Simulation and sensitivity of linear analog circuits under parameter variations by Robust interval analysis

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Simulation and sensitivity of linear analog circuits under parameter variations by Robust interval analysis

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ACM Transactions on Design Automation of Electronic Systems (TODAES) archive
Volume 4 , Issue 3 (July 1999) table of contents

Pages: 280 - 312

Year of Publication: 1999

ISSN:1084-4309

Authors

C.-J. Richard Shi	University of Washington
Michael W. Tian	University of Iowa

Publisher

ACM New York, NY, USA

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Downloads (6 Weeks): 3, Downloads (12 Months): 50, Citation Count: 3

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ABSTRACT

An interval-mathematic approach is presented for frequency-domain simulation and sensitivity analysis of linear analog circuits under parameter variations. With uncertain parameters represented as intervals, bounding frequency-domain responses is formulated as the problem of solving systems of linear interval equations. The formulation is based on a variant of modified nodal analysis, and is particularly amenable to interval analysis. Some characterization of the solution sets of systems of linear interval equations are derived. With these characterizations, an elegant and efficient algorithm is proposed to solve systems of linear interval equations. While the widely used Monte Carlo approach requires many circuit simulations to achieve even moderate accuracy, the computational cost of the proposed approach is about twice that of one circuit simulation. The computed response bounds contain provably, or are usually very close to, the actual response bounds. Further, sensitivity under parameter variations can be computed from the response bounds at minor computational cost. The algorithms are implemented in SPICE3F5, using sparse-matrix techniques and tested on several practical analog circuits.

REFERENCES

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CITED BY 3

	Guoyong Shi , C.-J. Richard Shi, Parametric reduced order modeling for interconnect analysis, Proceedings of the 2004 conference on Asia South Pacific design automation: electronic design and solution fair, p.774-779, January 27-30, 2004, Yokohama, Japan
	Nihal J. Godambe , C.-J. Richard Shi, Behavioral Level Noise Modeling and Jitter Simulation ofPhase-Locked Loops with Faults Using VHDL-AMS, Journal of Electronic Testing: Theory and Applications, v.13 n.1, p.7-17, Aug. 1, 1998
	Michael W. Tian , C.-J. Richard Shi, Rapid frequency-domain analog fault simulation under parameter tolerances, Proceedings of the 34th annual conference on Design automation, p.275-280, June 09-13, 1997, Anaheim, California, United States