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Periodic solutions of a planar delay equation

Published online by Cambridge University Press:  14 November 2011

Plácido Táboas
Affiliation:
Lefschetz Center for Dynamical Systems, Division of Applied Mathematics, Brown University, Providence, RI 02912, U.S.A.; and (permanent address) ICMSC-USP Caixa Postal 668, 13560 Sã;o Carlos SP, Brasil

Synopsis

We study the planar delay differential equation x′(t) = −x(t) + αF(x(t − 1)), for α > 0. An existence theorem for nonconstant periodic solutions is achieved for a certain class of maps F, for α > some α0. Besides a condition of nondegeneracy at x = 0, we assume F is bounded and satisfies a kind of planar negative feedback condition. The nonconstant periodic solutions are associated with nontrivial fixed points of a certain operator defined by the flow in the plase space C([−l, 0], R2). In our approach, the existence of such fixed points depends on the ejectivity of O ϵ C([−1, 0], R2) with respect to that operator. Relaxing the boundedness condition on F, we show the existence of a sequence of values of α, α0 < α1 <…, where a Hopf bifurcation occurs.

Type
Research Article
Copyright
Copyright © Royal Society of Edinburgh 1990

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References

1Browder, F.. A further generalization of the Schauder fixed point theorem. Duke Math. J. 32 (1965), 575578.Google Scholar
2Bellman, R. and Cooke, K.. Differential Difference Equations (New York: Academic Press, 1963).CrossRefGoogle Scholar
3Chow, S. N.. Existence of periodic solutions of autonomous functional differential equations. J. Differential Equations 15 (1974), 350378.CrossRefGoogle Scholar
4Chow, S. N. and Hale, J.. Periodic solutions of autonomous equations. J. Math. Anal. Appl. 66 (1978), 495506.CrossRefGoogle Scholar
5Cunningham, W.. A nonlinear differential difference equation of growth. Proc. Acad. Sci. U.S.A. 40 (1954), 709713.CrossRefGoogle ScholarPubMed
6Fiedler, B. and Maller-Paret, J.. Connections between Morse sets for delay-differential equations (to appear).Google Scholar
7Grafton, R.. A periodicity theorem for autonomous functional differential equations. J. Differential Equations 6 (1969), 87109.CrossRefGoogle Scholar
8Hadeler, K.. Delay equations in biology. In Functional Differential Equations and Approximations of Fixed Points, eds Peitgen, H.-O. and Walther, H.-O., Lecture Notes in Mathematics 730 (Berlin: Springer, 1979).Google Scholar
9Hadeler, K. and Tomiuk, J.. Periodic solutions of difference-differential equations. Arch. Rational Mech. Anal. 65 (1977), 8795.CrossRefGoogle Scholar
10Hale, J.. Theory of Functional Differential Equations (New York: Springer, 1977).CrossRefGoogle Scholar
11Hale, J.. Linear functional differential equations with constant coefficients. Contrib. Differential Equations 2 (1963), 291319.Google Scholar
12Jones, G.. The existence of periodic solutions of f′(x) = −αf(x − 1)[1 + f(x)]. J. Math. Anal. Appl. 5 (1962), 435450.CrossRefGoogle Scholar
13Kakutani, S. and Markus, L.. On the nonlinear differential difference equation y′(t) = [ABy(t − τ)]y(t). In Contributions to the Theory of Nonlinear Oscillations (Princeton: Princeton University Press, 1958).Google Scholar
14Kaplan, J. and Yorke, J.. On the nonlinear delay equation “x′(t) = f(x(t), x(t − 1))”. J. Differential Equations 23 (1977), 293314.CrossRefGoogle Scholar
15Mallet-Paret, J.. Morse decompositions for delay-differential equations. J. Differential Equations 78 (1988), 270315.CrossRefGoogle Scholar
16Mallet-Paret, J. and Nussbaum, R.. Global continuation and complicated trajectories for periodic solutions of a differential-delay equation. Proc. Symposia in Pure Math. A.M.S. 45 Part 2 (1986).CrossRefGoogle Scholar
17Mallet-Paret, J. and Nussbaum, R.. Global continuation ans asymptotic behaviour for periodic solutions of a differential-delay equation. Ann. Mat. Pura Appl. (to appear).Google Scholar
18Nussbaum, R.. Periodic solutions of nonautonomous functional differential equations. In Functional Differential Equations and Approximations of Fixed Points, eds Peitgen, H.-O. and Walther, H.-O., Lecture Notes in Mathematics 730 (Berlin: Springer, 1979).Google Scholar
19Nussbaum, R.. Periodic solutions of some nonlinear autonomous functional differential equations. Ann. Mat. Pura Appl. 101 (1974), 263306.CrossRefGoogle Scholar
20Nussbaum, R.. Periodic solutions of some nonlinear autonomous functional differential equations II. J. Differential Equations 14 (1973), 360394.CrossRefGoogle Scholar
21Nussbaum, R.. A Hopf global bifurcation theorem for retarded functional differential equations. Trans. Amer. Math. Soc. 238 (1978), 139163.CrossRefGoogle Scholar
22Pontryagin, L.. On the zeros of some elementary transcendental functions. Amer. Math. Soc. Transl. Ser. (2) 1 (1955), 95110.Google Scholar
23Walther, H.-O.. On density of slowly oscillating solutions of ẋ(t) = −f(x(t − 1)). J. Math. Anal. Appl. 79 (1981), 127140.CrossRefGoogle Scholar
24Wright, E.. A functional equation in the heuristic theory of primes. Math. Gaz. 45 (1961), 1516.CrossRefGoogle Scholar
25Wright, E.. A nonlinear difference-differential equation. J. Reine Angew. Math. 194 (1955), 6687.CrossRefGoogle Scholar