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Limit cycles in a rotated family of generalized Liénard systems allowing for finitely many switching lines

Published online by Cambridge University Press:  21 March 2024

Hebai Chen
Affiliation:
School of Mathematics and Statistics, HNP-LAMA, Central South University, Changsha, Hunan 410083, P. R. China (chen_hebai@csu.edu.cn)
Yilei Tang
Affiliation:
School of Mathematical Sciences, CMA-Shanghai, Shanghai Jiao Tong University, Shanghai 200240, P. R. China (mathtyl@sjtu.edu.cn)
Weinian Zhang
Affiliation:
Department of Mathematics, Sichuan University, Chengdu, Sichuan 610064, P. R. China (wnzhang@scu.edu.cn)
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Abstract

Analytic rotated vector fields have four significant properties: as the rotated parameter $\alpha$ changes, the amplitude of each stable (or unstable) limit cycle varies monotonically, each semi-stable limit cycle bifurcates at most two limit cycles, the isolated homoclinic loop (if exists) disappears while a unique limit cycle with the same stability arises or no closed orbits arise oppositely, and a unique limit cycle arises near the weak focus (if exists). In this paper, we prove that the four properties remain true for a rotated family of generalized Liénard systems having finitely many switching lines. Furthermore, we discuss variational exponent and use it to formulate multiplicity of limit cycles. Then we apply our results to give exact number of limit cycles to a continuous piecewise linear system with three zones and answer to a question on the maximum number of limit cycles in an SD oscillator.

Type
Research Article
Copyright
Copyright © The Author(s), 2024. Published by Cambridge University Press on behalf of The Royal Society of Edinburgh

1. Introduction

Consider a planar differential system

(1.1)\begin{equation} \frac{{\rm d}x}{{\rm d}t}=P(x,y,\alpha ), \qquad \frac{{\rm d}y}{{\rm d}t}=Q(x,y,\alpha),\end{equation}

parameterized by $\alpha \in I$ (an interval of $\mathbb {R}$), and use $(P(x,y,\alpha ),Q(x,y,\alpha ))$ to present its vector field, where functions $P, Q, \partial P/\partial \alpha, \partial Q/\partial \alpha$ are Lipschitzian in $D\times I$ and $D\subset \mathbb {R}^2$ is a connected open set. The vector field $(P(x,y,\alpha ),Q(x,y,\alpha ))$ is called a complete family of rotated vector fields with a rotated parameter $\alpha$ if the following conditions hold:

  1. (D1) Equilibria fixed: The number and location of equilibria are fixed as $\alpha$ varies.

  2. (D2) Direction fixed: $(P(x,y,\alpha ), Q(x,y,\alpha ))$ rotates counter-clockwise at any regular point $(x,y)$ as the rotated parameter $\alpha$ increases.

  3. (D3) Symmetrically periodic: $P,Q$ are periodic functions in $\alpha$ with minimum period $2\pi$, and $(P(x,y,\alpha +\pi ), Q(x,y,\alpha +\pi ))=-(P(x,y,\alpha ), ~Q(x,y,\alpha ))$.

This concept, originated by Duff ([Reference Duff8]) in 1953, was proved to have the following properties: (DR1) the limit cycles $L(\alpha _1)$ and $L(\alpha _2)$ of the vector fields with different $\alpha _1$ and $\alpha _2$ respectively in the family do not intersect each other; (DR2) every simple limit cycle expands or contracts monotonically as $\alpha$ varies monotonically; (DR3) every semi-stable limit cycle splits into a stable cycle and an unstable one when $\alpha$ increases or decreases, but disappears when $\alpha$ varies in the opposite direction; (DR4) the outer boundary and the inner one of the annulus $\mathcal {R}$ covered by all limit cycles $L(\alpha )$, $\alpha \in I$, i.e., $\mathcal {R}:=\{(x,y)\in \mathbb {R}^2: (x,y)\in L(\alpha ), \alpha \in I\}$, surround an equilibrium each. These properties attracted great attentions (see e.g. [Reference Cândido, Llibre and Valls3, Reference Dumortier and Li9, Reference Dumortier and Rousseau12, Reference Perko21, Reference Perko22, Reference Perko24, Reference Perko25, Reference Ye28Reference Zhang, Ding, Huang and Dong30]) to rotated vector fields because they can be used to discuss the non-existence and the uniqueness of limit cycles as well as bifurcations of heteroclinic loops.

Perko ([Reference Perko20, Reference Perko23]) weakened Duff's complete version to an uncomplete one, not requiring the symmetric periodicity but allowing the vector field not to rotate on an analytic curve $\Omega (x,y)=0$ not having a branch congruent to a limit cycle of (1.1). He called $(P(x,y,\alpha ), Q(x,y,\alpha ))$ a family of rotated vector fields (mod $\Omega =0$) with the rotated parameter $\alpha$ if the following conditions hold:

  1. (P1) Equilibria fixed: the same as (D1).

  2. (P2) Direction fixed: $(P(x,y,\alpha ), Q(x,y,\alpha ))$ rotates counter-clockwise at any regular point $(x,y)$ as the rotated parameter $\alpha$ increases except on the curve $\Omega (x,y)=0$.

Assuming that the family of rotated vector fields is analytic in $(x,y,\alpha )$, he proved in [Reference Perko23, Reference Perko26] the following results:

  • (PR1) If the rotated vector field with $\alpha =\alpha _0$ exhibits a limit cycle $\Gamma _0$ of odd multiplicity then the cycle remains for $\alpha :=\alpha _0+\varepsilon$ with small enough $|\varepsilon |$ and expands or contracts monotonically as $\varepsilon$ increases (see [Reference Perko26, Theorem 1 of Section 6 of Chapter IV]).

  • (PR2) If the rotated vector field with $\alpha =\alpha _0$ exhibits a limit cycle $\Gamma _0$ of even multiplicity then, as the parameter $\alpha$ increases or decreases, $\Gamma _0$ splits into two simple limit cycles $\Gamma _\alpha ^-$ and $\Gamma _\alpha ^+$, where the inner one $\Gamma _\alpha ^-$ contracts and the outer one $\Gamma _\alpha ^+$ expands, but disappears as $\alpha$ varies oppositely (see [Reference Perko26, Theorem 2 of Section 6 of Chapter IV]).

  • (PR3) If the origin $O$ of the rotated vector field with $\alpha =\alpha _0$ is a weak focus then a unique limit cycle occurs in a small neighbourhood of $O$ as $\alpha$ varies from $\alpha _0$ with the change of stability at $O$ (see [Reference Perko26, Theorem 5 of Section 6 of Chapter IV]) and, moreover, the limit cycle is of the same stability as the weak focus at the origin when $\alpha =\alpha _0$.

  • (PR4) If the rotated vector field with $\alpha =\alpha _0$ has an isolated homoclinic loop $\Gamma _*$ then, as the parameter $\alpha$ increases or decreases, the loop disappears while a unique limit cycle $\Gamma _\alpha$ with the same stability arises near $\Gamma _*$, but no closed orbits arise as $\alpha$ varies oppositely (see [Reference Perko26, Theorem 3 of Section 6 of Chapter IV]).

However, the above properties (PR1)(PR4) may not be true if the rotated vector field is not analytic. The two examples of piecewise-defined families given in § 2, which are smooth but not analytic and satisfy the rotated conditions, show that a limit cycle of odd multiplicity may produce new limit cycles and a limit cycle of even multiplicity may produce more than two limit cycles, which do not match (PR1) and (PR2) separately.

In this paper, we investigate rotated vector fields of piecewise analytic generalized Liénard form and see which one of results (PR1)(PR4) remains true. For this purpose, we consider the family of generalized Liénard equations

(1.2)\begin{equation} \ddot x+f(x,\dot x, \alpha )\dot x+g(x )=0\end{equation}

with non-analytic functions $f$ and $g$ in $x$ or $\dot {x}$ such that its corresponding planar vector field is rotated with the parameter $\alpha \in I$. In § 2 we give our main results on the relation between variational exponent and multiplicity of hyperbolic limit cycles (which was not obtained for analytic rotated vector fields), non-hyperbolic limit cycles and semi-stable limit cycles of the vector field of (1.2) as $\alpha$ varies and answer to the questions:

  • (Q1) Can we find conditions such that the aforementioned results (PR1)(PR4) still hold?

  • (Q2) Can we give an expanding (or contracting) rate for limit cycles in terms of the rotated parameter $\alpha$?

  • (Q3) Can we use the rotated rule to determine the number of bifurcated limit cycles for a class of non-analytic systems?

In § 3 we further investigate the number of limit cycles bifurcated from a weak focus or a homoclinic loop in rotated vector fields. In § 4 and 5 we apply our main results obtained in § 2 to an SD oscillator and a continuous piecewise linear differential system with three zones and asymmetry for the number of limit cycles, respectively.

2. Main results

Let us begin this section from the family

(2.1)\begin{equation} \begin{aligned} \frac{{\rm d}x}{{\rm d}t}=\tilde X_n(x,y,\alpha):=X_n(x,y)\cos\alpha-Y_n(x,y)\sin\alpha, \\ \frac{{\rm d}y}{{\rm d}t}=\tilde Y_n(x,y,\alpha):=X_n(x,y)\sin\alpha+Y_n(x,y)\cos\alpha \end{aligned} \end{equation}

with the functions

(2.2)\begin{equation} \begin{aligned} X_n(x,y) & := \left\{ \begin{array}{ll} -y+x\tan\left((r-r_0)^{2n+1}\Bigg(\sin\dfrac{1}{r-r_0}+2\Bigg)\right), & ~{\rm as}~r\ne r_0, \\ - y, & ~{\rm as}~r=r_0, \end{array}\right. \\ Y_n(x,y) & := \left\{ \begin{array}{ll} x+y\tan\left((r-r_0)^{2n+1}\Bigg(\sin\dfrac{1}{r-r_0}+2\Bigg)\right), \quad & ~{\rm as}~r\ne r_0, \\ x , & ~{\rm as}~r=r_0, \end{array}\right. \end{aligned} \end{equation}

or

(2.3)\begin{equation} \begin{aligned} X_n(x,y) & := \left\{ \begin{array}{ll} -y+x\tan\left((r-r_0)^{2n}\Bigg(\sin\dfrac{1}{r-r_0}+2\Bigg)\right), & ~{\rm as}~r\ne r_0, \\ - y, & ~{\rm as}~r=r_0, \end{array}\right. \\ Y_n(x,y) & := \left\{ \begin{array}{ll} x+y\tan\left((r-r_0)^{2n}\Bigg(\sin\dfrac{1}{r-r_0}+2\Bigg)\right), \quad & ~{\rm as}~r\ne r_0, \\ x , & ~{\rm as}~r=r_0, \end{array}\right. \end{aligned} \end{equation}

where $r:=\sqrt {x^2+y^2}$ is near $r_0>0$ and $n$ is a positive integer. Note that system (2.1) with (2.2) (resp. (2.3)) is continuous and even $\mathcal {C}^{n}$ (resp. $\mathcal {C}^{n-1}$) but not analytic because its derivative is $\mathcal {C}^{n-1}$ (resp. $\mathcal {C}^{n-2}$) by an inductive proof from $n=1$.

We first consider family (2.1) with (2.2), which is a Duff's complete family of rotated vector fields with the rotated parameter $\alpha \in [-\pi, \pi )$ and therefore a Perko's family because

(2.4)\begin{equation} (\tilde X_n(x,y,\alpha+\pi),\tilde Y_n(x,y,\alpha+\pi))={-}(\tilde X_n(x,y,\alpha),\tilde Y_n(x,y,\alpha))\end{equation}

and

(2.5)\begin{equation} {\rm det} \left( \begin{array}{cc} \tilde X_n(x,y,\alpha) & \tilde Y_n(x,y,\alpha) \\ \dfrac{\partial \tilde X_n(x,y,\alpha)}{\partial \alpha} & \dfrac{\partial \tilde Y_n(x,y,\alpha)}{\partial \alpha} \\ \end{array} \right) = \big( \tilde X_n(x,y,\alpha)\big)^2+\big(\tilde Y_n(x,y,\alpha)\big)^2>0 \end{equation}

at each regular point. For $\alpha =0$, $\tilde X_n(x,y,0)=X_n(x,y)$ and $\tilde Y_n(x,y,0)=Y_n(x,y)$. Then system (2.1) with (2.2) as $\alpha =0$, denoted by (E1), has a unique limit cycle $r=r_0$, which is of multiplicity $2n+1$, because the function $V(x,y):=x^2+y^2$ satisfies

\begin{align*} \frac{{\rm d}V}{{\rm d}t}|_{\bf (E1)}= 2r\frac{{\rm d}r}{{\rm d}t}|_{\bf (E1)} = \left\{\begin{array}{ll} 2(x^2+y^2)\tan\\ \quad \left((r-r_0)^{2n+1}\Bigg(\sin\dfrac{1}{r-r_0}+2\Bigg)\right)>0, & ~{\rm as}~r> r_0, \\ 0, & ~{\rm as}~r=r_0, \\ 2(x^2+y^2)\tan\\ \quad \left((r-r_0)^{2n+1}\Bigg(\sin\dfrac{1}{r-r_0}+2\Bigg)\right)<0, & ~{\rm as}~r< r_0 \end{array}\right. \end{align*}

for $r$ near $r_0$. On the other hand, for arbitrary $m\in \mathbb {Z}_+$ there exist $\alpha >0$ and three values $r_1=r_0+2/(5\pi +4m\pi )$, $r_2=r_0+2/(\pi +4m\pi )$ and $r_3=r_0+2/(-\pi +4m\pi )$ such that $3(r_1-r_0)^{2n+1}<\alpha <3(r_2-r_0)^{2n+1}<3(r_3-r_0)^{2n+1}$ and $r_1< r_2< r_3$. Thus, it is not difficult to check that

\begin{align*} \frac{{\rm d}r}{{\rm d}t} & = \left\{ r\cos\alpha\left\{\tan\left((r-r_0)^{2n+1}\Bigg(\sin\dfrac{1}{r-r_0}+2\Bigg)\right)-\tan\alpha \right\}, \quad ~{\rm as}~r\ne r_0, \right. \\ & \left. \quad - r\sin\alpha,\quad ~{\rm as}~r=r_0 \right. \end{align*}

and

\[ \frac{{\rm d}r}{{\rm d}t} \left\{ \begin{array}{@{}ll} <0, & ~{\rm as}~r\leq r_0, \\ < 0, & ~{\rm as}~r=r_1, \\ > 0, & ~{\rm as}~r=r_2, \\ < 0, & ~{\rm as}~r=r_3. \end{array}\right. \]

By the mean value theorem, ${\rm d}r/{\rm d}t$ has two zeros, one lies in $(r_1, r_2)$ and the other lies in $(r_2, r_3)$, which implies that system (2.1) has at least two limit cycles in a small neighbourhood of $r=r_0$ if the positive integer $m$ is large enough, a result different from (PR1). This implies that for an arbitrary $\varepsilon$-neighbourhood of the circle $r=r_0$ there exists a number $N\in \mathbb {Z}_+$ such that the circle $r=r_i$ for $i=1,2,3$ lies in the $\varepsilon$-neighbourhood of $r=r_0$ if $m>N$.

Family (2.1) with (2.3) is also a Duff's complete family of rotated vector fields with the rotated parameter $\alpha \in [-\pi, \pi )$ and therefore a Perko's family because (2.4) and (2.5) hold for this system at each regular point. Then system (2.1) with (2.3) as $\alpha =0$, denoted by (E2), has a unique limit cycle $r=r_0$, which is of multiplicity $2n$ and semi-stable, because

\[ \frac{{\rm d}V}{{\rm d}t}|_{\bf (E2)}= 2r\frac{{\rm d}r}{{\rm d}t}|_{\bf (E2)}= \left\{\begin{array}{@{}ll} 2(x^2+y^2)\tan\\ \quad \left((r-r_0)^{2n}\Bigg(\sin\dfrac{1}{r-r_0}+2\Bigg)\right)>0, & ~{\rm as}~r> r_0, \\ 0, & ~{\rm as}~r=r_0, \\ 2(x^2+y^2)\tan\\ \quad \left((r-r_0)^{2n}\Bigg(\sin\dfrac{1}{r-r_0}+2\Bigg)\right)>0, & ~{\rm as}~r< r_0 \end{array}\right. \]

for $r$ near $r_0$. On the other hand, for $\alpha \neq 0$ we have

\[ \frac{{\rm d}r}{{\rm d}t}= \left\{ \begin{array}{@{}ll} r\cos\alpha\left(\tan\left((r-r_0)^{2n}\Bigg(\sin\dfrac{1}{r-r_0}+2\Bigg)\right)-\tan\alpha\right), & ~{\rm as}~r\ne r_0, \\ - r\sin\alpha, & ~{\rm as}~r=r_0. \end{array}\right. \]

Since ${\rm d}r/{\rm d}t>0$, there is no limit cycle as $\alpha <0$. For $\alpha =\varepsilon >0$ is small, we can obtain two limit cycles by a similar discussion as for system (2.1) with (2.2) in both cases $r>r_0$ and $r< r_0$ near $r=r_0$ respectively, which implies that system (2.1) with (2.3) has at least four limit cycles in a small neighbourhood of $r=r_0$, a result different from (PR2).

The above two examples show that the properties (PR1) and (PR2) do not always hold for some non-analytic rotated vector fields, which suggest considering some non-analytic rotated vector fields for those properties (PR1)(PR4). In this paper, we discuss the generalized Liénard equation (1.2), which is equivalent to the following planar system

(2.6)\begin{equation} \begin{aligned} & \dot x=y=:X(x,y,\alpha), \\ & \dot y={-}g(x )-f(x,y,\alpha )y=:Y(x,y,\alpha), \end{aligned} \end{equation}

where $(x,y)\in D$, a connected open set in $\mathbb {R}^2$. The system defines the corresponding vector field $\mathcal {L}_\alpha :=(y, -g(x )-f(x,y,\alpha )y)$.

Let $a_1$(resp. $a_2$) denote the minimum (resp. maximum) for abscissas of points in $D$, which may be $-\infty$ (resp. $+\infty$). We need the following hypotheses:

  1. (H 1) Piecewise analytic : The function $g(x)$ is piecewise analytic on $(a_1,x_1)\cup (x_1,x_2)\cup (x_2,x_3)\cup \ldots \cup (x_n,a_2)$, and functions $f(x,y,\alpha )$, $\partial f(x,y,\alpha )/\partial y$ are piecewise analytic on $D_1\cup D_2\cup \ldots \cup D_{n+1}$, where $D_1=\{(x,y)\in D: a_1< x< x_1\}$, $D_i=\{(x,y)\in D: x_{i-1}< x< x_{i} \}$ for $i=2,\ldots,n$ and $D_{n+1}=\{(x,y)\in D: x_n< x< a_2\}$.

  2. (H 2) ($H_2$) Rotated

    (2.7)\begin{equation} \frac{\partial f(x,y, \alpha )}{\partial \alpha}\geq0~({\rm or}~\leq0) \end{equation}
    in $D$ and the equality in (2.7) does not hold on an entire closed orbit of (2.6).

Note that $D= D_1\cup \bar D_2\cup \ldots \cup \bar D_n \cup D_{n+1}$, where $\bar D_i$ denotes the closure of $D_i$. Without loss of generality, in this paper we only consider the case ‘$\geq$’ in (2.7). Otherwise, we can make the transformation $(y,t)\to (-y,-t)$. Inequality (2.7) is not very restrictive because, for example, one can easily check that the function $f(x,y,\alpha ):= \alpha x^{2m}y^{2n}+\hat f(x,y)$ with non-negative integers $m,n$ and a piecewise analytic function $\hat f(x,y)$ satisfies $\frac {\partial f(x,y, \alpha )}{\partial \alpha }= x^{2m}y^{2n}\geq 0$, i.e. inequality (2.7). The following proposition indicates that the generalized Liénard system (2.6) is rotated if inequality (2.7) is satisfied.

Proposition 2.1 $\mathcal {L}_\alpha$ with the hypotheses ($H_1$) and ($H_2$) satisfies conditions (P1) and (P2) in Perko's definition.

Proof. One can check that (P1) is true because all equilibria lie at the $x$-axis and the abscissas of all equilibria are the roots of $g(x)=0$ which are independent of $\alpha$. In order to check (P2), let $\theta$ denote the angle from the $x$-axis to the vector $(X(x,y,\alpha ),Y(x,y,\alpha ))$ of system (1.1) in counter-clockwise direction. Then

\[ \frac{\partial \theta}{\partial\alpha}=\frac{\partial}{\partial\alpha}(\arctan({Y}/{X})) =\frac{1}{X^2+Y^2} \left| \begin{array}{cc} X & Y \\ \dfrac{\partial X}{\partial\alpha} & \dfrac{\partial Y}{\partial\alpha} \\ \end{array} \right|. \]

For $\mathcal {L}_\alpha$, we have $X(x,y,\alpha )=y$ and $Y(x,y,\alpha )=-g(x)-f(x,y,\alpha )y$. Then, it implies that the vector $(X(x,y,\alpha ), Y(x,y,\alpha ))$ rotates counter-clockwise at a regular point $P_0(x,y)$ as $\alpha$ varies since

\[ \left| \begin{array}{cc} X(x,y,\alpha) & Y(x,y,\alpha) \\ \dfrac{\partial X}{\partial\alpha}(x,y,\alpha) & \dfrac{\partial Y}{\partial\alpha}(x,y,\alpha) \\ \end{array} \right| = \left| \begin{array}{cc} y & -g(x)-f(x,y,\alpha)y \\ 0 & -\dfrac{\partial f(x,y, \alpha )}{\partial \alpha}y \\ \end{array} \right|={-}\frac{\partial f(x,y, \alpha )}{\partial \alpha}y^2<0 \]

at the regular point $P_0(x,y)$ for all $\alpha \in I$ except in the curves $\Omega (x,y):=\frac {\partial f(x,y, \alpha )}{\partial \alpha }y^2=0$. Thus, condition (P2) holds.

As indicated in the theory of non-analytic dynamical systems ([Reference di Bernardo, Budd, Champneys and Kowalczyk1, Reference Kunze15]), limit cycles of piecewise analytic vector field $\mathcal {L}_\alpha$ are referred to the three types: crossing limit cycle (limit cycle intersecting a switching manifold transversely and only containing isolated crossing points of the switching manifold), grazing limit cycle (limit cycle tangent to a switching manifold) and sliding limit cycle (a curve segment of the limit cycle lies on a switching manifold). System (2.6) has no sliding limit cycles because only one point $\{(x_i, 0)\}$ lies in the sliding set of each switching line $x=x_i$. Thus, we only discuss crossing limit cycles and grazing limit cycles.

The first equation of (2.6) shows that the $x$-axis is a unique vertical isocline of the vector field $\mathcal {L}_\alpha$. Then each limit cycle $\Gamma _\alpha$ of system (2.6) has exactly two intersection points with the $x$-axis, denoted by $Q_0:(x_l,0)$ and $P_0:(x_r,0)$ with $x_l< x_r$. Without loss of generality, in what follows we assume that $\Gamma _\alpha$ is a crossing limit cycle; otherwise, we can research similarly because any small vicinity of the grazing limit cycle $\Gamma _\alpha$ (where $\Gamma _\alpha$ is not included) only possibly contains the crossing points (see the definition in [Reference di Bernardo, Budd, Champneys and Kowalczyk1, Reference Kuznetsov, Rinaldi and Gragnani16]) of the switching line $x=x_i$ for $i=1,\ldots,n$. Since any small neighbourhood of the crossing limit cycle $\Gamma _\alpha$ only possibly contains the crossing points of the included switching lines, the solution of system (2.6) is Lipschitzian ([Reference di Bernardo, Budd, Champneys, Kowalczyk, Nordmark, Tost and Piiroinen2]). Then, the well-known existence and uniqueness theorem and the continuous dependence theorem of solutions remain true for system (2.6) in the small neighbourhood of $\Gamma _\alpha$. Obviously, the $x$-axis is the normal of $\Gamma _\alpha$ at $P_0$ and $Q_0$. In this sense, we call the right-hand intersection point $P_0:(x_r(\alpha ),0)$ the right-endpoint of the limit cycle $\Gamma _\alpha$ and regard $x_r$, denoted by $x_r(\alpha )$ for the dependence on the rotated parameter $\alpha$, as the $x$-radius of the cycle. By a translation, we can assume that $x_r(\alpha )=0$ without loss of generality. Thus, $g(0 )>0$ and $g(x_l )<0$. Consider variation $\varepsilon$ of $\alpha$ and suppose that the vector field $\mathcal {L}_{\alpha +\varepsilon }$ has a limit cycle $\Gamma _{\alpha +\varepsilon }$ with right-endpoint $\tilde {P}_0:(\tilde {x}_r(\alpha +\varepsilon ),0)$. Then the difference between $x$-radii $\tilde {x}_r(\alpha +\varepsilon )$ and $x_r(\alpha )$ depends on $\varepsilon$, i.e. the function

\[ \Delta_\alpha(\varepsilon):=\tilde{x}_r(\alpha+\varepsilon) - x_r(\alpha) \]

has the same smoothness as $x_r(\alpha )$ or $\tilde {x}_r(\alpha )$. By the continuity, $\Delta _\alpha (\varepsilon )\to 0$ as $\varepsilon \to 0$. In the following theorem 2.3, we prove that

(2.8)\begin{equation} \Delta_\alpha(\varepsilon)=\zeta \varepsilon^\ell + o(\varepsilon^\ell) \mbox{ as } \varepsilon\to 0+\end{equation}

for a certain $\ell \in \mathbb {R}^+$. Clearly, the amplitude of the limit cycle $\Gamma _\alpha$ expands outwards if $\zeta >0$ or inwards (or say contracts) if $\zeta <0$ with the variational exponent $\ell$.

On the other hand, we also consider those spiral orbits near limit cycles. Let $P$ denote $(x_0,0)$, where $|x_0|<\delta$ and $\delta >0$ is small. By the continuous dependence theorem, the orbit $\varphi (P, I^+)$ starting from $P$ intersects the $x$-axis again for the first time at a point $P_1=(x_1,0)$, as shown in figure 1. Here, without loss of generality, we only show the case of the external neighbourhood of $\Gamma$ in figure 1. Thus, we can define the map $\mathcal {P}:P\mapsto P_1$ (or $x_0\mapsto x_1$ equivalently) on the $x$-axis, called a Poincaré map, and the successive function $\varrho$ between $P$ and $\mathcal {P}(P)$, i.e.

(2.9)\begin{equation} \varrho(x_0):=x_1-x_0. \end{equation}

As indicated in Definition 2 of [Reference Perko26, p.216] or Section 2 of [Reference Zhang, Ding, Huang and Dong30, Chapter 4], $\Gamma _\alpha$ is externally stable (resp. unstable) when there is a sufficiently small $\delta >0$ such that $\varrho (x)<0$ (resp. $>0$) for all $x\in (0,\delta )$. Similarly, $\Gamma _\alpha$ is internally stable (resp. unstable) if $\varrho (x)>0$ (resp. $<0$) for all $x\in (-\delta,0)$. $\Gamma _\alpha$ is stable (resp. unstable) if it is both externally stable (resp. unstable) and internally stable (resp. unstable). Naturally, we have $\varrho (0)=0$ and $\varrho (x)=x^kh(x)$, where $k>0$ is a real number and $h$ is a continuous function such that $h(0)\neq 0$. $\Gamma _\alpha$ is called a limit cycle of multiplicity $k$ (which may not be an integer) if

(2.10)\begin{equation} \varrho(x_0)=c_k x_0^k+o(|x_0|^k), ~~~ c_k\ne 0. \end{equation}

In particular, if system (2.6) is smooth then $k\in \mathbb {Z}_+$ and condition (2.10) is equivalent to the following $\varrho (0)=\varrho '(0)=\cdots =\varrho ^{(k-1)}(0)=0~{\rm and}~\varrho ^{(k)}(0)\neq 0$ by [Reference Zhang, Ding, Huang and Dong30, Chapter 4.2, Definition 2.1]. Then, $\Gamma _\alpha$ is called a simple or hyperbolic limit cycle for $k=1$; for odd $k$, $\Gamma _\alpha$ is stable (resp. unstable) if $\varrho ^{(k)}(0)<0$ or $c_k<0$ (resp. $\varrho ^{(k)}(0)>0$ or $c_k>0$); for even $k$, $\Gamma _\alpha$ is semi-stable. The multiplicity $k$ is an integer if the system is smooth (see Theorem 7.19 in [Reference Dumortier, Llibre and Artés11, p.196]), but may not be integer for piecewise analytic systems. For example, the following system

\[ \frac{{\rm d}x}{{\rm d}t}=y-x(x^2+y^2-1)^{p/q},\qquad \frac{{\rm d}y}{{\rm d}t}={-}x-y(x^2+y^2-1)^{p/q} \]

with an integer $p$ and an odd number $q$ has the limit cycle $x^2+y^2=1$, which is of multiplicity $p/q$ because one can reduce the system to the equation $\frac {{\rm d}r}{{\rm d}t}=-r(r^2-1)^{p/q},$ where $r=\sqrt {x^2+y^2}$. For simplicity, let $p/q=5/3$. Then, for an initial value $(r,\theta )=(1+\varepsilon,0)$ with arbitrarily small $|\varepsilon |$, near the cycle $r=1$ we can use the method of indeterminate coefficients to give the successive function

\[ \varrho(\varepsilon)= c_k\varepsilon^{k} +o (|\varepsilon|^{k})=\varepsilon^{k} (c_k+o(1)), \]

where $k=5/3$ and $c_k=- 2^{8/3}\pi$.

Figure 1. The orbits close to limit cycle $\Gamma$ for $\varepsilon >0$.

Unlike (2.10), $\Gamma _{\alpha }$ is called an externally (or internally) compound limit cycle (see [Reference Zhang, Ding, Huang and Dong30, Chapter 4.2]) if for arbitrarily given small $\delta >0$ there are two points $x_0,\tilde x_0\in (0,\delta )$ (or $\in (-\delta,0)$) such that

\[ \mathcal{P}(x_0)=x_0 \ {\rm and} \ \mathcal{P}(\tilde x_0)\ne \tilde x_0, \]

i.e. near a side of $\Gamma _{\alpha }$ there is not a periodic annulus but there is a sequence of periodic solutions approaching the cycle $\Gamma _{\alpha }$. Although any analytic system does not have a compound limit cycle ([Reference Zhang, Ding, Huang and Dong30, Theorem 2.1 of Chapter 4]), a piecewise analytic Liénard system may have. For example, consider system (2.6) with $g(x)=x$ and

(2.11)\begin{align} f(x,y)= \left\{ \begin{array}{@{}ll} (x^2+y^2-1)^k\sin\dfrac{2\pi}{x^2+y^2-1}, & ~{\rm as}~x^2+y^2\ne 1, \\ 0, & ~{\rm as}~x^2+y^2=1, \end{array}\right. \end{align}

where $k$ is a positive integer. In the polar coordinates $(x,y)=(r\cos \theta, r\sin \theta ),$ we obtain

\begin{align*} \frac{{\rm d}r}{{\rm d}t} & ={-} r\sin^2\theta f(r\cos\theta, r\sin\theta) \\ & = \left\{ \begin{array}{@{}ll} -r \sin^2\theta(r^2-1)^k\sin\dfrac{2\pi}{r^2-1}, & ~{\rm as}~r \ne 1, \\ 0, & ~{\rm as}~r =1. \end{array}\right. \end{align*}

It implies that system (2.6) with $g(x)=x$ and $f(x)$ exhibited in (2.11) has a compound limit cycle $x^2+y^2=1$ because it has closed orbits $x^2+y^2=1\pm 2/n$ for all integers $n\geq 3$, but for each $n\ge 3$ in the annular regions $\sqrt {1+2/(n+1)}< r<\sqrt {1+2/n}$ and $\sqrt {1-2/n}< r<\sqrt {1-2/(n+1)}$ system (2.6) with $g(x)=x$ and $f(x)$ exhibited in (2.11) has no closed orbits. Otherwise, integrating along a closed orbit $\gamma$ (if exists in one of the annular region), we obtain a contradiction

\begin{align*} 0= \oint_{\gamma} {\rm d}r & = r(2\pi)-r(0) =\int_0^{2\pi}\frac{{\rm d}r}{{\rm d}\theta}{\rm d}\theta \\ & = \int_0^{2\pi}\frac{r \sin^2\theta(r^2-1)^k\sin\frac{2\pi}{r^2-1}}{1+ \sin\theta\cos\theta (r^2-1)^k\sin\frac{2\pi}{r^2-1}}{\rm d}\theta\neq0 \end{align*}

because $\sin \frac {2\pi }{r^2-1}\ne 0$ and $1+\sin \theta \cos \theta (r^2-1)^k\sin \frac {2\pi }{r^2-1}>0$.

The above two examples show that compound limit cycle and limit cycle of fractional multiplicity are both possible for piecewise analytic systems, but neither of them happens in a Liénard system (2.6) with the specific piecewise analyticity ($H_1$).

Lemma 2.2 Any limit cycle of the generalized Liénard system (2.6) with hypothesis ($H_1$) is neither compound nor of fractional multiplicity.

Proof. Assume that system (2.6) with hypothesis ($H_1$) has a limit cycle $\Gamma$, as shown in figure 2. For compound structure and fractional multiplicity, we need to consider a small annulus surrounding $\Gamma$. Since the function $g$ is piecewise analytic on $(a_1,x_1)\cup (x_1,x_2)\cup (x_2,x_3)\cup \ldots \cup (x_n,a_2)$, and functions $f(x,y,\alpha )$, $\partial f(x,y,\alpha )/\partial y$ are piecewise analytic on $D_1\cup D_2\cup \ldots \cup D_{n+1}$, there is a small $\varepsilon >0$ such that each normal at any $P\in \Gamma$ restricted to the open annular neighbourhood $S(\Gamma,\varepsilon )$ of $\Gamma$ with the radius $\varepsilon$ is non-contact. Thus, we can set up curvilinear coordinates in the annulus $S(\Gamma,\varepsilon )$. Each point $\underline {P}$ in $S(\Gamma,\varepsilon )$ has a corresponding point $P\in \Gamma$ such that $\underline {P}$ lies on the normal at $P$.

Figure 2. The curvilinear coordinates in the annulus $S(\Gamma,\varepsilon )$.

Note that a point on limit cycle $\Gamma$ can be written as

\[ (x,y)=(\varphi(s), \psi(s)), \]

where $s$ is the arclength (parameter) from $P$ to a specified point in the clockwise direction. Let $p$ be the length from $P$ to $\underline {P}$ positively in the outward direction. Thus, as shown in [Reference Zhang, Ding, Huang and Dong30, Chapter 4.2], we can represent the point $\underline {P}: (x,y)$ in the curvilinear coordinates $s$ and $p$ in each region $D_j$ ($j=1,2,\ldots,n+1$) as

\[ x=\varphi(s)-p\psi'(s), \quad y=\psi(s)+p\varphi'(s), \]

where

\begin{align*} & \varphi'(s)=\frac{{\rm d}x}{{\rm d}s}=\frac{X_0}{\sqrt{{X_0}^2+{Y_0}^2}}, \quad \psi'(s)=\frac{{\rm d}y}{{\rm d}s}=\frac{Y_0}{\sqrt{{X_0}^2+{Y_0}^2}}, \\ & X_0=X(\varphi(s),\psi(s),\alpha), \quad Y_0=Y(\varphi(s),\psi(s),\alpha). \end{align*}

Therefore, we have

\[ \frac{{\rm d}y}{{\rm d}x}=\frac{\psi'(s)+\frac{dp}{{\rm d}s}\varphi'(s)+p\varphi''(s)}{\varphi'(s)-\frac{dp}{{\rm d}s}\psi'(s)-p\psi''(s)}= \frac{Y(\varphi(s)-p\psi'(s),\psi(s)+p\varphi'(s),\alpha)}{X(\varphi(s)-p\psi'(s),\psi(s)+p\varphi'(s),\alpha)}, \]

implying that

(2.12)\begin{equation} \frac{dp}{{\rm d}s}=\frac{Y\varphi'-X\psi'-p(X\varphi''+Y\psi''(s))}{X\varphi'+Y\psi'}=F(s,p,\alpha),\end{equation}

where

\begin{align*} & \varphi''(s)=\frac{-Y_0}{\sqrt{{X_0}^2+{Y_0}^2}}\left({X_0}^2\frac{\partial Y}{\partial x}|_{p=0}+X_0Y_0\left(\frac{\partial Y}{\partial y}|_{p=0}-\frac{\partial X}{\partial x}|_{p=0}\right)-{Y_0}^2\frac{\partial X}{\partial y}|_{p=0}\right)\!, \\ & \psi''(s)=\frac{X_0}{\sqrt{{X_0}^2+{Y_0}^2}}\left({X_0}^2\frac{\partial Y}{\partial x}|_{p=0}+X_0Y_0 \left(\frac{\partial Y}{\partial y}|_{p=0}-\frac{\partial X}{\partial x}|_{p=0}\right)-{Y_0}^2\frac{\partial X}{\partial y}|_{p=0}\right)\!. \end{align*}

Having the above curvilinear coordinates, we first consider the case that $\Gamma$ does not intersect any switching line. Let $P_0:(0,p_0) \in \overline {P\underline {P}}$ and $p_0$ be the length from $P$ to $P_0$ positively in the outward direction, as shown in figure 2. It follows from (2.12) that the Poincaré map $\mathcal {P}$ satisfies

\[ \mathcal{P}(p_0)=p(l,p_0)=p_0+\int_0^lF(s,p(s,p_0),\alpha){\rm d}s, \]

where $l$ is the total arc length of $\Gamma$.

Second, consider the case that $\Gamma$ intersects only one switching line $x=x_j$. It is clear that $\Gamma$ is divided by $x=x_j$ into two parts: left part and right part. Consider $P_0:(0,p_0)$ to be the initial point of the Poincaré map on $x=x_j$, and let $(l_1,p_1)$ (resp. $(l_2,p_2)$) denote the first intersection point of the positive-(resp. negative-) half orbit with $x=x_j$. Without loss of generality, we can assume that the segment $\overline {PP_0}$ on the switching line $x=x_j$ is vertical to $\Gamma$. Otherwise, a rotation can achieve this because the switching line $x=x_j$ is transversal to $\Gamma$. Then, we can obtain the two half Poincaré maps

\[ \mathcal{P}_1(p_0)=p_1(l,p_0)=p_0+\int_0^{l_1}F(s,p(s,p_0),\alpha){\rm d}s \]

and

\[ \mathcal{P}_2(p_0)=p_2(l,p_0)=p_0-\int_{l_1}^lF(s,p(s,p_0),\alpha){\rm d}s, \]

as shown in figure 3. Notice that the denominator of the right-hand side of (2.12) does not equal zero since $X^2(\varphi (s),\phi (s),\alpha )+Y^2(\varphi (s),\phi (s),\alpha )\neq 0$. Moreover, the vector field of system (2.6) is analytic for $x< x_j$ and $x>x_j$ in $S(\Gamma,\varepsilon )$. Therefore,

\[ p_1(l,p_0)=p_0+\sum_{i=1}^{\infty}a_i{p_0}^i \text{ and } p_2(l,p_0)=p_0+\sum_{i=1}^{\infty}b_i{p_0}^i. \]

Thus, we obtain the following successive function

(2.13)\begin{equation} \varrho(p_0)= \mathcal{P}_1(p_0)- \mathcal{P}_2(p_0)=\sum_{i=1}^{\infty}(a_i-b_i){p_0}^i. \end{equation}

The coefficients $a_i-b_i$ in the above series have the two cases:

  1. (i) $a_i-b_i=0$ for each positive integer $i\in \mathbb {Z}_+$;

  2. (ii) there exists a positive integer $i_1$ such that $a_{i_1}-b_{i_1}\ne 0$ and $a_j-b_j= 0$ for all $1\le j< i_1$.

In case (i) we have a periodic annulus and no limit cycles exist. In case (ii), $\Gamma$ is a limit cycle of multiplicity $i_1\in \mathbb {Z}_+$ and there are at most $i_1$ zeros of $\varrho (p_0)$ near the origin by the Malgrange preparation theorem ([Reference Chow and Hale6]). Consequently, limit cycle $\Gamma$ is not compound and has a multiplicity $i_1 \in \mathbb {Z}_+$ if $\Gamma$ intersects only one switching line.

Figure 3. The successive function $\varrho (p_0)= \mathcal {P}_1(p_0)- \mathcal {P}_2(p_0)$.

In addition, if the crossing limit cycle $\Gamma$ intersects two or more switching lines, we can prove our result similarly as we do for the case of only one switching line. Actually, if $\Gamma$ intersects $n$ ($n>1$) switching lines, a small neighbourhood of the crossing limit cycle $\Gamma$ only possibly contains the crossing points of the switching lines. Thus, we can present the Poincaré map in $2n$ pieces, each of which is a map from a witching line to the next similar to (2.13). Since $\Gamma$ intersects transversally the switching lines, each piece of the Poincaré map is well defined and close to the corresponding segment of the orbit $\Gamma$ in the corresponding zone $D_i$ between the executive switching lines. In contrast, if $\Gamma$ is a grazing limit cycle, there are at most two grazing points, at which $\Gamma$ intersects two switching lines at the $x$-axis. Therefore, any small vicinity of $\Gamma$ (where $\Gamma$ is not included) only possibly contains the crossing points of the switching lines and thus the successive function can be constructed similarly as we did above for the case that $\Gamma$ intersects only one switching line.

Having the above lemma, we are ready to prove the following theorem, which shows that properties (PR1) and (PR2), obtained by Perko ([Reference Perko23, Reference Perko26]) for analytic families of rotated vector field, remain true for Liénard system (2.6) with hypotheses ($H_1$) and ($H_2$). Note that system (2.6) with hypotheses ($H_1$) and ($H_2$) is rotated in Perko's definition by proposition 2.1. Additionally, we give the relation between variational exponent and multiplicity of limit cycles.

Theorem 2.3 Assume that system (2.6) satisfies hypotheses ($H_1$) and ($H_2$) and has a limit cycle $\Gamma$ of multiplicity $k$ for $\alpha =\alpha _0$. Then

  1. (a) When $k$ is odd, the cycle $\Gamma$ still exists, denoted by $\Gamma _{\alpha }$, and expands inwards (resp. outwards) monotonically as $\alpha :=\alpha _0+\varepsilon$ increases if $\Gamma$ is stable (resp. unstable), where $\varepsilon >0$ is sufficiently small. Moreover, the variational exponent of the cycle $\Gamma _{\alpha }$ is $\varepsilon ^{2/k}$.

  2. (b) When $k$ is even, $\Gamma$ splits into exact two simple limit cycles $\Gamma _{\alpha }^\pm$, one of which is stable but the other is unstable as the parameter $\alpha$ varies in one direction and $\Gamma$ disappears as $\alpha$ varies in the opposite direction. Moreover, the outer limit cycle $\Gamma _{\alpha }^+$ expands outwards and the inner one $\Gamma _{\alpha }^-$ expands inwards as $\alpha$ varies. Additionally, the variational exponent of the two cycles $\Gamma _{\alpha }^\pm$ is $\varepsilon ^{2/k}$, where $\alpha =\alpha _0+\varepsilon$.

Proof. By lemma 2.2, $k$ is a positive integer. In the following, we discuss the distance between an orbit without perturbation and the orbit under perturbation near a limit cycle. From the distance we can further investigate zeros of successive function and the relation between variational exponent and multiplicity of limit cycles.

Without loss of generality, we only discuss the case that the limit cycle $\Gamma$ is externally stable as $\alpha =\alpha _0$, i.e. those points $P_0, P_1$ and $P$ defined by the Poincaré map and the successive function $\varrho$ (see (2.9) and figure 1) are ranked by $0< x_1< x_0$. Otherwise, $\Gamma$ is externally unstable, for which we make a time-rescaling $t\to -t$, so that the limit cycle of the rescaled system is externally stable.

We always let $Q:(x_Q, y_Q)$ be a general point $Q$. Notice that the closed orbit $\Gamma$ has two intersection points $P_0$ and $Q_0$ with the $x$-axis. Moreover, the orbit $\widehat {PQ_1P_1}$ starts from $P:(x_0,0)$, passes through $Q_1:(x_{Q_1},0)$ and returns the positive $x$-axis at $P_1:(x_1,0)$ such that $x_{Q_1}<0< x_{P_1}< x_P$, as shown in figure 1. We consider the perturbed system (2.6)$|_{\alpha =\alpha _0+\varepsilon }$ and let $\widehat {Q_3Q_1Q_2}$ be the orbit of system (2.6)$|_{\alpha =\alpha _0+\varepsilon }$ crossing $Q_1$ and having two intersection points $Q_2$ and $Q_3$ with the positive $x$-axis. For simplicity, let

\[ x_{12}:=\min\{x_1,x_{Q_2}\} ~~{\rm and} ~~x_{03}:=\min\{x_0,x_{Q_3}\}. \]

For $x\in (x_{Q_1}, x_{12})$, let

(2.14)\begin{equation} z_1:={\tilde y}_{\varepsilon}(x)-{\tilde y}_0(x),\end{equation}

where $y={\tilde y}_0(x)$ and $y={\tilde y}_{\varepsilon }(x)$ represent the orbit segments $\widehat {Q_1P_1}$ and $\widehat {Q_1Q_2}$, respectively. For $x\in (x_{Q_1}, x_{03})$, let

(2.15)\begin{equation} z_2:={\hat y}_{\varepsilon}(x)-{\hat y}_0(x),\end{equation}

where $y={\hat y}_0(x)$ and $y={\hat y}_{\varepsilon }(x)$ represent the orbit segments $\widehat {P Q_1}$ and $\widehat {Q_3 Q_1}$, respectively. Moreover, let

\[ P_2= \left\{ \begin{array}{ll} (x_{12}, \tilde y_0(x_{12}) & \mbox{ if } x_1\geq x_{Q_2}, \\ (x_{12}, \tilde y_{\varepsilon}(x_{12}) & \mbox{ if } x_1< x_{Q_2}, \end{array} \right. \ \ P_3= \left\{ \begin{array}{ll} (x_{03}, \hat y_{\varepsilon}(x_{12}) & \mbox{ if } x_0\leq x_{Q_3}, \\ (x_{03}, \hat y_0(x_{12}) & \mbox{ if } x_0> x_{Q_3}. \end{array} \right. \]

By the mean value theorem, we see from the equations ${\tilde y}_{\varepsilon }(x_{Q_1})={\tilde y}_0(x_{Q_1})=0$ that

(2.16)\begin{align} z_1(x) & = z_1(x)-z_1(x_{Q_1}) \nonumber\\ & =\left\{\tilde y_\varepsilon(\tau)-\tilde y_0(\tau)\right\}\mid^{\tau=x}_{\tau=x_{Q_1}} \nonumber\\ & =\int_{x_{Q_1}}^{x} \Bigg(\frac{-g(\tau )-f(\tau,\tilde y_\varepsilon(\tau), \alpha+\varepsilon) \tilde y_\varepsilon(\tau)}{\tilde y_\varepsilon(\tau)}- \nonumber\\ & \quad\frac{-g(\tau )-f(\tau,\tilde y_0(\tau), \alpha )\tilde y_0(\tau)}{\tilde y_0(\tau)} ~ \Bigg) {\rm d}\tau \nonumber \\ & =\int_{x_{Q_1}}^{x} \Bigg( \frac{-g(\tau )}{\tilde y_\varepsilon(\tau)} + \frac{g(\tau )}{\tilde y_0(\tau)} -f(\tau,\tilde y_\varepsilon(\tau), \alpha+\varepsilon )+f(\tau,\tilde y_0(\tau), \alpha+\varepsilon ) \nonumber\\ & \qquad - f(\tau,\tilde y_0(\tau), \alpha+\varepsilon ) +f(\tau,\tilde y_0(\tau), \alpha ) ~ \Bigg) {\rm d}\tau \nonumber\\ & =\int_{x_{Q_1}}^{x} \Bigg(\frac{-g(\tau )}{\tilde y_\varepsilon(\tau)} + \frac{g(\tau )}{\tilde y_0(\tau)} -\frac{\partial f(\tau,\tilde y^*(\tau), \alpha+\varepsilon )}{\partial y}z_1(\tau) \nonumber\\ & \quad -\frac{\partial f(\tau,\tilde y_0(\tau), \alpha+\varepsilon_1 )}{\partial \alpha}\varepsilon~ \Bigg) {\rm d}\tau \nonumber\\ & =h_1(x)+\int^x_{x_{Q_1}}z_1(\tau)h_2(\tau){\rm d}\tau, \end{align}

where $\tilde y^*$ lies between $\tilde y_0$ and $\tilde y_\varepsilon$, $\varepsilon _1$ lies between $0$ and $\varepsilon$, and

\begin{align*} h_1(x)& :={-}\varepsilon\int_{x_{Q_1}}^{x}\frac{\partial f(\tau,\tilde y_0(\tau), \alpha+\varepsilon_1 )}{\partial \alpha}{\rm d}\tau, \ \ h_2(x):=\frac{g(x )}{\tilde y_0(x)\tilde y_\varepsilon(x)}\\ & \quad-\frac{\partial f(\tau,\tilde y^*(\tau), \alpha+\varepsilon )}{\partial y}. \end{align*}

By (2.16),

\[ h_2(x)z_1(x)=h_2(x)h_1(x)+h_2(x)\int^x_{x_{Q_1}}z_1(\tau)h_2(\tau){\rm d}\tau, \]

indicating that the function $h_3(x):=\int ^x_{x_{Q_1}}z_1(\tau )h_2(\tau ){\rm d}\tau$ satisfies

(2.17)\begin{equation} \frac{dh_3(x)}{{\rm d}x}=z_1(x)h_2(x)=h_2(x)h_3(x)+h_1(x)h_2(x).\end{equation}

By the variation of constant formula, we get from (2.17) that

(2.18)\begin{equation} h_3(x)=\int^x_{x_{Q_1}} ~h_1(\tau)h_2(\tau)\exp{\left\{\int^x_{\tau}h_2(\eta){\rm d}\eta\right\}}{\rm d}\tau.\end{equation}

Since $h_1(x_{Q_1})=0$, we see from (2.7), (2.16) and (2.18) that for all $x\in (x_{Q_1},x_{12})$

(2.19)\begin{equation} \begin{aligned} z_1(x) & = h_1(x)+\int^x_{x_{Q_1}}h_1(\tau)h_2(\tau)\exp{\left\{\int^x_{\tau}h_2(\eta){\rm d}\eta\right\}}{\rm d}\tau \\ & = h_1(x)-\int^x_{x_{Q_1}}h_1(\tau) ~ d\Bigg(\exp{\left\{\int^x_{\tau}h_2(\eta){\rm d}\eta\right\}} \Bigg) \\ & = h_1(x_{Q_1})\exp\left\{\int^x_{x_{Q_1}}h_2(\eta){\rm d}\eta\right\}+\int_{x_{Q_1}}^xh_1'(\tau)\exp\left\{\int^x_{\tau}h_2(\eta){\rm d}\eta\right\}{\rm d}\tau \\ & ={-}\varepsilon\int_{x_{Q_1}}^x\frac{\partial f(\tau,\tilde y_0(\tau), \alpha+\varepsilon_1 )}{\partial \alpha}\exp\left\{\int^x_{\tau}h_2(\eta){\rm d}\eta\right\}{\rm d}\tau<0. \end{aligned} \end{equation}

Similarly, for all $x\in (x_{Q_1},x_{03})$ we can obtain

(2.20)\begin{equation} z_2(x) ={-}\varepsilon\int_{x_{Q_1}}^x\frac{\partial f(\tau,\hat y_0(\tau), \alpha+\varepsilon_2 )}{\partial \alpha}\exp\left\{\int^x_{\tau}h_4(\eta){\rm d}\eta\right\}{\rm d}\tau<0, \end{equation}

where $\varepsilon _2\in (0, \varepsilon )$ and

\[ h_4(x):=\frac{g(x )}{\hat y_0(x)\hat y_\varepsilon(x)}-\frac{\partial f(\tau,\hat y^*(\tau), \alpha+\varepsilon )}{\partial y} \]

for $\hat y^*$ lying between $\hat y_0$ and $\hat y_\varepsilon$.

Construct an energy function

(2.21)\begin{equation} E(x,y)=\int_0^xg(s ){\rm d}s+\frac{y^2}{2}.\end{equation}

Then

(2.22)\begin{equation} \frac{{\rm d}E }{{\rm d}t}={-}f(x,y,\alpha )y^2\end{equation}

restricted on system (2.6). From (2.19) and (2.20) we see that the two points $P_2$ and $P_3$ lie on the two orbit segments $\widehat {Q_1P_1}$ and $\widehat {Q_3Q_1}$ respectively, where $x_{P_2}=x_{Q_2}$, $x_{P_3}=x_{P}$, $y_{P_2}>0$ and $y_{P_3}<0$, as shown in figure 1. From (2.19)–(2.22), and $\int _{\widehat {P_2P_1}}{\rm d}E=E(P_1)-E(P_2)$, we obtain

\begin{align*} \int^0_{ {-}z_1(x_{Q_2}) } ~\frac{ f(x,y,\alpha )y^2}{ g(x )+f(x,y,\alpha )y} {\rm d}y & =\frac{y_{P_1}^2}{2}+\int_0^{x_1} ~ g(s ){\rm d}s -\frac{y_{P_2}^2}{2}-\int_0^{x_{Q_2}}~ g(s ){\rm d}s\\ & = \int_{x_{Q_2}}^{x_1} ~ g(s ){\rm d}s-\frac{z_1^2(x_{Q_2})}{2}, \end{align*}

where $z_1(\cdot )$ is defined in (2.14). Thus, there exist $x^*\in [x_{Q_2},x_1]$ and $y^*\in [0, -z_1(x_{Q_2})]$ such that

\begin{align*} \int^0_{{-}z_1(x_{Q_2})} ~\frac{ f(x,y,\alpha )y^2}{ g(x )+f(x,y,\alpha )y} {\rm d}y & = \frac{ f(x,y^*,\alpha )(y^*)^2}{ g(x )+f(x,y^*,\alpha )y^*} z_1(x_{Q_2}) \\ & = (x_1-x_{Q_2})g(x^* ) -\frac{z_1^2(x_{Q_2})}{2} \end{align*}

by the mean value theorem for integrals. Thus,

(2.23)\begin{equation} x_1-x_{Q_2}=\frac{z_1^2(x_{Q_2})}{2g(x_0)}+o(\varepsilon^2) \end{equation}

because $g(x^*)=g(x_0)+O(\varepsilon )$. From (2.19)–(2.22) and the equality

\[ \int_{\widehat{Q_3P_3}}{\rm d}E=E(P_3)-E(Q_3), \]

we obtain

(2.24)\begin{align} -\int^0_{ z_2(x_0) } ~\frac{ f(x,y,\alpha )y^2}{ g(x )+f(x,y,\alpha )y} {\rm d}y& =\frac{y_{P_3}^2}{2}+\int_0^{x_0} ~ g(s ){\rm d}s -\frac{y_{Q_3}^2}{2}-\int_0^{x_{Q_3}}~ g(s ){\rm d}s\nonumber\\ & = \int_{x_{Q_3}}^{x_0} ~ g(s ){\rm d}s +\frac{{z_2}^2(x_0)}{2}, \end{align}

where $z_2(\cdot )$ is defined in (2.15). It follows from equality (2.24) that

(2.25)\begin{equation} x_{Q_3}-x_0=\frac{z_2^2(x_0)}{2g(x_0 )}+o(\varepsilon^2).\end{equation}

On the other hand, $\Gamma$ is a limit cycle of multiple $k$, i.e.

(2.26)\begin{equation} x_0-x_1={-}a_k{x_1}^k+o({x_1}^k),\end{equation}

as seen in the definition of a limit cycle of multiple $k$ in [Reference Zhang, Ding, Huang and Dong30, Chapter 4.2]. Moreover, $\Gamma$ is externally stable, i.e. $a_k<0$. It follows from (2.23)–(2.26) that

(2.27)\begin{equation} x_{Q_3}-x_{Q_2}= \frac{z_1^2(x_{Q_2})}{2g(x_0 )}+\frac{z_2^2(x_0)}{2g(x_0 )}+o(\varepsilon^2)-a_k {x_1}^k+o({x_1}^k).\end{equation}

Since $\dot {y}=-g(x)<0$ on both the positive $x$-axis and the negative $x$-axis near the origin, we see that $g(x_0)>0$.

Consider the case that $k$ is odd, i.e. $\Gamma$ is stable in both internal and external neighbourhoods of $\Gamma$. In the external neighbourhood of $\Gamma$, we can obtain that $x_{Q_3}-x_{Q_2}>0$ by (2.27) and the inequalities $a_k<0$, $g(x_0)>0$ and $x_1>0$, implying that no limit cycles exist in the external neighbourhood of $\Gamma$ when $\alpha$ increases. In the internal neighbourhood of $\Gamma$, we can also obtain equality (2.27) and the inequalities $a_k<0$, $g(x_0)>0$ but $x_1<0$ from a similar discussion to the external neighbourhood of $\Gamma$. Since the solution of system (2.6) is Lipschitzian, the implicit function theorem is applicable. Thus, from (2.27) with $X_1:={x_1}^k$, we see that equality $x_{Q_3}-x_{Q_2}=0$ has a unique root $X_1= (z_1^2(x_{Q_2})+z_2^2(x_0))/(2a_kg(x_0 )) +o(\varepsilon ^{2})<0$, which is equivalent to

(2.28)\begin{equation} x_1=\left( \frac{z_1^2(x_{Q_2})+z_2^2(x_0)}{2a_kg(x_0 )} \right)^{1/k}+o(\varepsilon^{2/k})<0.\end{equation}

It implies that system (2.6)$|_{\alpha =\alpha _0+\varepsilon }$ produces a stable limit cycle $\Gamma _{\alpha }$ in the internal neighbourhood of $\Gamma$, where the bifurcated limit cycle $\Gamma _{\alpha }$ passes through the point $(x_1, 0)$. Moreover, the stable limit cycle expands inwards (or contracts) monotonically as $\alpha$ increases. From (2.8) and (2.28), we can obtain

\[ \Delta_\alpha(\varepsilon):=x_1-0=x_1, \]

implying that the variational exponent is $2/k$. This proves the results of statement (a).

In the case that $k$ is even, i.e. $\Gamma$ is semi-stable (externally stable but internally unstable), we obtain equality (2.27), $a_k<0$ and $g(x_0)>0$ in the neighbourhood of $\Gamma$, implying that $x_{Q_3}-x_{Q_2}>0$ near the origin and then system (2.6) has no limit cycles in a neighbourhood of $\Gamma$ as $\alpha$ increases.

In order to completely investigate limit cycles bifurcating from semi-stable $\Gamma$ for even $k$, we consider the case that $\alpha :=\alpha _0-\varepsilon$ decreases. By a similar calculation to (2.27), we obtain

(2.29)\begin{equation} x_{Q_3}-x_{Q_2}={-}\frac{z_1^2(x_{P_2})}{2g(x_0 )}-\frac{z_2^2(x_{Q_3})}{2g(x_0 )} +o(\varepsilon^2)-a_k{x_1}^k+o({x_1}^k),\end{equation}

where $g(x_0)>0$ and $a_k<0$. Let $k:=2n$ for $n\in \mathbb {Z}_+$ and $X_2:={x_1}^n$. By the implicit function theorem and (2.29), the equality $x_{Q_3}-x_{Q_2}=0$ has exactly two roots

$X_2= \pm \sqrt { -(z_1^2(x_{P_2})+z_2^2(x_{Q_3}))/(2a_kg(x_0 ))}+o(\varepsilon ^{2})$, which is equivalent to

(2.30)\begin{equation} x_1={\pm}\left(-\frac{z_1^2(x_{P_2})+z_2^2(x_{Q_3})}{2a_kg(x_0 )}\right)^{1/k}+o(\varepsilon^{2/k}).\end{equation}

It follows that two simple limit cycles $\Gamma _{\alpha }^{\pm }$ of system (2.6)$|_{\alpha =\alpha _0-\varepsilon }$ exist in a neighbourhood of $\Gamma$, and the outer limit cycle $\Gamma _{\alpha }^+$ is stable but the inner one $\Gamma _{\alpha }^-$ is unstable. Moreover, $\Gamma _{\alpha }^+$ expands outwards monotonically and $\Gamma _{\alpha }^-$ expands inwards monotonically as $\alpha$ decreases. From (2.8) and (2.30), we can obtain $\Delta _\alpha (\varepsilon ):=x_1-0=x_1$, implying that the variational exponent is $2/k$. This proves the results of statement (b).

In conclusion, for odd $k$ system (2.6) produces a stable (resp. unstable) limit cycle $\Gamma _{\alpha }$ when $\Gamma$ is stable (resp. unstable) in an internal (resp. external) neighbourhood of $\Gamma _{\alpha }$ as $\alpha$ increases. On the other hand, for even $k$ the externally stable and internally unstable (resp. externally stable and internally unstable) $\Gamma$ splits into exact two simple limit cycles $\Gamma _{\alpha }^{\pm }$. Moreover, the outer limit cycle $\Gamma _{\alpha }^+$ is stable (resp. unstable) and expands outwards, but the inner one $\Gamma _{\alpha }^-$ is unstable (resp. stable) and expands inwards as $\alpha$ decreases (resp. increases). However, the limit cycle $\Gamma$ disappears as $\alpha$ varies in the opposite direction. Furthermore, the variational exponent of the new limit cycle is $\varepsilon ^{2/k}$.

Theorem 2.3 shows how the limit cycle expands or bifurcates as the rotated parameter $\alpha$ varies, where the stable (or unstable) limit cycle may be hyperbolic or non-hyperbolic. Clearly, the results of theorem 2.3 are true for analytic rotated Liénard systems. Additionally, theorem 2.3 gives variational exponents to show the expanding rates of the limit cycles depending on the rotated parameter $\alpha$, which was not discussed yet even for analytic rotated vector fields.

3. Rotated Hopf bifurcation and rotated homoclinic bifurcation

In this section, we introduce results on homoclinic loops and Hopf bifurcation of the one-parameter family of rotated vector fields (2.6) with hypotheses ($H_1$) and ($H_2$).

Theorem 3.1 Properties (PR3) and (PR4) in §$1$ are still true for system (2.6) with hypotheses ($H_1$) and ($H_2$).

Proof. First, we prove property (PR3). Without loss of generality, assume that the origin of system (2.6) is a weak focus as $\alpha =\alpha _0$ and the weak focus is stable, as shown in figure 4. When the vector field of system (2.6) is analytic in a small neighbourhood of the origin, the conclusion holds directly by [Reference Perko23]. Since the origin is a weak focus, we obtain that

\[ \mathcal{P}(x)-x=a_kx^k+o(x^k) \]

on the $x$-axis, where $\mathcal {P}(x)$ is the Poincaré map, $k$ is a positive integer and ${x>0}$ is small. As proven in theorem 2.3, (2.27) still holds, where $P, P_1, Q_1, Q_2, Q_3$, $x_0,x_1, x_{Q_1}, x_{Q_2}, x_{Q_3}$ are defined similarly in figure 1 and the proof of theorem 2.3, as shown in figure 4. Then, $a_k<0$ since the weak focus is stable. For positive integer $k$ and $\alpha =\alpha _0-\varepsilon$, the equality $x_{Q_3}-x_{Q_2}=0$ has a unique positive zero

\[ x_1=\left(-\frac{z_1^2(x_{P_2})+z_2^2(x_{Q_3})}{2a_k g(x_0)} \right)^{1/k}+o(\varepsilon^{2/k})>0, \]

where $\varepsilon >0$ is small and $g(x_0)>0$. When $\alpha =\alpha _0+\varepsilon$, for even $k$ the equality $x_{Q_3}-x_{Q_2}=0$ has no positive zeros. Thus, system (2.6)$|_{\alpha =\alpha _0-\varepsilon }$ produces a new stable limit cycle in a small neighbourhood of the origin. Thus, property (PR3) still holds.

Figure 4. Poincaré map near $O$ in system (2.6).

Next, we prove property (PR4). Assume that system (2.6) exhibits a homoclinic loop $\Gamma _0$ as $\alpha =\alpha _0$. Without loss of generality, we consider that the saddle in the homoclinic loop is the origin and the homoclinic loop is stable. By the sign of the vector field $(y,-g(x)-f(x,y,\alpha )y)$ near the saddle, in a small neighbourhood of the origin one side of the stable manifold and one side of the unstable manifold of the saddle lie in the left-half plane, but the other sides of the two manifolds lie in the right-half plane. Assume that $\Gamma _0$ intersects the positive (or negative) $y$-axis and surrounds neither one stable manifold nor one unstable manifold of the origin other than those in $\Gamma _0$, as shown in figures 5a, b. Notice that $\dot x=y>0$ in the positive $y$-axis and $\dot x=y<0$ in the negative $y$-axis. However, in figures 5a, b the sign of $\dot x$ at the intersection point $\Gamma _0$ and the $y$-axis is opposite by the location of the stable and unstable manifolds of $\Gamma _0$. Thus, system (2.6) has no homoclinic loops which intersect the positive (or negative) $y$-axis and do not surround the other stable and unstable manifolds. In other words, if system (2.6) has a homoclinic loop $\Gamma _0$ which does not surround one stable and one unstable manifolds of $O$ other than those in $\Gamma _0$, then $\Gamma _0$ lies in the left-half (or right-half) plane. It is similar to prove that system (2.6) has no homoclinic loops which intersect the positive and negative $y$-axes, and surround the other two manifolds, as shown in figures 5c, d. Therefore, it is sufficient to prove that the homoclinic loop has one of the configurations shown in figure 6. Otherwise, we apply the transformation $(x,y)\to (-x,-y)$. The case of figure 6b can be treated by a similar mean to the case of figure 6a, where the only difference is that the Poincaré map need to be considered in the outer neighbourhood of the homoclinic loop for the case of figure 6b. Therefore, we only need to discuss the case of figure 6a. Now, consider $\delta _0:=-f(0,0, \alpha _0)\neq 0$. In other words, the sum of the two eigenvalues of the hyperbolic saddle is not equal to zero. Let

\[ \delta:={-}\frac{\partial f(\varphi(t),\phi(t), \alpha_0)}{\partial y}\phi(t)-f(\varphi(t),\phi(t), \alpha_0), \]

where $(x,y)=(\varphi (t),\phi (t))$ represents the homoclinic loop. Consider the perturbed system of (2.6) for $\alpha =\alpha _0+\varepsilon$ with sufficiently small $|\varepsilon |$. By Theorem 3.7 of [Reference Chow, Li and Wang7, Chapter 3], we have the following conclusions:

  1. (a) There is exactly one limit cycle bifurcating from the homoclinic loop of system (2.6) when $\delta _0\varepsilon \Delta >0$ (resp. $<0$), which is stable for $\delta _0<0$ and unstable for $\delta _0>0$, where

    \[ \Delta:={-}\int_{-\infty}^{+\infty}e^{-\int_0^t \delta(s){\rm d}s} \frac{\partial f(\varphi(t),\phi(t),\alpha)}{\partial \alpha}|_{\alpha=\alpha_0} \phi^2(t){\rm d}t. \]
  2. (b) There are no limit cycles in a small neighbourhood of the homoclinic loop of system (2.6) when $\delta _0\varepsilon \Delta <0$ (resp. $>0$).

Figure 5. Impossible cases of homoclinic loops for system (2.6).

Figure 6. Classification of homoclinic loops for system (2.6).

We consider the case $\delta _0=0$. In this case we cannot apply [Reference Chow, Li and Wang7, Theorem 3.7 of Chapter 3] directly, which only considers the case $\delta _0\ne 0$. We can obtain the Poincaré map again

\[ \mathcal{P}(x)-x=a_kx^k+o(x^k) \]

on the $x$-axis, defined in an interior neighbourhood of any homoclinic loop, where $k$ is a positive integer. As proven in theorem 2.3, (2.27) still holds, where $P$, $P_0$, $P_1$, $Q_1$, $Q_2$, $Q_3$, $x_0,x_1, x_{Q_2}, x_{Q_3}$ are defined similarly in the proof of theorem 2.3, as shown in figure 6. Then, $a_k>0$ since the homoclinic loop is stable. For $\alpha =\alpha _0+\varepsilon$ and positive integer $k$, the equality $x_{Q_3}-x_{Q_2}=0$ has a unique zero

\[ x_1=\tilde{x}_0- \left(\frac{z_1^2(x_{Q_2})+z_2^2(x_0)}{2a_kg(x_0 )} \right)^{1/k} +o(\varepsilon^{2/k})<\tilde{x}_0, \]

where $\tilde {x}_0$ is the abscissa of $P_0$ and $\varepsilon >0$ is small. When $\alpha =\alpha _0-\varepsilon$, for even $k$ and small $\varepsilon _1>0$ the equality $x_{Q_3}-x_{Q_2}=0$ has no zeros in $(\tilde {x}_0-\varepsilon _1, \tilde {x}_0)$. Thus, the proof is completed.

Note that theorems 2.3 and 3.1 give positive answers to questions (Q1) and (Q2) mentioned in the Introduction.

The following assumptions are needed for studying singular closed orbits (homoclinic loops or heteroclinic loops).

  1. (H a) Assume that system (1.1) defines a family of analytic rotated vector fields. Let system (1.1) have a singular closed orbit $L_0\subset \bar {D}$ for some $\lambda _0 \in I$ such that the Poincaré map is well defined on one side of $L_0$, where $\bar {D}$ is the closure of $D$.

For singular closed orbits in a family of analytic rotated vector fields, it was proved by Han in [Reference Han14, Theorem 2.4] that

  1. (i) if $L_0$ is non-isolated, system (1.1) has no closed orbits in a small neighbourhood of $L_0$ for $\lambda \in I\backslash \{\lambda _0\}$, and

  2. (ii) if $L_0$ is isolated, system (1.1) has at least one limit cycle near $L_0$ as $\lambda$ varies in a suitable sense but no closed orbits near $L_0$ as $\lambda$ varies in the opposite sense.

Based on result (ii), a conjecture follows.

Conjecture of [Reference Han14]: There is at most one limit cycle near $L_0$ for $\lambda \in I$ satisfying $0<|\lambda -\lambda _0|\ll 1$ under the conditions of [Reference Han14, Theorem 2.4], i.e. under the assumptions ( $H_a$) for the vector field of (1.1).

The following theorem, indicating that two limit cycles can be bifurcated from a cuspidal loop, gives a negative answer to the above conjecture.

Theorem 3.2 Assume that system (2.6) with hypotheses ($H_1$) and ($H_2$) has a cuspidal loop $\Gamma$ for $\alpha =\alpha _0$ and the cusp persists if $|\alpha -\alpha _0|\ll 1$. Moreover, the vector field of system (2.6) is analytic in a small neighbourhood of the cusp. Then, we have the following conclusions:

  1. (i) If $\Gamma$ is of odd multiplicity, system (2.6) has a unique limit cycle near $\Gamma$ for $\alpha \in I$ with $0<|\alpha -\alpha _0|\ll 1$.

  2. (ii) If $\Gamma$ is of even multiplicity, system (2.6) has exactly two limit cycles near $\Gamma$ as $\alpha$ varies in a suitable sense and has no closed orbits near $\Gamma$ as $\alpha$ varies in the opposite sense.

Proof. Without loss of generality, we can assume that the cusp is located at $(0,0)$. Since the vector field of system (2.6) at the cusp is analytic, in a small neighbourhood of $(0,0)$ system (2.6) can be rewritten as

(3.1)\begin{equation} \begin{aligned} \dot x & = y, \\ \dot y & = a_kx^k \big(1+p_1(x )\big) +b_nx^ny\big(1+p_2(x )\big)+y^2p_3(x,y ) \\ & \quad +(\alpha-\alpha_0)y^lp_4(x,y,\alpha ) \end{aligned} \end{equation}

by [Reference Dumortier, Llibre and Artés11, Chapter 3] or [Reference Zhang, Ding, Huang and Dong30, Chapter 2], where integer $k\ge 2$, integers $n,l$ are positive, and functions $p_1(x)$, $p_2(x)$, $p_3(x,y)$ and $p_4(x,y,\alpha )$ are analytic such that $p_1(0)=0$, $p_2(0)=0$ and $y^{l}p_4(x,y,\alpha )\geq 0$. By Theorem 3.5 of [Reference Dumortier, Llibre and Artés11, Chapter 3] or Theorem 7.3 of [Reference Zhang, Ding, Huang and Dong30, Chapter 2], the origin $(0,0)$ of system (3.1) is a cusp when one of the following statements holds:

  1. (a) $k=2\,m$ ($m\ge 1$), $l\geq 2$ and $b_n=0$.

  2. (b) $k=2\,m$ ($m\ge 1$), $n\geq m$, $l\geq 2$ and $b_n\neq 0$.

Therefore, according to the conditions of this theorem, we can define the Poincaré map on both sides of $\Gamma _0$ when $|\alpha -\alpha _0|\ll 1$. Moreover, system (3.1) is of the form of system (2.6), the remainder research is similar to the proof of theorem 2.3 and we omit it.

Remark that in theorem 3.2 we provide a class of singular closed orbits in a family of rotated vector fields for system (1.1) and two limit cycles can be bifurcated from the singular closed orbit.

By theorems 2.33.2, we have the following further result.

Proposition 3.3 When system (2.6) has a singular closed orbit $L_0\subset \bar {D}$ for some $\lambda _0 \in I$ such that the Poincaré map is well defined on only one side of $L_0$, conjecture of [Reference Han14] is correct. Furthermore, when system (2.6) has a singular closed orbit $L_0\subset \bar {D}$ with even multiplicity for some $\lambda _0 \in I$ such that the Poincaré map is well defined on both sides of $L_0$, there can exist more than one limit cycle near $L_0$ for $0<|\lambda -\lambda _0|\ll 1$, i.e. a negative answer to the conjecture of [Reference Han14].

For a specific example to proposition 3.3, consider the system

(3.2)\begin{equation} \dot{x}=y, \quad \dot{y}={-}x^2(x+1)+\delta\left(\alpha+\beta x+x^2\right) y, \end{equation}

where $\delta$ is a perturbation parameter. For $\delta =0$ system (3.2) is Hamiltonian and has a cuspidal loop $\Gamma _0$. As indicated in the main theorem on page 211 of [Reference Dumortier and Li10], limit cycles of system (3.2) have been researched by computing Abelian integrals. Let $\alpha _1:=\delta \alpha$. Then the vector field of (3.2) is rotated with the rotated parameter $\alpha _1$. Thus, system (3.2) can have two limit cycles near $\Gamma _0$ with even multiplicity for $0<|\alpha _1|$ as the rotated parameter $\alpha _1$ varies and $(\alpha _1, \beta )$ is near the point $C_2:(0,14 / 15)$.

4. Application to SD oscillator

The main results in § 2 can be applied to the problem of limit cycles for the SD oscillator. In other words, we will use our theorems to give a positive answer to question (Q3), mentioned in the Introduction for this differential system.

The authors of [Reference Chen, Llibre and Tang4] studied the global bifurcation diagram and all phase portraits of the SD oscillator

(4.1)\begin{equation} \dot x=y-\xi(bx+x^3), \quad \dot y={-}x\left(1-\frac{1}{\sqrt{x^2+a^2}}\right),\end{equation}

where $(a,b,\xi )\in \mathbb {R}^+\times \mathbb {R}\times \mathbb {R}^+$. It is shown in [Reference Chen, Llibre and Tang4] that system (4.1) has three equilibria

\begin{align*} & E_L: (-\sqrt{1-a^2}, (a^2-1-b)\xi\sqrt{1-a^2} ), ~E_0: (0,0),\\ & \quad E_R: (\sqrt{1-a^2}, (1-a^2+b)\xi\sqrt{1-a^2}) \end{align*}

if $a<1$, and only $E_0$ exists if $a\ge 1$. Large limit cycles represent the ones surrounding all three equilibria and small limit cycles the ones surrounding a single equilibrium. However, the maximum number of small limit cycles of system (4.1) are not proven as parameters belong to the region

\begin{align*} & \mathcal{G}:=\Bigg\{(a,b,\xi)\in \mathbb{R}^+{\times}\mathbb{R}\times\mathbb{R}^+: 0< a<\sqrt{3}/3,~2\sqrt{3}a-4\\ & \quad < b<\min\{\varphi(a,\xi),3a^2-3\}\Bigg\}, \end{align*}

where $b=\varphi (a,\xi )$ is the homoclinic bifurcation surface and $2\sqrt {3}a-4<\varphi (a,\xi )< a^2-1$. By the symmetry of system (4.1), we only need to study the maximum number of small limit cycles surrounding $E_R$. Moreover, the authors of [Reference Chen, Llibre and Tang4] conjectured that system (4.1) has at most two small limit cycles surrounding $E_R$. In other words, the bifurcation surface of double limit cycle can be expressed as a function $b=\phi (a,\xi )$, continuous in $a\in (0,\sqrt {3}/3)$, such that $2\sqrt {3}a-4 <\phi (a,\xi )<\min \{\varphi (a,\xi ),3a^2-3\}$, $\phi (1/\sqrt {3},\xi )=-2$ and $\phi (0,\xi )=\varphi (0,\xi )$.

Recently, Liu and Sun ([Reference Sun and Liu27]) proved that the conjecture is true in $\mathcal {G}$ for small $\xi$ by computing Abelian integrals. However, the approach of Abelian integrals is not available for general (large) $\xi$ because system (4.1) is no longer near-Hamiltonian. In this paper, we use theorem 2.3 to prove that at most two small limit cycles surround equilibrium $E_R$ of system (4.1) as parameters lie in the region $\mathcal {G}$ for general $\xi$.

Theorem 4.1 System (4.1) has at most two small limit cycles surrounding $E_R$ for $(a,b,\xi )\in \mathcal {G}$ with general $\xi$. Specially, a path of a small semi-stable limit cycle can be presented by a function $b=\phi (a,\xi )$, where $0< a<\sqrt {3}/3$, $2\sqrt {3}a-4 <\phi (a,\xi )<\min \{\varphi (a,\xi ),3a^2-3\}$, $\phi (1/\sqrt {3},\xi )=-2$ and $\phi (0,\xi )=\varphi (0,\xi )$.

Proof. Let $\tilde b=b\xi$ and take $(a, \tilde b, \xi )$ as new parameter. With the transformation $(x,y)\to (x, y+\tilde bx+\xi x^3)$, system (4.1) can be changed into the following form

(4.2)\begin{equation} \dot x=y, \quad \dot y={-}x\left(1-\frac{1}{\sqrt{x^2+a^2}}\right)-(\tilde b+3\xi x^2)y. \end{equation}

We can check that $(y,-x(1-{1}/{\sqrt {x^2+a^2}})-(\tilde b+3\xi x^2)y)$ is a rotated vector field with respect to $\tilde b$ and $\xi$. Moreover, the parameter region $\mathcal {G}$ can be changed into

\begin{align*} & \mathcal{G}_1:=\Bigg\{(a,\tilde b,\xi)\in \mathbb{R}^+{\times}\mathbb{R}\times\mathbb{R}^+: 0< a<\frac{\sqrt{3}}{3}, (2\sqrt{3}a-4)\xi\\ & \qquad <\tilde b<\min\{\xi\varphi(a,\xi),(3a^2-3)\xi\}\Bigg\}. \end{align*}

By theorem 2.3, unstable limit cycles of system (4.2) expand and stable limit cycles contract as either $\tilde b$ or $\xi$ increases. Assume that system (4.2) has at least three limit cycles $\Gamma _1$, $\Gamma _2$ and $\Gamma _3$ surrounding $E_R$ only. Without loss of generality, we assume that $\Gamma _1$, $\Gamma _2$ and $\Gamma _3$ are innermost limit cycles and $\Gamma _i$ lies in the interior region surrounded by $\Gamma _{i+1}$ for $i=1,2$.

In the following we prove by reduction to absurdity that at most two small limit cycles surround $E_R$ only as the parameter belongs to region $\mathcal {G}_1$. First, we exhibit the idea of the proof. We assume that there may exist three small limit cycles surrounding $E_R$ only as the parameter belongs to region $\mathcal {G}_1$. Then we enlarge or lessen those rotated parameters $\tilde b$ and $\xi$ in order, and the parameters lie in a region at last for such case the number of limit cycles has been obtained which is smaller than three. Thus, it induces a contradiction.

By the instability of $E_R$, we can consider the case that $\Gamma _1$ and $\Gamma _3$ are stable and $\Gamma _2$ is unstable. Otherwise, we will vary the rotated parameters to obtain such case. Now we go on the following steps:

Step 1: Lessen $\xi =\xi _1<\xi _0$ till either $\Gamma _1$ and $\Gamma _2$ coincidence or $\Gamma _3$ becomes a homoclinic loop or $\Gamma _3$ becomes a semi-stable limit cycle for fixed $a=a_0$ and $\tilde b=\tilde b_0$. We claim that $(a,\tilde b, \xi )=(a_0,\tilde b_0, \xi _1)\in \mathcal {G}_1$. Otherwise, system (4.1) has at least three small limit cycles surrounding $E_R$ as parameters lie in the other region except $\mathcal {G}_1$ by the rotated properties of vector fields. By theorem 1 of [Reference Chen, Llibre and Tang4], this is a contradiction. We also claim that $\xi _1$ is not small. By the results of [Reference Sun and Liu27], system (4.1) has at most two small limit cycles surrounding $E_R$ for small $\xi _1$, also implying a contradiction.

Step 2: Enlarge $\tilde b=\tilde b_1>\tilde b_0$. We can get three limit cycles, which are still denoted by $\Gamma _1, \Gamma _2$ and $\Gamma _3$ by the rotated properties of vector fields. We continue to enlarge $\tilde b$ till $\Gamma _2$ and $\Gamma _3$ coincide. In other words, we get a stable $\Gamma _1$ and a semi-stable $\tilde \Gamma _{23}$. Moreover, $\tilde \Gamma _{23}$ is internally unstable and externally stable. We claim that $(a,\tilde b, \xi )=(a_0,\tilde b_1, \xi _1)\in \mathcal {G}_1$ and $\tilde b_1$ is not small. Otherwise, we can similarly obtain a contradiction as tep 1.

Step 3: Repeat step 1, i.e. lessen $\xi =\xi _2<\xi _1$ till either $\Gamma _1$ and $\Gamma _2$ coincide or $\Gamma _3$ becomes a homoclinic loop or $\Gamma _3$ becomes a semi-stable limit cycle for fixed $a=a_0$ and $\tilde b=\tilde b_1$. We also claim that $(a,\tilde b, \xi )=(a_0,\tilde b_1, \xi _2)\in \mathcal {G}_1$ and $\xi _2$ is not small. Otherwise, we can obtain the similar contradiction as step 1. Then repeat step 2, step 1, step 2,…, up to $n$ times.

On the other hand, by the proof of theorem 2.3, both the variations of $\tilde b$ and $\xi$ in the aforementioned steps are not sufficiently small (i.e. there exists a positive $d_0$ such that the variations are larger than $d_0$) because none of distances between any two of given $\Gamma _1, \Gamma _2$ and $\Gamma _3$ is sufficiently small. Thus, we stop the aforementioned process in finitely many steps when either $\xi$ is sufficiently close to $0$ or $\tilde b\ge \min \{\xi \varphi (a,\xi ),(3a^2-3)\xi \}$. Then there exists $n_0\in \mathbb {Z}_+$ such that the number of limit cycles is larger than $2$ as $(a,\tilde b, \xi )=(a_0,\tilde b_n, \xi _n)$ for $n>n_0$, contradicting the result ‘a unique limit cycle’ for $\tilde b=\min \{\xi \varphi (a,\xi ),(3a^2-3)\xi \}$ and the result ‘at most $2$ limit cycles’ for small $\xi$. This is a contradiction. Therefore, there are at most two small limit cycles only surrounding $E_R$ as the parameter belongs to region $\mathcal {G}$. By the instability of $E_0$, the interior small limit cycle is stable and the outer one is unstable respectively if there exist exactly two small limit cycles surrounding $E_R$.

Remark that the global dynamics of system (4.1) can be presented completely by [Reference Chen, Llibre and Tang4, Theorem 1], results of [Reference Sun and Liu27] and theorem 4.1.

5. Application to switching system with three zones

The main results in § 2 can also be applied to the problem of limit cycles for piecewise linear differential system with three zones and asymmetry. Consider a piecewise linear differential system

(5.1)\begin{equation} \dot x=F(x)-y, \qquad \dot y= g(x)\end{equation}

with two parallel lines and asymmetry, which was introduced in [Reference Chen and Tang5, Reference Euzébio, Pazim and Ponce13, Reference Llibre, Ponce and Valls18, Reference Llibre, Ponce and Valls19], where

\begin{align*} F(x)& := \left\{ \begin{array}{l} t_r(x-v)+t_cv,~~\mbox{if}~x> v, \\ t_cx,\ \ \ \ \ \ \ \ \ \ \ \ \ \ \ \ \mbox{if}~-u\leq x\leq v, \\ t_l(x+u)-t_cu,~~\mbox{if}~x<{-}u, \end{array}\right. \ \ g(x)\\ & := \left\{\begin{array}{l} r(x-v)+v,~~\mbox{if}~x> v, \\ x,\ \ \ \ \ \ \ \ \ \ \ \ \ \ \ \mbox{if}~-u\leq x\leq v, \\ l(x+u)-u,~~\mbox{if}~x<{-}u. \end{array}\right. \end{align*}

The plane is separated by two switching lines $\Gamma _L=\{(x,y): x=-u\}$ and $\Gamma _R=\{(x,y): x=v\}$.

Llibre et al. [Reference Llibre, Ponce and Valls18] discussed system (5.1) in the parameter regions

\begin{align*} & \mathcal{G}_1:=\{(u,v,l,r,t_l,t_r)\in\mathbb{R}^6: 0< v< u,\quad ~l>0, r=1, ~0\\& \quad < t_r<2, ~t_l<0, ~t_r+\frac{t_l}{\sqrt{l}}<0\}, \\ & \mathcal{G}_2:=\{(u,v,l,r,t_l,t_r)\in\mathbb{R}^6: 0< u< v, ~r>0, l=1, ~0\\& \quad < t_l<2, ~t_r<0, ~t_l+\frac{t_r}{\sqrt{r}}<0\}, \\ & \mathcal{G}_3:=\{(u,v,l,r,t_l,t_r)\in\mathbb{R}^6: 0< v< u, ~l>0, r=1, ~-2\\& \quad < t_r<0, ~t_l>0, ~t_r+\frac{t_l}{\sqrt{l}}>0\}, \\ & \mathcal{G}_4:=\{(u,v,l,r,t_l,t_r)\in\mathbb{R}^6: 0< u< v, ~r>0, l=1, ~-2\\& \quad < t_l<0, ~t_r>0, ~t_l+\frac{t_r}{\sqrt{r}}>0\} \end{align*}

and obtained the following results.

Proposition 5.1 [Reference Llibre, Ponce and Valls18, Theorems 7-10]

In the parameter region $\mathcal {G}_1$(resp. $\mathcal {G}_2$ , $\mathcal {G}_3$, $\mathcal {G}_4$), the following statements hold.

  1. (a) When $0< t_c\leq t_r$ (resp. $0< t_c\leq t_l$, $t_r\leq t_c<0$, $t_l\leq t_c<0$), system (5.1) has a unique limit cycle, which is stable (resp. stable, unstable, unstable).

  2. (b) When $t_c=0$, the origin of system (5.1) is surrounded by a bounded period annulus. The most external periodic orbit of the period annulus, which is tangent to the line $x=v$, is unstable (resp. unstable, stable, stable). There exists a stable (resp. stable, unstable, unstable) limit cycle surrounding such period annulus.

  3. (c) There exists small $\varepsilon >0$ such that if $-\varepsilon < t_c<0$ (resp. $-\varepsilon < t_c<0$, $0< t_c<\varepsilon$, $0< t_c<\varepsilon$), then the origin is surrounded by at least two limit cycles, where the smaller is unstable (resp. unstable, stable, stable) and the bigger is stable (resp. stable, unstable, unstable).

In order to study the hyperbolicity and exact number of limit cycles obtained in theorem 5.1, we further recall the following results, where

\begin{align*} h_1& := \min\left\{\frac{t_r(v-u)}{(u+v)}, \frac{t_rv+t_lu/l}{u+v}\right\}, \quad h_2:= \min\left\{\frac{t_l(u-v)}{(u+v)}, \frac{t_lu+t_rv/r}{u+v}\right\}, \\ h_3& :=\max\left\{\frac{t_r(v-u)}{(u+v)}, \frac{t_rv+t_lu/l}{u+v}\right\}, \quad h_4:=\max\left\{\frac{t_l(u-v)}{(u+v)}, \frac{t_lu+t_rv/r}{u+v}\right\}. \end{align*}

Proposition 5.2 [Reference Chen and Tang5, Theorem 1.2]

When $0\le t_c\leq t_r$ (resp. $0\le t_c\leq t_l$, $t_r\leq t_c \le 0$, $t_l\leq t_c\le 0$) and parameters lie in the region $\mathcal {G}_1$(resp. $\mathcal {G}_2$ , $\mathcal {G}_3$, $\mathcal {G}_4$), system (5.1) has a unique limit cycle, which is hyperbolic. Moreover, the limit cycle is stable in $\mathcal {G}_1$, $\mathcal {G}_2$ and unstable in $\mathcal {G}_3$, $\mathcal {G}_4$.

Proposition 5.3 [Reference Chen and Tang5, Theorem 1.3]

In the parameter region $\mathcal {G}_1$(resp. $\mathcal {G}_2$ , $\mathcal {G}_3$, $\mathcal {G}_4$), the following statements hold.

  1. (1) When $t_c\leq h_1 ~({\rm resp.} ~t_c\leq h_2, ~t_c\geq h_3, ~t_c\geq h_4),$ system (5.1) exhibits no limit cycles.

  2. (2) When $-\varepsilon < t_c<0$ (resp. $-\varepsilon < t_c<0$, $0< t_c<\varepsilon$, $0< t_c<\varepsilon$) for small $\varepsilon >0$, system (5.1) exhibits exactly two limit cycles, where the inner limit cycle which only intersects $\Gamma _R$ is hyperbolic and unstable (resp. unstable, stable, stable) and the outer one which intersects $\Gamma _L$ and $\Gamma _R$ is hyperbolic and stable(resp. stable, unstable, unstable).

By propositions 5.2 and 5.3, we naturally have the following question:

(Q4) When $h_1< t_c<-\varepsilon$ (resp. $h_2< t_c<-\varepsilon$, $\varepsilon < t_c< h_3$, $\varepsilon < t_c< h_4$) for small $\varepsilon >0$, how many limit cycles does system (5.1) exhibit?

The following theorem can answer question (Q4).

Theorem 5.4 In the parameter region $\mathcal {G}_1$(resp. $\mathcal {G}_2$ , $\mathcal {G}_3$, $\mathcal {G}_4$), there are four functions $t_c=\varphi _1(t_r)$ (resp. $\varphi _2(t_r)$, $\varphi _3(t_l)$, $\varphi _4(t_l)$) for any fixed ($t_l, l,r,u,v$) (resp. ($t_l, l,r,u,v$), ($t_r, l,r,u,v$), ($t_r, l, r,u,v$)) such that

  1. (1) system (5.1) has exactly two limit cycles when $\varphi _1(t_r)< t_c<0$ (resp. $\varphi _2(t_r)< t_c<0$, $0< t_c<\varphi _3(t_l)$, $0< t_c<\varphi _4(t_l)$) for small $\varepsilon >0$, where the inner limit cycle which only intersects $\Gamma _R$ is unstable (resp. unstable, stable, stable) and the outer one which intersects $\Gamma _L$ and $\Gamma _R$ is stable (resp. stable, unstable, unstable);

  2. (2) system (5.1) has exactly one semi-stable limit cycle when $t_c=\varphi _1(t_r)$ (resp. $\varphi _2(t_r)$, $\varphi _3(t_l)$, $\varphi _4(t_l)$), where the limit cycle which intersects $\Gamma _L$ and $\Gamma _R$ is externally stable (resp. stable, unstable, unstable);

  3. (3) system (5.1) has no limit cycles when $t_c<\varphi _1(t_r)$ (resp. $t_c<\varphi _2(t_r)$, $t_c>\varphi _3(t_l)$, $t_c>\varphi _4(t_l)$).

Proof. Without loss of generality, we only discuss $\mathcal {G}_1$ since the remainder cases $\mathcal {G}_2$ , $\mathcal {G}_3$, $\mathcal {G}_4$ can be discussed similarly. With the transformation $(x,y)\to (x,y+F(x))$, system (5.1) is changed into the following discontinuous system

(5.2)\begin{equation} \dot x={-}y, \qquad \dot y= g(x)+f(x)y,\end{equation}

where

\[ f(x)= \left\{ \begin{array}{l} t_r,~~\mbox{if}~x> v, \\ t_c,\ \mbox{if}~-u\leq x\leq v, \\ t_l,~~\mbox{if}~x<{-}u. \end{array}\right. \]

We can check that the vector field $(-y, g(x)+f(x)y)$ of system (5.2) is rotated about $t_c, t_l$ and $t_r$.

Assume that system (5.2) has at least three limit cycles as parameters lie in the region $\mathcal {G}_1$ and $(t_c,t_r)=(t_c^0, t_r^0)$ for $h_1< t_c^0<-\varepsilon$ and $0< t_r^0<2$, and $\Gamma _1$, $\Gamma _2$ and $\Gamma _3$ are the three innermost limit cycles, where $\Gamma _2$ lies in the annular region surrounded by inner boundary $\Gamma _1$ and outer boundary $\Gamma _3$. Without loss of generality, we can let $\Gamma _1, \Gamma _3$ be unstable and $\Gamma _2$ be stable. By theorem 2.3, $\Gamma _1, \Gamma _3$ contract and $\Gamma _2$ expands when one of $t_c$, $t_l$, $t_r$ increases. Now we make a similar process to the proof of theorem 4.1 as follows.

Step 1: There is $t_c^1\in (t_c^0,0)$ such that $\Gamma _2, \Gamma _3$ coincide when the other parameters are fixed. We claim that $|t_c^1|$ is not small. Otherwise, system (5.2) has more than one limit cycle as $t_c=0$ by the rotated properties of vector fields. This contradicts proposition 5.2 and what we claimed is true.

Step 2: There is $t_r^1\in (0, t_r^0)$ such that $\Gamma _1, \Gamma _2$ coincide or $\Gamma _3$ becomes a semi-stable limit cycle when the other parameters are fixed. In this step, we claim that $t_r^1$ is not small. Otherwise, system (5.2) has more than one limit cycle as $t_r=0$. By [Reference Llibre, Ordóñez and Ponce17], system (5.2) has at most one limit cycle for $t_r=0$. This is a contradiction. We claim that $t_c^1$ keeps in $(h_1, -\varepsilon )$. Otherwise, assume that $t_c^1\leq h_1$. From proposition 5.3 system (5.2) has no limit cycles if $t_c^1\leq h_1$. This is also a contradiction. Then, we turn to step 1 again.

Finally, for arbitrary small $\varepsilon >0$ there exists $n_0\in \mathbb {Z}_+$ such that $|t_c^n|<\varepsilon$ or $t_r^n<\varepsilon$ as $n>n_0$ step by step. We can find that system (5.2) still has at least three limit cycles as $|t_c^n|$ or $t_r^n$ is small, which contradicts proposition 5.3. Therefore, in the parameter region $\mathcal {G}_1$ for $h_1< t_c<-\varepsilon$ system (5.1) has at most two limit cycles. Applying the rotated properties from theorem 2.3, the continuity of vector fields and propositions 5.15.3, there exists a function $t_c=\varphi _1(t_r)$ such that system (5.1) has exactly two limit cycles when $\varphi _1(t_r)< t_c<0$, where the inner limit cycle which only intersects $\Gamma _R$ is unstable and the outer one which intersects $\Gamma _L$ and $\Gamma _R$ is stable; system (5.1) has exactly one semi-stable limit cycle when $t_c=\varphi _1(t_r)$, where the limit cycle which intersects $\Gamma _L$ and $\Gamma _R$ is externally stable; and system (5.1) has no limit cycles when $t_c<\varphi _1(t_r)$. The proof is completed.

Therefore, the exact number of limit cycles of system (5.1) can be obtained completely when parameters lie in regions $\mathcal {G}_1$, $\mathcal {G}_2$, $\mathcal {G}_3$ or $\mathcal {G}_4$ by propositions 5.15.3 and theorem 5.4.

Acknowledgements

This work is financially supported by the National Key R&D Program of China (No. 2022YFA1005900). The first author is supported by the National Natural Science Foundation of China (Nos. 12322109, 12171485) and Science and Technology Innovation Program of Hunan Province (No. 2023RC3040). The second author is supported by the National Natural Science Foundations of China (Nos. 11931016, 12271355, 12161131001). The third author is supported by the National Natural Science Foundation of China (Nos. 12171336, 11831012).

References

di Bernardo, M., Budd, C. J., Champneys, A. R. and Kowalczyk, P.. Piecewise-Smooth Dynamical Systems: Theory and Applications (London: Springer, 2008).Google Scholar
di Bernardo, M., Budd, C. J., Champneys, A. R., Kowalczyk, P., Nordmark, A. B., Tost, G. O. and Piiroinen, P. T.. Bifurcations in nonsmooth dynamical systems. SIAM Rev 50 (2008), 629701.CrossRefGoogle Scholar
Cândido, M. R., Llibre, J. and Valls, C.. Non-existence, existence, and uniqueness of limit cycles for a generalization of the van der Pol–Duffing and the Rayleigh–Duffing oscillators. Phys. D 407 (2020), 132458.CrossRefGoogle Scholar
Chen, H., Llibre, J. and Tang, Y.. Global study of SD oscillator. Nonlinear Dyn. 91 (2018), 17551777.CrossRefGoogle Scholar
Chen, H. and Tang, Y.. At most two limit cycles in a piecewise linear differential system with three zones and asymmetry. Phys. D 386–387 (2019), 2330.CrossRefGoogle Scholar
Chow, S. N. and Hale, J. K.. Methods of Bifurcation Theory (New York: Springer, 1982).CrossRefGoogle Scholar
Chow, S. N., Li, C. and Wang, D.. Normal Forms and Bifurcation of Planar Vector Fields (London: Cambridge University Press, 1994).CrossRefGoogle Scholar
Duff, G. F. D.. Limit cycles and rotated vector fields. Ann. Math 57 (1953), 1531.CrossRefGoogle Scholar
Dumortier, F. and Li, C.. Quadratic Liénard equations with quadratic damping. J. Differ. Equ. 139 (1997), 4159.CrossRefGoogle Scholar
Dumortier, F. and Li, C.. Perturbations from an elliptic Hamiltonian of degree four. II. Cuspidal loop. J. Differ. Equ. 175 (2001), 209243.CrossRefGoogle Scholar
Dumortier, F., Llibre, J. and Artés, J. C.. Qualitative Theory of Planar Differential Systems (New York: Springer, 2006).Google Scholar
Dumortier, F. and Rousseau, C.. Cubic Liénard equations with linear damping. Nonlinearity 3 (1990), 10151039.CrossRefGoogle Scholar
Euzébio, R., Pazim, R. and Ponce, E.. Jump bifurcations in some degenerate planar piecewise linear differential systems with three zones. Physica D 325 (2016), 7485.CrossRefGoogle Scholar
Han, M.. Global behavior of limit cycles in rotated vector fields. J. Differ. Equ. 151 (1999), 2035.CrossRefGoogle Scholar
Kunze, M.. Non-Smooth Dynamical Systems (Berlin: Springer, 2000).CrossRefGoogle Scholar
Kuznetsov, Yu.A., Rinaldi, S. and Gragnani, A.. One-parameter bifurcations in planar Filippov systems. Internat. J. Bifur. Chaos 13 (2003), 21572188.CrossRefGoogle Scholar
Llibre, J., Ordóñez, M. and Ponce, E.. On the existence and uniqueness of limit cycles in planar continuous piecewise linear systems without symmetry. Nonlinear Anal. RWA 14 (2013), 20022012.CrossRefGoogle Scholar
Llibre, J., Ponce, E. and Valls, C.. Uniqueness and non-uniqueness of limit cycles for piecewise linear differential systems with three zones and no symmetry. J. Nonlinear Sci. 25 (2015), 861887.CrossRefGoogle Scholar
Llibre, J., Ponce, E. and Valls, C.. Two limit cycles in Liénard piecewise linear differential systems. J. Nonlinear Sci. 29 (2019), 14991522.CrossRefGoogle Scholar
Perko, L. M.. Rotated vector fields and the global behavior of limit cycles for a class of quadratic systems in the plane. J. Differ. Equ. 18 (1975), 6386.CrossRefGoogle Scholar
Perko, L. M.. Global families of limit cycles of planar analytic systems. Trans. Amer. Math. Soc 322 (1990), 627656.CrossRefGoogle Scholar
Perko, L. M.. A global analysis of the Bogdanov-Takens system. SIAM J. Appl. Math 52 (1992), 11721192.CrossRefGoogle Scholar
Perko, L. M.. Rotated vector fields. J. Differ. Equ. 103 (1993), 127145.CrossRefGoogle Scholar
Perko, L. M.. Homoclinic loop and multiple limit cycle bifurcation surfaces. Trans. Amer. Math. Soc 344 (1994), 101130.CrossRefGoogle Scholar
Perko, L. M.. Multiple limit cycle bifurcation surfaces and global families of multiple limit cycles. J. Differ. Equ. 122 (1995), 89113.CrossRefGoogle Scholar
Perko, L. M.. Differential Equations and Dynamical Systems. 3rd Ed. (New York: Springer, 2002).Google Scholar
Sun, Y. and Liu, C.. The Poincaré Bifurcation of a SD Oscillator. Discrete Contin. Dyn. Syst. Ser. B 26 (2021), 15651577.Google Scholar
Ye, Y.. A qualitative study of the integral curves of a quadratic differential equation, $I$ and $II$. Sci. China Ser. A 3 (1963), 6270.Google Scholar
Ye, Y.. Rotated vector fields decomposition method and its application, Bifurcations of Planar Vector Fields (Luminy, 1989), Lecture Notes in Math. Vol. 1455 (Springer, Berlin, 1990), pp. 385–392.Google Scholar
Zhang, Z., Ding, T., Huang, W. and Dong, Z.. Qualitative Theory of Differential Equations, Transl. Math. Monogr. Vol. 101 (Amer. Math. Soc., Providence, RI, 1992).Google Scholar
Figure 0

Figure 1. The orbits close to limit cycle $\Gamma$ for $\varepsilon >0$.

Figure 1

Figure 2. The curvilinear coordinates in the annulus $S(\Gamma,\varepsilon )$.

Figure 2

Figure 3. The successive function $\varrho (p_0)= \mathcal {P}_1(p_0)- \mathcal {P}_2(p_0)$.

Figure 3

Figure 4. Poincaré map near $O$ in system (2.6).

Figure 4

Figure 5. Impossible cases of homoclinic loops for system (2.6).

Figure 5

Figure 6. Classification of homoclinic loops for system (2.6).