrate film to internally illuminate at least portion of the structure for external perception via associated outcoupling areas, wherein for each light source of the plurality of light sources there is optically transmissive plastic layer, produced upon the first side of the substrate film, said plastic layer at least laterally surrounding the light source, the substrate film at least having a similar or lower refractive index therewith; and reflector design including at least one material layer, provided at least upon the light source and configured to reflect the light emitted by the light source and incident upon the reflective layer towards the plastic layer.

A communication device for a vehicle which can transmit information in the form of light signals to other road users, wherein the communication device has at least one light source from which light emerges when operating the communication device, and controllable light influencer which selectively deflect or reflect or shade at least a portion of the light emanating from the at least one light source such that the at least one portion of the light exits the communication device as a light signal, or wherein the communication device comprises an array of light sources that can selectively generate light that at least partially emerges as a light signal from the communication device.

Described are optical systems for a digital micromirror device (DMD) illuminator. The optical systems include a LED array, a tapered non-imaging collection optic, a reflective stop and a telecentric lens system. The telecentric lens system is disposed along an optical axis defined between the tapered non-imaging collection optic and the reflective stop. The telecentric lens system is configured as a first half of a symmetric one to one imager for an object plane on the optical axis and as a second half of the symmetric one to one imager for optical energy reflected from the reflective aperture stop. The optical systems reclaim optical energy emitted by the LED array that does not initially pass through the reflective stop and provide an improved intensity distribution at the DMD. Reductions in stray light and the thermal loads on the illuminator and DMD are achieved relative to conventional illumination systems for DMDs.

The invention relates to a projector module. In particular, the invention relates to a projector module for the use in mobile devices, wherein a most compact, stable and reliable module structure with high module efficiency can be achieved. A projector module according to the invention comprises a beam path with a laser source, designed to emit coherent electromagnetic radiation with a divergent beam profile; a collection optics, designed to collimate or focus convergently into an image plane the divergent radiation emitted by the laser source; and a diffractive optical element, DOE, designed to generate a projection pattern from the radiation collimated or converged by the collection optics; wherein a deflector, designed to deflect the divergent radiation emitted by the laser source from a first direction into a second direction deviating from the first direction, is arranged in front of the collection optics or is designed as a collection optics.

An optical unit includes an input portion configured to have measurement light having a wavelength extending from an ultraviolet region to a visible region input thereto, an optical system configured to condense the measurement light in a state where a chromatic aberration is caused to occur, and an opening portion configured not to image light having a wavelength in the visible region and to image light having a wavelength in the ultraviolet region of the measurement light having a chromatic aberration having occurred therein.

An optical element includes: a first transmissive section 3 that causes light emitted from a light source to be incident on the optical element; a first reflection section 4 which is located at a facing section facing the first transmissive section and from which light incident from the first transmissive section is reflected; a second reflection section 5 which is located around the first transmissive section and from which the light reflected from the first reflection section is reflected; and a second transmissive section 6 that causes the light reflected from the second reflection section to be emitted out of the optical element in an optical axis direction of the light source.

The system captures and concentrates sunlight for transmission to interior spaces or to a PV system. A solar collector uses arrayed refractive lenses, opposing concave focusing mirrors, and a movable coupling sheet forming part of a lightguide. The lenses and mirrors have an asymmetric shape, such as having aspect ratios of 3:4 or 1:2, so as to have an asymmetric aperture to better receive light at the different ranges of angles of the sun's rays over the course of a year. The long axis of the apertures is generally oriented in an East-West. The movable sheet contains small angled mirrors, and the sheet is translated to position the angled mirrors at the focal points of the sunlight for maximum deflection of the sunlight to an output of the collection system. A position sensor provides feedback regarding the position of the angled mirrors relative to the focal points.

The invention relates to a projector module. In particular, the invention relates to a projector module for the use in mobile devices, wherein a most compact, stable and reliable module structure with high module efficiency can be achieved. A projector module according to the invention comprises a beam path with a laser source, designed to emit coherent electromagnetic radiation with a divergent beam profile; a collection optics, designed to collimate or focus the divergent radiation emitted by the laser source convergently into an image plane; and a diffractive optical element, DOE, designed to generate a projection pattern from the radiation collimated or focused by the collection optics; wherein a deflector, designed to deflect the divergent radiation emitted by the laser source from a first direction into a second direction deviating from the first direction, is arranged in front of the collection optics or is designed as a collection optics.

A reticle includes an illumination device having an optical component configured to introduce light from a light source into the reticle. The optical component has an entrance face and a reflecting face for the light of the light source. Two parallel bounding surfaces that are oriented perpendicular to an optical axis have an optical marking. A peripheral edge joins the bounding surfaces. The optical component is disposed at the peripheral edge of the reticle such that the light of the light source enters the reticle via the entrance face and the reflecting face and impinges on the marking. The entrance face is configured to act as a collecting lens on which the light of the light source impinges divergently.

Described are optical systems for a digital micromirror device (DMD) illuminator. The optical systems include a LED array, a tapered non-imaging collection optic, a reflective stop and a telecentric lens system. The telecentric lens system is disposed along an optical axis defined between the tapered non-imaging collection optic and the reflective stop. The telecentric lens system is configured as a first half of a symmetric one to one imager for an object plane on the optical axis and as a second half of the symmetric one to one imager for optical energy reflected from the reflective aperture stop. The optical systems reclaim optical energy emitted by the LED array that does not initially pass through the reflective stop and provide an improved intensity distribution at the DMD. Reductions in stray light and the thermal loads on the illuminator and DMD are achieved relative to conventional illumination systems for DMDs.