A compensator for manipulating a radiation beam traveling along an optical path. The compensator includes a fixed support holding a first optical wedge and an adjustable support holding a second optical wedge. The adjustable support includes a base, a stage holding the second optical wedge, first and second flexures, and a drive block. The stage defines a cavity and is movable relative to the base and the fixed support. The first and second flexures couple the stage to the base such that the stage translates along a stage path. The drive block is disposed in the cavity of the stage and is configured to translate along a drive block path perpendicular to the optical path and perpendicular to the stage path. The drive block includes first and second drive bearing surfaces configured to translate the stage in first and second stage directions, respectively, along the stage path.

The disclosure provides an optical system, having a first optical control loop, which is set up to regulate a position and/or spatial orientation of a first optical element relative to a first module sensor frame, and a first module control loop, which is set up to regulate a position and/or spatial orientation of the first module sensor frame relative to a base sensor frame. Related components and methods are also provided

An arrangement of a microlithographic optical imaging device includes first and supporting structures. The first supporting structure supports an optical element of the imaging device. The first supporting structure supports the second supporting structure via supporting spring devices of a vibration decoupling device. The supporting spring devices act kinematically parallel to one another between the first and second supporting structures. Each supporting spring device defines a supporting force direction and a supporting length along the supporting force direction. The second supporting structure supports a measuring device configured to measure the position and/or orientation of the optical element in relation to a reference in at least one degree of freedom and up to all six degrees of freedom in space. A creep compensation device compensates a change in a static relative situation between the first and second supporting structures in at least one correction degree of freedom.

An arrangement of a microlithographic optical imaging device includes first and second supporting structures. The first supporting structure supports an optical element of the imaging device. The first supporting structure supports the second supporting structure via supporting spring devices of a vibration decoupling device. The supporting spring devices act kinematically parallel to one another between the first and second supporting structures. Each of the supporting spring devices defines a supporting force direction and a supporting length along the supporting force direction. The second supporting structure supports a measuring device which measures the position and/or orientation of the at least one optical element in relation to a reference in at least one degree of freedom up to all six degrees of freedom in space. A reduction device reduces a change in a static relative situation between the first and second supporting structures in at least one correction degree of freedom.

An arrangement of a microlithographic optical imaging device includes first and second supporting structures. The first supporting structure supports an optical element of the imaging device. The first supporting structure supports the second supporting structure via supporting spring devices of a vibration decoupling device. The supporting spring devices act kinematically parallel to one another between the first and second supporting structures. Each supporting spring device defines a supporting force direction and a supporting length along the supporting force direction. The second supporting structure supports a measuring device which is configured to measure the position and/or orientation of the at least one optical element in relation to a reference in at least one degree of freedom. A creep compensation device compensates a creep-induced change in a static relative situation between the first and second supporting structures in at least one correction degree of freedom.

An arrangement of a microlithographic optical imaging device includes first and second supporting structures. The first supporting structure supports at least one optical element of the imaging device via an active relative situation control device of a control device. The first supporting structure supports the second supporting structure via supporting spring devices of a vibration decoupling device. The supporting spring devices act kinematically parallel to one another. Each supporting spring device defines a supporting force direction and a supporting length along the supporting force direction. The second supporting structure supports a measuring device of the control device. The measuring device is connected to the relative situation control device. The measuring device outputs to the relative situation control device measurement information representative for the position and/or the orientation of the at least one optical element in relation to a reference in at least one degree of freedom in space.

An actuator device aligns an optical element of a projection exposure apparatus. The actuator device includes a shaft. The first end portion of the shaft is deflectably suspended from a base point of a supporting structure by way of a joint. The second end portion of the shaft is fixed on the optical element. At least one actuator unit has a translator fixed on the shaft and a stator mechanically connected to the supporting structure to apply a deflection force to the shaft to radially deflect the shaft from a middle position. A compensation device is set up to apply to the shaft, independently of the deflection force, a compensation force which increases in accordance with the deflection of the shaft from the middle position and which counteracts a restoring force acting on the shaft in the direction of the middle position caused by the weight of the optical element

An optical component holding apparatus which is capable of easily correcting tilts of optical components by reducing distortion of the optical components themselves even if the optical components are not substantially circular. A first lens and a second lens which are the optical components are housed in a lens holder. An elastic member urges the first lens against a lens holder to determine a position of the first lens in a direction of an optical axis. The lens holder, the first lens, and the elastic member abut against one another at three positions that are substantially the same when the lens holder, the first lens, and the elastic member are viewed in the direction of the optical axis.

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.

An optical arrangement of an imaging device for microlithography, particularly for using light in the extreme UV range, includes an optical element and a holding device for holding the optical element. The optical element includes an optical surface and defines a plane of main extension, in which the optical element defines a radial direction and a circumferential direction. The holding device includes a base element and more than three separate holding units. The holding units are connected to the base element and arranged in a manner distributed along the circumferential direction and spaced apart from one another. The holding units hold the optical element with respect to the base element. Each of the holding units establishes a clamping connection between the optical element and the base element. The clamping connection for each holding unit is separate from the clamping connections of the other holding units.