Patent Number: 
Section: claims

1. A lithography system in which an electronic image pattern is delivered to a charged particle exposure tool for projecting an image on a target surface, said exposure tool including a frame for elements constituting a charged particle projection column, and said exposure tool comprising a vacuum housing for housing said frame and particle column, and said lithography system comprising a control unit external to said vacuum housing for controlling exposure projections by means of control data, said control data being provided to a modulator for modulating charged particle beams generated in said exposure tool, said control data being provided via an optical interconnect conveying modulated light signals, said beam modulator thereto comprising an array of deflectors for modulating projection beams and light sensitive areas for receiving said control data, and said beam modulator at least partly extending in a charged particle projection space of said exposure tool, and being included in said element frame via a modulator holder, said control data finally being coupled in to said modulator using a free space optical interconnect for emitting modulated light beams to said light sensitive parts of said beam modulator, said optical interconnect further comprising an array of fibers coupled into said tool via a part of said vacuum housing, wherein an inner vacuum housing end part of said fibers is at its end mechanically secured to a light optics housing which in turn is secured to said modulator holder. 2. A system according to claim 1, wherein said feed through housing part is demountable. 3. A system according to claim 1, wherein said inner vacuum housing end part of said fibers is secured from outside mechanical impulses. 4. A system according to claim 1, wherein a feed through of an array of fibers in said vacuum housing realizes an air tight sealing by using a sealing material. 5. A system according to claim 1, wherein said light optics housing secures the positions of fiber ends of said array of fibers relative to light sensitive areas of the modulator. 6. A system according to claim 1, wherein the optics housing houses a lens part of the light optics interconnect. 7. A system according to claim 1, wherein the optics housing houses a mirror part of the light optics interconnect. 8. A system according to claim 7, wherein said mirror is holed. 9. A lithography system according to claim 1, in which an electronic image pattern is delivered to an exposure tool formed by a writing tool by means of light projection, utilizing an exposure projection, in particular a multi beam system for mask-less projection of a pattern on to an exposure surface, comprising a vacuum housing within which such writing tool is incorporated,a multi beam projection source being present, creating a plurality of writing beams for writing said pattern,which writing beams are directed to an blanker array comprising a control unit with individual controllers such as electrostatic blanker deflectors for individually controlling a writing beam in accordance received pattern information, in particular deflecting a writing beam or not, to a beam stopping part,a light optical system comprising light transmitting parts being present for transmitting pattern information signals to such controllers, in particular blanker deflectors,which controllers comprise light sensitive elements for receiving such modulated light beams, such light sensitive elements preferably being accommodated within near vicinity of the deflectors,said light optical system comprising a free space optical interconnect, forming a light optical data carrier system, transmitting pattern data carrying, modulated light beams towards said controllers,which free space optical interconnect comprises an emitter part emitting free space interconnect, pattern data carrying light beams to said light sensitive elements,whereinsaid free space optical interconnect comprises a holey mirror, incorporated in the projection trajectory of said plurality of writing beams,said mirror being arranged relative to said emitter part and said light sensitive elements to realize an on-axis incidence of said light beams on said light sensitive elements,and said mirror being provided with at least one hole allowing passage of one or more of said writing beams. 10. A system according to claim 1, in which an emitting part is incorporated to emit said light beams at least virtually perpendicular relative to a direction of said exposure projection. 11. A system according to claim 10, wherein said writing tool preferably utilizing a multi beam system for preferably mask-less projection of a pattern on to an exposure surface, comprising a vacuum housing within which such lithographic system is incorporated. 12. A system according to claim 1, in which said free space interconnect is included at a down stream side of the control unit. 13. A system according to claim 1, in which said free space interconnect, including an emitter and said holey mirror is included in a housing that is mechanically connected to the control unit, in particular a blanker array, more in particular via a holder therefore. 14. A system according to claim 1, in which a focusing lens is incorporated in said free space optical interconnect in near proximity to said holey mirror, in particular significantly nearer to said mirror than to said emitter, said lens in particular being common to all of the light beams emitted by said emitter. 15. A system according to claim 1, in which a micro lens is incorporated in said free space optical interconnect, in particular thereby forming said emitter, in close proximity to a light carrier end, in particular significantly closer to said carrier end than to said holey mirror, in particular each light carrier composing part such as an optic fiber end being provided with a micro lens. 16. A system according to claim 1, wherein the free space optical interconnect comprises a micro lens and a focusing lens common to a possible plurality of micro-lens completed fibers, the micro lens therein magnifying a fiber transmitted light signal, and the focusing lens de-magnifying the entirety of light signals transmitted by said possible plurality of fibers. 17. A system according to claim 1, wherein said free space optical interconnect is included in between a control unit formed by a blanker array for blanking writing beams, and a stopping plate for stopping writing beams deflected by said blanker array. 18. A system according to claim 1, wherein one or more light signal carriers are fed through a vacuum wall for the exposure tool using vacuum compatible sealing material, and are with end parts thereof subsequently mechanically coupled to a free space optical connect housing located in a vacuum space for the charged particle beam column. 19. A lithography system in which an electronic image pattern is delivered to a charged particle exposure tool for projecting an image on a target surface, said exposure tool including a frame for elements constituting a charged particle projection column, and said exposure tool comprising a vacuum housing for housing said frame and particle column, and said lithography system comprising a control unit external to said vacuum housing for controlling exposure projections by means of control data, said control data being provided to a modulator for modulating charged particle beams generated in said exposure tool, said control data being provided via an optical interconnect conveying modulated light signals, said beam modulator thereto comprising an array of deflectors for modulating projection beams and light sensitive areas for receiving said control data, and said beam modulator at least partly extending in a charged particle projection space of said exposure tool, and being included in said element frame via a modulator holder, said control data finally being coupled in to said modulator using an optical interconnect for transmitting light beams to said light sensitive parts of said beam modulator, said optical interconnect further comprising an array of fibers coupled into said tool via a part of said vacuum housing, wherein the array of fibers is fed through an opening in a part of said housing by using an amount of vacuum compatible sealing material for realizing an air tight sealing of the fibers in the opening. 20. Lithography system according to claim 19, wherein the array of fibers is fed through the opening in a demountable part of said housing.