An optical module that includes (a) an optical interface that includes an input surface and an output surface, and (b) a scintillator that has a flat surface. The scintillator is configured emit emitted light through the flat surface in response to an impingement of a charged particle on the scintillator. The flat surface is optically coupled to the input surface. The optical interface is configured to (i) receive the emitted light from the scintillator and (ii) output, via the output surface, output light. An optical interface refractive index substantially equals a scintillator refractive index.

A light-beam control member according to the present invention includes: an entrance face and an exit face. The exit face includes: a first exit face constituting an inner face of a second concave portion located so as to intersect the central axis; and a second exit face constituting a convex curved face located so as to surround the first exit face. The second exit face has multiple, circular ring-shaped convex portions disposed concentrically about the central axis and projecting in the direction along the central axis. The pitch of the convex portions in the direction perpendicular to the central axis in a cross section including the central axis is constant.

A lighting device (1) include a light source (2) that emits coherent light, a scanner (5) that causes the coherent light emitted from the light source to move, a first optical system (6) that regulates an optical path of the coherent light from the scanner, a first optical member (7) that causes the coherent light from the first optical system to diffuse, and a second optical system (8) that regulates an optical path of the coherent light from the first optical member. A lighting zone (LZ) on a plane of projection (PP) is illuminated with the coherent light emitted from the second optical system. An irradiance [W/m2] in a plane orthogonal to an optical axis of the coherent light irradiated on the lighting zone is non-discrete.

The invention relates to a motorcycle lamp (2) for implementing at least one lamp function. The motorcycle lamp (2) comprises a housing (4) having a light-emission aperture (6), a bracket (8) mounted on the housing (4) for securing the motorcycle lamp (2) to a motorcycle, at least one light source (10) disposed in the housing (4) and a front optics (12) made of a solid transparent material disposed between the at least one light source (10) and the light-emission aperture (6), wherein the at least one light source (10) comprises an LED and is disposed and oriented in the housing (4) such that it emits light in a main radiation direction (14) extending through the light-emission aperture (6), and wherein the front optics (12) closes the light-emission aperture (6) and deflects and shapes the light emitted by the at least one light source (10) to generate a light distribution corresponding to a lamp function implemented by the motorcycle lamp (2). In order for the lamp (2) to improve the lateral perceptibility without the use of additional optical elements in the optical path, it is proposed that a light-emission surface (16) of the front optics (12) has a first convex curvature when viewed in a horizontal plane (yz) and a second convex curvature when viewed in a vertical plane (xz), the latter being smaller than the first convex curvature in the horizontal plane (yz) or flat.

A lens for distribution of light predominantly toward a preferential side from a light emitter having an emitter axis. The lens has a faceted output region, a smooth output surface and at least one reflective surface which reflects light through total-internal-reflection (TIR) toward the faceted output region. The faceted output region is formed by pairs of transverse surfaces each surface of which redirects the received light to provide a composite illuminance pattern. The lens may further have faceted input surfaces at least partially defining a light-input cavity about the emitter axis. The faceted input region are formed by pairs of transverse surfaces each surface of which redirects the received light.

In an illumination system, a lens can substantially collimate light that is emitted from a location on a light source. The emitted light can have a central light portion and a peripheral light portion. The lens can have a first surface that faces the light source and a second surface opposite the first surface. The first surface can include a first convex central portion and a first total internal reflection (TIR) portion. The second surface can include a second convex central portion and a second TIR portion. The first and second convex central portions can substantially collimate the central light portion via refraction at the first convex central portion and refraction at the second convex central portion. The first and second TER portions can substantially collimate the peripheral light portion via total internal reflection at the first TIR portion and total internal reflection at the second TIR portion.

An optical system includes a splitting optic configured to receive a light beam from a light source and form a set of light bands radiating from the optical system at predetermined angles relative to illuminate a scene. The optical system further includes a lens configured to project a field of view of the scene into a two-dimensional format. The optical system further includes an optical sensor arranged offset from the central axis of the lens to capture a segment of the field of view projected by the lens.

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.

An optical device includes a reflector-section that includes a light-ingress surface for receiving light from a light source, a reflector surface for reflecting the light based on total internal reflection, and a light-egress surface through which the reflected light exits the optical device. When the light source is at a predetermined position with respect to the optical device, an angle of incidence (θ.sub.i) of the light at the light-egress surface is a polarization angle at which a p-polarized component of the light is transmitted through the light-egress surface without being reflected by the light-egress surface. Thus, unwanted reflections at the light-egress surface can be reduced and thereby unwanted scattering of light is reduced while having good transmitting efficacy.

The invention discloses an optical lens and a light emitting module having the same. The optical lens includes an incident surface around a recess in a center of the bottom surface; a light exit surface for emitting light incident; and a flange portion disposed between the light exit surface and a second edge of the bottom surface. A bottom of the recess has a width in a first axis direction that is greater than a width in a second axis direction orthogonal to the first axis direction. An outer diameter of the bottom surface has a length in the first axis direction that is smaller than a length in the second axis direction. The bottom surface includes a first rough region around the recess and second and third rough regions around the first rough region.