Abstract: A method and apparatus for providing correction for microloading effects is described. Hybrid proximity correction techniques are used to make the problem computationally more feasible. More specifically, feature edges in a layout can be grouped into those edges, or edge segments, with a large edge separation (group B), e.g. greater than n, and those having less than that separation (group A). The group B features can then be corrected for microloading effects rapidly using rules based correction. Then both groups of edges can be corrected using model based optical proximity correction using the output of the rule based correction as the ideal, or reference, layout.

Abstract: An accurate, cost-effective system and method for correcting 3D effects on an alternating phase-shifting mask (PSM) is provided. To facilitate this correction, a library can be built to include a first group of 180 degree phase-shifting regions, wherein these regions have a common first size. Based on this first size, 3D simulation is performed. A transmission and a phase are altered in a 2D simulation based on this first size until a shape dependent transmission and a shape dependent phase allow the 2D simulation to substantially match the 3D simulation. Finally, a modified first size is chosen using the shape dependent transmission and the shape dependent phase such that a 2D simulation based on the modified first size substantially matches the 3D simulation based on the first size. The library associates the first size with the modified first size, the shape dependent transmission, and the shape dependent phase.

Abstract: Phase shifting layouts and masks with phase conflicts are described. The phase shifting layout defines light transmissive regions for use in defining selected features in a layer of material of an integrated circuit (IC). The phase shifting layout includes a phase conflict caused by two light transmissive regions that are out of phase with each other and which, without correction, would lead to the definition of an artifact in the layer of material. A corresponding mask adapted for use in conjunction with the phase shifting mask can ensure that the artifact is ultimately erased. The phase conflict is intentionally introduced into the phase shifting layout during phase assignment to permit all of the selected features to be defined using the phase shifting mask.

Abstract: An automated phase assignment method is described that allows multiple rules for defining phase shifters to be used within a single cell. The rules for defining phase shifters can be sequenced. Then for a cell, the rules can be recursively applied. At each stage if the number of phase conflicts is below a threshold, then portions of the cell having conflicts are masked and processed using the next less aggressive rule set. This in turn leads to phase shifting masks with greater variation in phase shifter shapes and sizes. When the mask is used to fabricate integrated circuits (ICs), the resulting IC may have a greater number of small transistors and other features than a mask defined using only a single rule set per cell. Additional benefits can include better process latitude during IC fabrication and improved yield.

Abstract: A critical dimension, or width, of a feature, or a semiconductor device, can be measured to provide direct and meaningful information regarding the impact of line end shortening, or length, on the function of the device. Specifically, a location on the feature where the width will have an impact on device performance can be selected. Using a simulation, the width at that location can be computed. Given the difficulties of direct measurement of line end shortening and the relationship between the width measurement and the impact on device performance, better layout checking is facilitated than by standard measurements of line end shortening.

Abstract: By using a test pattern that has been corrected according to an optical model to prepare test wafers, better data can be obtained for calibrating the optical model. As a result: fewer measurements need to be taken from the wafer to calibrate the model and the measurements that are taken are more valuable because they better assist in calibrating the model. Embodiments of the invention include data comprising the corrected test pattern, masks including the corrected test pattern, and methods and apparatuses for using the modified test pattern. Additionally, by taking more measurements closer to the target dimensions, more information is available for performing optical proximity correction of layouts. Another benefit includes increased ease of model accuracy determinations.

Abstract: A method and system of determining a sensitivity of an edge of a feature to mask error can be advantageously provided using information from multiple simulations. Input data as well as revised data regarding the edge can be used, wherein the revised data includes a first mask error. The input data can be simulated to generate first deviation information, whereas the revised data can be simulated to generate second deviation information accounting for the first mask error. The sensitivity of the edge to mask error can be generated using the first deviation information, the second deviation information, and the first mask error. Specifically, generating the sensitivity can include subtracting the first deviation information from the second deviation and dividing the difference by the first mask error.

Abstract: One embodiment of the invention provides a system for reducing incidental exposure caused by phase shifting during fabrication of a semiconductor chip. The system operates by identifying a problem area of likely incidental exposure in close proximity to an existing phase shifter on a phase shifting mask, wherein the problem area includes a polysilicon line passing through a field region of the semiconductor chip. The system places an additional phase shifter into the problem area on the phase shifting mask so that a regulator within the additional phase shifter protects the polysilicon line passing through the field region. This additional phase shifter has a wider regulator than the existing phase shifter, wherein the existing phase shifter is used to expose a polysilicon line in a gate region of the semiconductor chip.

Abstract: One embodiment of the invention provides a system that facilitates a semiconductor fabrication process to create a line end in a manner that controls line end shortening arising from optical effects, and is especially applicable in alternating aperture phase shifting. This system operates by positioning a first mask over a photoresist layer on a surface of a semiconductor wafer. This first mask includes opaque regions and transmissive regions that are organized into a first pattern that defines an unexposed line on the photoresist layer. The system then exposes the photoresist layer through the first mask. The system also positions a second mask over the photoresist layer on the surface of the semiconductor wafer. This second mask includes opaque regions and transmissive regions that are organized into a second pattern that defines an exposure region.

Abstract: One embodiment of the invention provides a system and a method for reducing line end shortening during an optical lithography process for manufacturing an integrated circuit. The system operates by receiving a specification of the integrated circuit, wherein the specification defines transistors that include gates. Next, the system identifies a gate within the specification, wherein the gate includes an endcap that is susceptible to line end shortening during the optical lithography process. The system then extends a phase shifter used to form the gate, so that the phase shifter defines at least a portion of the endcap and thereby reduces line end shortening of the endcap due to optical effects.

Abstract: An accurate, cost-effective system and method for correcting 3D effects on an alternating phase-shifting mask (PSM) is provided. To facilitate this correction, a library can be built to include a first group of 180 degree phase-shifting regions, wherein these regions have a common first size. Based on this first size, 3D simulation is performed. A transmission and a phase are altered in a 2D simulation based on this first size until a shape dependent transmission and a shape dependent phase allow the 2D simulation to substantially match the 3D simulation. Finally, a modified first size is chosen using the shape dependent transmission and the shape dependent phase such that a 2D simulation based on the modified first size substantially matches the 3D simulation based on the first size. The library associates the first size with the modified first size, the shape dependent transmission, and the shape dependent phase.

Abstract: One embodiment of the invention provides a system and a method for reducing line end shortening during an optical lithography process for manufacturing an integrated circuit. The system operates by receiving a specification of the integrated circuit, wherein the specification defines transistors that include gates. Next, the system identifies a gate within the specification, wherein the gate includes an endcap that is susceptible to line end shortening during the optical lithography process. The system then extends a phase shifter used to form the gate, so that the phase shifter defines at least a portion of the endcap and thereby reduces line end shortening of the endcap due to optical effects.

Abstract: Methods and apparatuses for preparing layouts and masks that use phase shifting to enable production of subwavelength features on an integrated circuit in close (optical) proximity to other structures are described. One embodiment selects from several strategies for resolving conflicts between phase shifters used to define features and (optically) proximate structures that are being defined other than by phase shifting. One embodiment adds additional phase shifters to define the conflicting structures. Another embodiment corrects the shape of the phase shifters in proximity to a conflicting structure. Resulting integrated circuits can include a greater number of subwavelength features even in areas that are in close proximity to structures that were not initially identified for production using a phase shifting mask.

Abstract: A method and apparatus for providing correction for microloading effects is described. Hybrid proximity correction techniques are used to make the problem computationally more feasible. More specifically, feature edges in a layout can be grouped into those edges, or edge segments, with a large edge separation (group B), e.g. greater than n, and those having less than that separation (group A). The group B features can then be corrected for microloading effects rapidly using rules based correction. Then both groups of edges can be corrected using model based optical proximity correction using the output of the rule based correction as the ideal, or reference, layout.

Abstract: Methods and apparatuses for preparing layouts and masks that use phase shifting to enable production of subwavelength features on an integrated circuit in close (optical) proximity to other structures are described. One embodiment selects from several strategies for resolving conflicts between phase shifters used to define features and (optically) proximate structures that are being defined other than by phase shifting. One embodiment adds additional phase shifters to define the conflicting structures. Another embodiment optically corrects the shape of the phase shifters in proximity to a conflicting structure. Resulting integrated circuits can include a greater number of subwavelength features even in areas that are in close proximity to structures that were not initially identified for production using a phase shifting mask.

Abstract: Phase shifting layouts and masks with phase conflicts are described. The phase shifting layout defines light transmissive regions for use in defining selected features in a layer of material of an integrated circuit (IC). The phase shifting layout includes a phase conflict caused by two light transmissive regions that are out of phase with each other and which, without correction, would lead to the definition of an artifact in the layer of material. A corresponding mask adapted for use in conjunction with the phase shifting mask can ensure that the artifact is ultimately erased. The phase conflict is intentionally introduced into the phase shifting layout during phase assignment to permit all of the selected features to be defined using the phase shifting mask.

Abstract: Methods and apparatuses for preparing layouts and masks that use phase shifting to enable production of subwavelength features on an integrated circuit in close (optical) proximity to other structures are described. One embodiment selects from several strategies for resolving conflicts between phase shifters used to define features and (optically) proximate structures that are being defined other than by phase shifting. One embodiment adds additional phase shifters to define the conflicting structures. Another embodiment optically corrects the shape of the phase shifters in proximity to a conflicting structure. Resulting integrated circuits can include a greater number of subwavelength features even in areas that are in close proximity to structures that were not initially identified for production using a phase shifting mask.

Abstract: One embodiment of the invention provides a system and a method for reducing line end shortening during an optical lithography process for manufacturing an integrated circuit. The system operates by receiving a specification of the integrated circuit, wherein the specification defines transistors that include gates. Next, the system identifies a gate within the specification, wherein the gate includes an endcap that is susceptible to line end shortening during the optical lithography process. The system then extends a phase shifter used to form the gate, so that the phase shifter defines at least a portion of the endcap and thereby reduces line end shortening of the endcap due to optical effects.

Abstract: One embodiment of the invention provides a system for reducing incidental exposure caused by phase shifting during fabrication of a semiconductor chip. The system operates by identifying a problem area of likely incidental exposure in close proximity to an existing phase shifter on a phase shifting mask, wherein the problem area includes a polysilicon line passing through a field region of the semiconductor chip. The system places an additional phase shifter into the problem area on the phase shifting mask so that a regulator within the additional phase shifter protects the polysilicon line passing through the field region. This additional phase shifter has a wider regulator than the existing phase shifter, wherein the existing phase shifter is used to expose a polysilicon line in a gate region of the semiconductor chip.

Abstract: One embodiment of the invention provides a system that facilitates a semiconductor fabrication process to create a line end in a manner that controls line end shortening arising from optical effects, and is especially applicable in alternating aperture phase shifting. This system operates by positioning a first mask over a photoresist layer on a surface of a semiconductor wafer. This first mask includes opaque regions and transmissive regions that are organized into a first pattern that defines an unexposed line on the photoresist layer. The system then exposes the photoresist layer through the first mask. The system also positions a second mask over the photoresist layer on the surface of the semiconductor wafer. This second mask includes opaque regions and transmissive regions that are organized into a second pattern that defines an exposure region.