Abstract: According to one embodiment, a semiconductor device includes a plurality of first interconnects, a second interconnect, a third interconnect, and a plurality of conductive members. The plurality of first interconnects are arranged periodically to extend in one direction. The second interconnect is disposed outside a group of the plurality of first interconnects to extend in the one direction. The third interconnect is provided between the group and the second interconnect. The plurality of conductive members are disposed on a side opposite to the group as viewed from the second interconnect. A shortest distance between the first interconnect and the third interconnect, a shortest distance between the third interconnect and the second interconnect, and a shortest distance between the first interconnects are equal. A shortest distance between the second interconnect and the conductive member is longer than the shortest distance between the first interconnects.

Abstract: A pattern dimension calculation method according to one embodiment calculates a taper shape of a mask member used as a mask when a circuit pattern is processed in an upper layer of the circuit pattern formed on a substrate. The method calculates an opening angle facing the mask member from a shape prediction position on the circuit pattern on the basis of the taper shape. The method calculates a dimension of the circuit pattern according to the opening angle formed at the shape prediction position.

Abstract: According to one embodiment, a memory cell array includes memory cells arranged at crossing points of bit lines and word lines. The bit lines include first, second, third, and fourth bit lines sequentially arranged. A first sense circuit is arranged on a first end side of the memory cell array, electrically connected to the first and third bit lines. A second sense circuit is arranged on a second end side of the memory cell array, electrically connected to the second and fourth bit lines. A first hookup region is arranged between the memory cell array and the first sense circuit and includes a first transfer transistor connected to the first bit line and the first sense circuit. A second hookup region is arranged between the first hookup region and the first sense circuit and includes a second transfer transistor connected to the third bit line and the first sense circuit.

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: According to one embodiment, a mask pattern determining method includes a mask-pattern dimension variation amount of a first photomask is derived. Moreover, a correspondence relationship between a target dimension value of an on-substrate test pattern formed by using a second photomask and a dimension allowable variation amount of a mask pattern formed on the second photomask is derived. Then, it is determined whether pattern formation is possible with a pattern dimension that needs to be formed when performing the pattern formation on a substrate by using the first photomask based on the mask-pattern dimension variation amount and the correspondence relationship.

Abstract: According to the embodiments, a first representative point is set on outline pattern data on a pattern formed in a process before a processed pattern. Then, a minimum distance from the first representative point to a peripheral pattern is calculated. Then, area of a region with no pattern, which is sandwiched by the first representative point and the peripheral pattern, in a region within a predetermined range from the first representative point is calculated. Then, it is determined whether the first representative point becomes a processing failure by using the minimum distance and the area.

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 method of manufacturing a semiconductor device according to an embodiment includes determining a second exposure parameter including exposure parameters except for an exposure amount from a dimension distribution information so that a resist pattern of a first resist pattern formed based on a second pattern has a desired dimension in a plurality of regions to be shot within a surface of a wafer.

Abstract: Pattern formation simulations are performed based on design layout data subjected to OPC processing with a plurality of process parameters set in process conditions. A worst condition of the process conditions is calculated based on risk points extracted from simulation results. The design layout data or the OPC processing is changed such that when a pattern is formed under the worst condition based on the changed design layout data or the changed OPC processing a number of the risk points or a risk degree of the risk points of the pattern is smaller than the simulation result.

Abstract: A semiconductor-device manufacturing method includes: correcting a systematic component of process proximity effect, which occurs in a process other than exposure processing to thereby set a target pattern after exposure; adjusting an exposure parameter such that a difference between a dimension of the target pattern and a pattern dimension after the exposure is within tolerance; and forming, when an exposure margin calculated from the exposure parameter by using the exposure the random component of fluctuation in the process proximity effect is within the tolerance, a pattern on a semiconductor substrate with the adjusted exposure parameter.

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.

Abstract: A pattern generating method includes: extracting, from a shape of a pattern generated on a substrate, a contour of the pattern shape; setting evaluation points as verification points for the pattern shape on the contour; calculating curvatures on the contour in the evaluation points; and verifying the pattern shape based on whether the curvatures satisfy a predetermined threshold set in advance.

Abstract: A pattern data creating method comprising: referring to a first correspondence relation between an amount of dimension variation between a first pattern formed on a substrate and a second pattern formed by processing the substrate using the first pattern and either one of a pattern total surface area and a pattern boundary length of the first pattern; and creating pattern data for forming the first pattern.

Abstract: A mask verification method includes setting optical parameters, verifying whether a pattern, which is obtained when a mask pattern other than a reference pattern of patterns on a mask is transferred on a substrate with use of the set optical parameters, satisfies dimensional specifications, and varying, when the pattern which is obtained when the mask pattern is transferred on the substrate is determined to fail to satisfy the dimensional specifications, the optical parameters at the time of transfer such that the pattern, which is obtained when the reference pattern is transferred on the substrate, satisfies a target dimensional condition, and verifying whether a pattern, which is obtained when the mask pattern other than the reference pattern of the patterns on the mask is transferred on the substrate with use of the varied optical parameters, satisfies the dimensional specifications.

Abstract: According to an aspect of the present invention, there is provided a method of manufacturing a semiconductor device, the method including: forming a first film on a target film; forming resist patterns on the first film; processing the first film with the resist patterns to form first patterns including: periodic patterns; and aperiodic patterns; removing the resist patterns; forming a second film over the target film; processing the second film to form second side wall patterns on side walls of the first patterns; removing the periodic patterns; and processing the target film with the aperiodic patterns and the second side wall patterns, thereby forming a target patterns including: periodic target patterns; aperiodic target patterns; and dummy patterns arranged between the periodic target patterns and the aperiodic patterns and arranged periodically with the periodic target patterns.

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.

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: According to an aspect of the present invention, there is provided a method of manufacturing a semiconductor device, the method including: forming a first film on a target film; forming resist patterns on the first film; processing the first film with the resist patterns to form first patterns including: periodic patterns; and aperiodic patterns; removing the resist patterns; forming a second film over the target film; processing the second film to form second side wall patterns on side walls of the first patterns; removing the periodic patterns; and processing the target film with the aperiodic patterns and the second side wall patterns, thereby forming a target patterns including: periodic target patterns; aperiodic target patterns; and dummy patterns arranged between the periodic target patterns and the aperiodic patterns and arranged periodically with the periodic target patterns.

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: A method of fabricating a semiconductor device according to an embodiment includes forming a first pattern having linear parts of a constant line width and a second pattern on a foundation layer, the second pattern including parts close to the linear parts of the first pattern and parts away from the linear parts of the first pattern and constituting closed loop shapes independently of the first pattern or in a state of being connected to the first pattern and carrying out a closed loop cut at the parts of the second pattern away from the linear parts of the first pattern.