Critique of "Asynchronous Logic Implementation Based on Factorized DIMS"

TL;DR

This paper critiques a previous work on asynchronous logic implementation, highlighting issues like the gate orphan problem, lack of a general synthesis algorithm, unsafe decomposition, and missing comparison with existing methods, ultimately causing confusion.

Contribution

It provides a detailed critique of the referenced article, clarifying its shortcomings and highlighting relevant literature on robust asynchronous circuit synthesis techniques.

Findings

Identifies gate orphan problem in the referenced approach

Points out absence of a general synthesis algorithm

Highlights unsafe logic decomposition in the example

Abstract

This paper comments on "Asynchronous Logic Implementation Based on Factorized DIMS" [Journal of Circuits, Systems, and Computers, vol. 26, no. 5, 1750087: 1-9, May 2017] with respect to two main problematic issues: i) the gate orphan problem implicit in the factorized DIMS approach discussed in the referenced article which affects its strong-indication, and ii) how the enumeration of product terms to represent the synthesis cost is skewed in the referenced article because the logic expression contains sum of products and also product of sums. It is observed that the referenced article has not provided a general logic synthesis algorithm excepting only an example illustration involving a 3-input AND logic function. The absence of a general logic synthesis algorithm would make it difficult to reproduce the research described in the referenced article. Moreover, the example illustration in the referenced article describes an unsafe logic decomposition which is not suitable for the multi-level synthesis of strong-indication asynchronous circuits. Further, a logic synthesis method which safely decomposes the DIMS solution to synthesize multi-level strong-indication asynchronous circuits is available in the existing literature, which was neither cited nor taken up for comparison in the referenced article, which is another drawback. Subsequently, it is concluded that the referenced article has not advanced existing knowledge in the field but on the contrary, has caused confusions. Hence, in the interest of readers, this paper additionally highlights some important and relevant literature which provide valuable information about robust asynchronous circuit synthesis techniques which employ delay-insensitive codes for data representation and processing and the 4-phase return-to-zero handshake protocol for data communication.