Simulation by Rounds of Letter-to-Letter Transducers

TL;DR

This paper introduces the concepts of simulation and equivalence by rounds for letter-to-letter transducers, enabling analysis of system symmetry and behavior under permutations within fixed-length segments.

Contribution

It defines and studies the notions of simulation and equivalence by rounds, providing decision procedures for their verification in transducers.

Findings

Decidable algorithms for $k$-round simulation and equivalence.

Application to process symmetry and system stability analysis.

Framework for analyzing permutations within fixed-length segments.

Abstract

Letter-to-letter transducers are a standard formalism for modeling reactive systems. Often, two transducers that model similar systems differ locally from one another, by behaving similarly, up to permutations of the input and output letters within "rounds". In this work, we introduce and study notions of simulation by rounds and equivalence by rounds of transducers. In our setting, words are partitioned to consecutive subwords of a fixed length $k$, called rounds. Then, a transducer $\mathcal{T}_1$ is $k$-round simulated by transducer $\mathcal{T}_2$ if, intuitively, for every input word $x$, we can permute the letters within each round in $x$, such that the output of $\mathcal{T}_2$ on the permuted word is itself a permutation of the output of $\mathcal{T}_1$ on $x$. Finally, two transducers are $k$-round equivalent if they simulate each other. We solve two main decision problems, namely whether $\mathcal{T}_2$ $k$-round simulates $\mathcal{T}_1$ (1) when $k$ is given as input, and (2) for an existentially quantified $k$. We demonstrate the usefulness of the definitions by applying them to process symmetry: a setting in which a permutation in the identities of processes in a multi-process system naturally gives rise to two transducers, whose $k$-round equivalence corresponds to stability against such permutations.