Patent Number: 
Section: claims

1. A charged particle beam writing apparatus, comprising:a storage unit configured to input and store a plurality of set data including a set of a proximity effect correction coefficient map and a base dose map of a beam;a first dose calculating unit configured to read each the set data and to calculate a first dose map for each set;a dimension map creation unit configured to create a dimension map of a pattern by using the first dose map calculated for each set;an adder configured to add dimensions of all sets for each position of the dimension map by using the dimension map of each set;a set map creation unit configured to create a set of a proximity effect correction coefficient map and a base dose map by using an added dimension map after addition;a second dose calculating unit configured to calculate a second dose map by using a created set of the proximity effect correction coefficient map and the base dose map; anda writing unit configured to write the pattern to a target object by using a charged particle beam of a dose defined in the second dose map. 2. The apparatus according to claim 1, wherein the plurality of set data includes the set data to correct dimensional fluctuations of a pattern caused by a loading effect when the target object is developed and the set data to correct dimensional fluctuations of a pattern caused by the loading effect when the target object is etched. 3. The apparatus according to claim 1, wherein the second dose calculating unit calculates, as the second dose map, a value obtained by further multiplying each value of a dose map calculated by using the created set of the proximity effect correction coefficient map and the base dose map by a correction coefficient of a fogging effect defined for each map position. 4. A charged particle beam writing apparatus, comprising:a storage unit configured to input and store a plurality of set data including a set of a proximity effect correction coefficient map and a base dose map of a beam;a first dose calculating unit configured to read each the set data and to calculates a first dose map for each set;a dimension map creation unit configured to create a dimension map of a pattern for each of a plurality of proximity effect densities by using the first dose map calculated for each set;an adder configured to add dimensions of all sets for each position of the dimension map for each proximity effect density by using a plurality of dimension maps for mutually different proximity effect densities of each set;a selection unit configured to select a set of a proximity effect correction coefficient and a base dose with which dimensional errors of the pattern are corrected for a part of the proximity effect densities and correction residues of dimensional errors of the pattern are generated for a remaining proximity effect densities by using a plurality of added dimension maps for the mutually different proximity effect densities after addition;a correction term calculating unit configured to calculate a correction term to correct the correction residues depending on the proximity effect density for each position of the map;a second dose calculating unit configured to calculate a second dose map by using a selected set of the proximity effect correction coefficient and the base dose and the correction term in each position of the map; anda writing unit configured to write the pattern to a target object by using a charged particle beam of a dose defined in the second dose map. 5. A charged particle beam writing apparatus, comprising:a storage unit configured to input and store a correlation information among a pattern area ratio, a proximity effect correction coefficient, and a base dose for each of a plurality of phenomena causing dimensional fluctuations in a mask plane when mask fabricating;a first set map creation unit configured to read each of the correlation information and to create a first set of a proximity effect correction coefficient map and a base dose map to correct the phenomenon for each phenomenon;a first dose calculating unit configured to calculate a first dose map by using a corresponding proximity effect correction coefficient map and a base dose map for each set of the first sets;a dimension map creation unit configured to create a dimension map of a pattern by using the first dose map calculated for each set of the first sets;an adder configured to add dimensions of all sets for each position of the dimension map by using the dimension map of each set of the first sets;a set map creation unit configured to create a second set of a proximity effect correction coefficient map and a base dose map by using an added dimension map after addition;a second dose calculating unit configured to calculate a second dose map by using the second set of the proximity effect correction coefficient map and the base dose map; anda writing unit configured to write the pattern to a target object by using a charged particle beam of a dose defined in the second dose map. 6. A charged particle beam writing apparatus, comprising:a storage device configured to input and store a plurality of pattern dimension map data for mutually different proximity effect densities indicating a distribution of a pattern dimension formed on a substrate when a pattern is written to the substrate by making the proximity effect density variable;a selection unit configured to select a set of a proximity effect correction coefficient and a base dose with which dimensional errors of the pattern dimension are corrected for a part of the proximity effect densities and correction residues of dimensional errors of the pattern dimension are generated for a remaining proximity effect densities when a writing position corresponding to a map position is written to with a dose obtained by a dose function correcting dimensional errors calculated by using the proximity effect correction coefficient and the base dose for each map position;a correction term calculating unit configured to calculate a correction term to correct the correction residues depending on the proximity effect density for each map position;a dose calculating unit configured to calculate a dose by using a selected set of the proximity effect correction coefficient and the base dose and the correction term for each map position; anda writing unit configured to write a desired pattern to the substrate by using a charged particle beam of the dose calculated for each map position. 7. The apparatus according to claim 6, wherein three proximity effect densities of 10% or less, 50%, and 90% or more are used as the mutually different proximity effect densities. 8. The apparatus according to claim 6, wherein the selection unit selects the set of the proximity effect correction coefficient and the base dose that makes the correction residues smaller for each map position. 9. The apparatus according to claim 6, wherein the dose calculating unit calculates for the each map position a value obtained by further multiplying the dose calculated by using the selected set of the proximity effect correction coefficient and the base dose and the correction term by a correction coefficient of a fogging effect defined for each map position. 10. The apparatus according to claim 6, wherein one of the mutually different proximity effect densities is set as a reference proximity effect density and the set of the proximity effect correction coefficient and the base dose is correlated so that the desired pattern dimension is obtained in the reference proximity effect density,the storage device further stores correlation data among a plurality of sets of the proximity effect correction coefficient and the base dose, the pattern dimensions obtained for each of the plurality of sets in the reference proximity effect density, and dimensional fluctuation amounts for the plurality of sets in a remaining proximity effect densities, andthe selection unit selects the set of the proximity effect correction coefficient and the base dose by referring to the correlation data. 11. A charged particle beam writing method, comprising:reading each of set data from a storage device storing a plurality of set data including a set of a proximity effect correction coefficient map and a base dose map and calculating a first dose map for each set;creating a dimension map of a pattern by using a calculated first dose map for each set;adding dimensions of all sets for each position of the dimension map by using the dimension map of each set;creating a set of a proximity effect correction coefficient map and a base dose map by using an added dimension map after addition;calculating a second dose map by using a created set of the proximity effect correction coefficient map and the base dose map; andwriting the pattern to a target object by using a charged particle beam of a dose defined in the second dose map. 12. The method according to claim 11, wherein when the second dose is calculated, a value obtained by further multiplying each value of a dose map calculated by using the created set of the proximity effect correction coefficient map and the base dose map by a correction coefficient of a fogging effect defined for each map position is calculated as the second dose map. 13. A charged particle beam writing method, comprising:reading each piece of set data from a storage device storing a plurality of set data including a set of a proximity effect correction coefficient map and a base dose map and calculating a first dose map for each set;creating a plurality of dimension maps of a pattern for a plurality of proximity effect densities by using a calculated first dose map for each set;adding dimensions of all sets in each position of the dimension map for each proximity effect density by using a plurality of dimension maps for mutually different proximity effect densities of each set;selecting a set of a proximity effect correction coefficient and a base dose with which dimensional errors of the pattern are corrected for a part of the proximity effect densities and correction residues of dimensional errors of the pattern are generated for a remaining proximity effect densities by using a plurality of added dimension maps for the mutually different proximity effect densities after addition;calculating a correction term to correct the correction residues depending on the proximity effect density for each position of the map;calculating a second dose map by using a selected set of the proximity effect correction coefficient and the base dose and the correction term in each position of the map; andwriting the pattern to a target object by using a charged particle beam of a dose defined in the second dose map. 14. A charged particle beam writing method, comprising:reading a plurality of pattern dimension map data from a storage device storing the plurality of pieces of pattern dimension map data, for mutually different proximity effect densities, indicating a distribution of a pattern dimension formed on a substrate when a pattern is written to the substrate by making the proximity effect density variable;selecting a set of a proximity effect correction coefficient and a base dose with which dimensional errors of the pattern dimension are corrected for a part of the proximity effect densities and correction residues of dimensional errors of the pattern dimension are generated for a remaining proximity effect densities when a writing position corresponding to a map position is written to with a dose obtained by a dose function correcting dimensional errors calculated by using the proximity effect correction coefficient and the base dose for each map position;calculating a correction term to correct the correction residues depending on the proximity effect density for each map position;calculating a dose by using a selected set of the proximity effect correction coefficient and the base dose and the correction term for each map position; andwriting the desired pattern to the substrate by using a charged particle beam of the dose calculated for each map position. 15. The method according to claim 14, wherein when the dose is calculated, for the each map position, a value obtained by further multiplying a dose calculated by using the selected set of the proximity effect correction coefficient and the base dose and the correction term by a correction coefficient of a fogging effect defined for each map position is calculated.