Statistical static timing analysis of nonzero clock skew circuit

As microprocessor and ASIC manufacturers continue to push the limits of transistor sizing into the sub-100nm regime, variations in the manufacturing process lead to increased uncertainty about the exact geometry and performance of the resulting devices. Traditional corner-based Static Timing Analysis (STA) assumes worst-case values for process parameters such as transistor channel length and threshold voltage when verifying integrated circuit timing performance. This has become unrea-sonably pessimistic and causes over-design that degrades full-chip performance, wastes engineering effort, and erodes profits while providing negligible yield improvement. Recently, Statistical Static Timing Analysis (SSTA) methods, which model process variations statistically as probability distribution functions (PDFs) rather than deterministically, have emerged to more accurately portray integrated circuit performance. This analysis has been thoroughly performed on traditional zero clock skew circuits where the synchronizing clock signal is assumed to arrive in phase with respect to each register. However, designers will often schedule the clock skew to different registers in order to decrease the minimum clock period of the entire circuit. Clock skew scheduling (CSS) imparts very different timing constraints that are based, in part, on the topology of the circuit. In this thesis, SSTA is applied to nonzero clock skew circuits in order to determine the accuracy improvement relative to their zero skew counterparts, and also to assess how the results of skew scheduling might be impacted with more accurate statistical modeling. For 99.7% timing yield (3 variation), SSTA is observed to improve the accuracy, and therefore increase the timing margin, of nonzero clock skew circuits by up to 2.5x, and on average by 1.3x, the amount seen by zero skew circuits.M.S., Computer Engineering -- Drexel University, 200