Title :
Predicting coupled noise in RC circuits
Author :
Sheehan, Bernard N.
Author_Institution :
MentorGraphics, Wilsonville, OR, USA
Abstract :
A novel method which can be regarded as the noise-counterpart of the celebrated Elmore´s delay formula-both being based on the first two moments of the network´s transfer function-efficiently and accurately predicts maximum noise between two capacitively coupled RC networks, without simulation. The method applies to general topologies (with significant simplification for coupled trees), accurately models how coupling varies with driver transition time, and quantifies the uncertainty in the calculated noise values. Efficient enough for large circuits, the new method can serve as a key ingredient in CAD methodologies to ensure that a layout is noise-problem free
Keywords :
RC circuits; capacitance; coupled circuits; crosstalk; integrated circuit interconnections; integrated circuit layout; integrated circuit noise; linear network analysis; passive networks; CAD methodologies; RC circuits; capacitively coupled networks; coupled noise prediction; driver transition time; general topologies; large circuits; maximum noise; noise-problem free layout; transfer function; Circuit noise; Circuit simulation; Circuit topology; Coupling circuits; Crosstalk; Delay; Laplace equations; Network topology; Noise figure; Transfer functions;
Conference_Titel :
Design, Automation and Test in Europe Conference and Exhibition 2000. Proceedings
Conference_Location :
Paris
Print_ISBN :
0-7695-0537-6
DOI :
10.1109/DATE.2000.840834
