Stability Results for Some Classes of Cubic Functional Equations

El-hady, El-sayed; Sayyari, Yamin; Dehghanian, Mehdi; Alruwaily, Ymnah

doi:10.3390/axioms13070480

Open AccessArticle

Stability Results for Some Classes of Cubic Functional Equations

¹

Mathematics Department, College of Science, Jouf University, Sakaka P.O. Box 2014, Saudi Arabia

²

Department of Mathematics, Sirjan University of Technology, Sirjan 7813733385, Iran

^*

Authors to whom correspondence should be addressed.

Axioms 2024, 13(7), 480; https://doi.org/10.3390/axioms13070480

Submission received: 4 June 2024 / Revised: 2 July 2024 / Accepted: 5 July 2024 / Published: 18 July 2024

(This article belongs to the Special Issue Difference, Functional, and Related Equations)

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Abstract

:

Applications involving functional equations (FUEQs) are commonplace. They are essential to various applications, such as fog computing. Ulam’s notion of stability is highly helpful since it provides a range of estimates between exact and approximate solutions. Using Brzdȩk’s fixed point technique (FPT), we establish the stability of the following cubic type functional equations (CFUEQs):

F (\sqrt[3]{ξ_{1}^{3} + ξ_{2}^{3}}) + F (\sqrt[3]{ξ_{1}^{3} - ξ_{2}^{3}}) = 2 F (ξ_{1}) + 2 F (ξ_{2}),

2 F (\sqrt[3]{\frac{ξ_{1}^{3} + ξ_{2}^{3}}{2}}) = F (ξ_{1}) + F (ξ_{2})

for all

ξ_{1}, ξ_{2} \in R

.

Keywords:

Jensen cubic functional equation; fixed point theory; quadratic cubic functional equation; stability

MSC:

39B22; 47H10

1. Introduction

Functional equations (FUEQs) are widely used in a variety of fascinating contexts; see, e.g., [1,2,3]. Their applicability and inherent mathematical elegance make the theory of FUEQs attractive. FUEQs are crucial in a wide range of applications, providing an effective means of refining the models used to analyze different phenomena.

The concept of stability was introduced by Ulam [4], followed by Hyers [5,6], and it has been widely studied in mathematics and FUEQs. There is some connection between it and the topics covered in other branches of mathematics, such as shadowing (see [7]), approximation theory, and optimization. It concerns various equations (functional, differential, integral, difference, etc.), in order to determine how much an equation’s approximate answer and its exact solution vary from one another. This topic has inspired many papers, and we refer the reader to [6,8,9,10,11] for further information on this subject.

In addition, many researchers have studied the stabilities of Drygas [12,13], the Pexiderized additive-quadratic equation (see [14]), the Frechet FUEQ [15], radical FUEQs [16,17,18], the quadratic FUEQ [19,20,21], and systems of FUEQs [22,23].

Many investigations on stability have been conducted in recent years, using various techniques to generate results that have been used for various functional inequalities, FUEQs, derivations, antiderivatives, and homomorphisms (see [24,25,26,27,28]).

In this work, applying the Brzdȩk FPT, we determine the stability results of the quadratic CFUEQ

F (\sqrt[3]{ξ_{1}^{3} + ξ_{2}^{3}}) + F (\sqrt[3]{ξ_{1}^{3} - ξ_{2}^{3}}) = 2 F (ξ_{1}) + 2 F (ξ_{2})

(1)

and the Jensen CFUEQ

2 F (\sqrt[3]{\frac{ξ_{1}^{3} + ξ_{2}^{3}}{2}}) = F (ξ_{1}) + F (ξ_{2})

(2)

for all

ξ_{1}, ξ_{2} \in R

.

For example, the function

F : R \to R

given by

F (ξ_{1}) = c ξ_{1}^{6}

is a solution of (1), and

F (ξ_{1}) = c ξ_{1}^{3}

is a solution of (2), where c is a constant.

In 2011, Brzdȩk et al. [29] gave a simple FPT. Before presenting the Brzdȩk FPT, let us introduce some hypotheses, which we use in this work.

H1.

A is a nonempty set, and E is a Banach space.

H2.

σ_{1}, \dots, σ_{k} : A \to A

and

λ_{1}, \dots, λ_{k} : A \to R_{+}

are given maps.

H3.

T : E^{A} \to E^{A}

is an operator satisfying the inequality

\begin{matrix} ∥ T f (ξ_{1}) - T g (ξ_{1}) ∥ \leq \sum_{i = 1}^{k} λ_{i} (ξ_{1}) ∥ f (σ_{i} (ξ_{1})) - g (σ_{i} (ξ_{1})) ∥ \end{matrix},

for all

f, g : A \to E

and

ξ_{1} \in A

.

H4.

Δ : R_{+}^{A} \to R_{+}^{A}

is a linear operator defined by

\begin{matrix} Δ μ (ξ_{1}) : = \sum_{i = 1}^{k} λ_{i} (ξ_{1}) μ (σ_{i} (ξ_{1})) \end{matrix},

for

μ : A \to R_{+}

and

ξ_{1} \in A

.

Theorem 1

([29]). Suppose that (H1)–(H4) are satisfied. Assume that there are functions

θ : A \to R_{+}

and

ψ : A \to E

:

\forall ξ_{1} \in A

, such that

\begin{matrix} ∥ T ψ (ξ_{1}) - ψ (ξ_{1}) ∥ \leq θ (ξ_{1}) and θ^{*} (ξ_{1}) : = \sum_{n = 0}^{\infty} Δ^{n} θ (ξ_{1}) < \infty \end{matrix}

hold. Then, for all

ξ_{1} \in A

, the limit

\begin{matrix} S (ξ_{1}) : = lim_{n \to \infty} T^{n} ψ (ξ_{1}) \end{matrix}

exists, and the function

S : A \to E

, so defined, is a unique FP of

T

with

\begin{matrix} ∥ ψ (ξ_{1}) - S (ξ_{1}) ∥ \leq θ^{*} (ξ_{1}), \end{matrix}

\forall ξ_{1} \in A

.

2. Preliminaries

We use this section to recall some interesting stability results of the CFUEQs. The following FE is considered the oldest CFUEQ, introduced by Rassias (see [30]),

Π (a + 2 b) + 3 Π (a) = 3 Π (a + b) + Π (a - b) + 6 Π (b) .

In [31], the authors investigated the general solution and the generalized Hyers–Ulam–Rassias stability for the following CFUEQ:

Π (2 a + b) + Π (2 a - b) = 2 Π (a + b) + 2 Π (a - b) + 12 Π (a) .

We highlight the papers [30,32] concerning the stability of the CFUEQ.

In this work, suppose that E is a Banach space, and

N_{0} = N \cup {0}

.

3. Stability of (1)

Applying the Brzdȩk FPT, we determine the stability of (1).

Theorem 2.

Suppose that a function

F : R \to E

satisfies

∥F (\sqrt[3]{ξ_{1}^{3} + ξ_{2}^{3}}) + F (\sqrt[3]{ξ_{1}^{3} - ξ_{2}^{3}}) - 2 F (ξ_{1}) - 2 F (ξ_{2})∥ \leq δ (| ξ_{1} |^{p} + {| ξ_{2} |}^{p})

(3)

for some

δ, p \geq 0

,

p \neq 6

, and all

ξ_{1}, ξ_{2} \in R

. Then, there exists a unique function

Q : R \to E

satisfying the quadratic CFUEQ on

R

with

\begin{matrix} ∥ F (ξ_{1}) - Q (ξ_{1}) ∥ \leq \frac{2 δ}{|{(\sqrt[3]{2})}^{p} - 4|} {| ξ_{1} |}^{p} \end{matrix}

\forall ξ_{1} \in R

.

Proof.

Setting

ξ_{1} = ξ_{2} = 0

in (3), we obtain

F (0) = 0

. For the case

p < 6

, replacing

ξ_{2}

by

ξ_{1}

in (3), we obtain

∥F (ξ_{1}) - \frac{1}{4} F (\sqrt[3]{2} ξ_{1})∥ \leq \frac{δ}{2} {| ξ_{1} |}^{p},

(4)

\forall ξ_{1} \in R

. Let

T : E^{R} \to E^{R}

and

θ : R \to R_{+}

be defined by

\begin{matrix} T f (ξ_{1}) = \frac{1}{4} f (\sqrt[3]{2} ξ_{1}), f \in E^{R}, \end{matrix}

and

θ (ξ_{1}) = \frac{δ}{2} {| ξ_{1} |}^{p}

\forall ξ_{1} \in R

. Thus, we can write (4) as

∥ T F (ξ_{1}) - F (ξ_{1}) ∥ \leq θ (ξ_{1})

\forall ξ_{1} \in R

. So,

\begin{matrix} ∥ T f (ξ_{1}) - T g (ξ_{1}) ∥ \leq \frac{1}{4} ∥f (\sqrt[3]{2} ξ_{1}) - g (\sqrt[3]{2} ξ_{1})∥, \end{matrix}

\forall f, g \in E^{R}

and

ξ_{1} \in R

. Hence

T : E^{R} \to E^{R}

satisfies the condition (H3) with

λ_{1} (ξ_{1}) = \frac{1}{4}

and

σ_{1} (ξ_{1}) = \sqrt[3]{2} ξ_{1}

. By (H4), the operator

Δ : R_{+}^{R} \to R_{+}^{R}

is defined by

\begin{matrix} Δ μ (ξ_{1}) = \frac{1}{4} μ (\sqrt[3]{2} ξ_{1}), μ \in R_{+}^{R}, \end{matrix}

\forall ξ_{1} \in R

. Hence,

\begin{matrix} Δ θ (ξ_{1}) = \frac{1}{4} θ (\sqrt[3]{2} ξ_{1}) = \frac{2^{\frac{p}{3}}}{4} θ (ξ_{1}), θ \in R_{+}^{R}, \end{matrix}

\forall ξ_{1} \in R

. Using induction and linearity

Δ

, it follows that

\begin{matrix} Δ^{m} θ (ξ_{1}) = {(\frac{2^{\frac{p}{3}}}{4})}^{m} θ (ξ_{1}), m \in N_{0}, \end{matrix}

\forall ξ_{1} \in R

. Hence, the series

\sum_{m = 0}^{\infty} Δ^{m} θ (ξ_{1})

is convergent to

\begin{matrix} θ^{*} (ξ_{1}) = \sum_{m = 0}^{\infty} Δ^{m} θ (ξ_{1}) = \frac{2 δ}{4 - {(\sqrt[3]{2})}^{p}} {| ξ_{1} |}^{p}, \end{matrix}

\forall ξ_{1} \in R

and

p < 6

. Using Theorem 1, there is a function

Q : R \to E

, such that

\begin{matrix} Q (ξ_{1}) = lim_{n \to \infty} T^{n} F (ξ_{1}), Q (ξ_{1}) = \frac{1}{4} Q (\sqrt[3]{2} ξ_{1}), \end{matrix}

and

\begin{matrix} ∥ F (ξ_{1}) - Q (ξ_{1}) ∥ \leq \frac{2 δ}{4 - {(\sqrt[3]{2})}^{p}} {| ξ_{1} |}^{p}, \end{matrix}

\forall ξ_{1} \in R

. From (3), we arrive at

\begin{matrix} ∥T F (\sqrt[3]{ξ_{1}^{3} + ξ_{2}^{3}}) + T F (\sqrt[3]{ξ_{1}^{3} - ξ_{2}^{3}}) - 2 T F (ξ_{1}) - 2 T F (ξ_{2})∥ \\ \leq \frac{1}{4} ∥F (\sqrt[3]{2 ξ_{1}^{3} + 2 ξ_{2}^{3}}) + F (\sqrt[3]{2 ξ_{1}^{3} - 2 ξ_{2}^{3}}) - 2 F (\sqrt[3]{2} ξ_{1}) - 2 F (\sqrt[3]{2} ξ_{2})∥ \\ \leq \frac{{(\sqrt[3]{2})}^{p} δ}{4} (| ξ_{1} |^{p} + {| ξ_{2} |}^{p}), \end{matrix}

\forall ξ_{1}, ξ_{2} \in R

. By induction on

m \in N_{0}

, we obtain

\begin{matrix} ∥T^{m} F (\sqrt[3]{ξ_{1}^{3} + ξ_{2}^{3}}) + T^{m} F (\sqrt[3]{ξ_{1}^{3} - ξ_{2}^{3}}) - 2 T^{m} F (ξ_{1}) - 2 T^{m} F (ξ_{2})∥ \\ \leq δ {(\frac{{(\sqrt[3]{2})}^{p}}{4})}^{m} (| ξ_{1} |^{p} + {| ξ_{2} |}^{p}), \end{matrix}

\forall ξ_{1}, ξ_{2} \in R

. This yields

\begin{matrix} Q (\sqrt[3]{ξ_{1}^{3} + ξ_{2}^{3}}) + Q (\sqrt[3]{ξ_{1}^{3} - ξ_{2}^{3}}) = 2 Q (ξ_{1}) + 2 Q (ξ_{2}), \end{matrix}

\forall ξ_{1}, ξ_{2} \in R

. For

p > 6

, replacing

ξ_{1}

and

ξ_{2}

by

\frac{x}{\sqrt[3]{2}}

in (3), we have

\begin{matrix} ∥ F (ξ_{1}) - 4 F (\frac{ξ_{1}}{\sqrt[3]{2}}) ∥ \leq \frac{2 δ}{{(\sqrt[3]{2})}^{p}} {| ξ_{1} |}^{p}, \end{matrix}

(5)

\forall ξ_{1} \in R

. Define

T : E^{R} \to E^{R}

and

θ : R \to R_{+}

by

\begin{matrix} T f (ξ_{1}) = 4 f (\frac{x}{\sqrt[3]{2}}) and θ (ξ_{1}) = \frac{2 δ}{{(\sqrt[3]{2})}^{p}} {| ξ_{1} |}^{p}, \end{matrix}

\forall ξ_{1} \in R

. So, we can write (5) as

∥ T F (ξ_{1}) - F (ξ_{1}) ∥ \leq θ (ξ_{1})

\forall ξ_{1} \in R

. Therefore,

\begin{matrix} ∥ T f (ξ_{1}) - T g (ξ_{1}) ∥ \leq 4 ∥f (\frac{ξ_{1}}{\sqrt[3]{2}}) - g (\frac{ξ_{1}}{\sqrt[3]{2}})∥, \end{matrix}

\forall f, g \in E^{R}

and

ξ_{1} \in R

. We apply Theorem 1 with

λ_{1} (ξ_{1}) = 4

,

σ_{1} (ξ_{1}) = \frac{ξ_{1}}{\sqrt[3]{2}}

and

Δ : R_{+}^{R} \to R_{+}^{R}

by

\begin{matrix} Δ μ (ξ_{1}) = 4 μ (\frac{ξ_{1}}{\sqrt[3]{2}}), μ \in R_{+}^{R}, \end{matrix}

\forall ξ_{1} \in R

. Accordingly,

\begin{matrix} Δ θ (ξ_{1}) = 4 θ (\frac{ξ_{1}}{\sqrt[3]{2}}) = \frac{4}{{(\sqrt[3]{2})}^{p}} θ (ξ_{1}), θ \in R_{+}^{R}, \end{matrix}

\forall ξ_{1} \in R

; thus,

\begin{matrix} Δ^{m} θ (ξ_{1}) = {(\frac{4}{{(\sqrt[3]{2})}^{p}})}^{m} θ (ξ_{1}), \end{matrix}

\forall ξ_{1} \in R

and

m \in N_{0}

. Since

p > 6

,

\begin{matrix} θ^{*} (ξ_{1}) : = \sum_{m = 0}^{\infty} Δ^{m} θ (ξ_{1}) = \frac{2 δ}{{(\sqrt[3]{2})}^{p} - 4} {| ξ_{1} |}^{p}, \end{matrix}

\forall ξ_{1} \in R

. Using Theorem 1, there exists a function

Q : R \to E

, such that

\begin{matrix} Q (ξ_{1}) = lim_{n \to \infty} T^{n} F (ξ_{1}), Q (ξ_{1}) = 4 Q (\frac{ξ_{1}}{\sqrt[3]{2}}), \end{matrix}

and

\begin{matrix} ∥ Q (ξ_{1}) - F (ξ_{1}) ∥ \leq \frac{2 δ}{{(\sqrt[3]{2})}^{p} - 4} {| ξ_{1} |}^{p}, \end{matrix}

\forall ξ_{1} \in R

.

Similar to the previous case, it can be easily shown that

Q

satisfies FE (1).

Finally, we prove, only for case

p < 6

, that

Q

is unique. The proof of the case

p > 6

is similar to the proof of the case

p < 6

.

Suppose that

Q_{1}, Q_{2} : R \to E

satisfy the quadratic CFUEQs on

R

and

\begin{matrix} ∥ Q_{1} (ξ_{1}) - F (ξ_{1}) ∥ \leq δ_{1} | ξ_{1} |^{p}, ∥ Q_{2} (ξ_{1}) - F (ξ_{1}) ∥ \leq δ_{2} {| ξ_{1} |}^{p}, \end{matrix}

for some

δ_{1}, δ_{2} \geq 0

and for all

ξ_{1} \in R

. Thus,

\begin{matrix} ∥ Q_{1} (ξ_{1}) - Q_{2} (ξ_{1}) ∥ \leq (δ_{1} + δ_{2}) {| ξ_{1} |}^{p}, \end{matrix}

\forall ξ_{1} \in R

. Hence,

\begin{matrix} Q_{1} (ξ_{1}) = \frac{1}{4} Q_{1} (\sqrt[3]{2} ξ_{1}), Q_{2} (ξ_{1}) = \frac{1}{4} Q_{2} (\sqrt[3]{2} ξ_{1}), \end{matrix}

\forall ξ_{1} \in R

. Therefore,

\begin{matrix} ∥ Q_{1} (ξ_{1}) - Q_{2} (ξ_{1}) ∥ \leq \frac{1}{4} ∥Q_{1} (\sqrt[3]{2} ξ_{1}) - Q_{2} (\sqrt[3]{2} ξ_{1})∥ \leq \frac{{(\sqrt[3]{2})}^{p}}{4} (δ_{1} + δ_{2}) {| ξ_{1} |}^{p} \end{matrix},

\forall ξ_{1} \in R

. By induction on

m \in N_{0}

, we see that

\begin{matrix} ∥ Q_{1} (ξ_{1}) - Q_{2} (ξ_{1}) ∥ \leq {(\frac{{(\sqrt[3]{2})}^{p}}{4})}^{m} (δ_{1} + δ_{2}) {| ξ_{1} |}^{p} \end{matrix},

which tends to 0 as

m \to \infty

for all

ξ_{1} \in R

. This implies

Q_{1} (ξ_{1}) = Q_{2} (ξ_{1})

\forall ξ_{1} \in R

. □

In the following example, we prove that, for

p = 6

, the quadratic CFUEQ is not stable.

Example 1.

Let

ψ : R \to R

be defined by

\begin{matrix} ψ (ξ_{1}) = & \{\begin{matrix} ξ_{1}^{6} & | ξ_{1} | < 1 \\ 1 & | ξ_{1} | \geq 1 \end{matrix} \end{matrix},

and suppose that

F : R \to R

is defined by

\begin{matrix} F (ξ_{1}) = \sum_{n = 0}^{\infty} \frac{ψ (2^{\frac{n}{3}} ξ_{1})}{4^{n}}, \end{matrix}

for all

ξ_{1} \in R

. We prove that

|F (\sqrt[3]{ξ_{1}^{3} + ξ_{2}^{3}}) + F (\sqrt[3]{ξ_{1}^{3} - ξ_{2}^{3}}) - 2 F (ξ_{1}) - 2 F (ξ_{2})| \leq 32 (ξ_{1}^{6} + ξ_{2}^{6}),

\forall ξ_{1}, ξ_{2} \in R

; but, there is no constant

k \geq 0

and no function

Q : R \to R

satisfying (1), and

\begin{matrix} |F (ξ_{1}) - Q (ξ_{1})| \leq k ξ_{1}^{6} \end{matrix},

\forall ξ_{1} \in R

.

Proof.

Clearly, we see that

| F (ξ_{1}) | \leq \frac{4}{3}

, for all

ξ_{1} \in R

. Now, we consider the two following cases.

Case 1: If

ξ_{1}, ξ_{2} \in R

and

ξ_{1}^{6} + ξ_{2}^{6} \geq \frac{1}{4}

, then

\begin{matrix} |F (\sqrt[3]{ξ_{1}^{3} + ξ_{2}^{3}}) + F (\sqrt[3]{ξ_{1}^{3} - ξ_{2}^{3}}) - 2 F (ξ_{1}) - 2 F (ξ_{2})| \leq 8 \leq 32 (ξ_{1}^{6} + ξ_{2}^{6}) . \end{matrix}

Case 2: Suppose that

ξ_{1}, ξ_{2} \in R

and

ξ_{1}^{6} + ξ_{2}^{6} < \frac{1}{4}

; hence,

ξ_{1}^{6} - ξ_{2}^{6} < \frac{1}{4}

,

ξ_{1}^{6} < \frac{1}{4}

, and

ξ_{2}^{6} < \frac{1}{4}

. Then, there exists

N \in N

, such that

\begin{matrix} \frac{1}{4^{N + 1}} \leq ξ_{1}^{6} + ξ_{2}^{6} < \frac{1}{4^{N}} . \end{matrix}

Therefore,

2^{n} (ξ_{1}^{6} + ξ_{2}^{6}) < 1

,

|2^{n} (ξ_{1}^{6} - ξ_{2}^{6})| < 1

,

2^{n} ξ_{1}^{6} < 1

, and

2^{n} ξ_{2}^{6} < 1

, for all

n = 0, 1, \dots, N - 1 .

Hence,

\begin{matrix} |F (\sqrt[3]{ξ_{1}^{3} + ξ_{2}^{3}}) + F (\sqrt[3]{ξ_{1}^{3} - ξ_{2}^{3}}) - 2 F (ξ_{1}) - 2 F (ξ_{2})| \\ = |\sum_{n = 0}^{\infty} \frac{ψ (2^{\frac{n}{3}} \sqrt[3]{ξ_{1}^{3} + ξ_{2}^{3}})}{4^{n}} + \sum_{n = 0}^{\infty} \frac{ψ (2^{\frac{n}{3}} \sqrt[3]{ξ_{1}^{3} - ξ_{2}^{3}})}{4^{n}} - 2 \sum_{n = 0}^{\infty} \frac{ψ (2^{\frac{n}{3}} ξ_{1})}{4^{n}} - 2 \sum_{n = 0}^{\infty} \frac{ψ (2^{\frac{n}{3}} ξ_{2})}{4^{n}}| \\ \leq 6 \sum_{n = N}^{\infty} \frac{1}{4^{n}} = \frac{2}{4^{N - 1}} \leq 32 (ξ_{1}^{6} + ξ_{2}^{6}), \end{matrix}

for all

ξ_{1}, ξ_{2} \in R

.

Suppose that there exists a constant

k \geq 0

and a function

Q : R \to R

satisfying (1) with

\begin{matrix} |F (ξ_{1}) - Q (ξ_{1})| \leq k ξ_{1}^{6} \end{matrix},

(6)

for all

ξ_{1} \in R

. Hence,

|Q (ξ_{1})| \leq k ξ_{1}^{6} + \frac{4}{3}

, for all

ξ_{1} \in R

. Substituting

2^{\frac{n}{3}} ξ_{1}

in the place of

ξ_{1}

in the above inequality yields

\begin{matrix} |Q (2^{\frac{n}{3}} ξ_{1})| \leq 4^{n} k ξ_{1}^{6} + \frac{4}{3} \end{matrix},

for all

ξ_{1} \in R

. Dividing the expression obtained by

4^{n}

, we obtain

\begin{matrix} |\frac{1}{4^{n}} Q (2^{\frac{n}{3}} ξ_{1})| \leq k ξ_{1}^{6} + \frac{1}{3 \times 4^{n - 1}} \end{matrix},

(7)

for all

ξ_{1} \in R

and all

n \in N

. Since

Q (ξ_{1}) = \frac{1}{4^{n}} Q (2^{\frac{n}{3}} ξ_{1})

, for all

ξ_{1} \in R

and

n \in N

,

\begin{matrix} |Q (ξ_{1})| \leq k ξ_{1}^{6} \end{matrix},

(8)

for all

ξ_{1} \in R

. From (6) and (8), we have

\begin{matrix} |\frac{F (ξ_{1})}{ξ_{1}^{6}}| \leq 2 k \end{matrix},

for all

ξ_{1} \in R

.

Choose

N \in N

, such that

N > 2 k

, and take

ξ_{1} > 0

with

ξ_{1} < \frac{1}{2^{\frac{N - 1}{3}}}

. Thus,

2^{\frac{n}{3}} ξ_{1} < 1

for

n = 0, 1, \dots, N - 1

, and

\begin{matrix} F (ξ_{1}) = \sum_{n = 0}^{N - 1} \frac{ψ (2^{\frac{n}{3}} ξ_{1})}{4^{n}} + \sum_{n = N}^{\infty} \frac{ψ (2^{\frac{n}{3}} ξ_{1})}{4^{n}} \geq N ξ_{1}^{6} \end{matrix},

which implies

\begin{matrix} \frac{F (ξ_{1})}{ξ_{1}^{6}} \geq N > 2 k \end{matrix},

which is a contradiction. □

4. Stability of the Jensen Cubic Functional Equation

Using the Brzdȩk FPT we determine the stability of the Jensen CFUEQs (2) for

⋂ p > 3

.

Theorem 3.

Assume that E is a Banach space. Suppose that there is a function

h : R \to E

satisfying

∥2 F (\sqrt[3]{\frac{ξ_{1}^{3} + ξ_{2}^{3}}{2}}) - F (ξ_{1}) - F (ξ_{2})∥ \leq δ (| ξ_{1} |^{p} + {| ξ_{2} |}^{p}),

(9)

for some

δ \geq 0

,

p > 3

and all

ξ_{1}, ξ_{2} \in R

. Then, there exists a unique function

J : R \to E

satisfying the Jensen CFUEQs on

R

:

\begin{matrix} ∥ F (ξ_{1}) - J (ξ_{1}) ∥ \leq \frac{2 + 2 {(2 {(\frac{1 + 2^{\frac{3 - p}{3}}}{4})}^{\frac{3}{p}} - 1)}^{\frac{p}{3}}}{1 - 2^{\frac{3 - p}{3}} - 2 {(2 {(\frac{1 + 2^{\frac{3 - p}{3}}}{4})}^{\frac{3}{p}} - 1)}^{\frac{p}{3}}} δ {| ξ_{1} |}^{p} \end{matrix},

\forall ξ_{1} \in R

.

Proof.

Fix

p > 3

. The replacement of

ξ_{2}

by

\sqrt[3]{2 {(\frac{1 + 2^{\frac{3 - p}{3}}}{4})}^{\frac{3}{p}} - 1} ξ_{1}

in (9) yields

\begin{matrix} ∥F (ξ_{1}) + F (\sqrt[3]{2 {(\frac{1 + 2^{\frac{3 - p}{3}}}{4})}^{\frac{3}{p}} - 1} ξ_{1}) - 2 F ({(\frac{1 + 2^{\frac{3 - p}{3}}}{4})}^{\frac{1}{p}} ξ_{1})∥ \\ \leq [1 + {(2 {(\frac{1 + 2^{\frac{3 - p}{3}}}{4})}^{\frac{3}{p}} - 1)}^{\frac{p}{3}}] δ {| ξ_{1} |}^{p} \end{matrix},

(10)

\forall ξ_{1} \in R

. Let

T : E^{R} \to E^{R}

and

θ : R \to R_{+}

be defined by

\begin{matrix} T f (ξ_{1}) = 2 f ({(\frac{1 + 2^{\frac{3 - p}{3}}}{4})}^{\frac{1}{p}} ξ_{1}) - f (\sqrt[3]{2 {(\frac{1 + 2^{\frac{3 - p}{3}}}{4})}^{\frac{3}{p}} - 1} ξ_{1}), f \in E^{R} \end{matrix}

and

\begin{matrix} θ (ξ_{1}) = [1 + {(2 {(\frac{1 + 2^{\frac{3 - p}{3}}}{4})}^{\frac{3}{p}} - 1)}^{\frac{p}{3}}] δ {| ξ_{1} |}^{p} \end{matrix},

\forall ξ_{1} \in R

. Then, we can write (10) as

∥ F (ξ_{1}) - T F (ξ_{1}) ∥ \leq θ (ξ_{1})

\forall ξ_{1} \in R

. Thus,

\begin{matrix} ∥ T f (ξ_{1}) - T g (ξ_{1}) ∥ \leq & 2 ∥f ({(\frac{1 + 2^{\frac{3 - p}{3}}}{4})}^{\frac{1}{p}} ξ_{1}) - g ({(\frac{1 + 2^{\frac{3 - p}{3}}}{4})}^{\frac{1}{p}} ξ_{1})∥ \\ + ∥f (\sqrt[3]{2 {(\frac{1 + 2^{\frac{3 - p}{3}}}{4})}^{\frac{3}{p}} - 1} ξ_{1}) - g (\sqrt[3]{2 {(\frac{1 + 2^{\frac{3 - p}{3}}}{4})}^{\frac{3}{p}} - 1} ξ_{1})∥ \end{matrix},

\forall f, g \in E^{R}

and

ξ_{1} \in R

. Hence,

T : E^{R} \to E^{R}

satisfies the condition (H3) with

λ_{1} (ξ_{1}) = 2

,

λ_{2} (ξ_{1}) = 1

,

σ_{1} (ξ_{1}) = {(\frac{1 + 2^{\frac{3 - p}{3}}}{4})}^{\frac{1}{p}} ξ_{1}, and σ_{2} (ξ_{1}) = \sqrt[3]{2 {(\frac{1 + 2^{\frac{3 - p}{3}}}{4})}^{\frac{3}{p}} - 1} ξ_{1} .

By (H4), the operator

Δ : R_{+}^{R} \to R_{+}^{R}

is defined by

\begin{matrix} Δ μ (ξ_{1}) = 2 μ ({(\frac{1 + 2^{\frac{3 - p}{3}}}{4})}^{\frac{1}{p}} ξ_{1}) + μ (\sqrt[3]{2 {(\frac{1 + 2^{\frac{3 - p}{3}}}{4})}^{\frac{3}{p}} - 1} ξ_{1}) \end{matrix},

\forall ξ_{1} \in R

. Hence,

\begin{matrix} Δ θ (ξ_{1}) = (\frac{1 + 2^{\frac{3 - p}{3}}}{2} + {(2 {(\frac{1 + 2^{\frac{3 - p}{3}}}{4})}^{\frac{3}{p}} - 1)}^{\frac{p}{3}}) θ (ξ_{1}), θ \in R^{R} \end{matrix},

\forall ξ_{1} \in R

. Since

Δ

is linear, by induction on

m \in N_{0}

,

\begin{matrix} Δ^{m} θ (ξ_{1}) = {(\frac{1 + 2^{\frac{3 - p}{3}}}{2} + {(2 {(\frac{1 + 2^{\frac{3 - p}{3}}}{4})}^{\frac{3}{p}} - 1)}^{\frac{p}{3}})}^{m} θ (ξ_{1}) \end{matrix},

\forall ξ_{1} \in R

. Since

{(2 {(\frac{1 + 2^{\frac{3 - p}{3}}}{4})}^{\frac{3}{p}} - 1)}^{\frac{1}{3}} < {(\frac{1 - 2^{\frac{3 - p}{3}}}{2})}^{\frac{1}{p}},

\forall p > 3

,

\frac{1 + 2^{\frac{3 - p}{3}}}{2} + {(2 {(\frac{1 + 2^{\frac{3 - p}{3}}}{4})}^{\frac{3}{p}} - 1)}^{\frac{p}{3}} < 1 .

Consequently, the series

\sum_{m = 0}^{\infty} Δ^{m} θ (ξ_{1})

is convergent for all

ξ_{1} \in R

, and

\begin{matrix} θ^{*} (ξ_{1}) = \sum_{m = 0}^{\infty} Δ^{m} θ (ξ_{1}) & = \sum_{m = 0}^{\infty} {(\frac{1 + 2^{\frac{3 - p}{3}}}{2} + {(2 {(\frac{1 + 2^{\frac{3 - p}{3}}}{4})}^{\frac{3}{p}} - 1)}^{\frac{p}{3}})}^{m} θ (ξ_{1}) \\ = \frac{2 + 2 {(2 {(\frac{1 + 2^{\frac{3 - p}{3}}}{4})}^{\frac{3}{p}} - 1)}^{\frac{p}{3}}}{1 - 2^{\frac{3 - p}{3}} - 2 {(2 {(\frac{1 + 2^{\frac{3 - p}{3}}}{4})}^{\frac{3}{p}} - 1)}^{\frac{p}{3}}} δ {| ξ_{1} |}^{p}, \end{matrix}

\forall ξ_{1} \in R

. By the use of Theorem 1, there is a function

J : R \to E

:

J (ξ_{1}) = {lim}_{n \to \infty} T^{n} F (ξ_{1})

,

\begin{matrix} J (ξ_{1}) = 2 J ({(\frac{1 + 2^{\frac{3 - p}{3}}}{4})}^{\frac{1}{p}} ξ_{1}) - J (\sqrt[3]{2 {(\frac{1 + 2^{\frac{3 - p}{3}}}{4})}^{\frac{3}{p}} - 1} ξ_{1}) \end{matrix},

and

\begin{matrix} ∥ J (ξ_{1}) - F (ξ_{1}) ∥ \leq \frac{2 + 2 {(2 {(\frac{1 + 2^{\frac{3 - p}{3}}}{4})}^{\frac{3}{p}} - 1)}^{\frac{p}{3}}}{1 - 2^{\frac{3 - p}{3}} - 2 {(2 {(\frac{1 + 2^{\frac{3 - p}{3}}}{4})}^{\frac{3}{p}} - 1)}^{\frac{p}{3}}} δ {| ξ_{1} |}^{p} \end{matrix},

\forall ξ_{1} \in R

. Now, we show that

J

satisfies the Jensen CFUEQs. From (9), we have

\begin{matrix} ∥2 T F (\sqrt[3]{\frac{ξ_{1}^{3} + ξ_{2}^{3}}{2}}) - T F (ξ_{1}) - T F (ξ_{2})∥ \\ = ∥ 4 F ({(\frac{1 + 2^{\frac{3 - p}{3}}}{4})}^{\frac{1}{p}} \sqrt[3]{\frac{ξ_{1}^{3} + ξ_{2}^{3}}{2}}) - 2 F (\sqrt[3]{(2 {(\frac{1 + 2^{\frac{3 - p}{3}}}{4})}^{\frac{3}{p}} - 1) (\frac{ξ_{1}^{3} + ξ_{2}^{3}}{2})} ξ_{1}) \\ - 2 F ({(\frac{1 + 2^{\frac{3 - p}{3}}}{4})}^{\frac{1}{p}} ξ_{1}) + F (\sqrt[3]{2 {(\frac{1 + 2^{\frac{3 - p}{3}}}{4})}^{\frac{3}{p}} - 1} ξ_{1}) \\ - 2 F ({(\frac{1 + 2^{\frac{3 - p}{3}}}{4})}^{\frac{1}{p}} ξ_{2}) + F (\sqrt[3]{2 {(\frac{1 + 2^{\frac{3 - p}{3}}}{4})}^{\frac{3}{p}} - 1} ξ_{2}) ∥ \\ \leq 2 ∥ 2 F ({(\frac{1 + 2^{\frac{3 - p}{3}}}{4})}^{\frac{1}{p}} \sqrt[3]{\frac{ξ_{1}^{3} + ξ_{2}^{3}}{2}}) - F ({(\frac{1 + 2^{\frac{3 - p}{3}}}{4})}^{\frac{1}{p}} ξ_{1}) - F ({(\frac{1 + 2^{\frac{3 - p}{3}}}{4})}^{\frac{1}{p}} ξ_{2}) ∥ \\ \leq ∥ 2 F (\sqrt[3]{(2 {(\frac{1 + 2^{\frac{3 - p}{3}}}{4})}^{\frac{3}{p}} - 1) (\frac{ξ_{1}^{3} + ξ_{2}^{3}}{2})} ξ_{1}) - F (\sqrt[3]{2 {(\frac{1 + 2^{\frac{3 - p}{3}}}{4})}^{\frac{3}{p}} - 1} ξ_{1}) \\ - F (\sqrt[3]{2 {(\frac{1 + 2^{\frac{3 - p}{3}}}{4})}^{\frac{3}{p}} - 1} ξ_{2}) ∥ \\ \leq δ (\frac{1 + 2^{\frac{3 - p}{3}}}{2} + {(2 {(\frac{1 + 2^{\frac{3 - p}{3}}}{4})}^{\frac{3}{p}} - 1)}^{\frac{p}{3}}) (| ξ_{1} |^{p} + | ξ_{2} |^{p}), \end{matrix}

\forall ξ_{1}, ξ_{2} \in R

. By induction on

m \in N_{0}

, we obtain

\begin{matrix} ∥2 T^{m} F (\sqrt[3]{\frac{ξ_{1}^{3} + ξ_{2}^{3}}{2}}) - T^{m} F (ξ_{1}) - T^{m} F (ξ_{2})∥ \\ \leq δ {(\frac{1 + 2^{\frac{3 - p}{3}}}{2} + {(2 {(\frac{1 + 2^{\frac{3 - p}{3}}}{4})}^{\frac{3}{p}} - 1)}^{\frac{p}{3}})}^{m} (| ξ_{1} |^{p} + {| ξ_{2} |}^{p}), \end{matrix}

\forall ξ_{1}, ξ_{2} \in R

. Letting

m \to \infty

, we conclude that

\begin{matrix} 2 J (\sqrt[3]{\frac{ξ_{1}^{3} + ξ_{2}^{3}}{2}}) = J (ξ_{1}) + J (ξ_{2}) \end{matrix},

\forall ξ_{1}, ξ_{2} \in R

.

Uniqueness: Consider two functions

J_{1}, J_{2} : R \to E

satisfying (2) with

∥ F (ξ_{1}) - J_{i} (ξ_{1}) ∥ \leq L | ξ_{1} |^{p}, i = 1, 2

for some

L > 0

and all

ξ_{1} \in R

. Therefore,

∥ J_{1} (ξ_{1}) - J_{2} (ξ_{1}) ∥ \leq 2 L | ξ_{1} |^{p},

(11)

\forall ξ_{1} \in R

.

Also,

J_{1}

and

J_{2}

satisfy (2); thus,

J_{i} (ξ_{1}) = 2 J_{i} ({(\frac{1 + 2^{\frac{3 - p}{3}}}{4})}^{\frac{1}{p}} ξ_{1}) - J_{i} (\sqrt[3]{2 {(\frac{1 + 2^{\frac{3 - p}{3}}}{4})}^{\frac{3}{p}} - 1} ξ_{1}), i = 1, 2,

\forall ξ_{1} \in R

. Therefore,

\begin{matrix} ∥ J_{1} (ξ_{1}) - J_{2} (ξ_{1}) ∥ \leq 2 ∥J_{1} ({(\frac{1 + 2^{\frac{3 - p}{3}}}{4})}^{\frac{1}{p}} ξ_{1}) - J_{2} ({(\frac{1 + 2^{\frac{3 - p}{3}}}{4})}^{\frac{1}{p}} ξ_{1})∥ \\ + ∥J_{1} (\sqrt[3]{2 {(\frac{1 + 2^{\frac{3 - p}{3}}}{4})}^{\frac{3}{p}} - 1} ξ_{1}) - J_{2} (\sqrt[3]{2 {(\frac{1 + 2^{\frac{3 - p}{3}}}{4})}^{\frac{3}{p}} - 1} ξ_{1})∥ \\ \leq (\frac{1 + 2^{\frac{3 - p}{3}}}{2} + {(2 {(\frac{1 + 2^{\frac{3 - p}{3}}}{4})}^{\frac{3}{p}} - 1)}^{\frac{p}{3}}) 2 L {| ξ_{1} |}^{p}, \end{matrix}

\forall ξ_{1} \in R

. By induction on

m \in N_{0}

, we obtain

\begin{matrix} ∥ J_{1} (ξ_{1}) - J_{2} (ξ_{1}) ∥ \leq {(\frac{1 + 2^{\frac{3 - p}{3}}}{2} + {(2 {(\frac{1 + 2^{\frac{3 - p}{3}}}{4})}^{\frac{3}{p}} - 1)}^{\frac{p}{3}})}^{m} 2 L {| ξ_{1} |}^{p} \end{matrix},

\forall ξ_{1} \in R

and all

m \in N_{0}

. This means that

J_{1} = J_{2}

. □

5. Conclusions

We employed a well-known FPT to study the Ulam stability of some classes of symmetric CFUEQ. Stability helped us to obtain estimates between the exact and approximate solutions in many cases. One can find such results for a more generalized version of the FUEQ. Future directions will involve studying the Hyers–Ulam–Rassias stability of much more complicated FUEQs or in some new function spaces.

Author Contributions

Conceptualization, Y.S., M.D. and E.-s.E.-h.; methodology, Y.S., M.D. and E.-s.E.-h.; software, Y.S., M.D., Y.A. and E.-s.E.-h.; validation, Y.S., M.D. and E.-s.E.-h.; formal analysis, Y.S., M.D. and Y.A.; investigation, Y.S. and M.D.; data curation, Y.S., M.D., Y.A. and E.-s.E.-h.; writing—original draft preparation, Y.S. and M.D.; writing—review and editing, Y.S., M.D. and E.-s.E.-h.; visualization, Y.S. and M.D.; supervision, Y.S. and M.D.; project administration, Y.S., M.D. and E.-s.E.-h.; funding acquisition, E.-s.E.-h. All authors have read and agreed to the published version of the manuscript.

Funding

This work was funded by the Deanship of Graduate Studies and Scientific Research at Jouf University under grant No. (DGSSR-2024-02-01049).

Institutional Review Board Statement

Not applicable.

Informed Consent Statement

Not applicable.

Data Availability Statement

The original contributions presented in the study are included in the article, further inquiries can be directed to the corresponding authors.

Conflicts of Interest

The authors declare no conflicts of interest.

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El-hady, E.-s.; Sayyari, Y.; Dehghanian, M.; Alruwaily, Y. Stability Results for Some Classes of Cubic Functional Equations. Axioms 2024, 13, 480. https://doi.org/10.3390/axioms13070480

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El-hady E-s, Sayyari Y, Dehghanian M, Alruwaily Y. Stability Results for Some Classes of Cubic Functional Equations. Axioms. 2024; 13(7):480. https://doi.org/10.3390/axioms13070480

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El-hady, El-sayed, Yamin Sayyari, Mehdi Dehghanian, and Ymnah Alruwaily. 2024. "Stability Results for Some Classes of Cubic Functional Equations" Axioms 13, no. 7: 480. https://doi.org/10.3390/axioms13070480

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Stability Results for Some Classes of Cubic Functional Equations

Abstract

1. Introduction

2. Preliminaries

3. Stability of (1)

4. Stability of the Jensen Cubic Functional Equation

5. Conclusions

Author Contributions

Funding

Institutional Review Board Statement

Informed Consent Statement

Data Availability Statement

Conflicts of Interest

References

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