Abstract: A semiconductor device includes a first transistor formed on a semiconductor substrate, and including a first channel region, and a first gate electrode formed on the first channel region, and a second transistor formed on the semiconductor substrate, and including a second channel region having a conductivity type identical to a conductivity type of the first channel region, and a second gate electrode formed on the second channel region and having a potential identical to a potential of the first gate electrode. A drain of the first transistor is electrically connected to a source of the second transistor. An absolute value of a threshold voltage of the first transistor is greater than an absolute value of a threshold voltage of the second transistor.

Abstract: A semiconductor device includes a first MIS transistor on a first active region of a semiconductor substrate, the first MIS transistor including: a first gate insulating film provided on the first active region; a first gate electrode provided on the first gate insulating film; a first stressor insulating film provided on an upper face and side faces facing in a gate length direction of the first gate electrode such that first stress acts on a channel of the first MIS transistor in the gate length direction; and a first base insulating film provided on side faces of the first gate electrode facing in a gate width direction, wherein the side faces of the first gate electrode facing in the gate width direction are not covered with the first stressor insulating film.

Abstract: A circuit simulation apparatus has a means to acquire data regarding a transistor, a model parameter generation unit for generating a model parameter representing effects of stress upon the transistor active region caused by the isolation region, and a simulation execution unit for evaluating characteristics of the transistor using a simulation program associated with the model parameter. The model parameter includes a term regarding width of the transistor active region, a term regarding width of the peripheral active region, and a term regarding width between the transistor active region and the peripheral active region.

Abstract: A semiconductor device includes a semiconductor substrate; a diffusion region which is formed in the semiconductor substrate and serves as a region for the formation of a MIS transistor; an element isolation region surrounding the diffusion region; at least one gate conductor film which is formed across the diffusion region and the element isolation region, includes a gate electrode part located on the diffusion region and a gate interconnect part located on the element isolation region, and has a constant dimension in the gate length direction; and an interlayer insulating film covering the gate electrode. The semiconductor device further includes a gate contact which passes through the interlayer insulating film, is connected to the gate interconnect part, and has the dimension in the gate length direction larger than the gate interconnect part.

Abstract: In a cell comprising an N well and a P well, a distance SP04 from a center line of a contact N-type region to an N well end of the N well is set to be a distance which causes a transistor not to be affected by resist. A distance from a well boundary to the center line of the contact N-type region is equal to SP04. A design on the P well is similar to that on the N well. Thereby, modeling of the transistor in the cell can be performed, taking into consideration an influence from resist in one direction. Also, by fabricating a cell array which satisfies the above-described conditions, design accuracy can be improved.

Abstract: An integrated circuit includes: a first well of a first conductivity type; a second well of a second conductivity type coming into contact with the first well at a well boundary extending in a gate length direction; a first transistor having a first active region of the second conductivity type provided in the first well; and a second transistor which has a second active region of the second conductivity type provided in the first well and differing from the first active region in length in a gate width direction. The center location of the first active region in the gate width direction is aligned with the center location of the second active region in the gate width direction with reference to the well boundary.

Abstract: A first PMIS transistor includes a first active region which is formed on a semiconductor substrate and a first gate electrode which is formed on the first active region and which is connected at one end thereof to a first gate wiring and includes at the other end thereof a first protruding portion protruding at a side opposite to the first gate wiring side from the first active region A first NMIS transistor includes a second active region which is formed on the semiconductor substrate with a space left from the first active region and a second gate electrode which is formed on the second active region and which is connected at one end thereof to the first gate wiring and includes at the other end thereof a second protruding portion protruding at a side opposite to the first gate wiring side from the second active region. A protruding length of the first protruding portion of the first PMIS transistor is greater than a protruding length of the second protruding portion of the first NMIS transistor.

Abstract: An integrated circuit includes: a first well of a first conductivity type; a second well of a second conductivity type coming into contact with the first well at a well boundary extending in a gate length direction; a first transistor having a first active region of the second conductivity type provided in the first well; and a second transistor which has a second active region of the second conductivity type provided in the first well and differing from the first active region in length in a gate width direction. The center location of the first active region in the gate width direction is aligned with the center location of the second active region in the gate width direction with reference to the well boundary.

Abstract: A semiconductor device includes a first MIS transistor on a first active region of a semiconductor substrate, the first MIS transistor including: a first gate insulating film provided on the first active region; a first gate electrode provided on the first gate insulating film; a first stressor insulating film provided on an upper face and side faces facing in a gate length direction of the first gate electrode such that first stress acts on a channel of the first MIS transistor in the gate length direction; and a first base insulating film provided on side faces of the first gate electrode facing in a gate width direction, wherein the side faces of the first gate electrode facing in the gate width direction are not covered with the first stressor insulating film.

Abstract: A circuit simulation apparatus has a means to acquire data regarding a transistor, a model parameter generation unit for generating a model parameter representing effects of stress upon the transistor active region caused by the isolation region, and a simulation execution unit for evaluating characteristics of the transistor using a simulation program associated with the model parameter. The model parameter includes a term regarding width of the transistor active region, a term regarding width of the peripheral active region, and a term regarding width between the transistor active region and the peripheral active region.

Abstract: The effective distance Deff_i between a well boundary and an active region of a transistor is used as a parameter for expressing a well proximity effect. For example, a delay library is created using the rising time Tslew of a signal input to the gate, load capacitance Cload at the output side and Deff_i. The use of the effective distance Deff_i between the well boundary and the transistor allows very simple modeling to be accurately performed, so that a gate-level simulation considering a well proximity effect at an LSI level is enabled.

Abstract: A semiconductor device includes a semiconductor substrate; a diffusion region which is formed in the semiconductor substrate and serves as a region for the formation of a MIS transistor; an element isolation region surrounding the diffusion region; at least one gate conductor film which is formed across the diffusion region and the element isolation region, includes a gate electrode part located on the diffusion region and a gate interconnect part located on the element isolation region, and has a constant dimension in the gate length direction; and an interlayer insulating film covering the gate electrode. The semiconductor device further includes a gate contact which passes through the interlayer insulating film, is connected to the gate interconnect part, and has the dimension in the gate length direction larger than the gate interconnect part.

Abstract: By using, as a model expression, an expression showing an inverse proportion between a change rate ?Idsat/Idsat of saturated current value and a product of a gate protrusion length E1 and a gate width Wg of a transistor and a coefficient, modeling is executed for a transistor property that depends on the gate protrusion length. This provides a circuit simulation that takes into consideration the gate protrusion length of a gate electrode.

Abstract: A semiconductor evaluation device evaluates an amount of mask misalignment in an optical exposure step during the fabrication of a semiconductor device. The semiconductor evaluation device has a first semiconductor region selectively formed in a semiconductor substrate, a first gate electrode having a cross-shaped plan configuration, formed on the first semiconductor region with a first gate insulating film interposed therebetween, and an intersecting portion at which a first gate portion disposed in an X-axis direction and a second gate portion disposed in a Y-axis direction intersect each other, and a first impurity diffusion layer formed in the area of the first semiconductor region which is other than the portion thereof underlying the first gate electrode and partitioned by the first gate electrode into four diffusion regions.

Abstract: A semiconductor device includes a semiconductor substrate; a diffusion region which is formed in the semiconductor substrate and serves as a region for the formation of a MIS transistor; an element isolation region surrounding the diffusion region; at least one gate conductor film which is formed across the diffusion region and the element isolation region, includes a gate electrode part located on the diffusion region and a gate interconnect part located on the element isolation region, and has a constant dimension in the gate length direction; and an interlayer insulating film covering the gate electrode. The semiconductor device further includes a gate contact which passes through the interlayer insulating film, is connected to the gate interconnect part, and has the dimension in the gate length direction larger than the gate interconnect part.

Abstract: In a cell comprising an N well and a P well, a distance SP04 from a center line of a contact N-type region to an N well end of the N well is set to be a distance which causes a transistor not to be affected by resist. A distance from a well boundary to the center line of the contact N-type region is equal to SP04. A design on the P well is similar to that on the N well. Thereby, modeling of the transistor in the cell can be performed, taking into consideration an influence from resist in one direction. Also, by fabricating a cell array which satisfies the above-described conditions, design accuracy can be improved.

Abstract: In a standard cell in which an active area and a gate conductor are provided, the active area has a largest length in a gate width direction at an end thereof in a gate length direction.

Abstract: A first PMIS transistor includes a first active region which is formed on a semiconductor substrate and a first gate electrode which is formed on the first active region and which is connected at one end thereof to a first gate wiring and includes at the other end thereof a first protruding portion protruding at a side opposite to the first gate wiring side from the first active region A first NMIS transistor includes a second active region which is formed on the semiconductor substrate with a space left from the first active region and a second gate electrode which is formed on the second active region and which is connected at one end thereof to the first gate wiring and includes at the other end thereof a second protruding portion protruding at a side opposite to the first gate wiring side from the second active region. A protruding length of the first protruding portion of the first PMIS transistor is greater than a protruding length of the second protruding portion of the first NMIS transistor.

Abstract: In designing a semiconductor integrated circuit, circuit information used for circuit simulation is extracted from measurement values of electric characteristics of a device included in TEG and parameters included in a netlist are modified using the measurement values and simulation values. Circuit simulation is carried out using the thus modified netlist to lead to a decrease in error in the circuit simulation which is caused due to difference between design dimension and actual finished dimension, thereby preventing an increase in design margin and a yield lowering by malfunction.

Abstract: A method for designing a semiconductor integrated circuit includes: a step (a) of setting basic patterns including a plurality of active region/gate patterns each including a gate and an active region and a dummy gate while taking account of patterns of gates on the respective sides of each gate; a step (b) of forming a plurality of basic pattern combinations by combining some of the basic patterns; and a step (c) of forming a standard cell by combining some of the plurality of basic pattern combinations. The plurality of basic pattern combinations include a single transistor (large width), a single transistor (small width), and parallel connected N transistors (large width), for example.