Publication Type |
technical report |
School or College |
College of Engineering |
Department |
School of Computing |
Program |
Advanced Research Projects Agency |
Creator |
Brunvand, Erik L. |
Other Author |
Gopalakrishnan, Ganesh; Michell, Nick; Nowick, Steven M. |
Title |
A correctness criterion for asynchronous circuit validation and optimization |
Date |
1992 |
Description |
In order to reason about the correctness of asynchronous circuit implementations and specifications, Dill has developed a variant of trace theory [1]. Trace theory describes the behavior of an asynchronous circuit by representing its possible executions as strings called "traces" A useful relation defined in this theory is called conformance which holds when one trace specification can be safely substituted for another. We propose a new relation in the context of Dill's trace theory called strong conformance. We show that this relation is capable of detecting certain errors in asynchronous circuits that cannot be detected through conformance, Strong conformance also helps to justify circuit optimization rules where a component is replaced by another component having extra capabilities (e.g., it can accept more inputs). The structural operators of Dill's trace theory compose rename and hide - are shown to be monotonic with respect to strong conformance. Experiments are presented using a modified version of Dill's trace theory verifier which implements the check for strong conformance. |
Type |
Text |
Publisher |
University of Utah |
Subject |
Asynchronous circuits; Circuit optimizations; Formal verification of hardware; Trace theory; Asynchronous circuit validation |
Subject LCSH |
Asynchronous circuits |
Language |
eng |
Bibliographic Citation |
Gopalakrishnan, G., Brunvand, E. L., Michell, N., & Nowick, S. M. (1992). A correctness criterion for asynchronous circuit validation and optimization. UUCS-92-004. |
Series |
University of Utah Computer Science Technical Report |
Relation is Part of |
ARPANET |
Rights Management |
©University of Utah |
Format Medium |
application/pdf |
Format Extent |
256,669 bytes |
Source |
University of Utah School of Computing |
ARK |
ark:/87278/s6765zgh |
Setname |
ir_uspace |
ID |
703084 |
Reference URL |
https://collections.lib.utah.edu/ark:/87278/s6765zgh |