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On elementary cellular automata asymptotic (a)synchronism sensitivity and complexity (2312.15078v2)

Published 22 Dec 2023 in nlin.CG, cs.DM, and math.DS

Abstract: Among the fundamental questions in computer science is that of the impact of synchronism/asynchronism on computations, which has been addressed in various fields of the discipline: in programming, in networking, in concurrence theory, in artificial learning, etc. In this paper, we tackle this question from a standpoint which mixes discrete dynamical system theory and computational complexity, by highlighting that the chosen way of making local computations can have a drastic influence on the performed global computation itself. To do so, we study how distinct update schedules may fundamentally change the asymptotic behaviors of finite dynamical systems, by analyzing in particular their limit cycle maximal period. For the message itself to be general and impacting enough, we choose to focus on a ``simple'' computational model which prevents underlying systems from having too many intrinsic degrees of freedom, namely elementary cellular automata. More precisely, for elementary cellular automata rules which are neither too simple nor too complex (the problem should be meaningless for both), we show that update schedule changes can lead to significant computational complexity jumps (from constant to superpolynomial ones) in terms of their temporal asymptotes.

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References (31)
  1. Combinatorics on update digraphs in Boolean networks. Dicrete Applied Mathematics, 159:401–409, 2011.
  2. D. M. Chapiro. Globally-asynchronous locally-synchronous systems. PhD thesis, Stanford University, 1984.
  3. Synchronous, asynchronous, and causally ordered communication. Distributed Computing, 9:173–191, 1996.
  4. K. Culik II and S. Yu. Undecidability of CA classification schemes. Complex Systems, 2:177–190, 1988.
  5. M. Deléglise and J.-L. Nicolas. On the largest product of primes with bounded sum. Journal of Integer sequences, 18:15.2.8, 2015.
  6. J. Demongeot and S. Sené. About block-parallel Boolean networks: a position paper. Natural Computing, 19:5–13, 2020.
  7. m𝑚mitalic_m-Asynchronous cellular automata: from fairness to quasi-fairness. Natural Computing, 12:561–572, 2013.
  8. Computational complexity of finite asynchronous cellular automata. Theoretical Computer Science, 664:131–143, 2017.
  9. N. Fatès and M. Morvan. An experimental study of robustness to asynchronism for elementary cellular automata. Complex Systems, 16:1–27, 2005.
  10. B. Fierz and M. G. Poirier. Biophysics of chromatin dynamics. Annual Review of Biophysics, 48:321–345, 2019.
  11. E. Goles and S. Martínez. Neural and automata networks: dynamical behavior and applications, volume 58 of Mathematics and Its Applications. Kluwer Academic Publishers, 1990.
  12. E. Goles and L. Salinas. Comparison between parallel and serial dynamics of Boolean networks. Theoretical Computer Science, 296:247)–253, 2008.
  13. Chromatin dynamics. Annual Review of Biophysics, 39:471–489, 2010.
  14. Structure in asynchronous cellular automata. Physica D: Nonlinear Phenomena, 10:59–68, 1984.
  15. J. Kari. Rice’s theorem for the limit sets of cellular automata. Theoretical Computer Science, 127:229–254, 1994.
  16. S. A. Kauffman. Metabolic stability and epigenesis in randomly constructed genetic nets. Journal of Theoretical Biology, 22:437–467, 1969.
  17. S. C. Kleene. Automata studies, volume 34 of Annals of Mathematics Studies, chapter Representation of events in nerve nets and finite automata, pages 3–41. Princeton Universtity Press, 1956.
  18. P. Kůrka. Languages, equicontinuity and attractors in cellular automata. Ergodic Theory and Dynamical Systems, 17:417–433, 1997.
  19. Wentian Li. Phenomenology of nonlocal cellular automata. Journal of Statistical Physics, 68:829–882, 1992.
  20. W. S. McCulloch and W. Pitts. A logical calculus of the ideas immanent in nervous activity. Journal of Mathematical Biophysics, 5:115–133, 1943.
  21. M. Noual and S. Sené. Synchronism versus asynchronism in monotonic Boolean automata networks. Natural Computing, 17:393–402, 2018.
  22. L. Paulevé and S. Sené. Systems biology modelling and analysis: formal bioinformatics methods and tools, chapter Boolean networks and their dynamics: the impact of updates. Wiley, 2022.
  23. On countings and enumerations of block-parallel automata networks. arXiv:2304.09664, 2023.
  24. M. Ríos-Wilson. On automata networks dynamics: an approach based on computational complexity theory. PhD thesis, Universidad de Chile & Aix-Marseille Université, 2021.
  25. M. Ríos-Wilson and G. Theyssier. On symmetry versus asynchronism: at the edge of universality in automata networks. arXiv:2105.08356, 2021.
  26. F. Robert. Itérations sur des ensembles finis et automates cellulaires contractants. Linear Algebra and its Applications, 29:393–412, 1980.
  27. F. Robert. Discrete iterations: a metric study, volume 6 of Springer Series in Computational Mathematics. Springer, 1986.
  28. A. R. Smith III. Simple computation-universal cellular spaces. Journal of the ACM, 18:339–353, 1971.
  29. R. Thomas. Boolean formalization of genetic control circuits. Journal of Theoretical Biology, 42:563–585, 1973.
  30. J. von Neumann. Theory of self-reproducing automata. University of Illinois Press, 1966. Edited and completed by A. W. Burks.
  31. S. Wolfram. Universality and complexity in cellular automata. Physica D: Nonlinear Phenomena, 10:1–35, 1984.

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