1. Introduction
Let
V and
W be real vector spaces,
X a real normed space,
Y a real Banach space,
(the set of natural numbers), and
a given mapping. Consider the functional equation
for all
, where
. The functional Equation (
1) is called an
n-monomial functional equation and every solution of the functional Equation (
1) is said to be a monomial mapping of degree
n. The function
given by
is a particular solution of the functional Equation (
1). In particular, the functional Equation (
1) is called an additive (quadratic, cubic, quartic, and quintic, respectively) functional equation for the case
(
,
,
, and
, respectively) and every solution of the functional Equation (
1) is said to be an additive (quadratic, cubic, quartic, and quintic, respectively) mapping for the case
(
,
,
, and
, respectively).
A mapping
is said to be additive if
for all
. It is easy to see that
for all
and all
(the set of rational numbers). A mapping
is called
n-additive if it is additive in each of its variables. A mapping
is called symmetric if
for every permutation
. If
is an
n-additive symmetric mapping, then
will denote the diagonal
for
and note that
whenever
and
. Such a mapping
will be called a monomial mapping of degree
n (assuming
). Furthermore, the resulting mapping after substitution
and
in
will be denoted by
. A mapping
is called a generalized polynomial (GP) mapping of degree
provided that there exist
and
i-additive symmetric mappings
(for
) such that
, for all
and
. For
, let
be the difference operator defined as follows:
for
. Furthermore, let
,
and
for all
and all
. For any given
, the functional equation
for all
is well studied. In explicit form we can have
The following theorem was proved by Mazur and Orlicz [
1,
2] and in greater generality by Djoković (see [
3]).
Theorem 1. Let V and W be real vector spaces, and , then the following are equivalent:
- (1)
for all .
- (2)
for all .
- (3)
for all , where is an arbitrary element of W and ) is the diagonal of an i-additive symmetric mapping .
In 2007, L. Cădariu and V. Radu [
4] proved a stability of the monomial functional Equation (
1) (see also [
5,
6,
7]), in particular, the following result is given by the author in [
6].
Theorem 2. Let p be a non-negative real number with , let , and let be a mapping such thatfor all . Then there exist a positive real number K and a unique monomial function of degree n such thatholds for all . The mapping is given byfor all . The concept of stability for the functional Equation (
1) arises when we replace the functional Equation (
1) by an inequality (
2), which is regarded as a perturbation of the equation. Thus, the stability question of functional Equation (
1) is whether there is an exact solution of (
1) near each solution of inequality (
2). If the answer is affirmative with inequality (
3), we would say that the Equation (
1) is stable.
The direct method of Hyers means that, in Theorem 2,
satisfying inequality (
3) is constructed by the limit of the sequence
as
.
Historically, in 1940, Ulam [
8] proposed the problem concerning the stability of group homomorphisms. In 1941, Hyers [
9] gave an affirmative answer to this problem for additive mappings between Banach spaces, using the direct method. Subsequently, many mathematicians came to deal with this problem (cf. [
10,
11,
12,
13,
14,
15,
16,
17]).
In 1998, A. Gilányi dealt with the stability of monomial functional equation for the case
(see [
18,
19]) and he proved for the case when
p is a real constant (see [
20]). Thereafter, C.-K. Choi proved stability theorems for many kinds of restricted domains, but his theorems are mainly connected with the case of
. If
in (
2), then the inequality (
2) cannot hold for all
, so we have to restrict the domain by excluding 0 from
X.
The main purpose of this paper is to generalize our previous result (Theorem 2) by replacing the real normed space X with a restricted domain S of a real vector space V and by replacing the control function with a more general function .
2. Stability of the Functional Equation (1) on a Restricted Domain
In this section, for a given mapping
, we use the following abbreviation
for all
.
Proof. From the equalities
we get the equality
for all
. Since the coefficient of the term
of the left-hand side in (
6) is
and the coefficient of the term
of the right-hand side in (
6) is
, we get the Equality (
4). We easily know that the coefficient of the term
of the left-hand side in (
6) is 0 and the coefficient of the term
of the right-hand side in (
6) is
. So we get the Equality (
5). ☐
We rewrite a refinement of the result given in [
6].
Lemma 2. (Lemma 1 in [
6])
The equalityholds for all . In particular, if for all , then Proof. By (
4), (
5), and the equality
, we get the equalities
for all
. ☐
Lemma 3. If f satisfies the functional equation for all with , then f satisfies the functional equation for all .
Proof. Since
,
for all
, and
for all
, we conclude that
f satisfies the functional equation
for all
. ☐
We rewrite a refinement of the result given in [
7].
Theorem 3. (Corollary 4 in [
7])
A mapping is a solution of the functional Equation (1)
if and only if f is of the form for all , where is the diagonal of the n-additive symmetric mapping . Proof. Assume that
f satisfies the functional Equation (
1). We get the equation
for all
. By Theorem 1,
f is a generalized polynomial mapping of degree at most
n, that is,
f is of the form
for all
, where
is an arbitrary element of
W and
) is the diagonal of an
i-additive symmetric mapping
. On the other hand,
holds for all
by Lemma 2, and so
.
Conversely, assume that
for all
, where
is the diagonal of the
n-additive symmetric mapping
. From
,
,
(
), we see that
f satisfies (
1), which completes the proof of this theorem. ☐
Theorem 4. Let S be a subset of a real vector space V and Y a real Banach space. Suppose that for each there exists a real number such that for all . Let be a function such thatfor all . If the mapping satisfies the inequalityfor all , then there exists a unique monomial mapping of degree n such thatfor all , whereIn particular, F is represented byfor all . Proof. Let
and
m be an integer such that
. It follows from (
7) in Lemma 2 and (
10) that
From the above inequality, we get the following inequalities
and
for all
. So the sequence
is a Cauchy sequence for all
. Since
and
Y is a real Banach space, we can define a mapping
by
for all
. By putting
and letting
in the inequality (
12), we obtain the inequality (
11) if
.
From the inequality (
10), we get
for all
, where
. Since the right-hand side in the above equality tends to zero as
, we obtain that
F satisfies the inequality (
1) for all
. By Lemma 3 and
,
F satisfies the Equality (
1) for all
. To prove the uniqueness of
F, assume that
is another monomial mapping of degree
n satisfying the inequality (
11) for all
. The equality
follows from the Equality (
8) in Lemma 2 for all
and
. Thus we can obtain the inequalities
for all
, where
. Since
as
and
,
for all
, i.e.,
for all
. This completes the proof of the theorem. ☐
We can give a generalization of Theorems 2 and 5 in [
6] as the following corollary.
Corollary 1. Let p and r be real numbers with and , let X be a normed space, , and be a mapping such thatfor all with . Then there exists a unique monomial mapping of degree n satisfying In particular, if , then f is a monomial mapping of degree n itself.
Proof. If we set
and
, then there exists a unique monomial mapping of degree
n satisfying
for all
with
by Theorem 4. Notice that if
F is a monomial mapping of degree
n, then
for all
and
. Hence the equality
holds for all
and
. So if
is the monomial mapping of degree
n satisfying (
14), then
satisfies the inequality with a real number
k
for all
.
Moreover, if
, then
and
. Hence we get
for all
by (
15). Since
and the inequality
holds for any fixed
with
and all natural numbers
k, we get
☐
Theorem 5. Let S be a subset of a real vector space V and Y a real Banach space. Suppose that for each there exists a real number such that for all . Let be a function such thatfor all . Suppose that a mapping satisfies the inequality (10)
for all , where for all . Then there exists a unique monomial mapping of degree n such thatfor all x with , where is defined as in Theorem 4.
In particular, F is represented byfor all . Proof. Let
and
m be an integer such that
. It follows from (
7) in Lemma 2 and (
10) that
for all
. From the above inequality, we get the inequality
for all
and
. So the sequence
is a Cauchy sequence by the inequality (
16). From the completeness of
Y, we can define a mapping
by
for all
. Moreover, by putting
and letting
in (
18), we get the inequality (
17) for all
with
. From the inequality (
10), if
m is a positive integer such that
for all
, then we get
for all
. Since the right-hand side in this inequality tends to zero as
, we obtain that
F is a monomial mapping of degree
n. To prove the uniqueness of
F assume that
is another monomial mapping of degree
n satisfying the inequality (
17) for all
with
. So the equality
holds for all
by (
8) in Lemma 2. Thus, we can infer that
for all positive integers
m, where
. Since
as
, we know that
for all
. This completes the proof of the theorem. ☐
We can give a generalization of Theorem 3 in [
6] as the following corollary.
Corollary 2. Let p and r be real numbers with and , and X a normed space. Let be a mapping satisfying the inequality (13)
for all with . Then there exists a unique monomial mapping of degree n satisfyingfor all with . The following example shows that the assumption
cannot be omitted in Corollarys 1 and 2. This example is an extension of the example of Gajda [
21] for the monomial functional inequality (
13) (see also [
22]).
Example 1. Let be defined byConsider that the function is defined byfor all . Then f satisfies the functional inequalityfor all , but there do not exist a monomial mapping of degree n and a constant such that for all . Proof. It is clear that f is bounded by 2 on
. If
, then
f satisfies (
21). And if
, then
which means that
f satisfies (
21). Now suppose that
. Then there exists a nonnegative integer
k such that
Hence
,
,
, and
for all
. Hence, for
,
From the definition of
f, the inequality (
22), and the inequality (
23), we obtain that
Therefore,
f satisfies (
21) for all
. Now, we claim that the functional Equation (
1) is not stable for
in Corollarys 1 and 2. Suppose on the contrary that there exists a monomial mapping of degree
n and constant
such that
for all
. Notice that
for all rational numbers
x. So we obtain that
for all
. Let
with
. If
x is a rational number in
, then
for all
, and for this
x we get
which contradicts (
25). ☐