Abstract: A layout method and apparatus based on a genetic algorithm are provided. The method includes: determining a gene code mode based on standard part information and layout part information; generating an initial population based on the gene code mode, the initial population including a plurality of gene codes, and the gene codes including standard code segments and layout code segments, and corresponding to layout schemes of standard parts and layout parts; acquiring fitness of each gene code; determining a dominant gene code based on the fitness; performing a double-point crossing operation and a double-point mutation operation on the dominant gene code to generate a next generation gene code, so as to form a dominant population; and if a preset termination condition is met, determining the layout scheme corresponding to the dominant gene code in the dominant population as a target layout scheme.

Abstract: A layout method and apparatus based on a genetic algorithm are provided. The method includes: determining a gene code mode based on standard part information and layout part information; generating an initial population based on the gene code mode, the initial population including a plurality of gene codes, and the gene codes including standard code segments and layout code segments, and corresponding to layout schemes of standard parts and layout parts; acquiring fitness of each gene code; determining a dominant gene code based on the fitness; performing a double-point crossing operation and a double-point mutation operation on the dominant gene code to generate a next generation gene code, so as to form a dominant population; and if a preset termination condition is met, determining the layout scheme corresponding to the dominant gene code in the dominant population as a target layout scheme.

Abstract: In some examples, a centralized management system comprises a central management console including a federated login system embedded in the centralized management system. The federated login system includes at least one processor configured to perform operations in a method of federated login and authorization allowing a user of the centralized management system to manage connected clusters or products without performing an individual cluster or product login.

Abstract: In some examples, a centralized management system comprises a central management console including a federated login system embedded in the centralized management system. The federated login system includes at least one processor configured to perform operations in a method of federated login and authorization allowing a user of the centralized management system to manage connected clusters or products without performing an individual cluster or product login.

Abstract: In some examples, a centralized management system comprises a central management console including a federated login system embedded in the centralized management system. The federated login system includes at least one processor configured to perform operations in a method of federated login and authorization allowing a user of the centralized management system to manage connected clusters or products without performing an individual cluster or product login.

Abstract: Oxidation of high aspect ratio IC structures, such as pillars and fins, can deform them. Disclosed is technology for simulating the deformation efficiently so that process conditions or pattern design can be altered to improve manufacturability. A database describing a 3D model of the structures prior to the oxidation process is provided. Oxidation is simulated in 1D on different surfaces to estimate a depth of starting material that will be converted during oxidation. Starting material is then replaced to that depth on all surfaces, by oxide with known expansion ratio. An initial mechanical stress and strain field is determined based on the model in dependence upon the replacement depth and the expansion ratio, and the system relaxes the fields to their equilibrium states, which include the deformations. The deformations are reported to a user, who can repeat the process using different oxidizing conditions and/or patterns to optimize manufacturability.

Abstract: Roughly described, the invention involves ways to characterize, take account of, or take advantage of stresses introduced by TSV's near transistors. The physical relationship between the TSV and nearby transistors can be taken into account when characterizing a circuit. A layout derived without knowledge of the physical relationships between TSV and nearby transistors, can be modified to do so. A macrocell can include both a TSV and nearby transistors, and a simulation model for the macrocell which takes into account physical relationships between the transistors and the TSV. A macrocell can include both a TSV and nearby transistors, one of the transistors being rotated relative to others. An IC can also include a transistor in such proximity to a TSV as to change the carrier mobility in the channel by more than the limit previously thought to define an exclusion zone.

Abstract: Roughly described, the invention involves ways to characterize, take account of, or take advantage of stresses introduced by TSV's near transistors. The physical relationship between the TSV and nearby transistors can be taken into account when characterizing a circuit. A layout derived without knowledge of the physical relationships between TSV and nearby transistors, can be modified to do so. A macrocell can include both a TSV and nearby transistors, and a simulation model for the macrocell which takes into account physical relationships between the transistors and the TSV. A macrocell can include both a TSV and nearby transistors, one of the transistors being rotated relative to others. An IC can also include a transistor in such proximity to a TSV as to change the carrier mobility in the channel by more than the limit previously thought to define an exclusion zone.

Abstract: Roughly described, the invention involves ways to characterize, take account of, or take advantage of stresses introduced by TSV's near transistors. The physical relationship between the TSV and nearby transistors can be taken into account when characterizing a circuit. A layout derived without knowledge of the physical relationships between TSV and nearby transistors, can be modified to do so. A macrocell can include both a TSV and nearby transistors, and a simulation model for the macrocell which takes into account physical relationships between the transistors and the TSV. A macrocell can include both a TSV and nearby transistors, one of the transistors being rotated relative to others. An IC can also include a transistor in such proximity to a TSV as to change the carrier mobility in the channel by more than the limit previously thought to define an exclusion zone.

Abstract: Computer-implemented techniques for modeling the mechanical behavior of integrated circuits using layout-dependent material properties are disclosed. The back end of line wiring that connects an integrated circuit to a substrate undergoes stresses and strains due to many heating and cooling cycles during a chip's packaging and lifecycle. Depending on integrated circuit design style, there may be vastly different thermal profiles across the integrated circuit. The mechanical behavior caused by the thermal cycles of the wire, vias, and insulators comprising the BEOL materials is simulated. Extraction of the integrated circuit structural information, regarding the BEOL materials, yields anisotropic information. Layout-dependent material volume fractions are computed using integrated circuit structural information. Anisotropic mechanical properties are determined based on the structural information.

Abstract: Computer-implemented techniques for modeling the mechanical behavior of integrated circuits using layout-dependent material properties are disclosed. The back end of line wiring that connects an integrated circuit to a substrate undergoes stresses and strains due to many heating and cooling cycles during a chip's packaging and lifecycle. Depending on integrated circuit design style, there may be vastly different thermal profiles across the integrated circuit. The mechanical behavior caused by the thermal cycles of the wire, vias, and insulators comprising the BEOL materials is simulated. Extraction of the integrated circuit structural information, regarding the BEOL materials, yields anisotropic information. Layout-dependent material volume fractions are computed using integrated circuit structural information. Anisotropic mechanical properties are determined based on the structural information.

Abstract: Roughly described, the invention involves ways to characterize, take account of, or take advantage of stresses introduced by TSV's near transistors. The physical relationship between the TSV and nearby transistors can be taken into account when characterizing a circuit. A layout derived without knowledge of the physical relationships between TSV and nearby transistors, can be modified to do so. A macrocell can include both a TSV and nearby transistors, and a simulation model for the macrocell which takes into account physical relationships between the transistors and the TSV. A macrocell can include both a TSV and nearby transistors, one of the transistors being rotated relative to others. An IC can also include a transistor in such proximity to a TSV as to change the carrier mobility in the channel by more than the limit previously thought to define an exclusion zone.

Abstract: Roughly described, the invention involves ways to characterize, take account of, or take advantage of stresses introduced by TSV's near transistors. The physical relationship between the TSV and nearby transistors can be taken into account when characterizing a circuit. A layout derived without knowledge of the physical relationships between TSV and nearby transistors, can be modified to do so. A macrocell can include both a TSV and nearby transistors, and a simulation model for the macrocell which takes into account physical relationships between the transistors and the TSV. A macrocell can include both a TSV and nearby transistors, one of the transistors being rotated relative to others. An IC can also include a transistor in such proximity to a TSV as to change the carrier mobility in the channel by more than the limit previously thought to define an exclusion zone.

Abstract: Roughly described, the invention involves ways to characterize, take account of, or take advantage of stresses introduced by TSV's near transistors. The physical relationship between the TSV and nearby transistors can be taken into account when characterizing a circuit. A layout derived without knowledge of the physical relationships between TSV and nearby transistors, can be modified to do so. A macrocell can include both a TSV and nearby transistors, and a simulation model for the macrocell which takes into account physical relationships between the transistors and the TSV. A macrocell can include both a TSV and nearby transistors, one of the transistors being rotated relative to others. An IC can also include a transistor in such proximity to a TSV as to change the carrier mobility in the channel by more than the limit previously thought to define an exclusion zone.

Abstract: Roughly described, the invention involves ways to characterize, take account of, or take advantage of stresses introduced by TSV's near transistors. The physical relationship between the TSV and nearby transistors can be taken into account when characterizing a circuit. A layout derived without knowledge of the physical relationships between TSV and nearby transistors, can be modified to do so. A macrocell can include both a TSV and nearby transistors, and a simulation model for the macrocell which takes into account physical relationships between the transistors and the TSV. A macrocell can include both a TSV and nearby transistors, one of the transistors being rotated relative to others. An IC can also include a transistor in such proximity to a TSV as to change the carrier mobility in the channel by more than the limit previously thought to define an exclusion zone.

Abstract: A method, a computer medium storing computer instructions performing a method, and a computer with processor and memory perform stress modeling as follows. The stress model transforms a representation of a material conversion of a first material in the integrated circuit to a second material in the integrated circuit. Prior to the material conversion the first material occupies a first space having a first boundary. After the material conversion the first material and the second material together occupy a second space having a second boundary. The first space and the second space are different. The stress model performed by the computer system transforms the representation of the material conversion of the first material to the second material into: i) the first material occupying the first space having the first boundary, and ii) a strain displacement condition of the first material. The strain displacement condition is determined by a spatial change from the first boundary to the second boundary.

Abstract: Roughly described, the invention involves ways to characterize, take account of, or take advantage of stresses introduced by TSV's near transistors. The physical relationship between the TSV and nearby transistors can be taken into account when characterizing a circuit. A layout derived without knowledge of the physical relationships between TSV and nearby transistors, can be modified to do so. A macrocell can include both a TSV and nearby transistors, and a simulation model for the macrocell which takes into account physical relationships between the transistors and the TSV. A macrocell can include both a TSV and nearby transistors, one of the transistors being rotated relative to others. An IC can also include a transistor in such proximity to a TSV as to change the carrier mobility in the channel by more than the limit previously thought to define an exclusion zone.

Abstract: A method, a computer medium storing computer instructions performing a method, and a computer with processor and memory perform stress modeling as follows. The stress model transforms a representation of a material conversion of a first material in the integrated circuit to a second material in the integrated circuit. Prior to the material conversion the first material occupies a first space having a first boundary. After the material conversion the first material and the second material together occupy a second space having a second boundary. The first space and the second space are different. The stress model performed by the computer system transforms the representation of the material conversion of the first material to the second material into: i) the first material occupying the first space having the first boundary, and ii) a strain displacement condition of the first material. The strain displacement condition is determined by a spatial change from the first boundary to the second boundary.

Abstract: Roughly described, high-stress volumetric regions of an integrated circuit structure are predicted by first scanning one or more layout layers to identify planar regions of high 2-dimensional stress, and then performing the much more expensive 3-dimensional stress analysis only on volumetric regions corresponding to those planar regions that were found to have high 2-dimensional stress. A windowing method can be used for the 2-dimensional scan, optionally with an overlap region extending slightly into adjacent windows. Very narrow features arising at the edges of an analysis window can be relocated to the edge of the analysis window in order to avoid numerical artifacts.

Abstract: Roughly described, high-stress volumetric regions of an integrated circuit structure are predicted by first scanning one or more layout layers to identify planar regions of high 2-dimensional stress, and then performing the much more expensive 3-dimensional stress analysis only on volumetric regions corresponding to those planar regions that were found to have high 2-dimensional stress. A windowing method can be used for the 2-dimensional scan, optionally with an overlap region extending slightly into adjacent windows. Very narrow features arising at the edges of an analysis window can be relocated to the edge of the analysis window in order to avoid numerical artifacts.