Hopf-pitchfork bifurcation of coupled van der Pol oscillator with delay

Transcription

1 ISSN Nonlinear Analysis: Modelling and Control, 2017, Vol. 22, No. 5, Hopf-pitchfork bifurcation of coupled van der Pol oscillator with delay Yuting Cai, Chunrui Zhang 1 Department of Mathematics, Northeast Forestry University, Harbin , China math@nefu.edu.cn Received: July 23, 2016 / Revised: April 15, 2017 / Published online: September 24, 2017 Abstract. In this paper, the Hopf-pitchfork bifurcation of coupled van der Pol with delay is studied. The interaction coefficient and time delay are taken as two bifurcation parameters. Firstly, the normal form is gotten by performing a center manifold reduction and using the normal form theory developed by Faria and Magalhães. Secondly, bifurcation diagrams and phase portraits are given through analyzing the unfolding structure. Finally, numerical simulations are used to support theoretical analysis. Keywords: delay, Hopf-pitchfork bifurcation, stability, coupled van der Pol model, normal form. 1 Introduction or the first section The coupling of nonlinear systems comes naturally from physics and engineering, for example, in electronics, nonlinear systems have been long used as an efficient system to generate higher harmonics from a given signal [26]. Studying of coupled nonlinear systems is significant in a number of areas of fundamental and applied mathematics, such as bifurcation in the presence of symmetries, chaos theory, nonlinear electronics. In the research of nonlinear dynamical system, van der Pol equation is one of the most intensely studied equation see [14, 15]). This celebrated equation has a nonlinear damping ẍ + ε x 2 1 ) ẋ + x = fx), which originally was a model for an electrical circuit with a triode valve and was extensively studied as a host of a rich class of dynamical behavior, including relaxation oscillations, quasi-periodicity, elementary bifurcations, and chaos [1]. Noting that most practical implementations of feedback have inherent delays, some researchers have considered the effect of time delay in van der Pol s oscillator [8,18,19,25,32,35,36]. It is shown that the presence of time delay can change the amplitude of limit cycle oscillations. Thus, time This research was supported by the Natural Science Foundations of Heilongjiang province No. A ). 1 Corresponding author. c Vilnius University, 2017

2 Hopf-pitchfork bifurcation of coupled van der Pol oscillator with delay 599 delay is inevitable in coupled systems, and effects of time delay are also very popular in the study of dynamical systems with many delay factors that appear in state variables, and some of them appear in parameters [42]. When time delay becomes a parameter, structural properties of dynamical systems such as the number of equilibrium, stability, ect.) will change, then the question belongs to the bifurcation question. Now, there are some articles on Hopf bifurcation in delay differential equations see [2,29,34]). However, there are other articles on Hopf-pitchfork bifurcation in delay differential equations see [3 6, 10, 17, 22, 24, 27, 30, 31, 38, 41]). Particularly, by our existing knowledge, there is no study in Hopf-pitchfork bifurcation of coupled van der Pol s equation with time delay. In recent years, various aspects of the van der Pol have been studied [28, 40]. Wen et al. [33] investigate the dynamics of Mathieu equation with two kinds of van der Pol fractional-order terms. Euzebio and Llibre [9] discuss some aspects on the periodic solutions of the extended Duffing van der Pol oscillator. They show that it can bifurcate one or three periodic solutions from a two-dimensional manifold filled by periodic solutions of the referred system. Kumar et al. [20] carry out investigations on the bifurcation characteristics of a Duffing van der Pol oscillator subjected to white noise excitations. Fu et al. [13] discuss noise-induced and delay-induced bifurcations in a bistable Duffing van der Pol oscillator under time delay and join noises theoretically and numerically. Dubkov and Litovsky [7] investigate that the exact Fokker Planck equation for the joint probability distribution of amplitude and phase of a van der Pol oscillator perturbed by both additive and multiplicative noise sources with arbitrary nonlinear damping is first derived by the method of functional splitting of averages. Yonkeu et al. [39] propose to compute the effective activation energy, usually referred to a pseudopotential or quasipotential, of a birhythmic system a van der Pol-like oscillator in the presence of correlated noise. Ji and Zhang [16] use the method of multiple time scales to investigate the following system with both external force and feedback control: ẍ µ βx 2) ẋ + ωx + αx 3 = e 0 cosω 0 t) + pxt τ) + qẋt τ) + k 1 x 3 t τ) + k 2 ẋ 3 + k 3 ẋt τ)x 2 t τ) + k 4 ẋ 2 t τ)xt τ). Njah [23] studied the synchronization and antisynchronization of the following van der Pol systems based on the theory of Lyapunov stability and Routh Hurwitz criteria: ẍ µ 1 x 2) ẋ + αx + βx 3 = 2F cosω 0 t). Yamapi and Filatrella [37] studied the strange attractors of the following coupled van der Pol systems: ẍ µ 1 x 2) ẋ + x + βx 3 = F cosω 0 t), ÿ µ 1 y 2) ẏ + y + βy 3 = F cosω 0 t) Ky x)ht T 0 ), where Ht) is the Heaviside function. In [37], they have obtained the stability of the equilibrium and the existence of Hopf bifurcation. Using the center manifold reduction technique and normal form theory, they Nonlinear Anal. Model. Control, 225):

3 600 Y. Cai, C. Zhang give the direction of the Hopf bifurcation. Therefore, I want to know if this model can produce Hopf-pitchfork bifurcation, and whether we can apply these theories to analyse of the Hopf-pitchfork bifurcation. Because there are only some articles to study Hopf-pitchfork bifurcation of coupled van der Pol with delay, in order to get more dynamic behaviors, we have the reason to believe that investigating Hopf-pitchfork bifurcation of coupled van der Pol with delay is interesting and worthwhile. Consider the following coupled van der Pol systems: ẍ α x 2) ẋ + x + βx 3 = k 1 g yt τ) ), ÿ α y 2) ẏ + y + βy 3 = k 2 g xt τ) ). 1) Let x = x 1, ẋ = x 2, y = x 3, ẏ = x 4, then equation 1) can be written as follows: ẋ 1 = x 2, ẋ 2 = x 1 + αx 2 x 2 1x 2 βx k 1 g x 3 t τ) ), ẋ 3 = x 4, ẋ 4 = x 3 + αx 4 x 2 3x 4 βx k 2 g x 1 t τ) ). 2) Because the activate function gt) belongs to sigmoidal function see [12, p. 356]), we assume g0) = g 0) = 0, g 0) = 1, and g 0) 0 throughout this paper. Clearly, we probe dynamical behaviors of system 1) equaling to investigate that of system 2). The rest of the article is organized as follows. In Section 2, we will give the existence condition of the Hopf-pitchfork bifurcation by taking interaction coefficient and delay as two parameters. In Section 3, we use center manifold theory and normal form method [11, 30] to investigate Hopf-pitchfork bifurcation with original parameters. In Section 4, we given some numerical simulations to support the analytic results. Finally, we draw the conclution in Section 5. 2 The existence of Hopf-pitchfork bifurcation In the following, if the characteristic equation 2) has a simple root 0 and a simple pair of purely imaginary roots ±iω 0, and all other roots of the characteristic equation have negative real parts, then the Hopf-zero bifurcation will occur. The linearization equation of system 2) at the origin is ẋ 1 = x 2, ẋ 2 = x 1 + αx 2 + k 1 x 3 t τ), ẋ 3 = x 4, ẋ 4 = x 3 + αx 4 + k 2 x 1 t τ). 3) The characteristic equation of system 3) is Eλ) = λ 2 αλ + 1 ae λτ ) λ 2 αλ ae λτ ) = 0, 4)

4 Hopf-pitchfork bifurcation of coupled van der Pol oscillator with delay 601 where a = k 1 k 2, k 1 k 2 > 0. If λ = 0 is one root of equation 4), we obtain a = ±1. By above analysis, we know a > 0, so we get a = 1. If τ = 0, then Hλ) = λ 2 αλ + 2 ) λ 2 αλ ) = 0. We obtain that if τ = 0, then α < 0. Except a single zero eigenvalue, all the roots of equation 4) have negative real parts. Next, we consider the case of τ 0. Let iω, ω > 0, be such a root of λ 2 αλ e λτ = 0, then the following holds: iω) 2 αiω) + 1 e iωτ = 0. Separating the real and imaginary parts, we have It follows that ω satisfies ω 2 1 = cos ωτ, αω = sin ωτ. 5) ω 2 ω 2 + α 2 2 ) = 0. If α 2 2 > 0, then equation 5) has no positive solutions. If α 2 2 < 0, then equation 5) has a positive solution ω 0 with ω 0 = 2 α 2. If 2 < α < 0, then sin ω 0 τ > 0, cos ω 0 τ > 0, we know the point in the first quadrant, then τ k = 1 ω 0 { arccos ω ) + 2kπ }, k = 0, 1, 2,.... We can obtain the following lemma immediately. Lemma 1. If a = 1 that means k 1 k 2 = 1 and 2 < α < 0 hold, when τ = τ k k = 0, 1, 2,... ), system 2) undergoes a Hopf-zero bifurcation at equilibrium 0, 0, 0, 0). 3 Normal form for Hopf-zero bifurcation In this section, center manifold theory and normal form method [11,30] are used to study Hopf-pitchfork bifurcation. After scaling t t/τ, system 2) can be written as ẋ 1 = τx 2, ẋ 2 = τ x 1 + αx 2 x 2 1x 2 βx 3 1) + τk1 g x 3 t 1) ), ẋ 3 = τx 4, ẋ 4 = τ x 3 + αx 4 x 2 3x 4 βx 3 3) + τk2 g x 1 t 1) ). 6) Let the Taylor expansion of g be gs) = g0) + g 0)s g 0)s g 0)s 3 + O s 4), where g0) = g 0) = 0, g 0) = 1. Nonlinear Anal. Model. Control, 225):

5 602 Y. Cai, C. Zhang Let τ = τ 0 + µ 1 and k 1 = 1/k 2 + µ 2, µ 1 and µ 2 are bifurcation parameters and expand the function g, equation 6) becomes ẋ 1 = τ 0 + µ 1 )x 2, ẋ 2 = τ 0 + µ 1 ) x 1 + αx 2 x 2 1x 2 βx 3 ) 1 )[ ] 1 + τ 0 + µ 1 ) + µ 2 x 3 t 1) + g 0) x 3 k 2 6 3t 1), ẋ 3 = τ 0 + µ 1 )x 4, ẋ 4 = τ 0 + µ 1 ) x 3 + αx 4 x 2 3x 4 βx 3 ) 3 [ ] + τ 0 + µ 1 )k 2 x 1 t 1) + g 0) x 3 6 1t 1). 7) Choosing the phase space C = C[ 1, 0]; R 4 ) with supreme norm, X t C is defined by X t θ) = Xt + θ), τ θ 0, and X t = sup X t θ). Then system 7) becomes where Ẋt) = Lµ)X t + F X t, µ), 8) x 2 t) Lµ)X t = τ 0 + µ 1 ) x 1 t) + αx 2 t) + 1 k 2 + µ 2 )x 3 t 1) x 4 t) x 3 t) + αx 4 + k 2 x 1 t 1) and 0 F X t, µ) = τ 0 + µ 1 ) x 2 1t)x 2 t) βx 3 1t) + 1 k 2 + µ 2 ) g 0) 6 x 3 3t 1)) 0, τ 0 + µ 1 ) x 2 3t)x 4 t) βx 3 g 3t) + k 0) 2 6 x 3 1t 1)) where Lµ)ϕ = 0 1 dηθ, µ)ϕξ) dξ for ϕ [ 1, 0], R4 ), 0, θ = 0, ηθ, µ) = τ 0 + µ 1 )A, θ 1, 0), τ 0 + µ 1 )A + B), θ = 1, with A = 1 α , B = k α k Consider the following linear system: Ẋt) = L0)X t.

6 Hopf-pitchfork bifurcation of coupled van der Pol oscillator with delay 603 Define the bilinear form between C and C = C[0, τ], C n ) by 0 ) ψs), ϕθ) = ψ0)ϕ0) 1 θ 0 ψξ θ) dηθ, 0)ϕξ) dξ ψ C, ϕ C, where ϕθ) = ϕ 1 θ), ϕ 2 θ), ϕ 3 θ)) C, ψs) = ψ 1 s), ψ 2 s), ψ 3 s)) T C. Because L0) has a simple 0 and a pair of purely imaginary eigenvalues ±iω 0, ω > 0, all other eigenvalues have negative real parts. Let Λ = {0, iω 0, iω 0 }, P can be the generalized eigenspace associated with Λ, and P the space adjoint with P. Then C can be decomposed as C = P Q, where Q = {ϕ C: ψ, ϕ) = 0 for all ψ P }. Choose the bases Φ and Ψ for P and P such that Ψs), Φθ)) = I, Φ = ΦJ, and Ψ = JΨ, where J = diag0, iω 0, iω 0 ). By calculating, we choose 1 e iw0τ0θ e iw0τ0θ Φθ) = 0 iw 0 e iw0τ0θ iw 0 e iw0τ0θ k 2 k 2 e iw0τ0θ k 2 e iw0τ0θ 0 iw 0 k 2 e iw0τ0θ iw 0 k 2 e iw0τ0θ and D 1 αk 2 ) D 1 k 2 D 1 α) D 1 Ψs) = D 2 α iw 0 )k 2 e iw0τ0s D 2 k 2 e iw0τ0s D 2 iw 0 α)e iw0τ0s D 2 e iw0τ0s, D 2 α+iw 0 )k 2 e iw0τ0s D 2 k 2 e iw0τ0s D 2 iw 0 α)e iw0τ0s D 2 e iw0τ0s where D 1 = 1 1, D 2 = 2τ 0 k 2 2αk 2 2αk 2 4iwk 2 + 2τ 0 k 2 e. iw0τ0 To consider system 8), we need to enlarge the space C to the following: { } BC = ϕ is continuous functions on [ 1, 0), and lim ϕθ) exists. θ 0 Its elements can be written as φ = ϕ + Y 0 c with ϕ C, c R 4, and { 0, θ [ 1, 0), Y 0 θ) = I, θ = 0. In BC, equation 8) becomes an abstract ODE where u C, A is defined by d dt X t = Au + Y 0 F u, µ), 9) A : C 1 BC, Au = u + Y 0 [ L0)u u0) ], Nonlinear Anal. Model. Control, 225):

7 604 Y. Cai, C. Zhang and F u, µ) = [ Lµ) L 0 ] u + F u, µ). Then the enlarged phase space BC can be decomposed as BC = P Ker π. Let X t = Φzt) + ỹθ), where zt) = z 1, z 2, z 3 ) T, namely x 1 θ) = z 1 + e iw0τ0θ z 2 + e iw0τ0θ z 3 + y 1 θ), x 2 θ) = iwe iw0τ0θ z 2 iwe iw0τ0θ z 3 + y 2 θ), x 3 θ) = k 2 z 1 k 2 e iw0τ0θ z 2 k 2 e iw0τ0θ z 3 + y 3 θ), x 4 θ) = iwk 2 e iw0τ0θ z 2 + i wk 2 e iw0τ0θ z 3 + y 4 θ). Let Ψ0) = ψ 11 ψ 12 ψ 13 ψ 14 ψ 21 ψ 22 ψ 23 ψ 24 ψ 31 ψ 32 ψ 33 ψ 34 D 1 αk 2 ) D 1 k 2 D 1 α) D 1 = D 2 α iw 0 )k 2 D 2 k 2 D 2 iw 0 α) D 2. D 2 α + iw 0 )k 2 D 2 k 2 D 2 iw 0 α) D 2 System 9) can be decomposed as ż = Jz + Ψ0) F Φz + ỹθ), µ ), ỹ = A Q1 ỹ + I π)y 0 F Φz + ỹ0), µ ), 10) where ỹθ) Q 1 := Q C 1 Ker π, A Q1 is the restriction of A as an operator from Q 1 to the Banach space Ker π. Neglecting higher-order terms with respect to parameters µ 1 and µ 2, equation 11) can be written as F2 ż 1 ψ 11 ψ 12 ψ 13 ψ 1 + F3 1 + O x 4 ) 14 ż 2 = ψ 21 ψ 22 ψ 23 ψ 24 F2 2 + F3 2 + O x 4 ) F2 ż 3 ψ 31 ψ 32 ψ 33 ψ 3 + F3 3 + O x 4 ), 34 F2 4 + F3 4 + O x 4 ) where F2 1 = µ 1 iωz2 iωz 3 + y 2 0) ), F2 2 = µ 1 z1 + z 2 + z 3 + y 1 0) ) + αµ 1 iωz2 iωz 3 + y 2 0) ) )) 1 k2 + τ 0 µ 2 + µ 1 µ 2 + µ 1 z 1 k 2 e iω0τ0 z 2 k 2 e iω0τ0 z 3 + y 3 1) ), k 2 F 3 2 = µ 1 iωk2 z 2 + iωk 2 z 3 + y 4 0) ), F 4 2 = µ 1 k2 z 1 k 2 z 2 k 2 z 3 + y 3 0) ) + αµ 1 iωk2 z 2 + iωk 2 z 3 + y 4 0) ) + µ 1 k 2 z1 + e iτ0ω0 z 2 + e iτ0ω0 z 3 + y 1 1) ),

8 Hopf-pitchfork bifurcation of coupled van der Pol oscillator with delay 605 F 1 3 = 0, F 2 3 = τ 0 + µ 1 ) z 1 + z 2 + z 3 + y 1 0) ) 2 iωz2 iωz 3 + y 2 0) ) F 3 3 = 0, βz 1 + z 2 + z 3 + y 1 0) ) 3, ) 1 g 0) + + µ 2 k2 z 1 k 2 e iω0τ0 z 2 k 2 e iω0τ0 z 3 + y 3 1) 3), k 2 6 F 4 3 = τ 0 + µ 1 ) k 2 z 1 k 2 z 2 k 2 z 3 + y 3 0) ) 2 iωk2 z 2 + iωk 2 z 3 + y 4 0) ) β k 2 z 1 k 2 z 2 k 2 z 3 + y 3 0) ) 3 + k 2 g 0) 6 z1 + e iω0τ0 z 2 + e iω0τ0 z 3 + y 1 1) 3). According to [30], ImM 1 2 )) c is spanned by { z 2 1 e 1, z 2 z 3 e 1, z 1 µ i e 1, µ 1 µ 2 e 1, z 1 z 2 e 2, z 2 µ i e 2, z 1 z 3 e 3, z 3 µ i e 3 }, i = 1, 2, with e 1 = 1, 0, 0) T, e 2 = 0, 1, 0) T, e 3 = 0, 0, 1) T. If g is an odd function, the Hopf-pitchfork will occur. ImM 1 3 )) c is spanned by { z 3 1 e 1, z 1 z 2 z 3 e 1, z 2 1z 2 e 2, z 2 2z 3 e 2, z 2 1z 3 e 3, z 2 z 2 3e 3 }. Then we get g 1 2x, 0, µ) = Proj ImM 1 2 )) c f 1 2 x, 0, µ) = Proj S1 f 1 2 x, 0, µ) + O µ 2), g 1 3x, 0, µ) = Proj ImM 1 3 )) c f 1 3 x, 0, µ) = Proj S1 f 1 3 x, 0, 0) + O µ 2 x + µ x 2), where S 1 and S 2 are spanned, respectively, by { z1 µ i e 1, z 2 µ i e 2, z 3 µ i e 3 }, i = 1, 2, and { z 3 1 e 1, z 1 z 2 z 3 e 1, z 2 1z 2 e 2, z 2 2z 3 e 2, z 2 1z 3 e 3, z 2 z 2 3e 3 }. On the center manifold, 8) can be transform as the following normal form: ż = Jz + 1 2! g1 2z, 0, µ) + 1 3! g1 3z, 0, 0) + h.o.t. with g 1 3z, 0, 0) = Proj ImM 1 3 )) c f 1 3 z, 0, 0). According to [11, Thm. 2.1], we obtain the dynamical behavior of 8) near X t = 0, which is governed by the general normal form of the third order. Then the equation becomes ż 1 = b 11 µ 1 z 1 + b 12 µ 2 z 1 + c 11 z c 12 z 1 z 2 z 3 + h.o.t., ż 2 = iτ 0 ω 0 z 2 + b 21 µ 1 z 2 + b 22 µ 2 z 2 + c 21 z 2 1z 2 + c 22 z 2 2z 3 + h.o.t., ż 3 = iτ 0 ω 0 z 3 + b 21 µ 1 z 3 + b 22 µ 2 z 3 + c 21 z 2 1z 3 + c 22 z 2 z h.o.t., 11) Nonlinear Anal. Model. Control, 225):

9 606 Y. Cai, C. Zhang where b 11 = 0, b 12 = D 1 τ 0 k 2 2, g 0) 6β)k2 3 + k 2 ) c 11 = D 1 τ 0, 6 c 12 = D 1 τ 0 g 0) 6β ) k2 3 ) + k 2, b 21 = 2D 2 k 2 ω 2 + e iτ0ω0 + 1 ), b 22 = D 2 τ 0 k 2 2e iτ0ω0, [ 1 ) c 21 = D 2 τ 0 k 2 + k 2 2 iω + 3β + g 0) e )], iτ0ω0 2 [ 1 ) c 22 = D 2 τ 0 k 2 + k 2 2 iω + 3β + g 0) e )]. iτ0ω0 2 Through the change of variables z 1 = ω 1, z 2 = ω 2 + iω 3, z 3 = ω 2 iω 3 and then a change to cylindrical coordinates according to ω 1 = ζ, ω 2 = r cos θ, ω 3 = r sin θ, r > 0, system 11) becomes ṙ = Reb 21 )µ 1 r + Reb 22 )µ 2 r + Rec 21 )rζ 2 + Rec 22 )r 3, ζ = b 12 µ 2 ζ + c 11 ζ 3 + c 12 ζr 2, θ = τ 0 ω 0 + µ 1 Imb 21 ) + µ 2 Imb 22 ) + Imc 21 )ζ 2 + Imc 22 )r 2. 12) Let ˆζ = ζ c 11 and ˆr = r Rec 22 ), after dropping the hats, equation 12) can be written as ṙ = r c 1 + Rec 22) Rec 22 ) r2 + Rec 21) ζ ), 2 c 21 c 12 ζ = ζ c 2 + Rec 22 ) r2 + c ) 13) 11 c 11 ζ2, where c 1 = Reb 21 )µ 1 + Reb 22 )µ 2, c 2 = b 12 µ 2. If c 11 < 0 and Rec 22 ) < 0, then 13) becomes ṙ = r c 1 r 2 σζ 2), ζ = ζ c2 δr 2 ζ 2), 14) where σ = Rec 21 )/c 11, δ = c 12 / Rec 22 ). In equation 14), M 0 = r, ζ) = 0, 0) is always an equilibrium, and the other equilibria are M 1 = c 1, 0) for c 1 > 0, M 2 ± = 0, ± c 2 ) for c 2 > 0, ) M 3 ± = σc2 c 1 σδ 1, ± δc1 c 2 for σc 2 c 1 σδ 1 1 σδ > 0, δc 1 c 2 1 σδ > 0.

10 Hopf-pitchfork bifurcation of coupled van der Pol oscillator with delay 607 Table 1. The five unfoldings of system 14) as σ δ. Case I II III IV V σ δ + + σδ Figure 1. Bifurcation diagrams for system 14) with parameter c 1, c 2 ) around 0, 0) see [31].) Figure 2. Phase portraits in D 1 D 7 see [31]). From [21] we obtain that if c 11 < 0 and Rec 22 ) < 0, σ, δ, σ δ, and σδ 1 are five distinct types of unfolding with respect to different signs in system 14), we demonstrate this in [21, Sect ] corresponding to Table 1. From [31] we can obtain Theorem 1. If the assumptions of Lemma 1 are satisfied, σ δ, σδ > 1, and signg 0)) signβ) < 0 hold, then system 2) undergoes a Hopf-pitchfork bifurcation of case I at equilibrium 0, 0, 0, 0), which is shown in Fig. 2, where σ, δ are expressed as 14). Nonlinear Anal. Model. Control, 225):

11 608 Y. Cai, C. Zhang Since system 12) rotates around the Z-axis, the correspondences between two-dimensional flows for 14) and three-dimensional flows 12) can be established. Thus, for 12), the equilibria on the Z-axis in 14) remain equilibria, while the equilibria outside the Z-axis in 14) become periodic orbits. Therefore, if case I occurs, then the detailed dynamics of system 2) in D 1 D 6 near the original parameters 1/k 2, τ 0 ) are as follows: In D 1, 2) has only one trivial equilibrium M 0, which is a sink. In D 2, the trivial equilibrium corresponding to M 0 ) becomes a saddle from a sink, and a stable periodic orbit corresponding to M 1 ) appears. In D 3, the trivial equilibrium corresponding to M 0 ) becomes a source from a saddle, a pair of unstable semitrivial equilibria corresponding to M 2 ± ) appear, and the periodic orbit corresponding to M 1 ) remains stable. In D 4, the semitrivial equilibria corresponding to M 2 ± ) become stable from its unstable state, a pair of unstable periodic orbits corresponding to M 3 ± ) appear, and the periodic orbit corresponding to M 1 ) remains stable. In D 5, the unstable periodic orbit corresponding to M 3 ± ) disappear, the periodic orbit corresponding to M 1 ) becomes unstable, and the semitrivial equilibria corresponding to M 2 ± ) remains stable. In D 6, the periodic orbit corresponding to M 1 ) disappears, the trivial equilibrium corresponding to M 0 ) becomes a saddle from a source, and the semitrivial equilibria corresponding to M 2 ± ) remains stable. Theorem 2. If the assumptions of Lemma 1 are satisfied, σ δ, σδ < 1, and signf 0)) signβ) < 0 hold, then system 2) undergoes a Hopf-pitchfork bifurcation of case II at equilibrium 0, 0, 0, 0), which is shown in Fig. 2, where σ, δ are expressed as 14). Noticing that if case II arises, then the detailed dynamics of system 2) in D1, D2, D3, D5, and D6 are the same as that in case I, except in D7. In D7, system 2) has a pair of stable periodic orbits corresponding to M 3 ± ), a pair of unstable semitrivial equilibria corresponding to M 2 ± ), an unstable periodic orbit corresponding to M 1), and an unstable trivial equilibrium corresponding to M 0 ). By analysing above, we can obtain the bifurcation critical lines as follows: L 1 : τ = Reb ) 22) k 1 1k2 + τ 0 Reb 21 ) corresponding to µ 1 = Reb 22) Reb 21 ) µ 2; L 2 : k 1 = 1 k 2 corresponding to µ 2 = 0;

12 Hopf-pitchfork bifurcation of coupled van der Pol oscillator with delay 609 corresponding to corresponding to L 3 : τ = [ Rec21 )b 12 c 11 Reb 21 ) Reb ) 22) ]k 1 1k2 + τ 0 Reb 21 ) µ 1 = 4 Numerical simulations [ σb12 Reb 21 ) Reb ] 22) µ 2 ; Reb 21 ) L 4 : τ = Rec ) 22)b 12 + c 12 Reb 22 ) k 1 1k2 + τ 0 c 12 Reb 21 ) µ 1 = b 12 + δreb 22 ) µ 2. δreb 21 ) In this section, some examples are given to illustrate the theoretical results. We select α = 1.3 and gt) = tanht) into system 2). From Theorem 1, if k 1 = 1/k 2 = 2 and τ = τ 0 = , then system 2) undergoes a Hopf-pitchfork bifurcation at 0, 0). According to the calculation, we obtain ω = , sin ωτ = , cos ωτ = , D 1 = , D 2 = i, g 0) = 2, b 11 = 0, b 12 = , c 11 = , c 12 = , b 21 = i, b 22 = i, c 21 = i, c 22 = i, Rec 22 ) < 0, c 11 < 0, c 1 = µ µ 2, c 2 = µ 2, σ = > 0, δ = > 0, σδ = > 1. Here, in Fig. 1, bifurcation critical lines are, respectively, L 1 : τ = k 1 2) , i.e. µ 1 = µ 2 ; L 2 : k 1 = 2, i.e. µ 2 = 0; L 3 : τ = k 1 2) , k 1 > 2, i.e. µ 1 = µ 2, µ 2 > 0; L 4 : τ = k 1 2) , k 1 > 2, i.e. µ 1 = µ 2, µ 2 > 0. Through the above analysis, we can obtain Figs Figure 3. The bifurcation set. Nonlinear Anal. Model. Control, 225):

13 610 Y. Cai, C. Zhang Figure 4. The stable trivial equilibrium in D 1 : µ 1, µ 2 ) = 1.87, 1.913), using the red line is 0.1, 0.1, 0.02, 0.5) and the blue line is 0.1, 0.1, 0.02, 0.5). Phase diagram for variable x 1, x 2, x 3 ) in left. Waveform diagram for variable of x 4 in right. Online version in color.) Figure 5. The stable periodic orbit in D 2 : µ 1, µ 2 ) = 0.01, 0.01), the initial value is 0.2, 0.2, 0.2, 0.2). Phase diagram for variable x 1, x 2, x 3 ) in left. Waveform diagram for variable of x 4 in right. Figure 6. The stable periodic orbit in D3: µ 1, µ 2 ) = 0.02, 0.01), the initial value is 0.2, 0.2, 0.2, 0.2). Phase diagram for variable x 1, x 2, x 3 ) in left. Waveform diagram for variable of x 4 in right.

14 Hopf-pitchfork bifurcation of coupled van der Pol oscillator with delay 611 Figure 7. Two stable nontrivial equilibria and a stable periodic orbit coexist in D 4 : µ 1, µ 2 ) = 0.01, 0.05). The red line expresses the initial values of 0.5, 0.5, 0.08, 0.5), the blue line expresses the value of 0.5, 0.5, 0.08, 0.5) and 0.3, 0.3, 0.3, 0.3) for magenta line. Phase diagram for variable x 1, x 2, x 3 ) in left. Waveform diagram for variable of x 4 in right. Online version in color.) 5 Conclusions In this paper, we have investigated the Hopf-pitchfork bifurcation of coupled van der Pol oscillator with delay. Our contributions include the following: 1. By analyzing the distribution of the eigenvalues of the corresponding characteristic equation of its linearized equation, we find the conditions for the occurrence of Hopf-pitchfork bifurcation. 2. By using the normal form method and the center manifold theorem, we have derived the normal form of the reduced system on the center manifold, discussed the Hopf-pitchfork bifurcation with the parameter in system 2), and analyzed the stability. Furthermore, we can obtain the coexistence of periodic orbits. 3. By comparing system 2) in this paper with non-coupled van der Pol system in [20], we obtain the coexistence of a pair of stable nontrivial equilibria and the coexistence of a stable periodic orbit and a pair of stable nontrivial equilibria. We know that the periodic orbit is stable, corresponding to the periodic spiking behavior. Our work is a further study of van der Pol oscillator, which is helpful in the study of the complex phenomenon caused by high co-dimensional bifurcation of delay differential equation. Acknowledgment. The authors would like to express their gratitude for valuable comments on this manuscript from the referees and the editor. References 1. F.M. Atay, Van der Pol s oscillator under delayed feedback, J. Sound Vib., 2182): , Nonlinear Anal. Model. Control, 225):

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