The illumination optical system includes a beam shaper which converts an intensity distribution of a laser beam in each of a short axis direction and a long axis direction, which is a Gaussian distribution, into an intensity distribution of a parallel beam on a modulation surface of the optical modulator in each of the short axis direction and the long axis direction, which is a top hat distribution. The modulation surface and an irradiated surface are optically conjugated with respect to the long axis direction by a third lens and a fourth lens. Further, the modulation surface and a front focus position of the fourth lens are optically conjugated with respect to the short axis direction by a first lens, a second lens, and the third lens. The fourth lens condenses a beam having a top hat distribution at the front focus position onto the irradiated surface.

An apparatus for generating a line-shaped intensity distribution of laser radiation comprises first and second beam transformation devices spaced apart from one another and at least one focusing element to focus laser radiation that has passed through the first and second beam transformation devices into a line-shaped intensity distribution. The apparatus is configured to change the line width of the line-shaped intensity distribution in a line transverse direction by changing a distance between the first and second beam transformation devices.

A laser system may include a laser resonator configured to emit an input laser beam having an elliptical cross-sectional shape. The laser system also may include first reflective device configured to reflect the input laser beam to produce a first reflected laser beam. The first reflective device may include a spherical surface for reflecting the input laser beam. The laser system also may include a second reflective device configured to reflect the first reflected laser beam to produce a second reflected laser beam. The laser system also may include a coupling device configured to focus the second reflected laser beam to produce an output laser beam. The coupling device may include a spherical surface for receiving the second reflected laser beam. The laser system also may include an optic fiber configured to transmit the output laser beam for emission of the output laser beam onto a target area.

An apparatus for light-sheet-like light illumination of a sample includes a light source configured to generate an illumination beam. A focusing system is configured to focus the illumination beam to form a light-sheet-like illumination light distribution, with which a focal plane of the sample can be illuminated. An imaging optical unit is configured to image the light-sheet-like illumination light distribution into the focal plane. A polarization element, arranged in a position conjugated to the focal plane between the focusing system and the imaging optical unit, is configured to split the illumination beam into two differently polarized sub-beams, which propagate into the imaging optical unit in different propagation directions, whereby the light-sheet-like illumination light distribution can be imaged by the imaging optical unit in the form of two differently polarized light-sheets, which from a same side of the focal plane are superimposed on each other in the focal plane.

A source module suitable for an optical coherence tomography system. The source module comprises a source operable to emit a divergent, source output beam either of circular cross-section (e.g. as output by a vertical cavity surface emitting laser) or of elliptical cross-section (e.g. as output by an edge-emitting semiconductor laser or diode). Collimation optics are provided to convert the source output beam into a non-divergent, collimated beam of elliptical cross-section having a major axis and a minor axis. A cylindrical lens is arranged with its plano axis aligned with the major axis of the elliptical collimated beam and its power axis aligned with the minor axis of the elliptical collimated beam so as to form a line focus extending along the major axis of the elliptical collimated beam.

Enhanced methods and systems for the automatic generation and rendering of anamorphic (e.g., curved, distorted, deformed, and/or warped) images are described. When viewed via a reflection from a non-planar (e.g., curved) surface, the automatically generated and rendered anamorphic images are perceived as being relatively non-distorted, deformed, and/or warped. The anamorphic images may be utilized for catoptric anamorphis, e.g., projective, mirrored and/or reflective anamorphic displays of images. Various artworks may employ the automatically generated anamorphic image, and the curved reflective surface to generate a relatively undistorted reflected image of the anamorphic image.

A catheter system for optical coherence tomography includes an elongate catheter body, an optical fiber in the elongate catheter body, and an anamorphic lens assembly coupled with a distal end of the optical fiber. The optical fiber and the lens assembly are together configured to provide a common path for optical radiation reflected from a target and from a reference interface between the distal end of the optical fiber and the lens assembly.

An apparatus and method for optically remapping projected pixels to maximize the utilization and to optimize the distribution of remapped projection pixels to achieve optimal visual performance (generally uniform resolution and luminance). A device interposed between a projector and an imaging surface for optically remapping projected pixel locations with minimal aberration. When this device is interposed between a projector and an imaging surface, it changes the terminal location of each focused pixel such that it maximally coincides with the imaging surface, which is often a surface of complex curvature and very different from the native focal surface of the projector. One implementation of the technology includes a device that uses multiple optical surfaces.

A tubular LED light fixture includes a lamp holder; printed circuit board; a plurality of point light sources; lens; strip-shaped convex lens array, located between the lens and printed circuit board and arranged along the length direction of the tubular LED light fixture for converting each point light source into a plurality of consecutive sub point light sources, and the sub point light source converted by the adjacent point light source is connected or overlapped. The invention adopts a strip-shaped convex lens array which forms a line light source only by diffusing light from the point light source only in the length direction of the strip light fixture, preventing light from diffusing in multiple directions, so that the line source is purified. The lens is arranged to perform light distribution in the other direction to the line source, thereby reducing energy attenuation and ensuring the light effect.

An optical arrangement converts laser beams from at least two laser light sources into a combination beam, which has a beam waist. The optical arrangement has: an optical beam guidance system having at least two separate optical channels for the laser beams, each of the optical channels having an optical terminator for exiting a respective channel output beam of the relevant one of the optical channels; and a deflecting body, which is associated with only one of the optical channels. The deflecting body is configured such that only the respective channel output beam of the associated one of the optical channels is captured and the captured channel output beam is deflected in a direction of a focus region.