English

A Framework for Universality in Physics, Computer Science, and Beyond

Computational Complexity 2024-09-04 v3 Formal Languages and Automata Theory Logic in Computer Science Mathematical Physics math.MP

Abstract

Turing machines and spin models share a notion of universality according to which some simulate all others. Is there a theory of universality that captures this notion? We set up a categorical framework for universality which includes as instances universal Turing machines, universal spin models, NP completeness, top of a preorder, denseness of a subset, and more. By identifying necessary conditions for universality, we show that universal spin models cannot be finite. We also characterize when universality can be distinguished from a trivial one and use it to show that universal Turing machines are non-trivial in this sense. Our framework allows not only to compare universalities within each instance, but also instances themselves. We leverage a Fixed Point Theorem inspired by a result of Lawvere to establish that universality and negation give rise to unreachability (such as uncomputability). As such, this work sets the basis for a unified approach to universality and invites the study of further examples within the framework.

Keywords

Cite

@article{arxiv.2307.06851,
  title  = {A Framework for Universality in Physics, Computer Science, and Beyond},
  author = {Tomáš Gonda and Tobias Reinhart and Sebastian Stengele and Gemma De les Coves},
  journal= {arXiv preprint arXiv:2307.06851},
  year   = {2024}
}

Comments

66 pages, 12 figures, many diagrams. v3: DOI changed

R2 v1 2026-06-28T11:29:34.062Z