B. Watson scite author profile

An automated litho-aware design migration solution has been implemented to enable designers to port existing IP layouts (custom, library, and block) to nanometer technologies while optimizing layout printability and silicon yield. With rapidly shrinking technology nodes, the industry consolidation toward fabless or fab-lite manufacturing, demand for second-sourcing and dramatic increase in cost of IP development, the automation of "vertical" (between nodes) and "horizontal" (between chip manufacturers) migration becomes a very important task. The challenge comes from the fact that even within the same technology node design and process-induced rules deviate substantially among different IDMs and foundries, which leads to costly, error-prone and time consuming design modifications. At the same time, fast and reliable adjustments to design and ability to switch between processes and chip manufacturers could represent significant improvement to TTM, and respectively improving ROI. Using conservative rules (or restricted design rules) is not always a viable option because of the area, performance and yield penalties. The difficulty of migration is augmented by the fact that design rules are not sufficient to guaranty good printability, maximum process window and high yield. Model-based detection of lithography-induced systematic yield-limiting defects (a.k.a. hotspots) is becoming a vital part of the design-for-manufacturing flow for advanced technology nodes at 65nm and below. Driven by customer demand, a collaborative effort between EDA vendors provides a complete design-for-manufacturing migration solution that allows sub-65 nanometer designers to comprehensively address the impact of manufacturing variations on design yield and performance during layout migration. First, the physical hard IP is migrated from its existing 90nm process to a more advanced 65 and 45 nm processes, resulting in an area-optimized DRC-clean 65nm design retaining the original hierarchy to facilitate further editing and design verification the original hierarchy is maintained. Then, the design manufacturability is checked using a model-based hotspot detection solution, applying foundry-certified models. Along with hotspots, it is also critical for the hotspot detection tool to generate directives on how to modify the layout to fix hotspots and prevent creation of new hotspots. Several alternative fixing guidelines, ranked by amount of design perturbation, are generated to provide focus and maximum flexibility to the correction tool. The correction tool reads hotspot locations, severities along with the fixing guidelines, identifies area to be fixed and converts the fixing guidelines into geometry constraints. Correction is then done on each area while respecting design rules, managing ripple effects through multiple layers and maintaining the hierarchy. When all the corrections are completed areas that have been affected are identified to allow these to be incrementally checked by the lithography verification tool (LPC) and reassem...

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Experimental investigation aiming at improving the suction flow capability of a gas expeller

Botros

Geerligs

Watson

2015

Journal of Natural Gas Science and Engineering

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Benefits of distribution automation and performance results from a network trial

Watson¹

1997

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B. Watson

Performance of expellers in evacuating gas pipelines—Part I: Measurements, models and field verification

Performance of expellers in evacuating gas pipelines—Part II: Effects of plug valve and natural gas as a drive gas

A lithography aware design optimization using foundry-certified models and hotspot detection

Experimental investigation aiming at improving the suction flow capability of a gas expeller

Benefits of distribution automation and performance results from a network trial

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