Provided are methods of manufacturing integrated circuit that include a polysilicon etch process in which the wafer having an etch poly pattern is loaded into a reactor chamber and exposed to an activated etchant and, during the etch process, adjusting the temperature conditions within the reactor chamber to increase polymeric deposition on an upper surface of the wafer.

Provided are methods of manufacturing integrated circuit that include a polysilicon etch process in which the wafer having an etch poly pattern is loaded into a reactor chamber and exposed to an activated etchant and, during the etch process, adjusting the temperature conditions within the reactor chamber to increase polymeric deposition on an upper surface of the wafer.

In a method of correcting a design layout of a semiconductor device, misaligned values of a portion of points of a target pattern of each of a plurality of regions of interest in a semiconductor device fabricated based on an original layout are measured, misaligned values of unmeasured points of the target pattern are estimated by using an artificial neural network trained based on the measured misaligned values of the portion of points, and a target layout of the semiconductor device is generated by using the estimated misaligned values.

In a method of correcting a design layout of a semiconductor device, misaligned values of a portion of points of a target pattern of each of a plurality of regions of interest in a semiconductor device fabricated based on an original layout are measured, misaligned values of unmeasured points of the target pattern are estimated by using an artificial neural network trained based on the measured misaligned values of the portion of points, and a target layout of the semiconductor device is generated by using the estimated misaligned values.

Computer-implemented methods of optimizing a process simulation model that predicts a result of a semiconductor device fabrication operation to process parameter values characterizing the semiconductor device fabrication operation are disclosed. The methods involve generating cost values using a computationally predicted result of the semiconductor device fabrication operation and a metrology result produced, at least in part, by performing the semiconductor device fabrication operation in a reaction chamber operating under a set of fixed process parameter values. The determination of the parameters of the process simulation model may employ pre-process profiles, via optimization of the resultant post-process profiles of the parameters against profile metrology results. Cost values for, e.g., optical scatterometry, scanning electron microscopy and transmission electron microscopy may be used to guide optimization.

An integrated circuit includes a first set of devices, a set of metal layers and a header circuit. The first set of devices are configured to operate on a first supply voltage, and are located on a first layer of the integrated circuit. The set of metal layers are above the first layer, and includes a first metal layer and a second metal layer. The first metal layer extends in at least a first direction and a second direction. The header circuit is above the first set of devices. At least a portion of the header circuit is positioned between the first metal layer and the second metal layer. The header circuit is configured to provide the first supply voltage to the first set of devices, and is configured to be coupled to a first voltage supply having the first supply voltage.

An integrated circuit includes a first set of devices, a set of metal layers and a header circuit. The first set of devices are configured to operate on a first supply voltage, and are located on a first layer of the integrated circuit. The set of metal layers are above the first layer, and includes a first metal layer and a second metal layer. The first metal layer extends in at least a first direction and a second direction. The header circuit is above the first set of devices. At least a portion of the header circuit is positioned between the first metal layer and the second metal layer. The header circuit is configured to provide the first supply voltage to the first set of devices, and is configured to be coupled to a first voltage supply having the first supply voltage.

A layout geometry of a lithographic mask is received. The layout geometry is partitioned into feature images, for example as selected from a library. The library contains predefined feature images and their corresponding precalculated mask 3D (M3D) filters. The M3D filter for a feature image represents the electromagnetic scattering effect of that feature image for a given source illumination. The mask function contribution from each of the feature images is calculated by convolving the feature image with its corresponding M3D filter. The mask function contributions are combined to determine a mask function for the lithographic mask illuminated by the source illumination.

A layout geometry of a lithographic mask is received. The layout geometry is partitioned into feature images, for example as selected from a library. The library contains predefined feature images and their corresponding precalculated mask 3D (M3D) filters. The M3D filter for a feature image represents the electromagnetic scattering effect of that feature image for a given source illumination. The mask function contribution from each of the feature images is calculated by convolving the feature image with its corresponding M3D filter. The mask function contributions are combined to determine a mask function for the lithographic mask illuminated by the source illumination.

A method of manufacturing a semiconductor device includes reducing errors in a migration of a first netlist to a second netlist, the first netlist corresponding to a first semiconductor process technology (SPT), the second first netlist corresponding to a second SPT, the first and second netlists each representing a same circuit design, the reducing errors including: inspecting a timing constraint list corresponding to the second netlist for addition candidates; generating a first version of the second netlist having a first number of comparison points relative to a logic equivalence check (LEC) context, the first number of comparison points being based on the addition candidates; performing a LEC between the first netlist and the first version of the second netlist, thereby identifying migration errors; and revising the second netlist to reduce the migration errors, thereby resulting in a second version of the second netlist.