Title :
Synchronization circuit performance
Author :
Kinniment, D.J. ; Bystrov, A. ; Yakovlev, A.V.
Author_Institution :
Dept. of Electr. & Electron. Eng., Univ. of Newcastle, Newcastle , UK
Abstract :
Synchronizer circuits are usually characterized by their rate of failure in transmitting data between two independently timed regions. The mean time between failures (MTBF) is given. These effects can be explained by extending the existing theory to take account of initial offsets, and we propose a new, more accurate, formula. Synchronizer performance depends on achieving a high reliability of synchronization together with a short time. We show that commonly used circuits, such as the jamb latch, do not produce the best compromise for very high reliability applications, and that a better circuit can be designed. In order to confirm that thermal noise does not influence the MTBF against synchronization-time relationship, we have devised an experiment to measure noise in an integrated CMOS bistable circuit. We show that the noise exhibits a Gaussian distribution, and is close to the value expected from thermal agitation.
Keywords :
CMOS digital integrated circuits; Gaussian noise; VLSI; circuit bistability; integrated circuit modelling; integrated circuit noise; integrated circuit reliability; synchronisation; thermal noise; CMOS bistable circuit; Gaussian noise distribution; independently timed regions; initial offsets; mean time between failures; synchronization-time relationship; synchronizer circuits; thermal agitation; thermal noise; very high reliability applications; Circuit optimization; Clocks; Frequency synchronization; Histograms; Integrated circuit measurements; Integrated circuit reliability; Latches; Metastasis; Noise measurement; Time measurement;
Journal_Title :
Solid-State Circuits, IEEE Journal of
