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Ghost cycles exhibit increased entrainment and richer dynamics in response to external forcing compared to slow-fast systems

Published 28 Mar 2024 in nlin.AO | (2403.19624v1)

Abstract: Many natural, living and engineered systems display oscillations that are characterized by multiple timescales. Typically, such systems are described as slow-fast systems, where the slow dynamics result from a hyperbolic slow manifold that guides the movement of the system trajectories. Recently, we have provided an alternative description in which the slow dynamics result from a non-hyperbolic and Lyapunov-unstable attracting sets from connected dynamical ghosts that form a closed orbit (termed ghost cycles). Here we investigate the response properties of both type of systems to external forcing. Using the classical Van-der-Pol oscillator and two modified versions of this model that correspond to a 1-ghost and a 2-ghost cycle, respectively, we find that ghost cycles are characterized by significant increase especially in the 1:1 entrainment regions as demonstrated by the corresponding Arnold tongues and exhibit richer dynamics (bursting, chaos) in contrast to the classical slow-fast system. Phase plane analysis reveals that these features result from the continuous remodeling of the attractor landscape of the ghost cycles models characteristic for non-autonomous systems, whereas the attractor landscape of the corresponding slow-fast system remains qualitatively unaltered. We propose that systems containing ghost cycles display increased flexibility and responsiveness to continuous environmental changes.

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References (45)
  1. T. Roenneberg and M. Merrow. The circadian clock and human health. Current Biology, 26(10):R432–R443, 2016.
  2. Pulsatile patterns in hormone secretion. Trends in Endocrinology & Metabolism, 3(5):183–190, 1992.
  3. L. Glass. Synchronization and rhythmic processes in physiology. Nature, 410(6825):277–284, 2001.
  4. E.M. Izhikevich. Dynamical Systems in Neuroscience: The Geometry of Excitability and Bursting. The MIT Press, 2006.
  5. Oscillatory chemical reactions. Annual Review of Physical Chemistry, 25(1):95–119, 1974.
  6. A. Goldbeter. Oscillatory enzyme reactions and michaelis–menten kinetics. FEBS Letters, 587(17):2778–2784, 2013.
  7. V. Volterra. Fluctuations in the abundance of a species considered mathematically1. Nature, 118(2972):558–560, 1926.
  8. C. Elton and M. Nicholson. The ten-year cycle in numbers of the lynx in canada. The Journal of Animal Ecology, 11(2):215, 1942.
  9. Long-term cyclic persistence in an experimental predator–prey system. Nature, 577(7789):226–230, 2019.
  10. Spatial synchrony in population dynamics. Annual Review of Ecology, Evolution, and Systematics, 35(1):467–490, 2004.
  11. El Niño and Southern Oscillation (ENSO): A Review, page 85–106. Springer Netherlands, 2016.
  12. H.A. Dijkstra and M. Ghil. Low‐frequency variability of the large‐scale ocean circulation: A dynamical systems approach. Reviews of Geophysics, 43(3), 2005.
  13. G. Vettoretti and W.R. Peltier. Fast physics and slow physics in the nonlinear dansgaard–oeschger relaxation oscillation. Journal of Climate, 31(9):3423–3449, 2018.
  14. North Greenland Ice Core Project members. High-resolution record of northern hemisphere climate extending into the last interglacial period. Nature, 431(7005):147–151, 2004.
  15. J.-M. Liu. Laser Oscillation, page 274–296. Cambridge University Press, 2016.
  16. C. Kuehn. Multiple Time Scale Dynamics. Springer International Publishing, 2015.
  17. R. Bertram and J.E. Rubin. Multi-timescale systems and fast-slow analysis. Mathematical Biosciences, 287:105–121, 2017.
  18. N. Fenichel. Persistence and smoothness of invariant manifolds for flows. Indiana University Mathematics Journal, 21(3):193–226, 1971.
  19. Metastable resting state brain dynamics. Frontiers in Computational Neuroscience, 13, 2019.
  20. Global brain dynamics embed the motor command sequence of caenorhabditis elegans. Cell, 163(3):656–669, 2015.
  21. The dynamics of pattern matching in camouflaging cuttlefish. Nature, 619(7968):122–128, 2023.
  22. Toward a multi-stressor theory for coral reefs in a changing world. Ecosystems, 27(2):310–328, 2024.
  23. Transient phenomena in ecology. Science, 361(6406):eaat6412, 2018.
  24. Arnold tongue entrainment reveals dynamical principles of the embryonic segmentation clock. eLife, 11:e79575, 2022.
  25. Developmental function and state transitions of a gene expression oscillator in Caenorhabditis elegans. Molecular Systems Biology, 16(7):e9498, 2020.
  26. Dynamical encoding by networks of competing neuron groups: Winnerless competition. Physical Review Letters, 87(6):068102, 2001.
  27. On the origin of reproducible sequential activity in neural circuits. Chaos: An Interdisciplinary Journal of Nonlinear Science, 14(4):1123–1129, 2004.
  28. P. Ashwin and C. Postlethwaite. On designing heteroclinic networks from graphs. Physica D: Nonlinear Phenomena, 265:26–39, 2013.
  29. Beyond fixed points: transient quasi-stable dynamics emerging from ghost channels and ghost cycles. arXiv, 2023. doi: 10.48550/ARXIV.2309.17201.
  30. A.N. Gorban. Singularities of transition processes in dynamical systems: Qualitative theory of critical delays. Electronic Journal of Differential Equations, 1:05, 2004.
  31. Lyapunov-like conditions of forward invariance and boundedness for a class of unstable systems. SIAM Journal on Control and Optimization, 51(3):2306–2334, 2013.
  32. J. van der Pol, B.and van der Mark. Lxxii.the heartbeat considered as a relaxation oscillation, and an electrical model of the heart. The London, Edinburgh, and Dublin Philosophical Magazine and Journal of Science, 6(38):763–775, 1928.
  33. Synchronization: A Universal Concept in Nonlinear Sciences. Cambridge University Press, 2001.
  34. Modeling Fireflies Synchronization, page 131–156. Springer International Publishing, 2018.
  35. Classification of transient behaviours in a time-dependent toggle switch model. BMC Systems Biology, 8(1), 2014.
  36. Organization at criticality enables processing of time-varying signals by receptor networks. Molecular Systems Biology, 16(2):e8870, 2020.
  37. C. Morris and H. Lecar. Voltage oscillations in the barnacle giant muscle fiber. Biophysical Journal, 35(1):193–213, 1981.
  38. Bifurcations in morris–lecar neuron model. Neurocomputing, 69(4–6):293–316, 2006.
  39. Geometric models for robust encoding of dynamical information into embryonic patterns. eLife, 9, 2020.
  40. Novel generic models for differentiating stem cells reveal oscillatory mechanisms. Journal of The Royal Society Interface, 18(183):20210442, 2021.
  41. Saddle-ghost induced heteroclinic cycling in five-dimensional positively auto-regulated and mutually repressive gene regulation networks. Nonlinear Dynamics, 109(2):1081–1105, 2022.
  42. Gated recurrent units viewed through the lens of continuous time dynamical systems. Frontiers in Computational Neuroscience, 15, 2021.
  43. D. Durstewitz. Self-organizing neural integrator predicts interval times through climbing activity. The Journal of Neuroscience, 23(12):5342–5353, 2003.
  44. Benettin, G., Galgani, L., and Strelcyn, J.-M., “Kolmogorov entropy and numerical experiments,” Physical Review A 14, 2338–2345 (1976).
  45. Koch, D., Nandan, A., Ramesan, G., and Koseska, A., “Beyond fixed points: transient quasi-stable dynamics emerging from ghost channels and ghost cycles,” arXiv  (2023), 10.48550/ARXIV.2309.17201.
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