Title :
Simulation of interconnect inductive impact in the presence of process variations in 90 nm and beyond
Author :
Qi, Xiaoning ; Gyure, Alex ; Luo, Yansheng ; Lo, Sam C. ; Shahram, Mahmoud ; Singhal, Kishore
Author_Institution :
Direct Silicon Access Lab., Synopsys Inc., Mountain View, CA
Abstract :
The on-chip inductive impact on signal integrity has been a problem for designs in deep-submicrometer technologies. The inductive impact increases the clock skew, max timing, and noise of bus signals. In this letter, circuit simulations using silicon-validated macromodels show that there is a significant inductive impact on the signal max timing (~ 10% pushout versus RC delay) and noise (~2timesRC noise). In nanometer technologies, process variations have become a concern. Results show that device and interconnect process variations add ~ 3% to the RLC max-timing impact. However, their impact on the RLC signal noise is not appreciable. Finally, inductive impact in 65- and 45-nm technologies is investigated, which indicates that the inductance impact will not diminish as technology scales
Keywords :
RC circuits; RLC circuits; circuit simulation; integrated circuit interconnections; integrated circuit modelling; integrated circuit noise; 45 nm; 65 nm; 90 nm; RLC signal noise; bus signal noise; circuit simulations; clock skew; deep-submicrometer technologies designs; interconnect inductive impact simulation; max timing; silicon-validated macromodels; very-high-frequency integrated circuits; Circuit noise; Circuit simulation; Inductance; Integrated circuit interconnections; Integrated circuit technology; RLC circuits; Semiconductor device noise; Space technology; Timing; Wires; Inductance; interconnections; very-high-frequency (VHF) integrated circuits;
Journal_Title :
Electron Device Letters, IEEE
DOI :
10.1109/LED.2006.879039
