Title :
Harmony: static noise analysis of deep submicron digital integrated circuits
Author :
Shepard, Kenneth L. ; Narayanan, Vinod ; Rose, Ron
Author_Institution :
Dept. of Electr. Eng., Columbia Univ., New York, NY, USA
fDate :
8/1/1999 12:00:00 AM
Abstract :
As technology scales into the deep submicron regime, noise immunity is becoming a metric of comparable importance to area, timing, and power for the analysis and design of very large scale integrated (VLSI) systems. A metric for noise immunity is defined, and a static noise analysis methodology based on this noise-stability metric is introduced to demonstrate how noise can be analyzed systematically on a full-chip basis using simulation-based transistor-level analysis. We then describe Harmony, a two-level (macro and global) hierarchical implementation of static noise analysis. At the macro level, simplified interconnect models and timing assumptions guide efficient analysis. The global level involves a careful combination of static noise analysis, static timing analysis, and detailed interconnect macromodels based on reduced-order modeling techniques. We describe how the interconnect macromodels are practically employed to perform coupling analysis and how timing constraints can be used to limit pessimism in the analysis
Keywords :
VLSI; digital integrated circuits; integrated circuit modelling; integrated circuit noise; Harmony; VLSI; coupling analysis; deep submicron digital integrated circuit; global model; interconnect; macromodel; noise immunity; noise stability; reduced order model; simulation; static noise analysis; timing analysis; two-level hierarchical model; 1f noise; Circuit noise; Digital circuits; Digital integrated circuits; Integrated circuit interconnections; Integrated circuit noise; Integrated circuit technology; Threshold voltage; Timing; Working environment noise;
Journal_Title :
Computer-Aided Design of Integrated Circuits and Systems, IEEE Transactions on
