Go to ICCAD 2006 homepageSystem-level process-driven variability analysis for single and multiple voltage-frequency island systems
Abstract: The problem of determining bounds for application completion times running on generic systems comprised of single or multiple voltage-frequency islands (VFIs) with arbitrary topologies is addressed in the context of manufacturing-driven variability. The approach provides an exact solution for the system-level timing yield in single clock, single voltage (SSV) and VFI systems with an underlying tree-based topology, and a tight upper bound for generic, non-tree based topologies. The results show that: (a) timing yield for overall source-to- sink completion time for generic systems can be modeled in an exact manner for both SSV and VFI systems; and (b) multiple VFI, latency-constrained systems can achieve 11--90% higher timing yield than their SSV counterparts. The results are proven formally and supported by experimental results on two embedded applications, namely software defined radio and MPEG2 encoder.
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