Post Silicon Clock Tuning System To Mitigate The Impact Of Process Variation On Performance

Nagaraj, Kelageri

01 January 2010

Optical shrink for process migration, manufacturing process variation and dynamic voltage control leads to clock skew as well as path delay variation in a manufactured chip. Since such variations are difficult to predict in pre-silicon phase, tunable clock buffers have been used in several microprocessor designs. The buffer delays are tuned to improve maximum operating clock frequency of a design. This however shifts the burden of finding tuning settings for individual clock buffers to the test process. In this project, we describe a process of using tester measurements to determine the settings of the tunable buffers for recovery of performance lost due to process variations. Then we study the impact of positioning of tunable buffers in the clock tree. In course of our study it was observed that the greatest benefit from tunable buffer placement can be derived, when the clock tree is synthesized with future tuning considerations. Accordingly, we present a clock tree synthesis procedure which offers very good mitigation against process variation, as borne out by the results. The results show that without any design intervention, an average improvement of 9% is achieved by our tuning system. However, when the clock tree is synthesized based on static timing information with tuning buffer placement considerations, much larger performance improvement is possible. In one example, performance improved by as much as 18%.

post silicon tunable

process variation

critical path tracing

die specific tuning

clock tree synthesis

Electrical engineering

Computer and Systems Architecture

Digital Circuits

Hardware Systems