Partial asymptotic stability of neutral pantograph stochastic differential equations with Markovian switching

In this paper, we investigate the partial asymptotic stability (PAS) of neutral pantograph stochastic differential equations with Markovian switching (NPSDEwMSs). The main tools used to show the results are the Lyapunov method and the stochastic calculus techniques. We discuss a numerical example to illustrate our main results.

Neutral stochastic delay differential equations with and without Markovian switching have been recently intensively investigated (see [1, 10, 11, 13, 14, 19, 20, 22], and [23]). Many systems are often subject to component repairs or failures, abrupt changes, environmental disturbances, and subsystem interconnections. The pantograph SDEs (PSDEs) have been widely used in electrodynamics and quantum mechanics. In the last decades the stability analysis of stochastic differential equations (SDEs) has received much attention (see [2, 3, 7–9, 15, 18, 25]). In general, due to the characteristics and specifications of SDEs themselves, it is difficult to obtain explicit solutions of equations. Therefore we use the Lyapunov method to study the stability and the asymptotic behavior of solutions. The almost sure polynomial and exponential stabilities were investigated by many researchers (see [2, 3], and [7–9]). The stochastic pantograph differential equations are a kind of stochastic delay differential equations (see [4, 7–9]), also called equations with proportional delay. They play an important role in industrial and mathematical problems. The NPSDEwMS are very well investigated (see [4, 25], and [17]). In [4] the authors proved the existence, uniqueness, and p-moment stability of solutions in the case \(p>0\). However, in many dynamical systems, such a stability is usually too strong to be satisfied. Therefore the notion of partial stability (PS) (see [5, 6, 12], and [16]) has been studied, and the Lyapunov method, as an important tool, has been used to investigate the PS in various practically important domains. In the literature, we did not find any result on PAS of NPSDEwMS. Using the technique of stochastic calculus and Lyapunov method, we show a new sufficient condition for the PS of a class of NPSDEwMS.

In [5] and [12] the authors investigated the PAS of the solutions of ordinary SDEs by using an appropriate Lyapunov function satisfying some specific properties. In our paper, we prove the PAS of solutions of NPSDEwMSs. In this sense, our results extend the analysis in [5] and [12] providing the neutral term and the delay in the case of the PSDE with Markovian switching.

Let us outline the framework of this paper. After preliminaries and notations (see Sect. 1), in Sect. 2, we recall some important notions and definitions. In Sect. 3, we establish the PAS for a class of NPSDEwMSs. Finally, in Sect. 4, we present a numerical example to show the applicability of our results.

Let \(\{\Omega ,\mathcal{F}, (\mathcal{F}_{s})_{s\geq 0},\mathbb{P}\}\) be a complete probability space with filtration \(\{\mathcal{F}_{s}\}_{s\geq 0}\) satisfying the usual conditions, and let \(W(s)\) be an m-dimensional Brownian motion defined on this probability space. Let \(s\geq s_{0}>0\), let \(C([qs_{0}, s_{0}];\mathbb{R}^{n})= \{ \psi :[qt_{0}, s_{0}] \rightarrow \mathbb{R}^{n} \text{such that} \psi \text{is a continuous function} \} \) with the norm \(\|\psi \|= \sup_{qs_{0}\leq b\leq s_{0}}|\psi (b)|\), and let \(|x|=\sqrt{x^{T}x}\) for \(x \in \mathbb{R}^{n}\). If B is a matrix, then its trace norm is denoted by \(|B| =\sqrt{\operatorname{Trace}(B^{T}B)}\), and its norm is given by \({\|B\| = \sup_{|x| = 1}|Bx|}\). Denote by \(L^{p}_{\mathcal{F}_{s_{0}}}([qs_{0}, s_{0}];\mathbb{R}^{n})\) the set of all \(\mathcal{F}_{s_{0}}\)-measurable \(C([qs_{0}, s_{0}];\mathbb{R}^{n})\)-valued random variables \(\psi = \{\psi (\theta ) : qs_{0}\leq \theta \leq s_{0}\}\) such that \(E\|\psi \|^{p}<\infty \), where \(p \in \mathbb{N}^{*}\).

Let \(\{m(s), s\geq 0 \}\) be a right-continuous Markov chain on \(\{\Omega ,\mathcal{F}, (\mathcal{F}_{s})_{s\geq 0},\mathbb{P}\}\) taking values in a finite state space \(\bar{S} = \{1,2,3,\dots ,N\}\), where \(\Gamma = (\gamma _{jk} )_{\mathbb{N}\times \mathbb{N}}\) is the generator given by

for \(\varpi >0\). Here \(\gamma _{jk}\geq 0\) is the transition rate from j to k if \(j \neq k\), whereas

We suppose that r and W are independent.

Consider the following NPSDEwMS:

with initial data \(\zeta \in L^{p}_{\mathcal{F}_{s_{0}}}([qs_{0}, s_{0}];\mathbb{R}^{n})\), i.e.,

Let \(u(s) = z(s)-G(s,z(qs), m(s))\), where \(G(s,z(qs), m(s))=(G_{1}(s,z(qs), m(s)),G_{2}(s,z(qs), m(s)))^{T}\in \mathbb{R}^{n}\). We assume that

Let \(z= (z_{1},z_{2} )^{T}\in \mathbb{R}^{n}\) be the solution of equation (2.1), where \(z_{1}\in \mathbb{R}^{k}\) and \(z_{2}\in \mathbb{R}^{p}\), and \(k+p=n\).

We will impose the following assumptions on f, g, and G:

(\(\mathcal{A}_{1}\)) For each \(l\in \mathbb{N}^{*}\), there exists \(k_{l}>0\) such that

(\(\mathcal{A}_{2}\)) For all \((s,j)\in [s_{0},+\infty )\times \bar{S} \) and \(\varsigma ,x\in \mathbb{R}^{n}\), there exists \(\kappa _{j}\in (0,1)\) such that

Set \(G(s,0,j)=0\) and \(\kappa =\max_{j\in \bar{S}}\kappa _{j}\).

Let \(C^{1,2} ([qs_{0},+\infty )\times \mathbb{R}^{n}\times \bar{S}; \mathbb{R}^{+} )\) be the set of all nonnegative functions \(V(s, z, j)\) on \([qs_{0},+\infty )\times \mathbb{R}^{n}\times \bar{S}\) that are once continuously differentiable with respect to s and twice continuously differentiable with respect to z.

For any \((s,z,v,j)\in [qs_{0},+\infty )\times \mathbb{R}^{n}\times \mathbb{R}^{n} \times S\), \(u = z-G(s,v,j)\), by the generalized Itô formula (see [18] and [24]) we have

where the stochastic process \(M(s)\) and the operator \(\mathcal{L}V(s,z,v,i):[qs_{0},+\infty )\times \mathbb{R}^{n}\times \mathbb{R}^{n}\times \bar{S}\rightarrow \mathbb{R}\) are defined by

(\(\mathcal{A}_{3}\)) There exist functions \(\mu _{1}\), \(\mu _{2}\), \(\mu _{3}\), \(\mu _{4}\) in \(\mathcal{K}\) and \(V\in C^{1,2} (\mathbb{R}_{+}\times \mathbb{R}^{n}\times \bar{S} ; \mathbb{R}_{+} )\) satisfying, for all \((s,z,v,j)\in [s_{0},+\infty )\times \mathbb{R}^{n}\times \mathbb{R}^{n} \times \bar{S}\),

1. (i)

   \(\mu _{1} (|z_{1}| )\leq V (s,z,j )\leq \mu _{2} (|z_{1}| )\),

2. (ii)

   \(LV ( s,z,v,j )\leq - \mu _{3} (|z_{1}| )+q \mu _{4} (|v_{1}| )\).

We discuss the PS in probability and PAS of equation (2.1).

Definition 3.1

1. (i)

   The solution \(z(s)= (z_{1}(s),z_{2}(s) )\) of equation (2.1) is called PS in probability with respect to \(z_{1}\) if for all \(\eta >0\) and \(\lambda \in (0,1)\), there exists \(\delta _{0}=\delta _{0}(\lambda ,\eta ,s_{0})>0\) such that

   $$ P \bigl( \bigl\vert z_{1}(s) \bigr\vert < \eta , \forall s\geq s_{0} \bigr) \geq 1-\lambda $$

   whenever \(\|\zeta \|<\delta _{0}\).

2. (ii)

   The solution \(z(s)= (z_{1}(s),z_{2}(s) )\) of equation (2.1) is called PAS in probability with respect to \(z_{1}\) if it is stable in probability with respect to \(z_{1}\) and for all \(\zeta \in L^{p}_{\mathcal{F}_{s_{0}}}([qs_{0}, s_{0}];\mathbb{R}^{n})\), we have

   $$ P \Bigl(\lim_{s\to +\infty }z_{1}(s)=0 \Bigr)=1. $$

Let \(\mathcal{K}\) be the set of all continuous nondecreasing functions \(\mu :\mathbb{R}_{+}\rightarrow \mathbb{R}_{+}\) such that \(\mu (0)=0\) and \(\mu (\nu )>0\) for \(\nu >0\). For \(H>0\), let \(S_{H}= \{ z\in \mathbb{R}^{n}, \vert z_{1} \vert < H \} \).

Theorem 3.1

Suppose that there exist a function \(V(s,z,j)\in C^{1,2} ([s_{0},+\infty )\times S_{H}\times S; \mathbb{R}_{+} )\) and \(\mu \in \mathcal{K}\) such that

1. (i)

   \(\mu ( \vert z_{1} \vert )\leq V(s,z,j)\) for all \((s,z)\in [s_{0},+\infty )\times S_{H}\),

2. (ii)

   \(\mathcal{L}V(s,z,v,j)\leq 0\) for all \((s,z)\in [s_{0},+\infty )\times S_{H}\).

Then the solution of equation (2.1) is PS in probability with respect to \(z_{1}\).

Proof

By Assumptions (\(\mathcal{A}_{1}\))–(\(\mathcal{A}_{3}\)) system (2.1) has a unique global solution \(z(s)\) for \(s\geq s_{0}\) (see [17]).

Let \(\lambda \in (0,1)\) and \(\eta >0\) be arbitrary. We will assume that \(\eta < H\). By the continuity of \(V(s,z,j)\) and the fact \(V(s_{0},0,m(s_{0}))=0\) we can find \(\rho =\rho (\lambda ,\eta ,s_{0})>0\) such that

We can see that \(\rho <\eta \). Fix an arbitrary initial condition \(\zeta \in L^{p}_{\mathcal{F}_{s_{0}}}([qs_{0}, s_{0}];\mathbb{R}^{n})\) such that \(\|\zeta \|<\rho \). Let ϑ be the stopping time given by

By the Itô formula, for every \(s\geq s_{0}\), we have

Using (ii) and equation (3.1), we obtain that

Notice that if \(\vartheta \leq s\), then

Then by (i) we have

Using (3.2) and (3.3), we obtain \(P (\vartheta \leq s )\leq \lambda \). Letting \(s\to +\infty \), we have \(P (\vartheta \leq \infty )\leq \lambda \), which implies

and the proof is completed. □

(\(\mathcal{A}_{4}\)) There exist positive constants \(\alpha _{1}\) and p and functions \(\mu _{2}\), \(\mu _{3}\), \(\mu _{4}\) in \(\mathcal{K}\) and \(V\in C^{1,2} (\mathbb{R}_{+}\times \mathbb{R}^{n}\times \bar{S} ; \mathbb{R}_{+} )\) satisfying, for all \((s,z,v,j)\in [s_{0},+\infty )\times \mathbb{R}^{n}\times \mathbb{R}^{n} \times \bar{S}\),

1. (i)

   \(\alpha _{1}|z_{1}|^{p}\leq V (s,z,j )\leq \mu _{2} (|z_{1}| )\),

2. (ii)

   \(LV ( s,z,v,j )\leq - \mu _{3} (|z_{1}| )+q \mu _{4} (|v_{1}| )\).

Theorem 3.2

Suppose that assumptions (\(\mathcal{A}_{1}\)), (\(\mathcal{A}_{2}\)), and (\(\mathcal{A}_{4}\)) hold. Let \(\mu _{3}\) and \(\mu _{4}\) in \(\mathcal{K}\) satisfy, for all \((s,z)\in [s_{0},+\infty )\times \mathbb{R}^{n}\),

where \({\mu _{3}-\mu _{4}}\) is an increasing function. Then, for any initial value \(\zeta \in L^{p}_{\mathcal{F}_{s_{0}}}([qs_{0}, s_{0}];\mathbb{R}^{n})\), the solution of equation (2.1) is PAS in probability with respect to \(z_{1}\).

Proof

We will proceed as in the proof of Theorem 3.1 in [23] with necessary changes.

By Theorem 3.1 it is easy to prove that equation (2.1) is stable in probability with respect to \(z_{1}\).

Step 1. Fix \(\zeta \in L^{p}_{\mathcal{F}_{s_{0}}}([qs_{0}, s_{0}];\mathbb{R}^{n})\) and \(i_{0}\in \bar{S}\). By the Itô formula, (i), (ii), and (3.4) we have

where

is a continuous local martingale with \(M(s_{0})=0\) a.s. Applying Lemma 2.5 in [17] and taking \(\chi =\mu _{2}(|u(s_{0})|)+\mu _{4}(\|\zeta \|)s_{0}(1-q)\), \(A(s)=0\), \({N(s)=\int _{s_{0}}^{s} (\mu _{3}(|z_{1}(\tau )|)- \mu _{4}(|z_{1}(\tau )|) )\,d\tau ,}\) and \(M(s)=\int _{s_{0}}^{s}V_{z}(\tau ,u(\tau ),m(\tau ))g( \tau ,z(\tau ),z(q\tau ),m(\tau ))\,dW(\tau )\), we have

Then

Thus using (3.4), (3.7), and (i) (in Assumption (\(\mathcal{A}_{4}\))), we obtain

For \(T>0\), by Assumption (\(\mathcal{A}_{2}\)), for \(s_{0}\leq s\leq T\), we have

It then follows that

Thus

Using (3.8) and letting \(T\rightarrow \infty \), we have

Thus taking the expectations of both sides of (3.5) and letting \(s\rightarrow +\infty \), we have

This implies that

Step 2. Set \(\mu =\mu _{3}-\mu _{4}\) (\(\mu \in C(\mathbb{R}_{+},\mathbb{R}_{+})\)). By (3.11) we can see that (see [15])

Now we claim that

If (3.13) is false, then

Thus there exists a positive constant λ such that

with \(\Gamma _{1}= \{ \limsup_{s\rightarrow +\infty }\mu (|z_{1}(s)|)>2 \lambda \} \). By (3.9) and using the fact \(\Vert \zeta \Vert <\infty \), we can find \(h=h(\lambda )>0\) sufficiently large such that

where \(\Gamma _{2}= \{ \sup_{qs_{0}\leq s<\infty } (|z_{1}(s)|<h ) \} \). Using (3.14) and (3.15), we have

Now we define the following stopping times:

By the definitions of \(\Gamma _{1}\) and \(\Gamma _{2}\) and (3.12) we can see that if \(\omega \in \Gamma _{1}\cap \Gamma _{2}\), then

Since \(\vartheta _{2k}<\infty \) whenever \(\vartheta _{2k-1}<\infty \), by (3.10) we obtain that

In fact, by assumption (\(\mathcal{A}_{1}\)) there exists \(k_{h}>0\) such that

whenever \((s,j)\in [s_{0},+\infty )\times \bar{S}\) and \(|z|\vee |v|\leq h\). Using the Hölder and Doob martingale inequalities, we have that for \(k=1,2,3,\dots \) and \(T>0\),

We know that if μ is a continuous function in \(\mathbb{R}^{n}\), then it is uniformly continuous in \(\overline{B}_{h}= \{ z\in \mathbb{R}^{n} : \vert z \vert \leq h \} \). Thus we can choose sufficiently small \(\varphi =\varphi (\lambda )>0\) such that

Set \(T=T(\lambda ,\varphi ,h)>0\) sufficiently small such that \({\frac{2k_{h}T(T+4)}{\varphi ^{2}}<\lambda }\). By (3.19) we have

We can see that

Then we obtain

Using (3.16) and (3.17), we deduce

Therefore by (3.20) we have

Set \(\overline{M}_{k}= \{ \sup_{s_{0}\leq s\leq T} \vert \mu (z_{1}( \vartheta _{2k-1}+s)) -\mu (z_{1}(\vartheta _{2k-1})) \vert < \lambda \} \). Notice that if \(\omega \in \{ \vartheta _{2k-1}<\infty , \vartheta _{h}= \infty \} \cap \overline{M}_{k}\), then

By (3.18) and (3.21) we can derive that

which is impossible. Then (3.13) holds.

Step 3. By (3.9) and (3.13) there is \(\Omega _{0}\subset \Omega \) with \(P (\Omega _{0} )=1\) such that for all \(\omega \in \Omega _{0}\),

Now we must show that

If we suppose that (3.23) is false, then there is \(\hat{\omega }\in \Omega _{0}\) such that \({\lim_{s\rightarrow +\infty }\sup |z_{1}(s,\hat{\omega })|>0}\). Thus there exist subsequences \(\{ z_{1}(s_{k},\hat{\omega }) \} _{k\geq 0}\) of \(\{ z_{1}(s,\hat{\omega }) \} _{s\geq s_{0}}\) satisfying \(\vert z_{1}(s_{k},\hat{\omega }) \vert >\bar{\alpha }\) for some \(\bar{\alpha }>0\) and all \(k\geq 0\). Since \(\{ z_{1}(s_{k},\hat{\omega }) \} _{k\geq 0}\) is bounded, we can find an increasing subsequence \(\{ \hat{s}_{k} \} _{k\geq 0}\) such that \(\{ z_{1}(\hat{s}_{k},\omega ) \} _{k\geq 0}\) converges to some \(\bar{z}\in \mathbb{R}^{n}\) such that \(|\bar{z}|>\bar{\alpha }\). Therefore \({\mu (|\bar{z}| )=\lim_{k\rightarrow \infty }\mu (|z_{1}(s_{k},\omega )| )>0}\). However, by (3.22) we have \(\mu (|\bar{z}| )=0\), a contradiction.

Consequently, the solution of system (2.1) is asymptotically stable in probability with respect to \(z_{1}\). □

We will state a theorem about the asymptotic instability with respect to all variables of NPSDEwMS.

Definition 4.1

The solution \(z(s)= (z_{1}(s),z_{2}(s) )\) of equation (2.1) is called asymptotically unstable in probability if it is unstable in probability or for all \(\zeta \in L^{p}_{\mathcal{F}_{s_{0}}}([qs_{0}, s_{0}];\mathbb{R}^{n})\),

Theorem 4.1

Suppose that there exist a function \(V\in C^{1,2} (\mathbb{R}_{+}\times \mathbb{R}^{n}\times \bar{S} ; \mathbb{R}_{+} )\) and \(\mu _{1}\), \(\mu _{2}\), \(\mu _{3}\), and \(\mu _{4}\) in \(\mathcal{K}\) such that for all \((s,z,v,j)\in [s_{0},+\infty )\times \mathbb{R}^{n}\times \mathbb{R}^{n} \times \bar{S}\),

1. (i)

   \(\mu _{1} (|z| )\leq V (s,z,j )\leq \mu _{2} (|z| )\),

2. (ii)

   \(\mathcal{L}V ( s,z,v,j )\geq - \mu _{3} (|z| )+q \mu _{4} (|v| )\).

Then for any initial value \(\zeta \in L^{p}_{\mathcal{F}_{s_{0}}}([qs_{0}, s_{0}];\mathbb{R}^{n})\), the solution of equation (2.1) is asymptotically unstable in probability.

Proof

The proof is similar to that of Theorem 4.3 in [6]. □

We now give a numerical example to illustrate the application of our results.

Let \(W(s)\) be a three-dimensional Brownian motion. Let \(m(s)\) be a right-continuous Markov chain taking values in \(\bar{S} = \{ 1,2,3 \} \) with \(\Gamma = (\gamma _{jk} )_{1\leq j,k\leq 3}\) given by

Moreover, we assume that \(W(s)\) and \(m(s)\) are independent. Consider the following NPSDEwMS:

with initial data \(\zeta (s)\). Moreover, for \((s,z,v,j)\in [s_{0},+\infty )\times \mathbb{R}^{3}\times \mathbb{R}^{3} \times \bar{S}\), let

Let \(V(s,z,j)=z_{1}^{2}+z_{2}^{2}+z_{3}^{2}\) for \(j\in \bar{S}\). Then for \(j=1\), we have

For \(j=2\), it follows that

For \(j=3\), we deduce

Thus for \(j\in \bar{S}\), we obtain

Therefore by Theorem 4.1, system (5.1) is asymptotically unstable with respect to all variables.

For \(j\in \bar{S}\), we define \(V_{1}\) by

For \(j=1\), we have

For \(j=2\), we derive

For \(j=3\), we deduce

Then for \(j\in \bar{S}\), it follows that

Consequently, by Theorem 3.2 system (5.1) is asymptotically stable with respect to \(z_{3}\) with \(\mu _{1}(|z_{3}|)=4.38z_{3}^{2}\) and \(\mu _{2}(|v_{3}|)=3.88v_{3}^{2}\).

For system (5.1), we conduct a simulation using the Euler–Maruyama scheme with step size 0.001, \(q=0.35\), \(s_{0}=1\), and the linear initial function \(\zeta (s)= (s,-s,s-1 )\) for \(0.35\leq s\leq 1\). Next, we provide the simulations for system (5.1). In Fig. 1, we show the stability of the component \(z_{3}\) by simulation of its trajectories. In Fig. 2, we illustrate the instability of the components \(z_{1}\) and \(z_{2}\).

Simulations of the trajectory of \(z_{3}(s)\) in system (5.1) with \(\zeta _{3}(s)=s-1\) for \(s\in [0.35,5\times 10^{4}]\)

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Simulations of the trajectories of the components \(z_{1}(s)\) and \(z_{2}(s)\) with \(\zeta _{1}(s)=s\) and \(\zeta _{2}(s)=-s\) on \([0.35,5\times 10^{4}]\)

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The simulation results clearly show that the trajectories of the corresponding stochastic system converge asymptotically to the equilibrium state for any given initial values, thus verifying the effectiveness of theoretical results.

Not applicable.

The research of T. Caraballo has been supported by FEDER and the Spanish Ministerio de Ciencia, Innovación y Universidades under the project PGC2018-096540-B-I00, and Junta de Andalucía (Spain) under the FEDER projects US-1254251 and P18-FR-4509. Lassaad Mchiri and Mohamed Rhaima extend their appreciation to the Deanship of Scientific Research at King Saud University for funding this work through research group (No. RG-1441-328).

T. Caraballo acknowledges the FEDER and the Spanish Ministerio de Ciencia, Innovación y Universidades under the project PGC2018-096540-B-I00 and Junta de Andalucía (Spain) under the FEDER projects US-1254251 and P18-FR-4509.

Authors and Affiliations

1. Department of Statistics and Operation Research, College of Sciences, King Saud University, P.O. Box 2455, Z.C., 11451, Riyadh, Kingdom of Saudi Arabia

   Lassaad Mchiri & Mohamed Rhaima

2. Dpto. Ecuaciones Diferenciales y Análisis Numérico, Facultad de Matemáticas, Universidad de Sevilla, c/ Tarfia s/n, 41012, Sevilla, Spain

   Tomás Caraballo

3. Department of Mathematics, Faculty of Sciences of Tunis, University of Tunis El Manar, Tunis, Tunisia

   Mohamed Rhaima

Contributions

LM and TC carried out the problem and gave the instructions while writing the paper. LM and TC deduced the mathematical computation and theorems involved and wrote the manuscript. MR has done the numerical simulations and wrote the manuscript. All authors read and approved the final manuscript.

Corresponding author

Correspondence to Lassaad Mchiri.

Competing interests

The authors declare that they have no competing interests.

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