Paper Info
Title
Unfaithful Glitch Propagation in Existing Binary Circuit Models
Abstract
We show that no existing continuous-time, binary value-domain model for digital circuits is able to correctly capture glitch propagation. Prominent examples of such models are based on pure delay (P) channels, inertial delay (I) channels, or the elaborate PID channels proposed by Bellido-Díaz et al. We accomplish our goal by considering the solvability/non-solvability border of a simple problem called Short-Pulse Filtration (SPF), which is closely related to arbitration and synchronization. On one hand, we prove that SPF is solvable in bounded time in any such model that provides channels with non-constant delay, like I and PID. However, this is in opposition to the impossibility of solving bounded SPF in real (Newtonian) circuit models, which follows from well-known results on the behavior of bi-stable circuits obtained by Marino. On the other hand, for binary circuit models with pure delay channels, we prove that SPF cannot be solved even in unbounded time. This, however, is in opposition to the fact that one can easily solve the unbounded SPF problem in Newtonian circuit models. Consequently, indeed none of the binary value-domain models proposed so far faithfully captures glitch propagation of real circuits.
Year
DOI
Venue
2016
10.1109/ASYNC.2013.9
IEEE Transactions on Computers
Keywords
Field
DocType
binary models,modeling issues,binary circuit models,delay circuits,digital circuits,newtonian circuit models,pid channels,bistable circuits,nonconstant delay,delays,spf,short-pulse filtration,synchronization,circuit models,inertial delay channels,continuous-time binary value-domain model,pure delay channels,glitch propagation,synchronisation,solvability-nonsolvability border
Glitch,Digital electronics,Synchronization,PID controller,Computer science,Communication channel,Electronic engineering,Electronic circuit,Bounded function,Binary number
Journal
Volume
Issue
ISSN
PP
99
1522-8681
ISBN
Citations 
PageRank 
978-1-4673-5956-6
6
0.68
References 
Authors
9
3
Name
Order
Citations
PageRank
Matthias Függer116721.14
Thomas Nowak2329.18
Ulrich Schmid312717.24