Abstract: Mask and integrated circuit fabrication approaches are described to facilitate use of so called “full phase” masks. This facilitates use of masks where substantially all of a layout is defined using phase shifting. More specifically, exposure settings including relative dosing between the phase shift mask and the trim masks are described. Additionally, single reticle approaches for accommodating both masks are considered. In one embodiment, the phase shifting mask and the trim mask are exposed using the same exposure conditions, except for relative dosing. In another embodiment, the relative dosing between the phase and trim patterns is 1.0:r, 2.0<r<4.0. These approaches facilitate better exposure profiles for the resulting ICs and can thus improve chip yield and increase throughput by reducing the need to alter settings and/or switch reticles between exposures.

Abstract: Phase information is incorporated into a cell-based design methodology. Standard cells have four edges: top, bottom, left, and right. The top and bottom edges have fixed phase shifters placed, e.g. 0. A given cell C will have a phase set created with two versions: 0-180 (left-right) as well as 180-0. Alternatively, the same phase set: 0-0 and 180-180 could be created for a cell. The phase sets are selected based on the ability to phase shift the features within the cell C. By creating a phase set for most of the cells of a cell library, standard cell placement and routing techniques can be used and phase can then be quickly assigned using a simple ripple technique. This ensures a phase compliant design upfront for the standard cell areas.

Abstract: Definition of a phase shifting layout from an original layout can be time consuming. If the original layout is divided into useful groups, i.e. clusters that can be independently processed, then the phase shifting process can be performed more rapidly. If the shapes on the layout are enlarged, then the overlapping shapes can be grouped together to identify shapes that should be processed together. For large layouts, growing and grouping the shapes can be time consuming. Therefore, an approach that uses bins can speed up the clustering process, thereby allowing the phase shifting to be performed in parallel on multiple computers. Additional efficiencies result if identical clusters are identified and processing time saved so that repeated clusters of shapes only undergo the computationally expensive phase shifter placement and assignment process a single time.

Abstract: Methods and apparatuses for fully defining static random access memory (SRAM) using phase shifting layouts are described. The approach includes identifying that a layout includes SRAM cells and defining phase shifting regions in a mask description to fully define the SRAM cells. The phase conflicts between adjacent phase shifters are resolved by selecting cutting patterns designed for the SRAM shape and functional structure. Additionally, the transistor gates of the SRAM cells can be reduced in size relative to the original SRAM layout design. Thus, an SRAM cell can be lithographically printed with small, consistent critical dimensions including extremely small gate lengths resulting in higher yields and improved performance.

Abstract: A method for defining a full phase layout for defining a layer of material in an integrated circuit is described. The method can be used to define, arrange, and refine phase shifters to substantially define the layer using phase shifting. Through the process, computer readable definitions of an alternating aperture, dark field phase shift mask and of a complimentary mask are generated. Masks can be made from the definitions and then used to fabricate a layer of material in an integrated circuit. The separations between phase shifters, or cuts, are designed for easy mask manufacturability while also maximizing the amount of each feature defined by the phase shifting mask. Cost functions are used to describe the relative quality of phase assignments and to select higher quality phase assignments and reduce phase conflicts.