Abstract: The present disclosure provides integrated circuit methods for target-based dummy insertion. A method includes providing an integrated circuit (IC) design layout, and providing a thermal model for simulating thermal effect on the IC design layout, the thermal model including optical simulation and silicon calibration. The method further includes providing a convolution of the thermal model and the IC design layout to generate a thermal image profile of the IC design layout, defining a thermal target for optimizing thermal uniformity across the thermal image profile, comparing the thermal target and the thermal image profile to determine a difference data, and performing thermal dummy insertion to the IC design layout based on the difference data to provide a target-based IC design layout.

Abstract: The present disclosure provides for many different embodiments of a charged particle beam data storage system and method. In an example, a method includes dividing a design layout into a plurality of units; creating a lookup table that maps each of the plurality of units to its position within the design layout and a data set, wherein the lookup table associates any repeating units in the plurality of units to a same data set; and exposing an energy sensitive layer to a charged particle beam based on the lookup table.

Abstract: A method of optical proximity correction (OPC) convergence control that includes providing a lithography system having a photomask and an illuminator. The method further includes performing an exposure by the illuminator on the photomask. Also, the method includes optimizing an optical illuminator setting for the lithography system with a defined gate pitch in a first direction in a first template. Additionally, the method includes determining OPC correctors to converge the OPC results with a target edge placement error (EPE) to produce a first OPC setting for the first template. The first OPC setting targets a relatively small EPE and mask error enhancement factor (MEEF)of the defined gate pitch in the first template. In addition, the method includes checking the first OPC setting for a relatively small EPE, MEEF and DOM consistency with the first template of the defined gate pitch in a second, adjacent template.

Abstract: Provided is an apparatus for fabricating a semiconductor device. The apparatus includes a first photomask and a second photomask. The first photomask has a plurality of first features thereon, and the first photomask having a first global pattern density. The second photomask has a plurality of second features thereon, and the second photomask has a second global pattern density. The plurality of first and second features collectively define a layout image of a layer of the semiconductor device. The first and second global pattern densities have a predetermined ratio.

Abstract: The present disclosure is directed generally to a method and apparatus for monitoring mask process impact on lithography performance. A method including receiving a physical wafer pattern according to a mask, extracting a mask contour from the mask, and extracting a deconvolution pattern based on the mask contour. A lithography process is simulated to create a virtual wafer pattern based on the deconvolution pattern. The virtual wafer pattern is then compared to the physical wafer pattern.

Abstract: The present disclosure involves a method of performing a maskless lithography process. The method includes receiving a computer layout file for an integrated circuit (IC) device. The layout file contains a plurality of IC sections. The method includes separating the computer layout file into a plurality of sub-files. The method includes striping the plurality of sub-files concurrently using a plurality of computer processors, thereby generating a plurality of striped sub-files. The method includes transferring the plurality of striped sub-files to a maskless lithography system.

Abstract: The present disclosure describes a method of forming a pattern by an electron beam lithography system. The method includes receiving an integrated circuit (IC) design layout data having a polygon and a forbidden pattern, modifying the polygon and the forbidden pattern using an electron proximity correction (EPC) technique, stripping the modified polygon into subfields, converting the stripped polygon to an electron beam writer format data, and writing the electron beam writer formatted polygon onto a substrate by an electron beam writer. Stripping the modified polygon includes finding the modified forbidden pattern as a reference layer, and stitching the modified polygon to avoid stitching the modified forbidden pattern.

Abstract: A method for writing a design to a material using an electron beam includes assigning a first dosage to a first polygonal shape. The first polygonal shape occupies a first virtual layer and includes a first set of pixels. The method also includes simulating a first write operation using the first polygonal shape to create the design, discerning an error in the simulated first write operation, and assigning a second dosage to a second polygonal shape to reduce the error. The second polygonal shape occupies a second virtual layer. The method further includes creating a data structure that includes the first and second polygonal shapes and saving the data structure to a non-transitory computer-readable medium.

Abstract: A method of via patterning mask assignment for a via layer using double patterning technology, the method includes determining, using a processor, if a via of the via layer intercepts an underlying or overlaying metal structure assigned to a first metal mask. If the via intercepts the metal structure assigned to the first metal mask, assigning the via to a first via mask, wherein the first via mask aligns with the first metal mask. Otherwise, assigning the via to a second via mask, wherein the second via mask aligns with a second metal mask different from the first metal mask.

Abstract: An intensity selective exposure photomask, also describes as a gradated photomask, is provided. The photomask includes a first region including a first array of sub-resolution features. The first region blocks a first percentage of the incident radiation. The photomask also includes a second region including a second array of sub-resolution features. The second region blocks a second percentage of the incident radiation different that the first percentage.

Abstract: A method and apparatus for achieving multiple patterning compliant technology design layouts is provided. An exemplary method includes providing a routing grid having routing tracks; designating each of the routing tracks one of at least two colors; applying a pattern layout having a plurality of features to the routing grid, wherein each of the plurality of features corresponds with at least one routing track; and applying a feature splitting constraint to determine whether the pattern layout is a multiple patterning compliant layout. If the pattern layout is not a multiple patterning compliant layout, the pattern layout may be modified until a multiple patterning compliant layout is achieved.

Abstract: Provided is a lithography system operation to include a first aperture or a second aperture. Each of the first and second apertures has two pairs of radiation-transmitting regions where one pair of radiation-transmitting regions are larger than a second pair. For an aperture, each pair of radiation-transmitting regions are on different diametrical axis. In an embodiment, one aperture is used for x-dipole illumination and the second aperture is used for y-dipole illumination.

Abstract: The present disclosure involves a method of performing a maskless lithography process. The method includes receiving a computer layout file for an integrated circuit (IC) device. The layout file contains a plurality of IC sections. The method includes separating the computer layout file into a plurality of sub-files. The method includes striping the plurality of sub-files concurrently using a plurality of computer processors, thereby generating a plurality of striped sub-files. The method includes transferring the plurality of striped sub-files to a maskless lithography system.

Abstract: The present disclosure provides integrated circuit methods for target-based dummy insertion. A method includes providing an integrated circuit (IC) design layout, and providing a thermal model for simulating thermal effect on the IC design layout, the thermal model including optical simulation and silicon calibration. The method further includes providing a convolution of the thermal model and the IC design layout to generate a thermal image profile of the IC design layout, defining a thermal target for optimizing thermal uniformity across the thermal image profile, comparing the thermal target and the thermal image profile to determine a difference data, and performing thermal dummy insertion to the IC design layout based on the difference data to provide a target-based IC design layout.

Abstract: The present disclosure involves a method of performing a maskless lithography process. The method includes providing a proximity correction pattern. The method includes generating a deformed pattern based on the proximity correction pattern. The method includes performing a first convolution process to the proximity correction pattern to generate a first proximity correction pattern contour. The method includes processing the first proximity correction pattern contour to generate a second proximity correction pattern contour. The method includes performing a second convolution process to the deformed pattern to generate a first deformed pattern contour. The method includes processing the first deformed pattern contour to generate a second deformed pattern contour. The method includes identifying mismatches between the second proximity correction pattern contour and the second deformed pattern contour.

Abstract: The embodiments of via mask splitting methods for double patterning technology described enable via patterning to align to a metal layer underneath or overlying to reduce overlay error and to increase via landing. If adjacent vias violate the G0-mask-split-rule for space or pitch (or both) between vias, the mask assignment of end vias are given higher priority to ensure good landing of end vias, since they are at higher risk of mislanding. The metal correlated via mask splitting methods enable better via performance, such as lower via resistance, and higher via yield.

Abstract: The present disclosure provides one embodiment of an integrated circuit (IC) design method. The method includes receiving an IC design layout having a plurality of main features; applying a main feature dissection to the main features of the IC design layout and generating sub-portions of the main features; performing an optical proximity correction (OPC) to the main features; performing a mask rule check (MRC) to a main feature of the IC design layout; and modifying one of the sub-portions of the main feature if the main feature fails the MRC.

Abstract: An integrated circuit (IC) design method providing a circuit design layout having a plurality of functional blocks disposed a distance away from each other; identifying a local pattern density to an approximate dummy region, on the circuit design layout, within a predefined distance to one of the functional blocks; performing a local dummy insertion to the approximate dummy region according to the local pattern density; repeating the identifying and performing to at least some other of the functional blocks; and implementing a global dummy insertion to a non-local dummy region according to a global pattern density.

Abstract: Provided is a method of fabricating a semiconductor device. The method includes providing an integrated circuit layout plan, the integrated circuit layout plan containing a plurality of semiconductor features. The method includes selecting a subset of the features for decomposition as part of a double patterning process. The method includes designating a relationship between at least a first feature and a second feature of the subset of the features. The relationship dictates whether the first and second features are assigned to a same photomask or separate photomasks. The designating is carried out using a pseudo feature that is part of the layout plan but does not appear on a photomask. The method may further include a double patterning conflict check process, which may include an odd-loop check process.

Abstract: Methods and systems for providing processing parameters in a secure format are disclosed. In one aspect, a method for providing semiconductor fabrication processing parameters to a design facility is disclosed. The method comprises providing a set of processing parameters of a fabrication facility; creating a model from the set of processing parameters; converting the model into a corresponding set of kernels; converting the set of kernels into a corresponding set of matrices; and communicating the set of matrices to the design facility. In another aspect, a method for providing semiconductor fabrication processing parameters is disclosed. The method comprises providing a set of processing parameters of a fabrication facility; creating a processing model from the set of processing parameters; encrypting the processing model into a format for use with a plurality of EDA tools; and communicating the encrypted processing model format to a design facility.