In mathematics, in the study of dynamical systems with two-dimensional phase space, a limit cycle is a closed trajectory in phase space having the property that at least one other trajectory spirals into it either as time approaches infinity or as time approaches negative infinity. Such behavior is exhibited in some nonlinear systems. Limit cycles have been used to model the behavior of many real-world oscillatory systems. The study of limit cycles was initiated by Henri Poincaré (1854–1912).

Stable limit cycle (shown in bold) and two other trajectories spiraling into it
Stable limit cycle (shown in bold) for the Van der Pol oscillator

Definition

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We consider a two-dimensional dynamical system of the form   where   is a smooth function. A trajectory of this system is some smooth function   with values in   which satisfies this differential equation. Such a trajectory is called closed (or periodic) if it is not constant but returns to its starting point, i.e. if there exists some   such that   for all  . An orbit is the image of a trajectory, a subset of  . A closed orbit, or cycle, is the image of a closed trajectory. A limit cycle is a cycle which is the limit set of some other trajectory.

Properties

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By the Jordan curve theorem, every closed trajectory divides the plane into two regions, the interior and the exterior of the curve.

Given a limit cycle and a trajectory in its interior that approaches the limit cycle for time approaching  , then there is a neighborhood around the limit cycle such that all trajectories in the interior that start in the neighborhood approach the limit cycle for time approaching  . The corresponding statement holds for a trajectory in the interior that approaches the limit cycle for time approaching  , and also for trajectories in the exterior approaching the limit cycle.

Stable, unstable and semi-stable limit cycles

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In the case where all the neighboring trajectories approach the limit cycle as time approaches infinity, it is called a stable or attractive limit cycle (ω-limit cycle). If instead, all neighboring trajectories approach it as time approaches negative infinity, then it is an unstable limit cycle (α-limit cycle). If there is a neighboring trajectory which spirals into the limit cycle as time approaches infinity, and another one which spirals into it as time approaches negative infinity, then it is a semi-stable limit cycle. There are also limit cycles that are neither stable, unstable nor semi-stable: for instance, a neighboring trajectory may approach the limit cycle from the outside, but the inside of the limit cycle is approached by a family of other cycles (which would not be limit cycles).

Stable limit cycles are examples of attractors. They imply self-sustained oscillations: the closed trajectory describes the perfect periodic behavior of the system, and any small perturbation from this closed trajectory causes the system to return to it, making the system stick to the limit cycle.

Finding limit cycles

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Every closed trajectory contains within its interior a stationary point of the system, i.e. a point   where  . The Bendixson–Dulac theorem and the Poincaré–Bendixson theorem predict the absence or existence, respectively, of limit cycles of two-dimensional nonlinear dynamical systems.

Open problems

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Finding limit cycles, in general, is a very difficult problem. The number of limit cycles of a polynomial differential equation in the plane is the main object of the second part of Hilbert's sixteenth problem. It is unknown, for instance, whether there is any system   in the plane where both components of   are quadratic polynomials of the two variables, such that the system has more than 4 limit cycles.

Applications

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Examples of limit cycles branching from fixed points near Hopf bifurcation. Trajectories in red, stable structures in dark blue, unstable structures in light blue. The parameter choice determines the occurrence and stability of limit cycles.

Limit cycles are important in many scientific applications where systems with self-sustained oscillations are modelled. Some examples include:

See also

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References

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  1. ^ Thomas, Jeffrey P.; Dowell, Earl H.; Hall, Kenneth C. (2002), "Nonlinear Inviscid Aerodynamic Effects on Transonic Divergence, Flutter, and Limit-Cycle Oscillations" (PDF), AIAA Journal, 40 (4), American Institute of Aeronautics and Astronautics: 638, Bibcode:2002AIAAJ..40..638T, doi:10.2514/2.1720, retrieved December 9, 2019
  2. ^ Sel'kov, E. E. (1968). "Self-Oscillations in Glycolysis 1. A Simple Kinetic Model". European Journal of Biochemistry. 4 (1): 79–86. doi:10.1111/j.1432-1033.1968.tb00175.x. ISSN 1432-1033. PMID 4230812.
  3. ^ Leloup, Jean-Christophe; Gonze, Didier; Goldbeter, Albert (1999-12-01). "Limit Cycle Models for Circadian Rhythms Based on Transcriptional Regulation in Drosophila and Neurospora". Journal of Biological Rhythms. 14 (6): 433–448. doi:10.1177/074873099129000948. ISSN 0748-7304. PMID 10643740. S2CID 15074869.
  4. ^ Roenneberg, Till; Chua, Elaine Jane; Bernardo, Ric; Mendoza, Eduardo (2008-09-09). "Modelling Biological Rhythms". Current Biology. 18 (17): R826–R835. Bibcode:2008CBio...18.R826R. doi:10.1016/j.cub.2008.07.017. ISSN 0960-9822. PMID 18786388. S2CID 2798371.
  5. ^ Meijer, JH; Michel, S; Vanderleest, HT; Rohling, JH (December 2010). "Daily and seasonal adaptation of the circadian clock requires plasticity of the SCN neuronal network". The European Journal of Neuroscience. 32 (12): 2143–51. doi:10.1111/j.1460-9568.2010.07522.x. PMID 21143668. S2CID 12754517.
  6. ^ Brückner, David B.; Fink, Alexandra; Schreiber, Christoph; Röttgermann, Peter J. F.; Rädler, Joachim; Broedersz, Chase P. (2019). "Stochastic nonlinear dynamics of confined cell migration in two-state systems". Nature Physics. 15 (6): 595–601. Bibcode:2019NatPh..15..595B. doi:10.1038/s41567-019-0445-4. ISSN 1745-2481. S2CID 126819906.
  7. ^ Ginoux, Jean-Marc; Letellier, Christophe (2012-04-30). "Van der Pol and the history of relaxation oscillations: Toward the emergence of a concept". Chaos: An Interdisciplinary Journal of Nonlinear Science. 22 (2): 023120. arXiv:1408.4890. Bibcode:2012Chaos..22b3120G. doi:10.1063/1.3670008. ISSN 1054-1500. PMID 22757527. S2CID 293369.
  8. ^ Mackey, M.; Glass, L (1977-07-15). "Oscillation and chaos in physiological control systems". Science. 197 (4300): 287–289. Bibcode:1977Sci...197..287M. doi:10.1126/science.267326. ISSN 0036-8075. PMID 267326.

Further reading

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  • Steven H. Strogatz (2014). Nonlinear Dynamics and Chaos: With Applications to Physics, Biology, Chemistry, and Engineering. Avalon. ISBN 9780813349114.
  • M. Vidyasagar (2002). Nonlinear Systems Analysis (Second ed.). SIAM. ISBN 9780898715262.
  • Philip Hartman, "Ordinary Differential Equation", Society for Industrial and Applied Mathematics, 2002.
  • Witold Hurewicz, "Lectures on Ordinary Differential Equations", Dover, 2002.
  • Solomon Lefschetz, "Differential Equations: Geometric Theory", Dover, 2005.
  • Lawrence Perko, "Differential Equations and Dynamical Systems", Springer-Verlag, 2006.
  • Arthur Mattuck, Limit Cycles: Existence and Non-existence Criteria, MIT Open Courseware http://videolectures.net/mit1803s06_mattuck_lec32/#
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