English

Simplified Coalgebraic Trace Equivalence

Logic in Computer Science 2014-10-17 v2

Abstract

The analysis of concurrent and reactive systems is based to a large degree on various notions of process equivalence, ranging, on the so-called linear-time/branching-time spectrum, from fine-grained equivalences such as strong bisimilarity to coarse-grained ones such as trace equivalence. The theory of concurrent systems at large has benefited from developments in coalgebra, which has enabled uniform definitions and results that provide a common umbrella for seemingly disparate system types including non-deterministic, weighted, probabilistic, and game-based systems. In particular, there has been some success in identifying a generic coalgebraic theory of bisimulation that matches known definitions in many concrete cases. The situation is currently somewhat less settled regarding trace equivalence. A number of coalgebraic approaches to trace equivalence have been proposed, none of which however cover all cases of interest; notably, all these approaches depend on explicit termination, which is not always imposed in standard systems, e.g. LTS. Here, we discuss a joint generalization of these approaches based on embedding functors modelling various aspects of the system, such as transition and braching, into a global monad; this approach appears to cover all cases considered previously and some additional ones, notably standard LTS and probabilistic labelled transition systems.

Keywords

Cite

@article{arxiv.1410.2463,
  title  = {Simplified Coalgebraic Trace Equivalence},
  author = {Alexander Kurz and Stefan Milius and Dirk Pattinson and Lutz Schröder},
  journal= {arXiv preprint arXiv:1410.2463},
  year   = {2014}
}
R2 v1 2026-06-22T06:18:06.475Z