1. Introduction
A question of the stability of functional equations concerning group homomorphisms was first raised by S. M. Ulam in 1940 [
1]. In the next year, a partial affirmative answer to the question of Ulam was given by D. H. Hyers [
2] for additive mappings on Banach spaces. Hyers’ theorem was generalized by T. Aoki [
3] for additive mapping. In 1978, Rassias [
4] provided a generalization of the theorem for linear mappings by allowing the Cauchy differences to be unbounded. Subsequently, the result of Rassias’ theorem was generalized by P. Găvruta [
5], allowing the Cauchy difference controlled by a general unbounded function which is called
the generalized Hyers–Ulam stability. On the other hand, Rassias and Šemrl found an example of a continuous real-valued function from
for which the Hyers–Ulam stability does not occur. See [
6].
Let
X and
Y be real vector spaces and
a mapping. For a cubic function
,
f clearly satisfies the following functional equation
For this reason, it is natural that Equation (
1) is called a cubic functional equation and every solution of Equation (
1) is also called a cubic function. The general solution for Equation (
1) was solved by J. M. Rassias [
7] for a mapping from a real normed space to a Banach space. Jun et al. [
8] proved that the cubic functional Equation (
1) is equivalent to the following functional equation
In [
9], Chu et al. extended the cubic functional equation to the following generalized form
where
is an integer, and they also proved the generalized Hyers–Ulam stability. The stability problem for cubic functional equations has been extensively investigated by many mathematicians (see [
10,
11,
12].)
In [
13], J. M. Rassias introduced the functional equation as follows:
It is obvious that
is a solution of Equation (
3), so we call Equation (
3) a quartic functional equation. Chung and Sahoo [
14] investigated the general solution of (
3) and A. Najati [
15] proved the generalized Hyers–Ulam stability for the quartic functional Equation (
3) using the idea of Găvruta [
5]. The stability results of quartic functional equations can be found in several other papers (see [
16,
17,
18].) There are a number of papers and research monographs regarding various generalizations and applications of the generalized Hyers–Ulam stability of several functional equations. See [
19,
20,
21,
22]. Park investigated the generalized Hyers–Ulam stability for additive mappings, Jensen mappings and quadratic mappings in 2-Banach spaces in [
23,
24].
Misiak [
25,
26] introduced the notion of
n-normed spaces which is one of the generalizations of normed spaces and 2-normed spaces. For more information of the phase spaces, we refer to the papers [
27,
28,
29,
30]. Recently, Chu et al. [
31] studied the generalized Hyers–Ulam stabilities of the Cauchy functional equations, the Jensen functional equations and the quadratic functional equations on
n-Banach spaces. In [
32], Brzdȩk and Ciepliński proved a fixed point theorem for operator acting on a class of functions with values in an
n-Banach space. For study of the Hyers–Ulam stability, the extension to
n-Banach spaces is valuable in terms of development of the field of functional equations.
Motivated by results in [
31,
32], we focus on the generalized Hyers–Ulam stabilities of several functional equationss—in detail, the cubic functional equation expressed as Equation (
2) and the quartic functional equation expressed as Equation (
3) on
n-Banach spaces. We prove the generalized Hyers–Ulam stabilities of the functional equations on the spaces.
The contents of paper: In
Section 2, we recall definitions and lemma in
n-Banach spaces to investigate the generalized Hyers–Ulam stabilities on the spaces. In
Section 3, we investigate the generalized Hyers–Ulam stability problem in
n-Banach spaces. The problems for the generalized Hyers–Ulam stability related on the cubic functional equation in
n-Banach spaces are studied in
Section 3.1. We also deal with applications of the stabilities for the functional equations on the spaces. In
Section 3.2, we focus on the the quartic functional equation and prove the generalized stability on the
n-Banach spaces.
2. Preliminaries
In this section, we recall definitions and lemma in n-Banach spaces as a preliminary step toward the main theorems.
Definition 1 ([
25,
26])
. Let X be a real linear space with and be a function. Then is called a linear n-normed space if are linearly dependent;
for every permutation of ;
;
for all and all . The function is called an n-norm on X.
Definition 2 ([
31])
. Let be a sequence in a linear n-normed space X. The sequence is said to be n-convergent in X if there exists an element such thatfor all . In this case, we say that a sequence converges to the limit x, simply denoted by with a slight abuse of notation. Definition 3 ([
31])
. A sequence in a linear n-normed space X is called an n-Cauchy sequence if for any , there exists such that for all , for all . For convenience, we will write for an n-Cauchy sequence . An n-Banach space is defined to be a linear n-normed space in which every n-Cauchy sequence is n-convergent. The following lemma is a useful toolbox for a linear n-normed space.
Lemma 1 ([
31]).
Let be a linear n-normed space and . Then- (1)
If for all , then .
- (2)
for all .
- (3)
if a sequence is convergent in X, thenfor all
From now on, let X be a real linear space and let be an n-Banach space unless otherwise stated.
3. Main Results
In this section, we present the generalized Hyers–Ulam stabilities for the several functional equations in n-Banach spaces. We solve the problems for the stabilities and consider applications of the results in n-Banach spaces.
3.1. Stability of the Cubic Functional Equation
We start this subsection by investigating the generalized Hyers–Ulam stability for the cubic functional Equation (
2) in
n-Banach spaces. For convenience, we use the the notation
as follows:
for all
. If
then the function
f is a solution of the cubic functional equation. Thus,
is an approximate remainder of the functional Equation (
2) and acts as a perturbation of the equation. We use this approximate remainder to solve the generalized Hyers–Ulam stability for the cubic functional equation in
n-Banach spaces.
Now, in the following theorem, we present a solution of stability for the cubic funtional equation in the spaces.
Theorem 1. Let be a function such thatfor all Suppose that a function be a surjective mapping satisfyingfor all where for each . Then there is a unique cubic mapping such thatfor all where for each . We call the function f the pseudo-cubic function for the error function , and the solution function C is the cubic function induced from the pseudo-cubic function f.
Proof. Let
. First, take
in (
4) to have
for all
. Replacing
x by
in (
6) and dividing by 8, we obtain
for all
. Using the induction on
we get that
for all
. For
, divide inequality (
8) by
and also replace
x by
to find that
for all
. We then obtain
for all
. Since
f is surjective, by Lemma 1, the sequence
is an
n-Cauchy sequence in
Z. Therefore, we may define a mapping
by
for all
By letting
in (
8), we arrive at the formula (
5). To show that the mapping
satisfies Equation (
2), replace
with
respectively, in (
4) and divide by
; then it follows that
for all
. Taking the limit as
in (
9), we immediately obtain that the mapping
C satisfies (
2).
Now, let
be another cubic mapping satisfying (
5). Then we have
which tends to zero as
for all
. By Lemma 1, we conclude that
for all
This completes the proof of the theorem. □
As an application of Theorem 1, we obtain a stability of Equation (
2) in the following corollary.
Corollary 1. Assume that is a real normed space and that is a linear n-normed space. Let and and let be a surjective mapping satisfyingfor all where for each . Then there is a unique cubic mapping such thatfor all where for each . Proof. The assertion follows from Theorem 1 by setting
for all
. □
In the next theorem we also deal with a solution of the cubic functional equation in
n-Banach spaces under different conditions. Next, we investigate the change of conditions for the pseudo-cubic function
f and the error function
, and also obtain a stability of Equation (
2) in the following theorem (compare with Theorem 1).
Theorem 2. Let be a function such thatfor all where for each . Suppose that a function be a surjective mapping satisfying (4). Then there is a unique cubic mapping such thatfor all where for each . Proof. Let
for each
. Take
in (
6) and multiply by eight to have
for all
. By replacing
x with
in (
11) and multiplying by eight, we get
for all
. Then we can find a unique cubic mapping
defined by
for all
, as in the proof of Theorem
4. This completes the proof. □
Using the above theorem, we immediately get the following corollary.
Corollary 2. Assume that is a real normed space and that is a linear n-normed space. Let , and . Let be a surjective mapping satisfyingfor all where for each . Then there is a unique cubic mapping such thatfor all where for each . Proof. The proof follows from Theorem 2 with
for all
. □
3.2. Stability of the Quartic Functional Equation
In this subsection, we discuss the generalized Hyers–Ulam stability of the quartic functional Equation (
3) in
n-Banach spaces. For
, we define
given by
The difference
means an approximate remainder of the functional Equation (
3).
Now we provide important consequences for the stability of the quartic functional equation.
Theorem 3. Let be a function such thatfor all Suppose that a function be a surjective mapping satisfyingfor all where for each , where . Then there is a unique quartic mapping such thatfor all where for each . From now on we call the function f the pseudo-quartic function for , and the solution function T is the quartic function induced from the pseudo-quartic function f.
Proof. Let
for each
. By letting
in (
12), we get
for all
. If we replace
x by
in (
14) and divide both sides of (
14) by
, we have that
for all
and integers
. Therefore, for all integers
, we obtain
and so
for all
. In a similar way as in the proof of Theorem 1, we can show that the sequence
is an
n-Cauchy sequence in
Z for all
. Define a mapping
by
for all
. By (
15), we have the inequality (
13). It follows from (
12) that
for all
. This implies that
is a quartic mapping. Let
be another quartic mapping satisfying (
13). Therefore we have
for all
. It follows from Lemma 1 that
for all
. This proves the uniqueness of
T. □
Now we show a simple application of Theorem 3 to obtain a stability of Equation (
3).
Corollary 3. Assume that is a real normed space and that is a linear n-normed space. Let and . Let be a surjective mapping satisfyingfor all where for each . Then there is a unique quartic mapping such thatfor all where for each . Proof. It is a consequence of Theorem 3 with
for all
. □
Next we consider the changes of conditions of the pseudo-quartic function and the error function, and we find a solution of the quartic functional equation in
n-Banach spaces. We prove the existence of a solution of Equation (
3) in
n-Banach spaces.
Theorem 4. Let be a function such thatfor all Suppose that a function be a surjective mapping satisfyingfor all where for each . Then there is a unique quartic mapping such thatfor all where for each . Proof. It follows from (
16) that
. Thus, we have
from (
17). By letting
in (
17), we get
for all
where
for each
. Through replacing
x by
in (
19) and multiplying by
, we obtain
for all
where
for each
. By (
20), we have
for all
where
for each
. As in the proof of Theorem 3, we can find a unique quartic mapping
defined by
for all
. This completes the proof. □
As an application of Theorem 1, we obtain a stability of Equation (
2) in the following corollary.
Corollary 4. Assume that is a real normed space and that is a linear n-normed space. Let and . Let be a surjective mapping satisfyingfor all where for each . Then there is a unique quartic mapping such thatfor all where for each . Proof. It is a direct consequence of Theorem 4 with
for all
. □