In a method of manufacturing a semiconductor device, first to third active fins are formed on a substrate. Each of the first to third active fins extends in a first direction, and the second active fin, the first active fin, and the third active fin are disposed in this order in a second direction crossing the first direction. The second active fin is removed using a first etching mask covering the first and third active fins. The third active fin is removed using a second etching mask covering the first active fin and a portion of the substrate from which the second active fin is removed. A first gate structure is formed on the first active fin. A first source/drain layer is formed on a portion of the first active fin adjacent the first gate structure.

An integrated circuit (IC) including a plurality of finfet cells designed with digital circuit design rules to provide smaller finfet cells with decreased cell heights, and analog circuit cell structures including first finfet cells of the plurality of finfet cells and including at least one cut metal layer. The smaller finfet cells with decreased cell heights provide a first shorter metal track in one direction and the at least one cut metal layer provides a second shorter metal track in another direction to increase maximum electromigration currents in the integrated circuit.

A method (of manufacturing a semiconductor device) includes, for a layout diagram stored on a non-transitory computer-readable medium, the semiconductor device being based on the layout diagram, the layout diagram including a first level of metallization (M_1st level) and a first level of interconnection (VIA_1st level) thereover corresponding to a first layer of metallization and a first layer of interconnection thereover in the semiconductor device, generating the layout diagram including: selecting a candidate pattern in the layout diagram, the candidate pattern being a first conductive pattern in the M_1st level (first M_1st pattern); determining that the candidate pattern satisfies one or more criteria; and increasing a size of the candidate pattern thereby revising the layout diagram.

In a method of manufacturing a semiconductor device, first to third active fins are formed on a substrate. Each of the first to third active fins extends in a first direction, and the second active fin, the first active fin, and the third active fin are disposed in this order in a second direction crossing the first direction. The second active fin is removed using a first etching mask covering the first and third active fins. The third active fin is removed using a second etching mask covering the first active fin and a portion of the substrate from which the second active fin is removed. A first gate structure is formed on the first active fin. A first source/drain layer is formed on a portion of the first active fin adjacent the first gate structure.

A method includes: generating a design layout according to a circuit design by placing first and second components; identifying a first area and a second area between the first component and the second component; and determining a first cell configuration of the first component according to the first component and a second cell configuration of the second component according to the second component. The method further includes selecting a first cell comprising a first capacitor from a cell library, wherein the first cell has a third cell configuration identical to the first cell configuration; selecting a second cell comprising a second capacitor from the cell library, wherein the second cell has a fourth cell configuration identical to the second cell configuration; placing a first cell array formed of the first cell in the first area; and placing a second cell array formed of the second cell in the second area.

A method includes placing standard cells based on a standard cell library and generating layout data, and placing a filler cell selected from among a first type filler cell and a second type filler cell by using the layout data. The filler cell is placed based on a density of a pattern formed in the standard cell. The standard cell library includes data defining the first and second type filler cells. A density of a contact formed on an active region of the second type filler cell to contact the active region of the second type filler cell is lower than a density of a contact formed on an active region of a first type filler cell to contact the active region of the first type filler cell.

Split stack triple height cells and methods of generating layouts of same are described herein. The structure includes a circuit formed within three stacked rows. The circuit includes a first stage having a first plurality of electrical components and a second stage having a second plurality of electrical components. The first row includes a first electrical component of the first plurality of electrical components within a top portion of the first row. A first electrical component of the second plurality of electrical components is within a bottom portion of the first row and a top portion of the second row. A second electrical component of the second plurality of electrical components is within a top portion of the third row and a bottom portion of the second row. A second electrical component of the first plurality of electrical components is within a bottom portion of the third row.

An integrated circuit layout is provided. The integrated circuit layout includes one or more first cell rows partially extending across a space arranged for an integrated circuit layout along a first direction. Each of the one or more first cell rows has a first height along a second direction perpendicular to the first direction. The integrated circuit layout includes one or more third cell rows partially extending across the space along the first direction. Each of the one or more third cell rows has a second height along the second direction, the second height different from the first height.

Implementations disclosed herein may include receiving from a user a selection of at least one die, a package type, and at least one test condition; generating, using a processor, a product die configuration and a product package configuration using a predictive modeling module and the at least one die and the package type; generating a graphic design system file; generating a package bonding diagram; generating a product spice model of the discrete device product using a technology computer aided design module; generating, using a processor, one or more datasheet characteristics of the discrete device product with the product SPICE model; generating a product datasheet for the discrete device product using the graphic design system file; and using a second interface generated by a computing device to provide access to the graphic design system file, the package bonding diagram, the product datasheet, and the product SPICE model.

Implementations of a method of designing a module semiconductor product may include receiving a selection of a module type, one or more die, a placement of one or more wires, clips, or pins; and generating, using a processor, a module configuration file. The method may include generating a module bonding diagram using a build diagram system module; selecting one or more SPICE models corresponding with the die; and generating a product SPICE model and a three dimensional model for the module semiconductor product. The method may include generating one or more datasheet characteristics of the module semiconductor product with at least the product SPICE model and the product simulation module, generating a product datasheet for the module semiconductor product using the datasheet formation module, and providing access to at least the module bonding diagram, the product SPICE model, the three dimensional model, and the product datasheet to the user.