Patent Number: 
Section: claims

1. An exposure apparatus comprising:a mask having a pattern to be projected on an exposed object;a scan line set means for setting a plurality of scan lines to be scanned by a charged particle beam on said mask, and;a charged particle beam scan means for performing interlaced-scanning by number of overjumped lines being possible to control rise in temperature of said mask due to overlapping of said charged particle beam, and for repeating said interlaced-scanning for said overjumped lines to scan all said scan lines. 2. An exposure apparatus as set forth in claim 1, wherein said charged particle beam scan means performs said interlaced-scanning by said number of overjumped lines being possible to minimize rise in temperature of said mask by reducing overlapping of said charged particle beam, and by assuring time required for once interlaced-scanning of said mask. 3. An exposure apparatus as set forth in claim 1, whereinsaid scan line set means sets a plurality of said scan lines arranged at an interval larger than a size of said pattern formed on said mask, and;said charged particle beam scan means scans with said charged particle beam having beam diameter larger than said interval of said scan lines. 4. An exposure apparatus as set forth in claim 1, wherein said charged particle beam scan means performs repeatedly interlaced-scanning of said charged particle beam in a fixed direction. 5. An exposure apparatus as set forth in claim 1, wherein said charged particle beam scan means performs interlaced-scanning of said charged particle beam repeatedly in a fixed direction and in a direction opposite to said fixed direction. 6. An exposure apparatus as set forth in claim 5, wherein said charged particle beam scan means performs interlaced-scanning repeatedly in said fixed direction and in said opposite direction to said fixed direction by the number of overjumped lines about twice the number being possible to minimize rise in temperature. 7. An exposure apparatus as set forth in claim 1, wherein said mask is a stencil mask having said pattern formed by an aperture on a thin film. 8. An exposure apparatus as set forth in claim 7, wherein said mask further comprises a beam portion reinforcing strength of said thin film and sectioning said thin film. 9. An exposure apparatus as set forth in claim 7, wherein said scan line set means sets a plurality of scan lines having length of 1.5 times or more and less than double size of a unit exposed region of said exposed object. 10. An exposure apparatus as set forth in claim 1, wherein said mask is an equal scale mask that is arranged close to said exposed object and formed with a pattern to be projected to said exposed object by an equal scale. 11. An exposure method comprising:a step of setting a plurality of scan lines to be scanned by a charged particle beam on a mask formed with a pattern to be projected to an exposed object;a step of performing interlaced-scanning by number of overjumped lines being possible to control rise in temperature of said mask due to overlapping of said charged particle beam, and;a step of repeating said interlaced-scanning for overjumped lines to scan all said scan lines by said charged particle beam. 12. An exposure method as set forth in claim 11, wherein said interlaced-scanning is performed by said number of overjumped lines being possible to be minimum rise in temperature of said mask by reducing overlapping of said charged particle beam and by assuring time required for single interlaced-scanning of said mask in the step of performing said interlaced-scanning. 13. An exposure method as set forth in claim 11, whereina plurality of said scan lines are set to be arranged at an interval larger than size of said pattern formed on said mask in the step of setting said scan line, and;said interlaced-scanning is performed by charged particle beam having beam diameter larger than said interval of said scan line in the step of performing said interlaced-scanning. 14. An exposure method as set forth in claim 11, wherein interlaced-scanning of said charged particle beam in a fixed direction is performed repeatedly in the step of repeating said interlaced-scanning. 15. An exposure method as set forth in claim 11, wherein in the step of repeating said interlaced-scanning, interlaced-scanning of said charged particle beam is performed repeatedly in a fixed direction and in a direction opposite to said fixed direction. 16. An exposure method as set forth in claim 15, wherein interlaced-scanning is performed repeatedly in said fixed direction and in said opposite direction to said fixed direction by number of overjumped lines about twice the number being possible to minimize rise in temperature. 17. An exposure method as set forth in claim 11, wherein a stencil mask formed with an aperture pattern on a thin film is used as said mask. 18. An exposure method as set forth in claim 17, wherein said stencil mask is formed with a beam portion reinforcing strength of said thin film and sectioning said thin film. 19. An exposure method as set forth in claim 11, wherein a plurality of scan lines having length of 1.5 times or more and less than double size of a unit exposed region of said exposed object is set in the step of setting said scan lines. 20. An exposure method as set forth in claim 11, wherein said mask is formed with said pattern to be projected to said exposed object by an equal scale. 21. A semiconductor device production method, forming a circuit pattern of a semiconductor device, by projecting a pattern on a resist formed on a substrate and by using said resist after projecting a pattern to process said substrate, a semiconductor device production method comprising:a step of setting a plurality of scan lines to be scanned by a charged particle beam on a mask formed with a pattern to be projected to an exposed object;a step of performing interlaced-scanning by number of overjumped lines being possible to control rise in temperature of said mask due to overlapping of said charged particle beam, and;a step of repeating said interlaced-scanning for said overjumped lines to scan all said scan lines by said charged particle beam. 22. A semiconductor device production method as set forth in claim 21, wherein said interlaced-scanning is performed by said number of overjumped lines being possible to minimize rise in temperature of said mask by reducing overlapping of said charged particle beam, and by assuring time required for once interlaced-scanning of said mask in the step of performing said interlaced-scanning. 23. A semiconductor device production method as set forth in claim 21, whereina plurality of said scan lines arranged at an interval larger than a size of said pattern formed on said mask are set in a step of setting said scan lines, and;said charged particle beam having beam diameter larger than said interval of said scan lines are used in a step of performing said interlaced-scanning. 24. A semiconductor device production method as set forth in claim 21, wherein interlaced-scanning of said charged particle beam is performed repeatedly in a fixed direction in a step of repeating said interlaced-scanning. 25. A semiconductor device production method as set forth in claim 21, wherein interlaced-scanning of said charged particle beam is performed repeatedly in a fixed direction and in a direction opposite to said fixed direction in a step of repeating said interlaced-scanning. 26. A semiconductor device production method of a as set forth in claim 25, wherein interlaced-scanning is performed repeatedly in said fixed direction and in said opposite direction to said fixed direction by the number of overjumped lines about twice the number being possible to minimize rise in temperature in a step of repeating interlaced-scanning in said fixed direction and in said opposite direction to said fixed direction.