A beam reverser module for an optical power amplifier of a laser arrangement comprises at least one reflecting surface for receiving an incoming laser beam propagating in a first direction and reflecting the incoming laser beam into a second direction different from the first direction, wherein the at least one reflecting surface is a highly reflecting surface of at least one mirror.

An optical module for a machine for machining workpieces and/or for producing molded bodies by way of location-selective solidification of material powder into contiguous regions by a laser beam includes a housing for releasably fastening the optical module to the machine and a collimation optics changer releasably arranged in the housing, having at least two collimation optics which can be moved into a beam path of the laser beam for collimating the laser beam. The collimation optics changer has a mechanism for automatically changing the collimation optics.

An optical module for a machine for machining workpieces and/or for producing molded bodies by location-selective solidification of material powder to form connected regions by a focused laser beam includes a housing for releasably attaching the optical module to the machine and a plurality of optical components are arranged in or on the housing to collimate and focus the laser beam.

A display mirror assembly for a vehicle includes a housing. An electro-optic element may be operably coupled with the housing. A circuit board may be adjacent the electro-optic element. An electrostatic fluid accelerator may be adjacent the circuit board and may be configured to move ions within the housing. An actuator device may be disposed on the housing and may be operably coupled with the electro-optic element. The actuator device may be adjustable to tilt the electro-optic element in one direction, thereby moving the electro-optic element to an off-axis position which approximately simultaneously changes an activation state of a display module. The actuator device may be also adjustable to tilt the electro-optic element in another direction, thereby moving the electro-optic element to an on-axis position which approximately simultaneously changes the activation state of the display module.

An electro-optical apparatus has an element substrate that is provided with a mirror and a sealing member which seals the mirror, and the sealing member includes a light-transmitting cover which faces the mirror opposite from the element substrate. An infrared cut filter is laminated on the light-transmitting cover.

A method for temperature control of a component that is transferable between a first system and a second system includes: ascertaining a temperature drift of a temperature of the component that is to be expected after transfer of the component from the first system into the second system; and modifying a temperature prevailing in the first system and/or a temperature prevailing in the second system such that the temperature drift that is actually occurring after transfer of the component from the first system into the second system is reduced with respect to the expected temperature drift.

[Solving Means] A composite-optical-system unit includes a polarization beam splitter and a thermal conduction member. The polarization beam splitter includes a first prism including a first surface, a second prism including a second surface having an area different from an area of the first surface, and an overlap interface on which the first surface is attached to and overlaps the second surface. The thermal conduction member is thermally connected to a connection region being a region other than the overlap interface of the first surface or the second surface having an area larger than an area of the other surface.

An image modulating system including layers such as a formatter plate (PCB), an electrical connector plate called an interposer, a back cooling block, a front cooling frame and a reflective spatial light modulator. A cooling heat transfer channel is provided to transfer heat between the front cooling frame of the light valve and the back cooling block of the reflective spatial light modulator so as to reduce the thermal gradient between the front and back of the reflective spatial light modulator. The cooling heat transfer channel passes through any intervening layers such as the formatter plate (PCB), and/or the electrical connector plate called the interposer. The cooling heat transfer channel is preferably formed of a heat pipe or a circulating cooling medium.

A beam-forming unit for forming a laser beam and focusing the laser beam onto a workpiece, the unit including a movable component, an immovable component, and a cooling system configured for movement of a cooling medium to actively cool the movable component, wherein the cooling system has a cooling water circuit on the immovable component configured for water cooling of the immovable component and the cooling medium, and wherein the cooling system is within an outer housing of that is sealed from the environment.

A system for heating an optical component of a lithographic apparatus, the system comprising a heating radiation source, the heating radiation source being configured to emit heating radiation for heating of the optical component, wherein the system is configured to direct the heating radiation emitted by the heating radiation source onto the optical component, a portion of the heating radiation being absorbed by the optical component and another portion of the heating radiation being reflected by optical component, and wherein the system is configured to vary or change a property of the heating radiation emitted by the heating radiation source such that the other portion of the heating radiation that is reflected by the optical component is constant during operation of the lithographic apparatus.