Behavioral level noise modeling and jitter simulation of phase-locked loops with faults using VHDL-AMS

Author

Godambe, Nihal J. ; Shi, C. J Richard

Author_Institution

Dept. of Electr. & Comput. Eng., Iowa Univ., Iowa City, IA, USA

fYear

1997

fDate

27 Apr-1 May 1997

Firstpage

177

Lastpage

182

Abstract

It is important to predict noise at the early stages of a top down design. In this paper, we propose a methodology to model phase noise or jitter, a key specification for phase-locked loops, using a mixed-signal hardware description language, and to simulate the effects of catastrophic faults on the phase jitter at the behavioral level. In contrast to existing approaches which either require dedicated noise simulators or postpone noise and fault simulation to the transistor level, we have successfully demonstrated that noise in a voltage-controlled oscillator, power supply noise, and their effects on the overall phase jitter within a faulty phase locked loop can be modeled and simulated earlier on at the behavioral level. Our simulation results are consistent with experimentally verified, theoretical predictions

Keywords

circuit analysis computing; hardware description languages; integrated circuit design; integrated circuit noise; jitter; mixed analogue-digital integrated circuits; phase locked loops; phase noise; VHDL-AMS; behavioral level noise modeling; catastrophic faults; jitter simulation; mixed-signal hardware description language; phase noise; phase-locked loops; power supply noise; top down design; voltage-controlled oscillator; Circuit faults; Circuit noise; Hardware design languages; Jitter; Noise level; Phase locked loops; Phase noise; Power supplies; Transient analysis; Voltage-controlled oscillators;

fLanguage

English

Publisher

ieee

Conference_Titel

VLSI Test Symposium, 1997., 15th IEEE

Conference_Location

Monterey, CA

ISSN

1093-0167

Print_ISBN

0-8186-7810-0

Type

conf

DOI

10.1109/VTEST.1997.600251

Filename

600251