A laser system including: A. a laser apparatus configured to output a pulse laser beam; B. an optical pulse stretcher including a delay optical path for expanding a pulse width of the pulse laser beam; and C. a phase optical element included in the delay optical path and having a function of spatially and randomly shifting a phase of the pulse laser beam. The phase optical element includes a plurality of types of cells providing different amounts of phase shift to the pulse laser beam and arranged irregularly in any direction.

A faceted reflector (32, 32″) for receiving an incident radiation beam (2) and directing a reflected radiation beam at a target. The faceted reflector comprises a plurality of facets, each of the plurality of facets comprising a reflective surface. The reflective surfaces of each of a first subset of the plurality of facets define respective parts of a first continuous surface and are arranged to reflect respective first portions of the incident radiation beam in a first direction to provide a first portion of the reflected radiation beam. The reflective surfaces of each of a second subset of the plurality of facets define respective parts of a second continuous surface and are arranged to reflect respective second portions of the incident radiation beam in a second direction to provide a second portion of the reflected radiation beam.

A reflective optical element includes a first, inner surface region for reflecting a first inner beam portion of a light beam impinging on the reflective optical element in order to form a first reflected light beam, and at least one second, outer surface region for reflecting at least one second outer beam portion of the impinging light beam for forming at least one second reflected light beam. The second surface region is designed to reduce a beam cross section of the second reflected light beam by comparison to the first reflected light beam such that the second reflected light beam extends along a superposition length completely within the first reflected light beam. In addition a beam guiding device has at least one such reflective optical element and an EUV-beam generating device has such a beam guiding device.

A reflective beam former for changing a diameter of a collimated light beam. A first mirror surface of a first curvature type, a second mirror surface and a third mirror surface are in a beam path; the shapes of the surfaces cause a collimated light beam entering the beam former via a first or third mirror surface to leave via the third or first mirror surface, respectively. The beam former includes several third, curved mirror surfaces of a second, different curvature type, one type being convex, the other concave. The second mirror surface is a plane mirror surface with an axis perpendicular to the plane mirror surface, and is in the beam path between the first and one selected from the several third mirror surfaces such that the surfaces are confocal to each other. The beam former includes a selector for selecting one of the several third curved mirror surfaces.

An optical lens assembly includes an optical lens and a Pancharatnam Berry Phase (“PBP”) element coupled to the optical lens. The PBP element is configured to provide chromatic aberration correction for the optical lens. An Abbe number of the PBP element and an Abbe number of the optical lens have opposite signs.

Provided is an optoelectronic light source that includes a plurality of semiconductor lasers each configured to emit a laser beam and arranged on a mounting platform, and a redirecting optical element configured to redirect the laser beams. The redirecting optical element includes for each one of the plurality of semiconductor lasers a separate reflection zone, the reflection zones are shaped differently from one another, and after passing the redirecting optical element, the laser beams run in a common plane.

A light modulator includes a beam homogenizer having microstructure, and a curved light transmitting substrate having at least one curving surface, wherein the beam homogenizer is arranged on the curving surface of the curved light transmitting substrate to configure the microstructure of the beam homogenizer on the curving surface of the curved light transmitting substrate.

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.

A device for shaping laser radiation (2), with a first array (7) of optical elements for deflecting and/or imaging and/or collimating the laser radiation (2), the first array (7) having a plurality of optical elements arranged side by side in a first direction (X), and a second array (8) of optical elements for deflecting and/or imaging and/or collimating the laser radiation (2), the second array (8) having a plurality of optical elements arranged side by side in the second direction (Y), wherein the optical elements of at least one of the arrays (7, 8) are mirror elements (9, 10).

A device and a method for beam shaping and beam movement during laser material processing with a laser beam source (1) for continuously emitting a laser beam (2), a first optical deflection element (3), a second optical deflection element (4), and an optical focusing element (5) arranged between the second optical deflection element (4) and a workpiece surface (7) to be processed. The second optical deflection element (4) is configured to displace a point of incidence of the laser beam (2) on the workpiece surface (7), and the first optical deflection element (3) is configured to alter a position of a focal plane of the laser beam (2) relative to the workpiece surface (7) by means of a translational movement and/or to change an intensity distribution within a beam cross section of the laser beam.