Special functions and multi-stability of the Jensen type random operator equation in \(C^{*}\)-algebras via fixed point

In this paper, we apply some special functions to introduce a new class of control functions that help us define the concept of multi-stability. Further, we investigate the multi-stability of homomorphisms in \(C^{*}\)-algebras and Lie \(C^{*}\)-algebras, multi-stability of derivations in \(C^{*}\)-algebras, and Lie \(C^{*}\)-algebras for the following random operator equation via fixed point methods:

In particular, for \(\mu = 1\), the above equation turns out to be Jensen’s random operator equation.

The stability problem of functional equations originated from a question of Ulam, posed in 1940, concerning the stability of group homomorphisms. In the next year, Hyers gave a partial affirmative answer to the question of Ulam in the context of Banach spaces in the case of additive mappings; that was the first significant breakthrough and a step toward more solutions in this area. Since then, many papers have been published in connection with various generalizations of Ulam’s problem and Hyers’s theorem. In 1978, Rassias succeeded in extending Hyers’s theorem for mappings between Banach spaces by considering an unbounded Cauchy difference subject to a continuity condition upon the mapping. He was the first to prove the stability of linear mapping. This result of Rassias attracted several mathematicians worldwide who began to be stimulated to investigate the stability problems of functional equations. In the present paper, we apply some special functions to introduce a new class of control functions which help us define the concept of multi-stability.

Let \(\mho _{1}\) and \(\mho _{2}\) be Banach algebras and \((\partial , \Pi )\) be a probability measure space. Assume \((\mho _{1},{\mathfrak {B}}_{\mho _{1}})\) and \((\mho _{2},\mathfrak{B}_{\mho _{2}})\) are Borel measurable spaces. Clearly, a map \(f:\partial \times \mho _{1}\to \mho _{2}\) is well defined if \(\{\eth : f(\eth ,\mathsf{S})\in \mathcal{C}\}\in \Pi \) for all S in \(\mho _{1}\) and \(\mathcal{C}\in \mathfrak{B}_{\mho _{2}}\). We are going to investigate a vector valued generalized metric spaces. Let \(\lambda =(\lambda _{1},\ldots ,\lambda _{m}) \) and \(\gamma =(\gamma _{1},\ldots ,\gamma _{m})\), \(m\in \mathbb{N}\). Then we define

and

Definition 1.1

([1])

Suppose \(\mathcal{G} \) is a nonempty set, and \(d: \mathcal{G}^{2}\rightarrow [0,+\infty ]^{m}\) (with \(m\in \mathbb{N}\)) is a given mapping. We say that d is a generalized metric on \(\mathcal{G} \) if the following conditions satisfy:

(1) for every \((\Psi ,\Phi )\in \mathcal{G} \times \mathcal{G}\), we have

(2) for every \((\Psi ,\Phi )\in \mathcal{G}\times \mathcal{G}\),

(3) for every \(\Psi ,\Phi ,\Upsilon \in \mathcal{G}\),

Theorem 1.2

([1])

Let \((\mathcal{G} , d)\) be a complete generalized metric space, and let \(\Gamma : \mathcal{G} \rightarrow \mathcal{G}\) be strictly contractive, i.e.,

for some Lipschitz constants \(L_{i}<1\), for \(i=1, \ldots \) , \(m\in \mathbb{N}\). Then

(1) the mapping Γ has a unique fixed point \(\Psi ^{*} = \Gamma \Psi ^{*}\);

(2) the fixed point \(\Psi ^{*}\) is globally attractive, i.e.,

for any starting point \(\Psi \in \mathcal{G}\);

(3) the following three inequalities hold:

for all nonnegative integers n and all \(\Psi \in \mathcal{G}\) and \(m\in \mathbb{N}\).

Now, we generalize Theorem 1.2.

Theorem 1.3

([1])

Suppose \(d: \mathcal{G}^{2}\rightarrow [0,+\infty ]^{m}\), \(m\in \mathbb{N}\), and \(( \mathcal{G}, d)\) is a complete generalized metric space. Suppose \(\Gamma : \mathcal{G} \rightarrow \mathcal{G}\) is a strictly contractive mapping with Lipschitz constant \(\mathcal{Z} <1\). Then for any given element \(\Psi \in \mathcal{G}\), either

for any \(n\in \mathbb{N}\cup \{ 0\}\) or there exists an \(n_{0}\in \mathbb{N}\) such that

(1) \(d(\Gamma ^{n} \Psi , \Gamma ^{n+1}\Psi ) \preceq \underbrace{(+\infty , \ldots , +\infty )}_{m}\), \(\forall n\ge n_{0}\);

(2) The fixed point \(\Phi ^{*}\) of Γ is a convergent point of sequence \(\{\Gamma ^{n} \Psi \}\);

(3) \(\Phi ^{*}\) is the unique fixed point of Γ in the set \(\mathcal{Q} = \{\Phi \in \mathcal{G}| d(\Gamma ^{n_{0}} \Psi , \Phi ) \preceq \underbrace{(+\infty , \ldots , +\infty )}_{m}\}\);

(4) \(d(\Phi , \Phi ^{*}) \preceq \frac{1}{1-\mathcal{Z} } d(\Phi , \Gamma \Phi )\) for all \(\Phi \in \mathcal{Q}\).

For more applications of Theorem 1.3 in stability analysis see references [2–4]. We now consider the infinite contour \(\mathscr{Z} \) having one of the following forms:

▶:

\(\mathscr{Z}=\mathscr{Z}_{-\infty} \) is a left loop starting at −∞ and ending at −∞, enclosing all the poles of \(\Gamma (Y) \).

▶:

\(\mathscr{Z}=\mathscr{Z}_{+\infty} \) is a left loop starting at +∞ and ending at +∞, enclosing all the poles of \(\Gamma ( d_{j}-Y)\), for \(j=1,\ldots , s\), situated in a horizontal strip starting at the point \(+\infty +i \mathcal{P}_{1} \) and terminating at the point \(+\infty +i \mathcal{P}_{2} \) with \(-\infty <\mathcal{P}_{1}<\mathcal{P}_{2}<+\infty \), and \(d_{j}\in \mathbb{C} \).

▶:

\(\mathscr{Z}=\mathscr{Z}_{i\hslash \infty} \) is a contour starting at the point \(\hslash - i \infty \) and terminating at the point \(\hslash + i \infty \), where \(\hslash \in \mathbb{R}\mathbbm{.} \)

We now introduce some special functions as follows. For more details please see [5–9]. The standard Lie algebraic techniques are important methods for studying special functions. There are some operators defined on Lie algebras for the purpose of deriving properties of some special functions [10–12].

▶ Exponential function:

We first define the complex exponential function as

▶ Mittag–Leffler function (generalized exponential function):

The function

is said to be the Mittag–Leffler function of one-parameter.

▶ Hypergeometric function (the Gauss Hypergeometric series):

The series given as

is called the Hypergeometric function, where \(d_{1},d_{2},e_{1}\in \mathbb{C} \), \(\Re (d_{1}),\Re (d_{2}),\Re (e_{1})>0\). Furthermore, the Hypergeometric function can be represented in terms of the Mellin–Barnes integral of the form

where \(e_{1}\neq 0, -1, -2, -3, \ldots \) .

▶ Wright function (Bessel–Maitland function):

The series representation

is called Wright function, where \(d_{1}>-1 \), \(e_{1},X\in \mathbb{C}\).

▶ Fox–Wright function (the generalized Wright function):

Consider positive vectors \({\mathbf{D}}=(D_{1},\ldots ,D_{s} ) \), \({\mathbf{E}}=(E_{1},\ldots ,E_{r} ) \), complex vectors \({\mathbf{d}}=(d_{1},\ldots ,d_{s} ) \), and \({\mathbf{e}}=(e_{1},\ldots ,e_{r} ) \). The Fox–Wright function or the generalized Wright function is defined by the series

where

and \(\Gamma ({\mathbf{E }}n+{\mathbf{e}})\) follows similarly.

The series (1.1) has a nonzero radius of convergence if

Moreover, if \(\mathscr{N} >-1\) then the series converges for all finite values of X (hence it is an entire function), and if \(\mathscr{N} = -1\), its radius of convergence equals

The Convergence on the boundary \(\vert X\vert = \mathscr{M}\), however, depends on the value of

by noting that series (1.1) converges absolutely for \(\vert X \vert = \mathscr{M}\) if \(\Re (\mathscr{W})>0 \).

The function \({}_{s}\mathbb{H}_{r} \) is an extension of the generalized hypergeometric function (which we will present later). In addition, \({}_{1}\mathbb{H}_{1} \) and \({}_{0}\mathbb{H}_{1} \) are the Wright (the Bessel–Maitland) function and Mittag–Leffler function with \(D_{1}=d_{1}=1 \), respectively.

▶ Fox’s \(\mathbb{H}\)–function (generalized Fox–Wright function):

We now present Fox’s \(\mathbb{H}\)–function as

where \(i^{2}= -1\), \(X\in \mathbb{C}\backslash \{0\}\), \(X^{Y}= \text{exp}( Y [\text{log}\vert X \vert +i \text{arg}(X)]) \), \(\text{log}\vert X \vert \) denotes the natural logarithm of \(\vert X \vert \), and \(\text{arg}(X) \) is not necessarily the principal value. For convenience,

where an empty product is interpreted as 1, and the integers v, w, s, r satisfy the inequalities \(0\leq w \leq s \) and \(1\leq v \leq r\). Assume the coefficients

and the complex parameters

are constrained such that no poles of integrand in (1.6) coincide, and \(\mathscr{Z}\) is a suitable contour of the Mellin–Barnes type (in the complex Y-plane), which separates the poles of one product from the others. Further, if we assume

then the integral in (1.6) converges absolutely and defines the \(\mathbb{H}\)-function, which is analytic in the sector:

and with the point \(X=0 \) being tacitly excluded. Actually, the \(\mathbb{H}\)-function makes sense and also defines an analytic function of X when either

or

▶ Meijer \(\mathbb{G}\)-function:

The Meijer \(\mathbb{G}\)-function is a special case of the \(\mathbb{H}\)-function, that is,

where

\(X^{-Y}=\exp (- Y [\text{log}\vert X \vert +i \arg (X)])\), \(X \neq 0\) and \(i^{2}=-1 \), and also \(\log \vert X \vert \) represents the natural logarithm of \(\vert X \vert \), and \(\arg (X)\) is not necessarily the principle value as mentioned before.

Notice that an empty product in (1.8) is defined to be one, and the poles

of the gamma functions \(\Gamma (e_{j}+Y)\) and the poles

of the gamma functions \(\Gamma (1-d_{i}-Y)\) do not coincide, that is,

Further, \(\mathscr{Z} \) is one of the contours defined above, which separates all poles \(e_{j\wp} \) in (1.9) on the left from all poles \(d_{i\wp} \) in (1.10) on the right of \(\mathscr{Z}\).

▶ \(\mathbb{G}\)-function (generalized Hypergeometric function):

The generalized hypergeometric function is defined by the following generalized hypergeometric series

where \(X\in \mathbb{C}\), \(s,r\in \mathbb{N}_{0} \), and \(d_{i},e_{j} \in \mathbb{C}\), for \(i=1,\ldots ,s \) and \(j=1,\ldots ,r \). For \(z\in \mathbb{C} \), we denote

If \(d_{j}\neq -\wp \), \(j=1,\ldots , r \) and \(\wp \in \mathbb{N}_{0} \), then the generalized hypergeometric series (1.12) can be represented in terms of the Mellin–Barnes integral of the form

where \(e_{j}\neq 0, -1, -2, \ldots \) \(j=1,\ldots r \), \(e_{j}\neq 0, -1, -2, \ldots \) \(j=1,\ldots s \), and with the special contour \(\mathscr{Z} \).

Such a formula converts representation (1.12) as the Meijer \(\mathbb{G}\)-function given by:

▶ Generalized Hyperbolic function:

The generalizations of the Hyperbolic Functions are defined by

for \(R=0,\ldots, A-1 \), where \(\Bbbk \in \mathbb{C} \). Also, we have

where

We would like to point out that the special case \(\mathbb{J}^{1}_{A,0}(X) \) is the Mittag–Leffler function.

Now let

Note that \({\boldsymbol{\zeta}}:=\operatorname{diag}[\zeta _{1},\ldots ,\zeta _{n}] \preceq {\boldsymbol{\xi}}:=\operatorname{diag}[\xi _{1},\ldots ,\xi _{n}]\) if \(\zeta _{i}\leq \xi _{i}\) for all \(1\leq i\leq n\).

Consider the following matrix valued control function given by

Let a mapping Θ from vector space U to normed linear space V have Hyers–Ulam–Rassias stability. If we replace the control function of Hyers–Ulam–Rassias stability with \(\mathfrak{W}[X] \), we say Θ has multi-stability property.

Clearly, if we have

then the following are satisfied:

▶:

for any \(r<1 \), and \(\theta >0\), there exist constants \(L_{i} <1\) s.t.

$$\begin{aligned} \varphi _{i}(x, 0) \le 2 L_{i} \varphi _{i} \biggl(\frac{x}{2}, 0\biggr) ,\quad i=1,\ldots , 9; \end{aligned}$$

▶:

for any \(r>1 \), and \(\theta >0\), there exist constants \(L_{i} <1\) s.t.

$$\begin{aligned} \varphi _{i}(x, 0) \le \frac{1}{2} L_{i} \varphi _{i}(2x, 0),\quad i=1,\ldots ,9. \end{aligned}$$

Throughout this entire section, let A be a \(C^{*}\)-algebra with norm \(\| \cdot \|_{A}\) and that B be a \(C^{*}\)-algebra with norm \(\|\cdot \|_{B}\).

For a given mapping \(f: \partial \times A \rightarrow B\), we define

for \(\mu \in \mathbb{T}^{1}: = \{\nu \in \mathbb{C}: |\nu | = 1\}\) and \(x, y \in A\) and \(\eth \in \partial \).

Notice that a \(\mathbb{C}\)-linear mapping \(H : \partial \times A \rightarrow B\) is a homomorphism in \(C^{*}\)-algebras if H satisfies \(H (\eth ,xy) = H(\eth ,x) H(\eth ,y)\) and \(H(\eth ,x^{*}) = H(\eth ,x)^{*}\) for \(x, y\in A\) and \(\eth \in \partial \).

We investigate the generalized Hyers–Ulam stability of homomorphisms in \(C^{*}\)-algebras for the functional equation \(D_{\mu}f(\eth ,x, y) =0\).

Theorem 2.1

Assume \(f:\partial \times A \rightarrow B\) is a mapping for which there exist functions \(\varphi _{i} : A^{2} \rightarrow [0, \infty )\), for \(i=1,\ldots \) , \(n\in \mathbb{N} \), s.t.

and

for \(\mu \in \mathbb{T} ^{1}\) and \(x, y \in A\) and \(\eth \in \partial \). If there exist constants \(L_{i} <1\) s.t. \(\varphi _{i}(x, 0) \le 2 L_{i} \varphi _{i}(\frac{x}{2}, 0)\) for \(x \in A\) and \(i=1,\ldots , n \), then there exists a unique \(C^{*}\)-algebra homomorphism \(H :\partial \times A \rightarrow B\) s.t.

for \(x \in A\) and \(\eth \in \partial \).

Proof

Assume the set

and define the generalized metric d on X:

Then \((X, d)\) is complete.

Let the linear mapping \(J: X \rightarrow X\) s.t.

for \(x \in A\) and \(\eth \in \partial \).

According to Theorem 3.1 of [13] and [1],

for \(g, h \in X\).

Setting \(\mu =1\) and \(y = 0\) in (2.1), we have

for \(x \in A\) and \(\eth \in \partial \). So,

for \(x \in A\) and \(\eth \in \partial \). Hence \(d(f, Jf) \le (L_{1}, \ldots , L_{n})\).

According to Theorem 1.3, there exists a mapping \(H:\partial \times A \rightarrow B\) s.t.

(1) H is a fixed point of J, i.e.,

for \(x \in A\) and \(\eth \in \partial \). The mapping H is a unique fixed point of J in the set

This concludes that H is a unique mapping satisfying (2.6) s.t. there exists \((C_{1}, \ldots , C_{n})\in (0, \infty )^{n}\) satisfying

for \(x \in A\) and \(\eth \in \partial \).

(2) \(d(J^{k} f, H) \rightarrow \overbrace{(0, \ldots , 0)}^{n}\) as \(k \rightarrow \infty \). This concludes the equality

for \(x \in A\) and \(\eth \in \partial \).

(3) \(d(f, H) \le (\frac{1}{1-L_{1}} , \ldots , \frac{1}{1-L_{n}}) d(f, Jf)\), which implies the inequality

This claims that the inequality (2.4) holds.

According to (2.1) and (2.7),

for \(x, y \in A\) and \(\eth \in \partial \). So,

for \(x, y \in A\) and \(\eth \in \partial \). Letting \(z= \frac{x+y}{2}\) and \(w=\frac{x-y}{2}\) in (2.8), we have

for \(z, w \in A\) and \(\eth \in \partial \). So the mapping \(H :\partial \times A \rightarrow B\) is Cauchy additive, i.e., \(H(\eth ,z+w) = H(\eth ,z) + H(\eth ,w)\) for \(z, w \in A\) and \(\eth \in \partial \).

Letting \(y = x\) in (2.1), we have

for \(\mu \in \mathbb{T} ^{1}\) and \(x \in A\) and \(\eth \in \partial \). Similarly, we have

for \(\mu \in \mathbb{T} ^{1}\) and \(x \in A\) and \(\eth \in \partial \). Thus, one can prove that the mapping \(H :\partial \times A \rightarrow B\) is \(\mathbb{C}\)-linear.

According to (2.2),

for \(x, y \in A\) and \(\eth \in \partial \). So,

for \(x, y \in A\) and \(\eth \in \partial \).

According to (2.3),

for \(x \in A\) and \(\eth \in \partial \). So,

for \(x\in A\) and \(\eth \in \partial \).

Thus, \(H:\partial \times A \rightarrow B\) is a \(C^{*}\)-algebra homomorphism satisfying (2.4), as desired. □

Theorem 2.2

Assume \(f:\partial \times A \rightarrow B\) is a mapping for which there exist functions \(\varphi _{i} : A^{2} \rightarrow [0, \infty )\) satisfying (2.1), (2.2) and (2.3) for \(i=1, \ldots ,n\). Furthermore, if there exist constants \(L_{i} <1\) s.t. \(\varphi _{i}(x, 0) \le \frac{1}{2} L_{i} \varphi _{i}(2x, 0)\) for each \(x \in A\) and \(i=1,\ldots ,n \), then there exists a unique \(C^{*}\)-algebra homomorphism \(H :\partial \times A \rightarrow B\) s.t.

for \(x \in A\) and \(\eth \in \partial \).

Proof

We consider the linear mapping \(J: X \rightarrow X\) s.t.

for \(x \in A\) and \(\eth \in \partial \).

It follows from (2.5) that

for \(x \in A\) and \(\eth \in \partial \). Hence \(d(f, Jf) \le (\frac{L_{1}}{2}, \ldots , \frac{L_{n}}{2})\).

According to Theorem 1.3, there exists a mapping \(H:\partial \times A \rightarrow B\) s.t.

(1) H is a fixed point of J, i.e.,

for \(x \in A\). Moreover, the mapping H is a unique fixed point of J in the set

This implies that H is a unique mapping satisfying (2.10) s.t. there exists \((C_{1},\ldots ,C_{n})\in (0, \infty )^{n}\) satisfying

for \(x \in A\) and \(\eth \in \partial \).

(2) \(d(J^{k} f, H) \rightarrow \underbrace{ (0,\ldots , 0)}_{n}\) as \(k \rightarrow \infty \). This deduces the equality

for \(x \in A\) and \(\eth \in \partial \).

(3) \(d(f, H) \le (\frac{1}{1-L_{1}}, \ldots , \frac{1}{1-L_{n}}) d(f, Jf)\) claims the inequality

which infers that the inequality (2.9) holds.

The rest of the proof is similar to the proof of Theorem 2.1. □

Theorem 2.3

Assume \(f:\partial \times A \rightarrow B\) is an odd mapping for which there exist functions \(\varphi _{i} : A^{2} \rightarrow [0, \infty )\) satisfying (2.1), (2.2) and (2.3) for \(i=1, \ldots ,n\). Moreover, if there exist constants \(L_{i} <1\) s.t. \(\varphi _{i}(x, 3x) \le 2 L_{i} \varphi _{i}(\frac{x}{2}, \frac{3x}{2})\) for \(x \in A\) and \(i=1, \ldots ,n\), then there exists a unique \(C^{*}\)-algebra homomorphism \(H :\partial \times A \rightarrow B\) s.t.

for \(x \in A\) and \(\eth \in \partial \).

Proof

Assume the set

and introduce the generalized metric d on X as

Then the space \((X, d)\) is complete.

Now we assume the linear mapping \(J: X \rightarrow X\) s.t.

for \(x \in A\) and \(\eth \in \partial \).

According to Theorem 3.1 of [1],

for \(g, h \in X\).

Letting \(\mu =1\) and replacing y by 3x in (2.1), we have

for \(x \in A\) and \(\eth \in \partial \). So,

for \(x \in A\) and \(\eth \in \partial \). Hence \(d(f, Jf) \le ( \frac{1}{2}, \ldots , \frac{1}{2})\).

According to Theorem 1.3, there exists a mapping \(H:\partial \times A \rightarrow B\) s.t.

(1) H is a fixed point of J, i.e.,

for \(x \in A\) and \(\eth \in \partial \). In addition, the mapping H is a unique fixed point of J in the set

This concludes that H is a unique mapping satisfying (2.13) s.t. there exists \((C_{1},\ldots , C_{n})\in (0, \infty )^{n}\) satisfying

for \(x \in A\) and \(\eth \in \partial \).

(2) \(d(J^{n} f, H) \rightarrow \underbrace{ (0, \ldots ,0)}_{n}\) as \(n \rightarrow \infty \). This infers the equality

for \(x \in A\) and \(\eth \in \partial \).

(3) \(d(f, H) \le (\frac{1}{1-L_{1}},\ldots , \frac{1}{1-L_{n}}) d(f, Jf)\) confirms the inequality

Therefore, the inequality (2.11) holds.

The rest follows immediately from the proof of Theorem 2.1. □

Theorem 2.4

Assume \(f:\partial \times A \rightarrow B\) is an odd mapping for which there exist functions \(\varphi _{i} : A^{2} \rightarrow [0, \infty )\) satisfying (2.1), (2.2) and (2.3), for \(i=1, \ldots , n\). In addition, if there exist constants \(L_{i} <1\) s.t. \(\varphi _{i}(x, 3x) \le \frac{1}{2} L_{i} \varphi _{i}(2x, 6x)\) for \(x \in A\) and \(i=1, \ldots , n\), then there exists a unique \(C^{*}\)-algebra homomorphism \(H :\partial \times A \rightarrow B\) s.t.

for \(x \in A\) and \(\eth \in \partial \).

Proof

We assume the linear mapping \(J: X \rightarrow X\) s.t.

for \(x \in A\) and \(\eth \in \partial \).

According to (2.12),

for \(x \in A\) and \(\eth \in \partial \). Hence \(d(f, Jf) \le (\frac{L_{1}}{2}, \ldots ,\frac{L_{n}}{2})\).

Using Theorem 1.3, there exists a mapping \(H:\partial \times A \rightarrow B\) s.t.

(1) H is a fixed point of J, i.e.,

for \(x \in A\) and \(\eth \in \partial \). Further, the mapping H is a unique fixed point of J in the set

This indicates that H is a unique mapping satisfying (2.15) s.t. there exists \((C_{1}, \ldots , C_{n})\in (0, \infty )^{n}\) satisfying

for \(x \in A\) and \(\eth \in \partial \).

(2) The condition \(d(J^{k} f, H) \rightarrow \underbrace{( 0, \ldots , 0)}_{n}\) as \(k \rightarrow \infty \) derives the equality

for \(x \in A\) and \(\eth \in \partial \).

(3) The inequality \(d(f, H) \le (\frac{1}{1-L_{1}}, \ldots , \frac{1}{1-L_{n}}) d(f, Jf)\) claims

which concludes that the inequality (2.14) holds.

The rest of the proof follows from the proof of Theorem 2.1. □

In this section, we let A be a \(C^{*}\)-algebra with norm \(\| \cdot \|_{A}\).

Recall that a \(\mathbb{C}\)-linear mapping \(\delta :\partial \times A \rightarrow A\) is a derivation on A if δ satisfies \(\delta (\eth ,xy) = \delta (\eth ,x) y + x \delta (\eth ,y)\) for \(x, y\in A\) and \(\eth \in \partial \).

We are going to present the generalized Hyers-Ulam stability of derivations on \(C^{*}\)-algebras for the functional equation \(D_{\mu}f(\eth , x, y) =0\).

Theorem 3.1

Assume \(f:\partial \times A \rightarrow A\) is a mapping for which there exist functions \(\varphi _{i} : A^{2} \rightarrow [0, \infty )\) for \(i=1,\ldots , n\), such that

for \(\mu \in \mathbb{T} ^{1}\) and \(x, y \in A\), \(\eth \in \partial \). Additionally, suppose there exist constants \(L_{i} <1\) such that \(\varphi _{i}(x, 0) \le 2 L_{i} \varphi _{i}(\frac{x}{2}, 0)\) for \(x \in A\) and \(i=1,\ldots , n\). Then there exists a unique derivation \(\delta :\partial \times A \rightarrow A\) satisfying

for \(x \in A\) and \(\eth \in \partial \).

Proof

By the same reasoning as the proof of Theorem 2.1, there exists a unique evolutive \(\mathbb{C}\)-linear mapping \(\delta : \partial \times A\rightarrow A\) satisfying (3.3). The mapping \(\delta :\partial \times A\rightarrow A\) is given by

for \(x \in A\) and \(\eth \in \partial \).

Applying (3.2),

for \(x, y \in A\) and \(\eth \in \partial \). So,

for \(x, y \in A\) and \(\eth \in \partial \). Thus \(\delta :\partial \times A \rightarrow A\) is a derivation satisfying (3.3). □

Theorem 3.2

Assume \(f:\partial \times A \rightarrow A\) is a mapping for which there exist functions \(\varphi _{i} : A^{2} \rightarrow [0, \infty )\) satisfying (3.1) and (3.2) for \(i=1,\ldots , n\). Also assume there exist constants \(L_{i} <1\) s.t. \(\varphi _{i}(x, 0) \le \frac{1}{2} L_{i} \varphi _{i}(2x, 0)\) for \(x \in A\) and \(i=1,\ldots , n\). Then there exists a unique derivation \(\delta :\partial \times A \rightarrow A\) s.t.

for \(x \in A\) and \(\eth \in \partial \).

Proof

The proof is similar to the proofs of Theorems 2.2 and 3.1. □

Remark 3.3

For the inequalities controlled by the product of powers of norms, one can obtain results similar to Theorems 2.3 and 2.4.

A \(C^{*}\)-algebra \(\mathcal {C}\), endowed with the Lie product \([x, y]: = \frac{xy-yx}{2}\) on \(\mathcal {C}\), is called a Lie \(C^{*}\)-algebra.

Definition 4.1

([14])

Assume A and B are Lie \(C^{*}\)-algebras. A \(\mathbb{C}\)-linear mapping \(H:\partial \times A \rightarrow B\) is called a Lie \(C^{*}\)-algebra homomorphism if \(H([x, y]) = [H(x), H(y)]\) for \(x, y \in A\).

Throughout this section, we assume A is a Lie \(C^{*}\)-algebra with norm \(\| \cdot \|_{A}\), and B is a Lie \(C^{*}\)-algebra with norm \(\|\cdot \|_{B}\).

We show the generalized Hyers–Ulam stability of homomorphisms in Lie \(C^{*}\)-algebras for the functional equation \(D_{\mu}f(x, y) =0\).

Theorem 4.2

Assume \(f:\partial \times A \rightarrow B\) is a mapping for which there exist functions \(\varphi _{i} : A^{2} \rightarrow [0, \infty )\) for \(i=1,\ldots , n \) satisfying (2.1) and

for \(x, y \in A\), \(\eth \in \partial \). Furthermore, if there exist constants \(L_{i} <1\) s.t. \(\varphi _{i}(x, 0) \le 2 L_{i} \varphi _{i}(\frac{x}{2}, 0)\) for \(x \in A\), and \(i=1,\ldots , n \), then there exists a unique Lie \(C^{*}\)-algebra homomorphism \(H :\partial \times A \rightarrow B\) satisfying (2.4).

Proof

By the same arguments as the proof of Theorem 2.1, there exists a unique \(\mathbb{C}\)-linear mapping \(\delta :\partial \times A\rightarrow A\) satisfying (2.4). The mapping \(H :\partial \times A\rightarrow B\) is defined by

for \(x \in A\) and \(\eth \in \partial \).

Utilizing (4.1),

for \(x, y \in A\) and \(\eth \in \partial \). Hence,

for \(x, y \in A\) and \(\eth \in \partial \).

In summary, \(H:\partial \times A \rightarrow B\) is a Lie \(C^{*}\)-algebra homomorphism satisfying (2.4), as desired. □

Theorem 4.3

Assume \(f:\partial \times A \rightarrow B\) is a mapping for which there exist functions \(\varphi _{i} : A^{2} \rightarrow [0, \infty )\) satisfying (2.1) and (4.1) for \(i=1,\ldots , n\). Further, if there exist constants \(L_{i} <1\) s.t. \(\varphi _{i}(x, 0) \le \frac{1}{2} L_{i} \varphi _{i}(2x, 0)\) for \(x \in A\), and \(i=1,\ldots , n\) then there exists a unique Lie \(C^{*}\)-algebra homomorphism \(H :\partial \times A \rightarrow B\) satisfying (2.9).

Proof

The proof follows similarly from the proofs of Theorems 2.2 and 2.3. □

Remark 4.4

For the inequalities controlled by the product of powers of norms, one can derive results similar to Theorems 2.3 and 2.4.

Definition 5.1

([15])

Let A be a Lie \(C^{*}\)-algebra. A \(\mathbb{C}\)-linear mapping \(\delta :\partial \times A \rightarrow A\) is called a Lie derivation if \(\delta (\eth ,[x, y]) = [\delta (\eth ,x), y] + [x, \delta (\eth ,y)]\) for \(x, y \in A\) and \(\eth \in \partial \).

Throughout this section, we assume A is a Lie \(C^{*}\)-algebra with norm \(\| \cdot \|_{A}\).

We prove the generalized Hyers–Ulam stability of derivations on Lie \(C^{*}\)-algebras for the functional equation \(D_{\mu}f(\eth ,x, y) =0\).

Theorem 5.2

Let \(f:\partial \times A \rightarrow A\) be a mapping for which there exist functions \(\varphi _{i} : A^{2} \rightarrow [0, \infty )\) satisfying (3.1) and

for \(x, y \in A\), \(\eth \in \partial \) and \(i=1,\ldots , n\). Besides, there exist constants \(L_{i} <1\) s.t. \(\varphi _{i}(x, 0) \le 2 L_{i} \varphi _{i}(\frac{x}{2}, 0)\) for \(x \in A\) and \(i=1,\ldots , n\). Then there exists a unique Lie derivation \(\delta :\partial \times A \rightarrow A\) satisfying (3.3).

Proof

By the same reasoning as the proof of Theorem 2.1, there exists a unique evolutive \(\mathbb{C}\)-linear mapping \(\delta :\partial \times A\rightarrow A\) satisfying (3.3). The mapping \(\delta :\partial \times A\rightarrow A\) is further defined by

for \(x \in A\) and \(\eth \in \partial \).

According to (5.1),

for \(x, y \in A\) and \(\eth \in \partial \). So,

for \(x, y \in A\) and \(\eth \in \partial \). Thus, \(\delta :\partial \times A \rightarrow A\) is a derivation satisfying (3.3). □

Theorem 5.3

Assume \(f:\partial \times A \rightarrow A\) is a mapping for which there exist functions \(\varphi _{i} : A^{2} \rightarrow [0, \infty )\) satisfying (3.1) and (5.1) for \(i=1, \ldots , n\). In addition, if there exist constants \(L_{i} <1\) s.t. \(\varphi _{i}(x, 0) \le \frac{1}{2} L_{i} \varphi _{i}(2x, 0)\) for \(x \in A\) and \(i=1, \ldots , n\), then there exists a unique Lie derivation \(\delta :\partial \times A \rightarrow A\) satisfying (3.4).

Proof

The proof is similar to the proofs of Theorems 2.2 and 2.3. □

Remark 5.4

For the inequalities controlled by the product of powers of norms, one can obtain results similar to Theorems 2.3 and 2.4.

Corollary 6.1

Assume \(r<1\), \(\theta >0\) and \(f :\partial \times A \rightarrow B\) is a mapping such that

for \(\mu \in \mathbb{T} ^{1}\) and \(x, y \in A\) and \(\eth \in \partial \). Then there exists a unique \(C^{*}\)-algebra homomorphism \(H :\partial \times A \rightarrow B\) s.t.

for \(x \in A\) and \(\eth \in \partial \).

Proof

The proof follows from Theorem 2.1 by taking

for \(x, y \in A\). Setting \(L_{i}= 2^{r-1}\), \(i=1,\ldots ,9\), we have the desired result. □

Corollary 6.2

Assume \(r>2\), \(\theta >0\) and \(f : \partial \times A \rightarrow B\) is a mapping satisfying (6.1), (6.2) and (6.3). Then there exists a unique \(C^{*}\)-algebra homomorphism \(H :\partial \times A \rightarrow B\) s.t.

for \(x \in A\) and \(\eth \in \partial \).

Proof

The proof follows from Theorem 2.2 by taking

for \(x, y \in A\). Choosing \(L_{i}= 2^{1-r}\), \(i=1,\ldots , 9\), we get the desired result. □

Corollary 6.3

Assume \(r<\frac{1}{2}\), \(\theta >0\) and \(f : \partial \times A \rightarrow B\) is an odd mapping satisfying

for \(\mu \in \mathbb{T} ^{1}\) and \(x, y \in A\) and \(\eth \in \partial \). Then there exists a unique \(C^{*}\)-algebra homomorphism \(H :\partial \times A \rightarrow B\) s.t.

for \(x \in A\) and \(\eth \in \partial \).

Proof

The proof follows from Theorem 2.3 by taking

for \(x, y \in A\). Picking \(L_{i}= 2^{2r-1}\), \(i=1,\ldots ,9\), we come to the desired result. □

Corollary 6.4

Assume \(r>1\), \(\theta >0\) and \(f :\partial \times A \rightarrow B\) is an odd mapping satisfying (6.6), (6.7) and (6.8). Then there exists a unique \(C^{*}\)-algebra homomorphism \(H :\partial \times A \rightarrow B\) s.t.

for \(x \in A\) and \(\eth \in \partial \).

Proof

The proof can be derived from Theorem 2.4 by taking

for \(x, y \in A\). Letting \(L_{i}= 2^{1-2r}\), \(i=1,\ldots , 9\), we get the desired result. □

Corollary 6.5

Assume \(r <1\), \(\theta >0\) and \(f :\partial \times A \rightarrow A\) is a mapping s.t.

for \(\mu \in \mathbb{T} ^{1}\) and \(x, y \in A\) and \(\eth \in \partial \). Then there exists a unique derivation \(\delta :\partial \times A \rightarrow A\) s.t.

for \(x \in A\) and \(\eth \in \partial \).

Proof

The proof follows from Theorem 3.1 by taking

for \(x, y\in A\). Setting \(L_{i}= 2^{r-1}\), \(i=1, \ldots 9\), we come to the conclusion. □

Corollary 6.6

Assume \(r > 2\), \(\theta >0\) and \(f :\partial \times A \rightarrow A\) is a mapping satisfying (6.11) and (6.12). Then there exists a unique derivation \(\delta : \partial \times A \rightarrow A\) s.t.

for \(x \in A\) and \(\eth \in \partial \).

Proof

The proof comes directly from Theorem 3.2 by taking

for \(x, y \in A\). Choosing \(L_{i}= 2^{1-r}\), \(i=1,\ldots , 9\), we get the desired result. □

Remark 6.7

For the inequalities controlled by the product of powers of norms, one can obtain results similar to Corollaries 6.3 and 6.4.

Corollary 6.8

Assume \(r<1\), \(\theta >0\) and \(f : \partial \times A \rightarrow B\) is a mapping satisfying (6.1) s.t.

for \(x, y \in A\) and \(\eth \in \partial \). Then there exists a unique Lie \(C^{*}\)-algebra homomorphism \(H :\partial \times A \rightarrow B\) satisfying (6.4).

Proof

The proof follows from Theorem 5.2 by taking

for \(x, y \in A\). Then setting \(L_{i}= 2^{r-1}\), \(i=1, \ldots , 9\), we deduce the desired result. □

Corollary 6.9

Assume \(r>2\), \(\theta >0\) and \(f :\partial \times A \rightarrow B\) is a mapping satisfying (6.1) and (6.15). Then there exists a unique Lie \(C^{*}\)-algebra homomorphism \(H :\partial \times A \rightarrow B\) satisfying (6.5).

Proof

The proof follows from Theorem 5.3 by taking

for \(x, y \in A\). Letting \(L_{i}= 2^{1-r}\), \(i=1,\ldots , 9\), we get the desired result. □

Remark 6.10

For the inequalities controlled by the product of powers of norms, one can obtain results similar to Corollaries 6.3 and 6.4.

Corollary 6.11

Assume \(r <1\), \(\theta >0\) and \(f :\partial \times A \rightarrow A\) is a mapping satisfying (6.11) s.t.

for \(x, y \in A\) and \(\eth \in \partial \). Then there exists a unique Lie derivation \(\delta :\partial \times A \rightarrow A\) satisfying (6.13).

Proof

The proof comes directly from Theorem 5.2 by taking

for \(x, y\in A\). Then setting \(L_{i}= 2^{r-1}\), \(i=1,\ldots , 9\), we have the desired result. □

Corollary 6.12

Assume \(r > 2\), \(\theta >0\) and \(f :\partial \times A \rightarrow A\) is a mapping satisfying (6.11) and (6.16). Then there exists a unique Lie derivation \(\delta :\partial \times A \rightarrow A\) satisfying (6.14).

Proof

It follows from Theorem 5.3 by taking

for \(x, y \in A\). Then choosing \(L_{i}= 2^{1-r}\), \(i=1,\ldots , 9\), we imply the desired result. □

Remark 6.13

For the inequalities controlled by the product of powers of norms, we can derive results similar to Corollaries 6.3 and 6.4.

Using a new class of control functions defined by some special function, we study the generalized Hyers–Ulam stability of homomorphisms and multi-stability of derivations in \(C^{*}\)-algebras and Lie \(C^{*}\)-algebras for the following random operator equation based on fixed point methods:

where μ a complex number with \(|\mu | = 1\).

There are no data that we needed for this manuscript.

The authors are thankful to the area editor and referees for giving valuable comments and suggestions. Chenkuan Li is supported by NSERC Discovery Grant number 2019-03907.

This research does not receive specific funding, the corresponding author is a full-time member of the School of Mathematics, Iran University of Science and Technology, Narmak, Tehran, Iran.

Authors and Affiliations

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

   Safoura Rezaei Aderyani & Reza Saadati

2. Department of Mathematics and Computer Science, Brandon University, Brandon, Manitoba, R7A 6A9, Canada

   Chenkuan Li

3. Department of Mathematics, National Technical University of Athens, Zografou Campus, 157 80, Athens, Greece

   Themistocles M. Rassias

4. Research Institute for Natural Sciences, Hanyang University, Seoul, 04763, South Korea

   Choonkil Park

Contributions

S.R.A., methodology, writing–original draft preparation. R.S., supervision and project administration. CL, project administration. T.M.R., supervision and project administration. C.P., methodology. All authors read and approved the final manuscript.

Corresponding author

Correspondence to Reza Saadati.

Competing interests

The authors declare no competing interests.

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