Abstract: A pattern predicting method according to one embodiment includes obtaining shape data of a target pattern from shape data of a second pattern to be formed by transferring a first pattern at predetermined process conditions by using a first neutral network, the target pattern being to be a target of the second pattern when the first pattern is transferred at the predetermined process conditions, so as to keep the transferred patterns within an acceptable range, the transferred patterns being formed by transferring the first pattern at process conditions changed from the predetermined process conditions and obtaining shape data of a new first pattern for forming the target pattern at the predetermined process conditions by using a second neutral network.

Abstract: A design layout data creating method includes creating design layout data of a semiconductor device such that patterns formed on a wafer when patterns corresponding to the design layout data are formed on the wafer have a pattern coverage ratio within a predetermined range in a wafer surface and total peripheral length of the patterns formed on the wafer when the patterns corresponding to the design layout are formed on the wafer is pattern peripheral length within a predetermined range.

Abstract: A pattern verification method according to an embodiment includes, dividing a pattern data region or a pattern formation region formed based on the pattern data to a plurality of unit regions, calculating a pattern area ratio with respect to each unit region, calculating differences in the amount of the pattern area ratio between each unit region and adjacent unit regions thereto, setting the number or density of measurement point with respect to each unit region to the pattern of the pattern data region or the pattern formation region according to the difference in the amount of pattern area ratio, measuring the pattern size at each measurement point, and verifying whether the size measurement value is within a predetermined range or not.

Abstract: A method of manufacturing a semiconductor device, which forms a pattern by performing pattern transformation steps multiple times, comprises setting finished pattern sizes for patterns to be formed in each consecutive two pattern transformation steps among the plurality of pattern transformation steps based on a possible total amount of in-plane size variation of the patterns to be formed in the consecutive two pattern transformation steps.

Abstract: According to an aspect of the present invention, there is provided a mask pattern data generation method including: a first step of obtaining a mask data representing from a design pattern by performing a process simulation with a process parameter having a first value; a second step of obtaining a finished pattern from the mask data by performing the process simulation with the process parameter having a different value; a third step of verifying whether a dimensional error therebetween is within an allowable range; and a fourth step of: if the dimensional error is within the allowable range, determining the mask pattern data; and if the dimensional error is not within the allowable range, repeating the above steps by updating the process parameter until the dimensional error becomes within the allowable range.

Abstract: A pattern generation method includes: acquiring a first design constraint for first patterns to be formed on a process target film by a first process, the first design constraint using, as indices, a pattern width of an arbitrary one of the first patterns, and a space between the arbitrary pattern and a pattern adjacent to the arbitrary pattern; correcting the first design constraint in accordance with pattern conversion by the second process, and thereby acquiring a second design constraint for the second pattern which uses, as indices, two patterns on both sides of a predetermined pattern space of the second pattern; judging whether the design pattern fulfils the second design constraint; and changing the design pattern so as to correspond to a value allowed by the second design constraint when the design constraint is not fulfilled.

Abstract: In a pattern layout which includes a first device pattern having a uniformly repeated pattern group having first lines and first spaces formed parallel to one anther and uniformly arranged with constant width at a constant pitch and a non-uniformly repeated pattern group having first lines and first spaces non-uniformly arranged, and a second device pattern arranged adjacent to the end portion of the non-uniformly repeated pattern group in an arrangement direction thereof and having second lines and second spaces whose widths are larger than the widths of the first lines and first spaces of the non-uniformly repeated pattern group, at least part of the widths of the first lines and the first spaces of the non-uniformly repeated pattern group is made larger than the width of the first line or the width of the first space of the uniformly repeated pattern group.

Abstract: A lithography simulation method which predicts the result that a pattern formed on a mask is transferred onto a sample by use of a simulation based on pattern data of the mask includes subjecting a mask layout containing a pattern whose periodicity is disturbed to the simulation. At this time, a calculation area of pattern data used for the simulation is set to an integral multiple of minimum periodic length of the mask layout.

Abstract: A pattern layout for forming an integrated circuit includes a first device pattern, a second device pattern, and an auxiliary pattern. The first device pattern includes a line and a space alternately arrayed on a fixed pitch having regular intervals in a first direction. The second device pattern is disposed on the fixed pitch and separated from the first device pattern in the first direction. The second device pattern has a pattern width an odd-number times larger than the regular intervals of the fixed pitch, wherein the odd-number is set to be three or more. The auxiliary pattern is disposed on the fixed pitch and within the second device pattern and configured not to be resolved by light exposure.

Abstract: According to this invention, the NAND type flash memory of high reliability is realized. It provides a semiconductor memory device comprising: a plurality of memory cells; a plurality of word lines formed by a first gate wiring layer; a plurality of first transistors for providing voltages to said word lines; and electrical connections for connection said word lines and sources or drains of said first transistors, said electrical connections being formed of both first wirings of a first wiring layer formed above said first gate wiring layer and second wirings of a second wiring layers formed above said first wiring layer.

Abstract: A semiconductor device includes a semiconductor substrate, and a circuit pattern group comprising at least N (?2) circuit pattern on the semiconductor substrate, at least one vicinity of end portion among the at least of N circuit patterns including a connection area to electrically connect to a circuit pattern in another circuit pattern group different from the circuit pattern group, the at least N wirings pattern including a circuit pattern N1 and at least one circuit pattern Ni (i?2) arranged in one direction different from longitudinal direction of the circuit pattern N1, the at least one circuit patterns Ni having larger i being arranged at further position away from the circuit pattern N1, and in terms of a pattern including the connection area among the at least of Ni circuit patterns, the larger the i, the connection area being arranged at a further position in longitudinal direction.