An exposure apparatus and method. The exposure apparatus includes a control system, light source system, plurality of illumination systems and plurality of projection objective lenses. The light source system is configured to emit a plurality of first illumination beams incident on the illumination systems. Each illumination system includes a variable attenuator and branch energy detector. The branch energy detector is configured to detect an illuminance level of a second illumination beam generated in the corresponding illumination system and feed it back to the control system. The control system is configured to adjust the illuminance levels of the second illumination beams in the respective illumination systems by controlling the respective variable attenuators therein. The exposure apparatus and method have improved exposure performance and allow finer and faster energy adjustments, thus enabling precise control and higher exposure accuracy.

The present invention discloses a digital photolithography method for a fiber optic device (FOD) based on a DMD combination. In this method, reflected light modulated by two DMDs is simultaneously projected onto a same position on an optical fiber end surface through one reduction projection lens. The two DMDs form a primary and secondary digital mask for joint control of an exposure dose distribution formed when patterns are shrunk and projected onto the optical fiber end surface. After the optical fiber end surface coated with photoresist is subject to this dose of exposure, developing, fixing, and etching are conducted, to form a micro-optic device on the optical fiber end surface. In the present invention, distribution of the exposure dose jointly modulated by a digital mask combination formed by the primary and secondary DMD exceeds an order of modulation of an exposure dose by a single DMD.

An exposure apparatus according to the present invention includes an illumination optical system including a first optical modulation unit having a plurality of optical modulation elements, a second optical modulation unit having a plurality of optical modulation elements, and an imaging optical system forming optical images on a predetermined plane by using lights from the first optical modulation unit and the second optical modulation unit, and a projection optical system projecting the optical image formed on the predetermined plane onto a substrate.

An illumination optical system of the present invention includes a first lens array FE including a plurality of lens cells dividing a light flux emitted from a light source into a plurality of light fluxes, a second lens array MLAi including lens cells on which spot lights exiting from the lens cells included in the first lens array FE are condensed, and a first optical member IL3 imaging the spot light, which has been condensed on the lens cell included in the second lens array MLAi, on one of optical modulation elements constituting an optical modulation unit.

Techniques are disclosed for optical distortion reduction in projection systems for scanning projection and/or lithography. A projection system includes an illumination system configured to generate illumination radiation for generating an image of an object to be projected onto an image plane of the projection system. The illumination system includes a field omitting illumination condenser configured to receive the illumination radiation from a radiation source and provide a patterned illumination radiation beam to generate the image of the object, wherein the patterned illumination radiation beam comprises an omitted illumination portion corresponding to a ridge line of a roof prism disposed within an optical path of the projection system.

The present disclosure generally relates to lithography devices comprising an image projection system. The image projection system comprises a fiber bundle coupled to a first homogenizer and a second homogenizer. The first homogenizer is offset from the second homogenizer along a scan direction. The first homogenizer is optically aligned with a first digital micromirror device, and the second homogenizer is optically aligned with a second digital micromirror device. The first digital micromirror device is offset from the second digital micromirror device along the scan direction within an optical field of view of a projection lens. A scan field of the first digital micromirror device overlaps or aligns with a scan field of the second digital micromirror device to eliminate a gap between the scan field of the first digital micromirror device and the scan field of the second digital micromirror device.

According to one embodiment, an illumination optical apparatus comprises: a light splitting device which splits the beam into a plurality of beams with respective polarization states different from each other; a spatial light modulation device which is arranged on at least one of a first optical path in which a first beam out of the plurality of beams travels and a second optical path in which a second beam out of the plurality of beams travels, and which has a plurality of optical elements arranged two-dimensionally and driven individually; and a control device which controls the spatial modulation device to combine the first beam and the second beam at least in part.

A method of producing an optical element for a lithography apparatus, comprising the steps of: a) detecting a height profile of a surface of a crystal substrate of the optical element, and b) ascertaining, using the height profile detected, an installed orientation (2, 4, 6) of the optical element in an optical system of the lithography apparatus in relation to a stress-induced birefringence on incidence of polarized radiation, where the installed orientation (2, 4, 6) is an orientation in relation to a rotation of the optical element about a center axis of the optical element that runs through the surface.

A delivery system for use within a lithographic system. The beam delivery system comprises optical elements arranged to receive a radiation beam from a radiation source and to reflect portions of radiation along one or more directions to form a one or more branch radiation beams for provision to one or more tools.

An exposure apparatus includes a stage on which a substrate is placed, a plurality of light irradiation units configured to emit light independently of each other to different positions in a right and left direction on a surface of the substrate, so as to form a strip-like irradiation area extending from one end of the surface of the substrate to the other end of the substrate, a stage moving mechanism configured to move the stage in a back and forth direction relative to the irradiation area, such that the whole surface of the substrate is exposed, and a light receiving unit configured move in the irradiation area between one end and the other end of the irradiation area in order to detect an illuminance distribution of the irradiation area in a longitudinal direction of the irradiation area.