Title :
Fast Variational Interconnect Delay and Slew Computation Using Quadratic Models
Author :
Xiaoji Ye ; Liu, F.Y. ; Peng Li
Author_Institution :
Texas A&M Univ., College Station
Abstract :
Interconnects constitute a dominant source of circuit delay for modern chip designs. The variations of critical dimensions in modern VLSI technologies lead to variability in interconnect performance that must be fully accounted for in timing verification. However, handling a multitude of inter-die/intra-die variations and assessing their impacts on circuit performance can dramatically complicate the timing analysis. In this paper, a practical interconnect delay and slew analysis technique is presented to facilitate efficient evaluation of wire performance variability. By harnessing a collection of computationally efficient procedures and closed-form formulas, process variations are directly mapped into the variability of the output delay and slew. An efficient method based on sensitivity analysis is implemented to calculate driving point models under variations for gate-level timing analysis. The proposed adjoint technique not only provides statistical performance variations of the interconnect network under analysis, but also produces delay and slew expressions parameterized in the underlying process variations in a quadratic parametric form. As such, it can be harnessed to enable statistical timing analysis while considering important statistical correlations. Our experimental results have indicated that the presented analysis is accurate regardless of location of sink nodes and it is also robust over a wide range of process variations.
Keywords :
correlation methods; integrated circuit interconnections; integrated circuit modelling; sensitivity analysis; statistical analysis; variational techniques; driving point models; gate-level timing analysis; interconnect network; quadratic models; quadratic parametric form; sensitivity analysis; slew analysis technique; statistical correlations; statistical timing analysis; variational interconnect delay; wire performance variability; Chip scale packaging; Circuit optimization; Computational modeling; Delay; Integrated circuit interconnections; Performance analysis; Sensitivity analysis; Timing; Very large scale integration; Wire; Adjoint sensitivity analysis; driving part model; interconnect analysis; variational analysis;
Journal_Title :
Very Large Scale Integration (VLSI) Systems, IEEE Transactions on
DOI :
10.1109/TVLSI.2007.900738
