Fuzzy Mittag–Leffler–Hyers–Ulam–Rassias Stability of Stochastic Differential Equations

Chaharpashlou, Reza; Saadati, Reza; Lopes, António M.

doi:10.3390/math11092154

Open AccessArticle

Fuzzy Mittag–Leffler–Hyers–Ulam–Rassias Stability of Stochastic Differential Equations

by

Reza Chaharpashlou

¹

,

Reza Saadati

²

and

António M. Lopes

^3,*

¹

Department of Mathematics, Jundi-Shapur University of Technology, Dezful 64615-334, Iran

²

School of Mathematics, Iran University of Science and Technology, Narmak, Tehran 13114-16846, Iran

³

LAETA/INEGI, Faculty of Engineering, University of Porto, Rua Dr. Roberto Frias, 4200-465 Porto, Portugal

^*

Author to whom correspondence should be addressed.

Mathematics 2023, 11(9), 2154; https://doi.org/10.3390/math11092154

Submission received: 29 March 2023 / Revised: 29 April 2023 / Accepted: 1 May 2023 / Published: 4 May 2023

(This article belongs to the Special Issue Topological Study on Fuzzy Metric Spaces and Their Generalizations)

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Abstract

:

Stability is the most relevant property of dynamical systems. The stability of stochastic differential equations is a challenging and still open problem. In this article, using a fuzzy Mittag–Leffler function, we introduce a new fuzzy controller function to stabilize the stochastic differential equation (SDE)

ν^{^{'}} (γ, μ) = F (γ, μ, ν (γ, μ))

. By adopting the fixed point technique, we are able to prove the fuzzy Mittag–Leffler–Hyers–Ulam–Rassias stability of the SDE.

Keywords:

fuzzy Mittag–Leffler–Hyers–Ulam–Rassiass stability; fuzzy controller function; fuzzy normed space; random operator; stochastic differential equation

MSC:

34D30; 34K20; 60H35

1. Introduction and Mathematical Preliminaries

Morsi [1] used the concepts of Minkowski functionals of L-fuzzy sets and fuzzy metric space to introduce the notion of fuzzy (pseudo) normed spaces. Subsequently, Jäger and Shi [2], using random normed spaces, introduced the fuzzy normed spaces. In the last years, the fuzzy functional analysis and its applications, especially the Hyers–Ulam–Rassias stability [3,4,5] in fuzzy normed spaces, was widely investigated by several authors [6,7]. Furthermore, several fixed-point (

F P

) results were obtained, with applications to nonlinear functional analysis. To learn more about applications of

F P

theory, please see references [8,9,10].

Stability is crucial in any dynamical systems. Specifically, the stability of stochastic differential equations is a challenging and still open problem. In this paper, we consider the stochastic differential equation (

S D E

) of the form:

\begin{matrix} ν^{^{'}} (γ, μ) = F (γ, μ, ν (γ, μ)) . \end{matrix}

(1)

Using a new fuzzy controller function, constructed based on the fuzzy Mittag–Leffler (

F M L

) function, we are able to stabilize the pseudo

S D E

(1). Additionally, by adopting the

F P

technique [11,12,13] we prove the fuzzy Mittag–Leffler–Hyers–Ulam–Rassias (

M L H U S

) stability of the

S D E

[14,15]. Our findings extend and improve some existing results [16,17] by using a new fuzzy controller function that allows studying the

M L H U S

stability of SDEs in fuzzy normed spaces, and by using the alternative of

F P

-theorem [18,19].

In the subsequent analysis, for simplicity, we use the notions:

Π = (0, 1)

,

J = (0, 1]

,

Ω = [0, \infty]

and

Δ = (0, \infty)

.

Definition 1

([9,20,21]). Consider that S is a linear space and that η represents a fuzzy set from

S \times Δ

to J. Then, the ordered pair

(S, η)

is a fuzzy normed (

F N

) space whenever:

(FN1)

η (ζ, τ) = 1

,

\forall τ \in Δ

iff

ζ = 0

;

(FN2)

η (a ζ, τ) = η (ζ, \frac{τ}{| a |})

,

\forall ζ \in S

,

\forall a \in R \ {0}

;

(FN3)

η (ξ + ζ, τ + ς) \geq ⋀ (η (ξ, τ), η (ζ, ς))

,

\forall ξ, ζ \in S

,

\forall τ, ς \in Δ

;

(FN4)

η (ζ, .) : Δ \to J

is continuous.

A complete

F N

space is denoted by

F B

space.

Consider that

(S, ∥ . ∥)

is a linear normed space. If for all

ς \in Δ

η (ζ, ς) = exp (- \frac{∥ ζ ∥}{ς}),

then

(S, η)

is a

F N

-space.

Consider that

(ϝ, Σ, ξ)

is a probability measure space. Assume that

(T, B_{T})

and

(S, B_{S})

are Borel measurable spaces, in which T and S are

F B

spaces. A mapping

F : ϝ \times T \to S

is called a random operator (

R O

) if

{γ : F (γ, ξ) \in B} \in Σ

for all

ξ

in T and

B \in B_{S}

. In addition, F is

R O

if

F (γ, ξ) = ζ (γ)

is a S-valued random variable for every

ξ

in T. A

R O

F : ϝ \times T \to S

is called linear if

F (γ, a ξ_{1} + b ξ_{2}) = a F (γ, ξ_{1}) + b F (γ, ξ_{2})

almost everywhere for each

ξ_{1}, ξ_{2}

in T and

a, b

are scalars, and bounded if there exists a non-negative real-valued random variable

M (γ)

such that

η (F (γ, ξ_{1}) - F (γ, ξ_{2}), M (γ) τ) \geq η (ξ_{1} - ξ_{2}, τ),

almost everywhere for each

ξ_{1}, ξ_{2}

in T,

τ \in Δ

and

γ \in ϝ

.

In this work, we present the

F P

technique, which is the second most popular tool for proving the stability of functional equations [22,23].

Theorem 1

([10]). (The alternative of FP). Assume that

(T, ρ)

is a complete generalized metric space and that

Λ : T \to T

is a strictly contractive function with the Lipschitz constant

ι < 1

. Then, for every

ξ \in T

, either

ρ (Λ^{n} ξ, Λ^{n + 1} ξ) = \infty,

for each

n \in N

, or there is a

n_{0} \in N

for which:

(i)

ρ (Λ^{n} ξ, Λ^{n + 1} ξ) < \infty, \forall n \geq n_{0}

;

(ii) the FP

ξ^{*}

of

Λ

is the convergent point of the sequence

\{Λ^{n} ξ\}

;

(iii) in the set

V = \{ζ \in T ∣ ρ (Λ^{n_{0}} ξ, ζ) < \infty\}

,

ξ^{*}

is the unique FP of

Λ

;

(iv)

(1 - ι) ρ (ζ, ξ^{*}) \leq ρ (ζ, Λ ζ)

for every

ζ \in V

.

Definition 2

([24]). The Mittag–Leffler function is given by the series:

\begin{matrix} E_{q} (μ) = \sum_{k = 0}^{\infty} \frac{μ^{k}}{Γ (q k + 1)}, \end{matrix}

where

q \in C

,

R e (q) > 0

and

Γ (μ)

is a gamma function:

\begin{matrix} Γ (μ) = \int_{0}^{\infty} e^{- t} t^{μ - 1} d t, \end{matrix}

with

R e (μ) > 0

. In particular, if

q = 1

, we get:

\begin{matrix} E_{1} (μ) = \sum_{j = 0}^{\infty} \frac{μ^{j}}{Γ (j + 1)} = \sum_{j = 0}^{\infty} \frac{μ^{j}}{j!} = e^{μ} . \end{matrix}

Using Definition 2, we introduce the

F M L

function as:

\begin{matrix} E_{q} (μ, τ) = \frac{τ}{τ + E_{q} (μ)}, \forall τ > 0 . \end{matrix}

2. Fuzzy MLHUS Stability

The norm

L^{1} (ϝ \times Ξ, S)

is written

η {(., τ)}_{L^{1} (ϝ \times Ξ)}

. We prove the fuzzy

M L H U S

stability for the

S D E

ν^{^{'}} (γ, μ) = F (γ, μ, ν (γ, μ))

.

Theorem 2.

Consider that

c \in R

,

r > 0

,

\begin{matrix} Ξ = \{μ \in R ∣ | μ - c | \leq r\}, \end{matrix}

and

F : ϝ \times Ξ \times R \to R

is a continuous

R O

which satisfies a Lipschitz condition:

\begin{matrix} η (F (γ, μ, ν (γ, μ)) - F (γ, μ, ω (γ, μ)), τ) \geq η (ν - ω, \frac{τ}{L}), \end{matrix}

(2)

for any

μ \in Ξ

,

τ \in Δ

,

γ \in ϝ

and

ν, ω \in R

, where L is a constant with

r L \in Π

. If a continuously differentiable operator

ν : ϝ \times Ξ \to R

satisfies the differential inequality:

\begin{matrix} η (\int_{c}^{μ} [F (γ, ξ, ν (γ, ξ)) - ν^{^{'}} (γ, ξ)] d ξ, τ) \geq E_{q} (μ, τ), \end{matrix}

(3)

for any

μ \in Ξ

,

τ \in Δ

and

γ \in ϝ

, where

E_{q}

is a

F M L

function,

\begin{matrix} inf_{ξ \in Ξ} E_{q} (ξ, \frac{τ}{2 r}) \geq E_{q} (μ, \frac{τ}{r}), \end{matrix}

(4)

for any

μ \in Ξ

,

τ \in Δ

,

γ \in ϝ

, then there exists a unique continuous

R O

ν_{0} : ϝ \times Ξ \to R

such that

\begin{matrix} ν_{0} (γ, μ) = ν (γ, c) + \int_{c}^{μ} F (γ, ξ, ν_{0} (γ, ξ)) d ξ . \end{matrix}

Furthermore,

ν_{0}

is a solution of (1) and

\begin{matrix} η (ν (γ, μ) - ν_{0} (γ, μ), τ) \geq E_{q} (μ, (1 - r L) τ), \end{matrix}

(5)

for any

μ \in Ξ

,

τ \in Δ

,

γ \in ϝ

.

Proof.

Consider the space of continuous ROs

\begin{matrix} Y = \{α : ϝ \times Ξ \to R ∣ α is a continuous R O\} . \end{matrix}

(6)

Introduce the below function on

Y^{2}

as,

\begin{matrix} ρ (α, β) \\ = inf \{λ \in Δ ∣ η (α (γ, μ) - β (γ, μ), τ) \geq E_{q} (μ, \frac{τ}{λ}), \forall μ \in Ξ, τ \in Δ, γ \in ϝ\} . \end{matrix}

(7)

Mihet and Radu [25] proved that

(Y, ρ)

is a complete generalized metric (see also [26]).

We introduce the

R O

Λ : Y \to Y

by:

\begin{matrix} (Λ α) (γ, μ) = ν (γ, c) + \int_{c}^{μ} F (γ, ξ, α (γ, ξ)) d ξ, \end{matrix}

(8)

for every

α \in Y

,

γ \in ϝ

and

μ \in Ξ

. The continuity of

R O

α

implies the continuity of

Λ α

and well-defined

Λ

.

Consider

α, β \in Y

and

γ \in ϝ

. Additionally, consider

λ_{α, β} \in Δ

such that:

\begin{matrix} η (α (γ, μ) - β (γ, μ), τ) \geq E_{q} (μ, \frac{τ}{λ_{α β}}) . \end{matrix}

(9)

Assume that

c = ϖ_{1} < ϖ_{2} < \dots < ϖ_{k} = μ

,

Δ μ_{i} = ϖ_{i} - ϖ_{i - 1} = \frac{| μ - c |}{k}

,

i = 1, 2, \dots, k

, and

∥ Δ μ ∥ = {max}_{1 \leq i \leq k} (Δ μ_{i})

, for every

μ \in Ξ

,

τ \in Δ

and

γ \in ϝ

. Utilizing (2), (4), (8), and (9) we have the following

\begin{matrix} \begin{matrix} η ((Λ α) (γ, μ) - (Λ β) (γ, μ), τ) \\ by equality (8) \\ = η (\int_{c}^{μ} (F (γ, ϖ_{i}, α (γ, ϖ_{i})) - F (γ, ϖ_{i}, β (γ, ϖ_{i}))) d μ, τ) \\ by integral definition \\ = η (lim_{∥ Δ μ ∥ \to 0} \sum_{i = 1}^{k} (F (γ, ϖ_{i}, α (γ, ϖ_{i})) - F (γ, ϖ_{i}, β (γ, ϖ_{i}))) Δ μ_{i}, τ) \\ by continuity property of η \\ = lim_{∥ Δ μ ∥ \to 0} η (\sum_{i = 1}^{k} (F (γ, ϖ_{i}, α (γ, ϖ_{i})) - F (γ, ϖ_{i}, β (γ, ϖ_{i}))) Δ μ_{i}, τ) \\ by triangular inequality \\ \geq lim_{∥ Δ μ ∥ \to 0} ⋀ η ((F (γ, ϖ_{i}, α (γ, ϖ_{i})) - F (γ, ϖ_{i}, β (γ, ϖ_{i}))) Δ μ_{i}, \frac{τ}{k}) \\ by property of infimum \\ \geq inf_{ξ \in Ξ} η ((F (γ, ξ, α (γ, ξ)) - F (γ, ξ, β (γ, ξ))), \frac{τ}{k Δ μ_{i}}) \\ \geq inf_{ξ \in Ξ} η ((F (γ, ξ, α (γ, ξ)) - F (γ, ξ, β (γ, ξ))), \frac{τ}{k ∥ Δ μ ∥}) \\ \geq inf_{ξ \in Ξ} η ((F (γ, ξ, α (γ, ξ)) - F (γ, ξ, β (γ, ξ))), \frac{k τ}{k | μ - c |}) \\ by equality (2) \\ \geq inf_{ξ \in Ξ} η (α (γ, ξ) - β (γ, ξ), \frac{τ}{(2 r L)}) \\ by equality (9) \\ \geq inf_{ξ \in Ξ} E_{q} (ξ, \frac{τ}{(2 r L) λ_{α, β}}) \\ by equality (4) \\ \geq E_{q} (μ, \frac{τ}{(r L) λ_{α, β}}), \end{matrix} \end{matrix}

for every

μ \in Ξ

,

τ \in Δ

and

γ \in ϝ

, that is,

ρ (Λ α, Λ β) \leq (r L) λ_{α, β}

. Therefore, we can conclude that

ρ (Λ α, Λ β) \leq (r L) ρ (α, β)

for any

α, β \in Y

, in which

(r L) \in Π

. Therefore,

Λ

is a strictly contraction mapping.

By (3), (5), (8), and

ν \in Y

, we obtain:

\begin{matrix} \begin{matrix} η ((Λ ν) (γ, μ) - ν (γ, μ), τ) \\ by equality (8) \\ = η (ν (γ, c) + \int_{c}^{μ} F (γ, ξ, ν (γ, ξ)) d ξ - ν (γ, μ), τ) \\ by property of integral \\ = η (\int_{c}^{μ} [F (γ, ξ, ν (γ, ξ)) - ν^{'} (γ, ξ)] d ξ, τ) \\ by equality (3) \\ \geq E_{q} (μ, \frac{τ}{1}), \end{matrix} \end{matrix}

for any

μ \in Ξ

,

τ \in Δ

and

γ \in ϝ

. Thus, (7) implies that

\begin{matrix} ρ (Λ ν, ν) < 1, \end{matrix}

(10)

and hence,

\begin{matrix} ρ (Λ^{n + 1} ν, Λ^{n} ν) < 1 < \infty . \end{matrix}

Now, Theorem 1 implies that:

(i) there is a continuous

R O

ν_{0} : ϝ \times Ξ \to R

where

Λ ν_{0} = ν_{0}

, that is,

ν_{0}

is

F P

of

Λ

, which is uniqu in the set

V = {α \in Y : ρ (α, ν) < \infty} .

(ii)

Λ^{n} ν \to ν_{0}

in

(Y, ρ)

as

n \to \infty

.

(iii) using (10) we obtain:

\begin{matrix} ρ (ν, ν_{0}) \leq \frac{1}{1 - r L} ρ (Λ ν, ν) \leq \frac{1}{1 - r L}, \end{matrix}

which implies the validity of (5) for each

μ \in Ξ

,

τ \in Δ

and

γ \in ϝ

. □

Consider that

(Y, η)

is a

F N

space. We introduce the fuzzy set

η_{B}

as:

\begin{matrix} η_{B} (α (γ, ξ), τ) : = inf_{ξ \in Ξ} \{η (α (γ, ξ), \frac{τ}{e^{θ ξ}}) : θ \in Δ, Ξ \subset R_{+}\}, \end{matrix}

for every

μ \in Ξ

,

τ \in Δ

and

γ \in ϝ

. Then,

(Y, η_{B})

is a

F N

space (Bielecki

F N

space). In fact, (FN1), (FN2), and (FN4) are obvious. Now, we prove only (FN3). Observe that:

\begin{matrix} ⋀ (η_{B} (α (γ, ξ), τ), η_{B} (β (γ, ξ), ς)) \\ = & ⋀ (inf_{ξ \in Ξ} \{η (α (γ, ξ), \frac{τ}{e^{θ ξ}})\}, inf_{ξ \in Ξ} \{η (β (γ, ξ), \frac{ς}{e^{θ ξ}})\}) \\ \leq & ⋀ (inf_{ξ \in Ξ} \{η (α (γ, ξ), \frac{τ}{e^{θ ξ}}), η (β (γ, ξ), \frac{ς}{e^{θ ξ}})\}) \\ \leq & inf_{ξ \in Ξ} \{η ((α + β) (γ, ξ), \frac{(τ + ς)}{e^{θ ξ}})\} \\ = & inf_{ξ \in Ξ} \{η ((α + β) (γ, ξ), \frac{(τ + ς)}{e^{θ ξ}})\} \\ = & η_{B} ((α + β) (γ, ξ), (τ + ς)), \end{matrix}

for any

μ \in Ξ

,

τ \in Δ

and

γ \in ϝ

, which proves the triangle inequality (FN3).

Now, we prove the fuzzy

M L H U S

stability of the random Equation (1) via the Bielecki fuzzy norm.

Theorem 3.

Assume that

c \in R

,

r > 0

and

Ξ = \{μ \in R ∣ | μ - c | \leq r\}

. Consider that

F : ϝ \times Ξ \times R \to R

is a continuous

R O

which satisfies in the Lipschitz condition:

\begin{matrix} η (F (γ, μ, ν (γ, μ)) - F (γ, μ, ω (γ, μ)), τ) \geq η (ν - ω, \frac{τ}{L}), \end{matrix}

for any

μ \in Ξ

,

τ \in Δ

,

γ \in ϝ

and where L is a constant with

r L \in Π

. If a continuously differentiable function

ν : ϝ \times Ξ \to R

satisfies the differential inequality:

\begin{matrix} η (\int_{c}^{μ} [F (γ, ξ, ν (γ, ξ)) - ν^{^{'}} (γ, ξ)] d ξ, τ) \geq E_{q} (μ, τ), \end{matrix}

for any

μ \in Ξ

,

τ \in Δ

and

γ \in ϝ

, where

E_{q}

is a

F M L

function; then, with the Bielecki fuzzy norm, the fuzzy

M L H U S

stability is verified for the Equation (1).

Proof.

By the same method used in the proof of Theorem 2, we assume that

c = ϖ_{1} < ϖ_{2} < \dots < ϖ_{k} = μ

,

Δ μ_{i} = ϖ_{i} - ϖ_{i - 1} = \frac{| μ - c |}{k}

,

i = 1, 2, \dots, k

and

∥ Δ μ ∥ = {max}_{1 \leq i \leq k} (Δ μ_{i})

. Now, we show the contraction of

Λ

on

Y

with respect to the Bielecki fuzzy norm introduced in (6):

\begin{matrix} \begin{matrix} η ((Λ α) (γ, μ) - (Λ β) (γ, μ), τ) \\ by equality (8) \\ = η (\int_{c}^{μ} (F (γ, ϖ_{i}, α (γ, ϖ_{i})) - F (γ, ϖ_{i}, β (γ, ϖ_{i}))) d μ, τ) \\ by integral definition \\ = η (lim_{∥ Δ μ ∥ \to 0} \sum_{i = 1}^{k} (F (γ, ϖ_{i}, α (γ, ϖ_{i})) - F (γ, ϖ_{i}, β (γ, ϖ_{i}))) Δ μ_{i}, τ) \\ by continuity property of η \\ = lim_{∥ Δ μ ∥ \to 0} η (\sum_{i = 1}^{k} (F (γ, ϖ_{i}, α (γ, ϖ_{i})) - F (γ, ϖ_{i}, β (γ, ϖ_{i}))) Δ μ_{i}, τ) \\ by triangular inequality \\ \geq lim_{∥ Δ μ ∥ \to 0} ⋀ η ((F (γ, ϖ_{i}, α (γ, ϖ_{i})) - F (γ, ϖ_{i}, β (γ, ϖ_{i}))) Δ μ_{i}, \frac{τ}{k}) \\ by property of infimum \\ \geq inf_{ξ \in Ξ} η ((F (γ, ξ, α (γ, ξ)) - F (γ, ξ, β (γ, ξ))), \frac{τ}{k Δ μ_{i}}) \\ \geq inf_{ξ \in Ξ} η ((F (γ, ξ, α (γ, ξ)) - F (γ, ξ, β (γ, ξ))), \frac{τ}{k ∥ Δ μ ∥}) \\ \geq inf_{ξ \in Ξ} η ((F (γ, ξ, α (γ, ξ)) - F (γ, ξ, β (γ, ξ))), \frac{k τ}{k | μ - c |}) \\ by equality (2) \\ \geq inf_{ξ \in Ξ} η (α (γ, ξ) - β (γ, ξ), \frac{τ}{(r L)}) \\ \geq inf_{ξ \in Ξ} η (α (γ, ξ) - β (γ, ξ), \frac{τ}{(r L) e^{θ ξ}}) \\ by definition η_{B} \\ \geq η_{B} (α - β, \frac{τ}{(r L)}) . \end{matrix} \end{matrix}

then,

\begin{matrix} η ((Λ α) (γ, μ) - (Λ β) (γ, μ), τ) \geq η_{B} (α - β, \frac{τ}{(r L)}), \end{matrix}

for any

μ \in Ξ

,

τ \in Δ

,

γ \in ϝ

, that is,

ρ (Λ α, Λ β) \leq η_{B} (α - β, \frac{τ}{(r L)})

. Hence, we can conclude that

ρ (Λ α, Λ β) \leq (r L) ρ (α, β)

for any

α, β \in Y

. By letting

(r L) \in Π

, we obtain the strict continuity. Furthermore, by Theorem 1, we obtain:

\begin{matrix} ρ (ν, ν_{0}) \leq \frac{1}{1 - r L} ρ (Λ ν, ν) \leq \frac{1}{1 - r L}, \end{matrix}

so, the fuzzy

M L H U S

stability of Equation (1) is verified. □

Theorem 4.

Suppose that a and b are real numbers such that

a < b

. Let

Ξ = [a, b]

and

c \in Ξ

. Assume that K and L are positive constants such that

L K \in Π

. Consider that

F : ϝ \times Ξ \times R \to R

is a continuous

R O

which satisfies a Lipschitz condition:

\begin{matrix} η (F (γ, μ, ν) - F (γ, μ, ω), τ) \geq η (ν - ω, \frac{τ}{L}), \end{matrix}

(11)

for any

μ \in Ξ

,

τ \in Δ

,

γ \in ϝ

and

ν, ω \in R

. If a continuously differentiable operator

ν : ϝ \times Ξ \to R

satisfies the differential inequality:

\begin{matrix} η (\int_{0}^{μ} [F (γ, ξ, ν (γ, ξ)) - ν^{^{'}} (γ, ξ)] d ξ, τ) \geq E_{q} (μ, τ), \end{matrix}

(12)

for any

μ \in Ξ

,

τ \in Δ

and

γ \in ϝ

, where

E_{q}

is a

F M L

function,

\begin{matrix} inf_{ξ \in Ξ} E_{q} (ξ, \frac{τ}{(b - a)}) \geq E_{q} (μ, \frac{τ}{K}), \end{matrix}

(13)

for any

μ \in Ξ

,

τ \in Δ

,

γ \in ϝ

, then there exists a unique continuous

R O

ν_{0} : ϝ \times Ξ \to R

such that:

\begin{matrix} ν_{0} (γ, μ) = ν (γ, c) + \int_{0}^{μ} F (γ, ξ, ν_{0} (γ, ξ)) d ξ . \end{matrix}

Furthermore,

ν_{0}

is a solution of (1) and

\begin{matrix} η (ν (γ, μ) - ν_{0} (γ, μ), τ) \geq E_{q} (μ, (1 - r L) τ), \end{matrix}

for any

μ \in Ξ

,

τ \in Δ

,

γ \in ϝ

.

Proof.

Consider the space of continuous ROs:

\begin{matrix} Y = \{α : ϝ \times Ξ \to R ∣ α is a continuous R O\} . \end{matrix}

Introduce the below function on

Y^{2}

as,

\begin{matrix} ρ (α, β) = inf \{λ \in Δ ∣ η (α (γ, μ) - β (γ, μ), τ) \geq E_{q} (μ, \frac{τ}{λ}), \forall μ \in Ξ, τ \in Δ, γ \in ϝ\} . \end{matrix}

(14)

Further, introduce the

R O

Λ : Y \to Y

by:

\begin{matrix} (Λ α) (γ, μ) = ν (γ, c) + \int_{0}^{μ} F (μ, ξ, α (γ, ξ)) d ξ, \end{matrix}

(15)

for every

α \in Y

,

γ \in ϝ

and

μ \in Ξ

. The continuity of

R O

α

implies the continuity of

Λ α

and well defining

Λ

.

Consider

α, β \in Y

and

γ \in ϝ

. Let

λ_{α, β} \in Δ

such that:

\begin{matrix} η (α (γ, μ) - β (γ, μ), τ) \geq E_{q} (μ, \frac{τ}{λ_{α, β}}) . \end{matrix}

(16)

In addition, let

a = ϖ_{1} < ϖ_{2} < \dots < ϖ_{k} = b

,

Δ μ_{i} = ϖ_{i} - ϖ_{i - 1} = \frac{b - a}{k}

,

i = 1, 2, \dots, k

and

∥ Δ μ ∥ = {max}_{1 \leq i \leq k} (Δ μ_{i})

, for every

μ \in Ξ

,

τ \in Δ

and

γ \in ϝ

. Utilizing (11), (13), (14) and (15) we have the following

\begin{matrix} \begin{matrix} η ((Λ α) (γ, μ) - (Λ β) (γ, μ), τ) \\ by equality (15) \\ = η (\int_{0}^{μ} (F (γ, ϖ_{i}, α (γ, ϖ_{i})) - F (γ, ϖ_{i}, β (γ, ϖ_{i}))) d μ, τ) \\ by integral definition \\ = η (lim_{∥ Δ μ ∥ \to 0} \sum_{i = 1}^{k} (F (γ, ϖ_{i}, α (γ, ϖ_{i})) - F (γ, ϖ_{i}, β (γ, ϖ_{i}))) Δ μ_{i}, τ) \\ by continuity property of η \\ = lim_{∥ Δ μ ∥ \to 0} η (\sum_{i = 1}^{k} (F (γ, ϖ_{i}, α (γ, ϖ_{i})) - F (γ, ϖ_{i}, β (γ, ϖ_{i}))) Δ μ_{i}, τ) \\ by triangular inequality \\ \geq lim_{∥ Δ μ ∥ \to 0} ⋀ η ((F (γ, ϖ_{i}, α (γ, ϖ_{i})) - F (γ, ϖ_{i}, β (γ, ϖ_{i}))) Δ μ_{i}, \frac{τ}{k}) \\ by property of infimum \\ \geq inf_{ξ \in Ξ} η ((F (γ, ϖ_{i}, α (γ, ϖ_{i})) - F (γ, ϖ_{i}, β (γ, ϖ_{i}))), \frac{τ}{k Δ μ_{i}}) \\ \geq inf_{ξ \in Ξ} η ((F (γ, ϖ_{i}, α (γ, ϖ_{i})) - F (γ, ϖ_{i}, β (γ, ϖ_{i}))), \frac{τ}{k ∥ Δ μ ∥}) \\ \geq inf_{ξ \in Ξ} η ((F (γ, ϖ_{i}, α (γ, ϖ_{i})) - F (γ, ϖ_{i}, β (γ, ϖ_{i}))), \frac{k τ}{k (b - a)}) \\ by equality (11) \\ \geq inf_{ξ \in Ξ} η (α (γ, ξ) - β (γ, ξ), \frac{τ}{L (b - a)}) \\ by equality (16) \\ \geq inf_{ξ \in Ξ} E_{q} (ξ, \frac{τ}{L (b - a) λ_{α, β}}) \\ by equality (13) \\ \geq E_{q} (μ, \frac{τ}{L K λ_{α, β}}), \end{matrix} \end{matrix}

for any

μ \in Ξ

,

τ \in Δ

and

γ \in ϝ

, that is,

ρ (Λ α, Λ β) \leq (L K) λ_{α, β}

. Hence, we can conclude that

ρ (Λ α, Λ β) \leq (L K) ρ (α, β)

for all

α, β \in Y

, in which

(L K) \in Π

. Therefore,

Λ

is a strict contraction mapping.

By (3), (5), (7) and

ν \in Y

, we obtain:

\begin{matrix} \begin{matrix} η ((Λ ν) (γ, μ) - ν (γ, μ), τ) \\ by equality (15) \\ = η (ν (γ, c) + \int_{c}^{μ} F (γ, ξ, ν (γ, ξ)) d ξ - ν (γ, μ), τ) \\ by property of integral \\ = η (\int_{c}^{μ} [F (γ, ξ, ν (γ, ξ)) - ν^{'} (γ, ξ)] d ξ, τ) \\ by equality (12) \\ \geq E_{q} (μ, \frac{τ}{1}), \end{matrix} \end{matrix}

for any

μ \in Ξ

,

τ \in Δ

and

γ \in ϝ

. Thus, (7) implies that:

\begin{matrix} ρ (Λ ν, ν) < 1, \end{matrix}

(17)

and hence,

\begin{matrix} ρ (Λ^{n + 1} ν, Λ^{n} ν) < 1 < \infty . \end{matrix}

Now, Theorem 1 implies that:

(i) there is a continuous

R O

ν_{0} : ϝ \times Ξ \to R

where

Λ ν_{0} = ν_{0}

, that is,

ν_{0}

is

F P

of

Λ

, which is unique in the set

V = {α \in Y : ρ (α, ν) < \infty} .

(ii)

Λ^{n} ν \to ν_{0}

in

(Y, ρ)

as

n \to \infty

.

(iii) using (17) we obtain:

\begin{matrix} ρ (ν, ν_{0}) \leq \frac{1}{1 - r L} ρ (Λ ν, ν) \leq \frac{1}{1 - r L}, \end{matrix}

which implies the validity of (5) for each

μ \in Ξ

,

τ \in Δ

and

γ \in ϝ

. □

3. Application

Example 1.

Consider positive real numbers K and L such that

L K \in Π

,

K < \frac{b (b - a)}{a}

. Assume that

Ξ = [a, b]

. For an arbitrary polynomial

p (γ, μ)

, we let a continuously differentiable

R O

ν : ϝ \times Ξ \to R

to satisfy:

\begin{matrix} η (\int_{0}^{μ} [F (γ, ξ, ν (γ, ξ)) - ν^{^{'}} (γ, ξ)] d ξ, τ) \geq E_{q} (μ, τ), \end{matrix}

for any

μ \in Ξ

,

τ \in Δ

and

γ \in ϝ

. If we set

F (γ, μ, ν) = L ν (γ, μ) + p (γ, μ)

, where

E_{q}

is a

F M L

function,

\begin{matrix} inf_{ξ \in Ξ} E_{q} (ξ, \frac{τ}{(b - a)}) \geq E_{q} (μ, \frac{τ}{K}), \end{matrix}

for any

μ \in Ξ

,

τ \in Δ

and

γ \in ϝ

, then, by Theorem 4, there is a unique continuous

R O

ν_{0} : ϝ \times Ξ \to R

such that:

\begin{matrix} ν_{0} (γ, μ) = ν (γ, 0) + \int_{0}^{μ} (L ν (γ, ξ) + p (γ, ξ)) d ξ, \end{matrix}

and

\begin{matrix} η (ν (γ, μ) - ν_{0} (γ, μ), τ) \geq E_{q} (μ, (1 - r L) τ), \end{matrix}

for any

μ \in Ξ

,

τ \in Δ

and

γ \in ϝ

.

Example 2.

Consider that r and L are positive constants with

r L \in Π

and

Ξ = \{μ \in R ∣ | μ - c | \leq r, for some c \in R\} .

Let a continuous discrete random function

ν : ϝ \times Ξ \to R

satisfy the following inequality:

\begin{matrix} η (\int_{c}^{μ} [F (γ, ξ, ν (γ, ξ)) - ν^{^{'}} (γ, ξ)] d ξ, τ) \geq E_{q} (μ, τ), \end{matrix}

for any

μ \in Ξ

,

τ \in Δ

and

γ \in ϝ

, where

p (γ, μ)

is a polynomial. If we set

F (γ, μ, ν) = L ν (γ, μ) + p (γ, μ)

, where

E_{q}

is a

F M L

function,

\begin{matrix} inf_{ξ \in Ξ} E_{q} (ξ, \frac{τ}{2 r}) \geq E_{q} (μ, \frac{τ}{r}), \end{matrix}

for any

μ \in Ξ

,

τ \in Δ

,

γ \in ϝ

, then, by Theorem 2 there exists a unique random operator

ν_{0} : ϝ \times Ξ \to R

such that:

\begin{matrix} ν_{0} (γ, μ) = ν (γ, 0) + \int_{0}^{μ} (L ν (γ, ξ) + p (γ, ξ)) d ξ, \end{matrix}

and

\begin{matrix} η (ν (γ, μ) - ν_{0} (γ, μ), τ) \geq E_{q} (μ, (1 - r L) τ), \end{matrix}

for any

μ \in Ξ

,

τ \in Δ

and

γ \in ϝ

.

4. Conclusions

In this paper we introduced a new fuzzy controller function to stabilize the

S D E

of the form

ν^{^{'}} (γ, μ) = F (γ, μ, ν (γ, μ))

. By adopting the

F P

technique, we proved the fuzzy

M L H U S

stability of the

S D E

. Some examples were given to illustrate the theoretical findings and to show the effectiveness of the method. Extension of the method to SDEs of different types will be further investigated.

Author Contributions

Conceptualization, R.C.; Methodology, R.C., R.S.; Formal analysis, R.C., R.S. and A.M.L.; Investigation, R.C., R.S. and A.M.L.; Writing—original draft, R.C.; Writing—review & editing, R.C., R.S. and A.M.L.; Funding acquisition, A.M.L. All authors have read and agreed to the published version of the manuscript.

Funding

This research received no external funding.

Data Availability Statement

No new data were created.

Conflicts of Interest

The authors declare no conflict of interest.

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Chaharpashlou, R.; Saadati, R.; Lopes, A.M. Fuzzy Mittag–Leffler–Hyers–Ulam–Rassias Stability of Stochastic Differential Equations. Mathematics 2023, 11, 2154. https://doi.org/10.3390/math11092154

AMA Style

Chaharpashlou R, Saadati R, Lopes AM. Fuzzy Mittag–Leffler–Hyers–Ulam–Rassias Stability of Stochastic Differential Equations. Mathematics. 2023; 11(9):2154. https://doi.org/10.3390/math11092154

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Chaharpashlou, Reza, Reza Saadati, and António M. Lopes. 2023. "Fuzzy Mittag–Leffler–Hyers–Ulam–Rassias Stability of Stochastic Differential Equations" Mathematics 11, no. 9: 2154. https://doi.org/10.3390/math11092154

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Fuzzy Mittag–Leffler–Hyers–Ulam–Rassias Stability of Stochastic Differential Equations

Abstract

1. Introduction and Mathematical Preliminaries

2. Fuzzy MLHUS Stability

3. Application

4. Conclusions

Author Contributions

Funding

Data Availability Statement

Conflicts of Interest

References

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