1. Introduction and Motivation
As we all know, in the history of the research process of inequality theory, many important generalization studies often come from some simple inequalities that have widespread applications. Over the past more than five decades, rapid developments in inequality theory and its applications have contributed greatly to many branches of mathematics, economics, finance, physics, dynamic systems theory, game theory, and so on; for more details, one can refer to [
1,
2,
3,
4] and the references therein.
The following new integral inequality (here we regard it as a theorem) arose from the 29
International Mathematics Competition for University Students (for short, IMC 2022), which was held in Blagoevgrad, Bulgaria on 1–7 August 2022. For more information (including proofs), please visit the following official website of IMC 2022:
https://www.imc-math.org.uk (accessed on 1 August 2022).
Theorem 1. Let be an integrable function such that for all . Then .
Motivated by the above integral inequality, the following questions arise naturally.
Question 1. Can we establish new real generalizations of Theorem 1?
Question 2. Does Theorem 1 still hold if we replace the codomain of f with ?
In this work, our questions will be answered affirmatively. In
Section 2, we successfully establish a new real generalization (see Theorem 2 below) of Theorem 1, which is a positive answer to Question 1. In
Section 3, we first construct a new simple counterexample to show that Question 2 is not always true. Furthermore, we establish an equivalent theorem (see Theorem 3 below) of Theorem 2. Finally, some applications of our new results are given in
Section 4. The new results we present in this paper are novel and developmental.
2. New Results for Question 1
The following result is very crucial for answering Question 1.
Lemma 1. Let be an integrable function on . Then Proof. By using integration by substitution (see, e.g., [
5]), we have
Note that
so it is easy to see that
Combining (
1) and (
2) together with (
3), we prove the desired conclusion. □
With the help of Lemma 1, we can establish the following generalization of Theorem 1.
Theorem 2. Let be an integrable function such that for all , where is a constant. Then The case of equality holds in (5) if and only if for all . Proof. We use two methods to show (
5).
Method 1. By (
4) and using the arithmetic-mean–geometric-mean (AM-GM) inequality, we have
By (
6) and applying Lemma 1, we arrive at
Obviously, the equality holds in (
5) if and only if the equality holds in (
6) and if and only if
for all
.
Method 2. By applying Lemma 1 and using (
4), it follows that
Applying Cauchy–Schwarz inequality, we obtain
This proves the inequality (
5). Clearly, the equality holds in (
5) if and only if
for all
. □
Remark 1. By taking and in Theorem 2, we can prove Theorem 1.
Remark 2. There are many functions satisfying condition (4), as in Theorem 2, such as
- (i)
, , where is a constant;
- (ii)
, , where with ;
- (iii)
, ;
- (iv)
, ;
- (v)
3. New Results for Question 2
In this section, we first provide a simple counterexample to show that Question 2 is not always true if we replace the codomain of f with .
Example 1. Let be defined by Then, f is an integrable function on but not continuous on . Clearly, satisfies for all . However, it is easy to see that By applying Theorem 2, we obtain the following result.
Theorem 3. Let be an integrable function such that for all , where λ is a nonzero constant. Then The case of equality holds in (8) if and only if for all . Proof. Due to (
7), we know that
for all
. So we can define
by
Since
g is integrable,
f is integrable. From (
7) again, we obtain
Let
. Then
. Hence, all conditions in Theorem 2 are satisfied. By Theorem 2, we obtain
and the equality holds in (
8) if and only if
. The proof is completed. □
Remark 3. We applied Theorem 2 to show Theorem 3. It is obvious that Theorem 2 is a special case of Theorem 3. Therefore, we can conclude that Theorems 2 and 3 are indeed equivalent.
Taking advantage of Theorem 3, we easily obtain the following results.
Corollary 1. Let be an integrable function such that for all , where λ is a nonzero constant. Then The case of equality holds in (9) if and only if for all . Proof. Taking and in Theorem 3, then the desired result is obtained. □
Corollary 2. Let . Suppose that is an integrable function such that for all . Then The case of equality holds in (10) if and only if for all . Proof. Take , , and in Theorem 3, then the desired conclusion is proved. □
As a consequence of Theorem 3, we obtain the following theorem.
Theorem 4. Let be a function satisfying . Suppose that there exist with such that for all , where λ is a nonzero constant. Then, for any with and , we have Proof. Define
by
Since
,
. Hence,
h is integrable on
. It follows that
g,
, and
are integrable on
and
Hence all conditions in Theorem 3 are satisfied. By utilizing Theorem 3, we obtain
and
The proof is completed. □
4. Some Applications
In this section, we first establish the following new useful inequalities, which improve the known inequalities for exponential functions.
Theorem 5. Let . Then, the following hold.
- (i)
If , then for all .
- (ii)
If , then for all .
- (iii)
If , then for all .
Proof. Given
. Let
for
. Then
f is integrable on
, and
Hence, by applying Theorem 2, we have
(i) If
, then
. Note that
holds for
. So the equality does not hold in (
12). From (
12), we obtain
(ii) Clearly, if , then for all .
(iii) If
, then
. Since
holds for
, the equality does not hold in (
12). Hence, using (
12) again, we obtain
In particular, by taking
, we have
The proof is completed. □
Next, we provide a new simple proof of the following important fundamental inequality for hyperbolic sine functions by applying Theorem 2, Theorem 3, or their corollaries.
Theorem 6. for all
Proof. Given
. Let
for
. Then
f is integrable on
and
By applying Theorem 2 (or Theorem 3 or Corollary 2), we obtain
Since
for
, we obtain
The proof is completed. □
In this paper, we introduce the concept of quasi-hyperbolic sine function.
Definition 1. A function q-sinh is said to be a quasi-hyperbolic sine function if Remark 4. In [6], Nantomah, Okpoti, and Nasiru defined generalized hyperbolic sine function using It is obvious that a hyperbolic sine function is a generalized hyperbolic sine function, and a generalized hyperbolic sine function is a quasi-hyperbolic sine function, but the converse is not true.
We now give the following new inequalities for quasi-hyperbolic sine functions.
Theorem 7. Let . Then, the following hold.
- (i)
If , then q- for all .
- (ii)
If , then q- for all .
- (iii)
If , then q- for all .
Proof. Given
. Let
for
. Thus,
f is integrable on
and
By applying Theorem 2 (or Theorem 3 or Corollary 2), we obtain
(i) If
, then
. Since
for
, the equality does not hold in (
13). Hence (
13) yields
(ii) Clearly, q- for all .
(iii) If
, then
. Since
for
, the equality does not hold in (
13). So, from (
13) again, we obtain
The proof is completed. □
Remark 5. Theorem 6 is a special case of Theorem 7 (iii).
Theorem 8. Let . Then there exists such that Proof. From the Lagrange mean value theorem or integral mean value theorem, it is easy to see that there exists
such that
We now claim that
. Let
for
. Then
f is integrable on
and
Note that
holds for
. Accordingly, by applying Theorem 2, we obtain
which follows immediately from (
14) and (
15) that
. Therefore,
. □
Theorem 9. Let . Then there exists such that Proof. Making full use of the Lagrange mean value theorem, we can find
, such that
We now speculate that
. To this end, put
for
. Thus
f is integrable on
and
Note that
holds for
. So, by utilizing Theorem 2, we obtain
Combining (
16) and (
17), we obtain
. Therefore, we show
. □
5. Conclusions
In this paper, we study two questions for Theorem 1 as follows:
Question 1. Can we establish new real generalizations of Theorem 1?
Question 2. Does Theorem 1 still hold if we replace the codomain of f with ?
We establish Theorem 2, which is a new real generalization of Theorem 1, and a positive answer to Question 1. A new simple counterexample is given to verify that Question 2 is not always true. Furthermore, we prove Theorem 3, which is equivalent to Theorem 2, and show some applications of our new results. In summary, our new results are original, novel, and developmental in the literature. We hope that our new results can be applied to nonlinear analysis, mathematical physics, and related fields in the future.