Author_Institution :
Cypress Semicond., San Jose, CA, USA
Abstract :
DfM (design-for-manufacturability) for efficient generation of mask data, optimization of manufacturing process, cost reduction, and best circuit performance of systems-on-chip are discussed. Beyond 100 nm technology node, layout pattern has to comply to many new requirements pertaining to database structure and complexity, suitability for image enhancement by the optical proximity correction, and mask data pattern density and distribution over the image field. A number of macro-, meso-, and microscopic effects such as reticle macroloading, planarization dishing, and pattern bridging or breaking would compromise fab yield, device performance, or both. This, given the already extremely high (and growing) process complexity, design cycle time and manufacturing cost, requires simulations to ensure that the first silicon out of the fab would yield. This work discusses the fundamentals of DfM in the area of layout best practices, mask data preparation, printability, and uniformization and the cost reduction.
Keywords :
design for manufacture; integrated circuit layout; integrated circuit yield; masks; planarisation; proximity effect (lithography); system-on-chip; design cycle time; design-for-manufacturability; layout pattern; manufacturing process optimization; mask data generation; mask data pattern density; mask data preparation; optical proximity correction; pattern breaking; pattern bridging; planarization dishing; process complexity; reticle macroloading; systems-on-chip; Circuit optimization; Cost function; Design for manufacture; Design optimization; Image databases; Image enhancement; Manufacturing processes; Microscopy; Planarization; System-on-a-chip;
