A linear light concentrator includes a light emitting body and first and second optical element groups, wherein the first optical element group is divided in first and second directions into first optical elements, each having characteristics to deflect a beam in the first direction, and the characteristics of the first optical elements adjacent in the second direction are different, the second optical element group is divided in at least the first direction into second optical elements having a power in the second direction, and center axes of refraction of adjacent second optical elements are shifted in the second direction, the characteristics deflect a beam from each unit of the first optical elements arranged in the first direction toward one of apertures of the second optical element group, and a length in the second direction of the second optical element is longer than that of the first optical element.

Disclosed herein are techniques for providing an illumination system that emits illumination into an environment while also enabling that system to be undetectable to certain types of external light detection systems. The system includes a single photon avalanche diode (SPAD) low light (LL) detection device and a light emitting device. The light emitting device provides illumination having a wavelength of at least 950 nanometers (nm). An intensity of the illumination is set to a level that causes the illumination to be undetectable from a determined distance away based on the roll off rate of the light. While the light emitting device is providing the illumination, the SPAD LL detection device generates an image of an environment in which the illumination is being provided.

The present invention relates to the technical area of lens, particularly discloses a lens for focusing or collimating light emitted from an extended light source, which comprises a front surface facing towards the extended light source and a back surface facing away from the extended light source, wherein at least one of the surfaces comprises a central section and a plurality of annular sections concentrically surrounding the central section; and wherein each of the annular section corresponds to a small portion of the extended light source. A method of designing the above lens is also disclosed. Additionally, the present invention provides a cost-effective lens design with high precision and more particularly, a lens design which meets the transmittance requirement for extended light source.

Light emitting systems and optical systems including a light emitting system and a lens system are described. The light emitting system includes a pixelated light source having a plurality of discrete spaced apart pixels, and includes a plurality of light redirecting elements, each light redirecting element corresponding to a different pixel in the plurality of pixels. The light redirecting elements may be adapted to alter one or both of a central ray direction and a divergence angle of light received from the corresponding pixel. A lens system disposed to receive light from the light emitting system may include a reflective polarizer and a partial reflector.

A light guide includes a first exit portion emitting first exiting light, a second exit portion emitting second exiting light in a different direction than the first exiting light, and a reflecting portion reflecting light entering the light guide to each of the first and second exit portions. The first and second exit portions respectively have first and second curved surfaces each having a convex cross section perpendicular to the long axis direction. The second exit portion is connected to the first exit portion in the direction perpendicular to the long axis direction. The reflecting portion is provided, in a plane facing the first exit portion and the second exit portion, at a position shifted in the direction perpendicular to the long axis direction from a position where a normal to the plane passes through a connection portion between the first and second exit portions.

Provided is an illumination optical apparatus that illuminates the surface with light from a light source and includes an optical integrator (the integrator) configured to form a plurality of secondary source images (the images); a adjuster having a plurality of adjusting elements for adjusting a light of the images; and a consensor configured such that the adjuster is in a conjugate relationship with the end surface of the integrator, wherein the element is located at positions, which corresponds to a secondary source formed by an odd reflection times in the first direction by the integrator and a secondary source formed by an even times and a secondary source formed by an odd times in the second direction and a secondary source formed by an even times, wherein the element is not located at a position which corresponds to a secondary source formed by no reflection in the integrator.

An object of the present invention is to provide a technique capable of easily manufacturing a desired optical device at the inside of a transparent board. An optical device according to the present invention is manufactured by denaturing the vicinity of a hollow structure at the inside of the transparent board and deforming the shape of the hollow structure

An integrated imaging display system is provided. The integrated imaging display system includes: a light source, a converging lens, an illumination microlens array, and a projection microlens array, where illumination microlens units in the illumination microlens array and projection microlens units in the projection microlens array are disposed in a one-to-one correspondence, and the converging lens converts all light emitted by the light source into parallel light and then irradiates the parallel light to the illumination microlens array; a sub-image is provided on a side of each of the illumination microlens units close to the projection microlens unit; all light emitted by each of the illumination microlens units is irradiated on a corresponding projection microlens unit after passing through the sub-image, and the projection microlens array displays an image of the sub-image.

An apparatus for laser processing of very wide non-woven fabric materials at high speeds. This invention enables a laser beam to sever, perforate and pattern a large piece of fabric materials planarly disposed at regular or irregular spatial intervals over the entire width while the fabric passes from one roller to another roller at high speeds by precisely managing focus and intensity of the beam at the focal point on the web. A control system managing the laser processing system enables rapid reconfiguration of perforation patterns. The fabric can be woven or nonwoven, homogeneous or nonhomogeneous material with uniform or nonuniform thickness. An optical sensor is provided to sense the laser processing as it is performed and provide feedback to a system controller to optimize laser processing performance in real time.

A stealth dicing laser device including: a pulse laser generator configured to generate laser light; a condenser lens formed in an optical path of the laser light; a pupil filter configured to transform a phase of the laser light before the laser light passes through the condenser lens; and a controller configured to provide a phase control signal to the pupil filter, wherein the pupil filter transforms the phase of the laser light based on the phase control signal, wherein the phase control signal is a signal transforming a phase expression of the laser light based on a parameter.