1. Introduction and Some Basic Notations
As we all know, the following transform
is usually called a Laplace–Stieltjes transform, if
is a bounded variation on any finite interval
, and
and
t are real variables. Laplace–Stieltjes transform was first named after Pierre-Simon Laplace and Thomas Joannes Stieltjes, and is also an integral transform similar to the Laplace transform. Over the past 80 years or so, it has been used in many fields of mathematics, such as functional analysis, and certain areas of theoretical and applied probability.
Yu [
1] in 1963 first studied the growth and convergence of Laplace–Stieltjes transforms (
1) and gave the famous Valiron–Knopp–Bohr formula of the associated abscissas of bounded convergence, absolute convergence and uniform convergence of Laplace–Stieltjes transforms, and the Borel lines of entire functions represented by Laplace–Stieltjes transforms. After his wonderful results, many mathematicians had paid considerable attention focusing on the growth and the value distribution of analytic functions defined by Laplace–Stieltjes transforms convergent in the half-plane and whole complex plane, and obtained a series of classic and important results. For example, L. N. Shang, Z. S. Gao, Z. X. Xuan, etc. further investigated the value distributions of analytic functions of some kinds of growth defined by Laplace–Stieltjes transforms, and obtained some results about the singular direction and points of Laplace–Stieltjes transforms (see [
2,
3,
4,
5]); C. Singhal, G. S. Srivastava, Y. Y. Kong, S. Y. Liu and H. Y. Xu studied the properties on the approximation of entire functions represented by Laplace-stieltjes transforms, and obtained some interesting theorems on the relationship between the error and growth (see [
6,
7,
8,
9]); O. Posiko and M. M. Sheremeta [
10] in 2007 explored the relationships between the growth and the maximum term of Laplace–Stieltjes transform
, where
, M. S. Dobushovskyi, M. M. Sheremeta [
11,
12] in 2017 and 2021, respectively, further analyzed the convergence and relative growth of such transform; Y. J. Bi and Y. Y. Huo [
13] recently considered the growth of the double Laplace–Stieltjes transforms, and obtained some foundation growth theorems; Y. Y. Kong and his co-authors studied the growth of analytic functions defined by Laplace–Stieltjes transforms which converge in the half plane and the whole plane, and gave a great number of important theorems concerning the zero order, the generalized order, the finite and infinite order, and so on (see [
14,
15,
16,
17,
18,
19,
20,
21]).
In order to study the growth of Laplace–Stieltjes transform (
1), we usually take a sequence
satisfying
and
And denote
if Laplace–Stieltjes transform (
1) satisfies
then in view of Refs. [
1,
22,
23], we can conclude that
, i.e.,
is analytic on the whole plane. For convenience, let
to denote the class of all the functions
of the form (
1) which are analytic in the half plane
and the sequence
satisfy (
2)–(
4).
Usually, we utilize the order and the type to estimate the growth of , which are defined as follows.
Definition 1 (see [
19]).
If and we call is of order ρ in the whole plane; if we call is of lower order τ in the whole plane, where . Definition 2 (see [
19]).
If , and is of order , then we define the type and the lower type of Laplace–Stieltjes transform , respectively, For
, Luo and Kong [
19] in 2012 discussed the properties on entire functions represented by a Laplace–Stieltjes transform of finite order, and obtained.
Theorem 1 (see [
19,
20]).
If , and is of order and of type T, then Furthermore, if and form a non-decreasing function of n, then Remark 1. For , we can see that the (lower) order and the (lower) type cannot better characterize the growth of the maximum module of (1). In view of Remark 1, Xu and Liu [
9] in 2019 investigated the growth of Laplace–Stieltjes transforms for the case
, by using the concepts of the logarithmic order and the logarithmic type below.
Definition 3 (see [
9]).
If , and is of order , and then is called the logarithmic order of of zero order. Furthermore, if , we define the logarithmic type and the lower logarithmic type of , respectively, Remark 2. We say that is of perfectly logarithmic linear growth if and only if and . Obviously, as .
Theorem 2 (see ([
9], Theorem 1.5)).
If Laplace–Stieltjes transform , and is of zero order and of logarithmic order , then Theorem 3 (see ([
9], Theorem 1.6)).
If Laplace–Stieltjes transform , and is of zero order and of logarithmic order and logarithmic type , then Remark 3. In fact, in view of Theorem 3 and Lemma 1, we haveand Motivated by Theorems 2 and 3, one may ask the following questions.
Question 1. What will happened to the parameters , if is of the lower logarithmic type , or is of perfectly logarithmic linear growth?
Question 2. What can be said about the correlation between the logarithmic growth and the center index of the maximum term of Laplace–Stieltjes transform with zero order?
In view of the above questions, we will study the properties of logarithmic growth of entire functions defined by Laplace–Stieltjes transforms convergent in the whole plane, including the lower logarithmic type
, and the relations about the logarithmic type
, the lower logarithmic type
,
,
and
.
As far as we know, it appears that the study of the logarithmic growth of Laplace–Stieltjes transforms has seldom been involved in the literature before now. The paper is organized as follows. In
Section 2, we will discuss the lower logarithmic type
of entire functions defined by Laplace–Stieltjes transforms. In
Section 3, we will study the relation among the logarithmic order
, logarithmic type
, lower logarithmic type
and the center index
of the maximum term. In
Section 4, we will establish the expression of the (lower) logarithmic type by the logarithmic order
, and also obtain some equivalence conditions between the (lower) logarithmic type
and
. Finally, the conclusions of this paper will be presented in
Section 5.
2. The Lower Logarithmic Type of Laplace–Stieltjes Transform
We first give the following lemma, which is used to prove our two main theorems.
Lemma 1 (see [
19], Lemma 2.1)).
If Laplace–Stieltjes transform , for any and , we have where C is a constant. In fact, we obtain the main result about the lower logarithmic type of Laplace–Stieltjes transform in the case as follows.
Theorem 4. If Laplace–Stieltjes transform , and is of logarithmic order , and of lower logarithmic type , and if and the functionis a non-decreasing function of n, then Remark 4. Obviously, Theorem 4 is a good supplement of Theorems 2 and 3.
In order to prove Theorem 4, we only give the proof of Theorems 5 and 6 below.
Theorem 5. If Laplace–Stieltjes transform , and is of logarithmic order and lower logarithmic type , and if , then Proof. Assume that
, for any given
such that
, we have from (
8) that there exists a positive integer
such that for all
,
Thus, it follows by Lemma 1 and (
9) that
Taking
, we have from (
10) that
In view of (
11), and combining the definition of lower logarithmic type
, we have
. If
, the conclusion holds obviously. In the case
, similar to the above argument, we can also obtain the inequality when we replace
by an arbitrarily large number.
Therefore, this completes the proof of Theorem 5. □
Theorem 6. If Laplace–Stieltjes transform , and is of logarithmic order and lower logarithmic type , and if the function (7) form a non-decreasing function of n, then Proof. Assume that
. From the assumption of Theorem 6, and in view of Definition 3 and Lemma 1, for any given small number
, there exists a fixed
such that for all
,
that is,
Let
and let
and
be two consecutive maximum terms, then
for all
satisfying
. Let
, we have
and
Thus, it follows from (
12)–(
15) that
Let
, and let
, it follows from (
16) that
Besides, the conclusion holds obviously if . By using the same argument as in the above, we can also prove the inequality in the case when we replace by an arbitrarily large number.
Therefore, this completes the proof of Theorem 6. □
3. Some Inequalities on the Maximum Term Index
In order to further explore the properties of logarithmic growth of Laplace–Stieltjes transform
, we first introduce the following indicators. Let
be of logarithmic order
. Here and below, unless otherwise specified, we always assume
. Thus, we define
and
Obviously, we have and . As for the further relationship between them, we have
Theorem 7. If Laplace–Stieltjes transform , and is of logarithmic order , logarithmic type and lower logarithmic type . Then we haveand Remark 5. In view of , by combining with (17) and (18), we have To prove this result, we require the following lemma.
Lemma 2 (see [
20], Lemma 2.2)).
If Laplace–Stieltjes transform , then we have for . Proof of Theorem 7. In view of
and
, it follows that
and
. Thus,
holds obviously. Define
,
. Since
, then
is a increasing function in
. Thus,
. Replaced
x by
, we can easily prove that
In view of the definitions of
v and
V, we have that for any
By Lemma 2, for any
and
, it follows that
holds for any fixed positive number
. Since
is an increasing function of
, we have from (
21) and (
22) that
for all
. In view of Remark 1.2, and let
, it follows from (
23) that
Thus, let
in (
24), and let
in (), we have
By combining with the first inequality and (
22), we also obtain that
Thus, let
in (), and let
in (
27), we have
By combining with (
19), (
20), (
26) and (
29), we can prove the conclusions of Theorem 7 easily.
Therefore, this completes the proof of Theorem 7. □
Next, the following results show the relations among the quotas and H.
Theorem 8. If Laplace–Stieltjes transform , and is of logarithmic order . Then we have Proof. By making use of Lemma 2 and (
21), and combining with the definitions of
h and
H, we can prove the conclusions of Theorem 8 easily. □
Theorem 9. If Laplace–Stieltjes transform , and is of logarithmic order , logarithmic type and lower logarithmic type , . Then we have
Remark 6. From Theorem 9 (i), we can see that .
Proof. (i)
If
in view of Lemma 1, it follows
and
By Lemma 2, for
,
, we have
Dividing
into two side of (
31), and let
, we have
By applying L’Hospital’s rule, and let
, it is easy to obtain
Thus, in view of (
32) and (
33), we have
. Similarly, let
, we have
and
By combining with
, we have
Now, we will prove the sufficiency of Theorem 9 (i). Let
, in view of the definitions of
v and
V, we have
. By combining with Remark 5, we obtain that
, that is,
Therefore, this completes the conclusion (i) of Theorem 9.
(ii) We first prove the sufficiency of Theorem 9 (ii). Let . In view of Remark 5 and , it follows that and . Furthermore, in view of Theorem 7 (i), we can obtain that if . Thus, the sufficiency of Theorem 9 (ii) is proved.
Next, we will prove the necessity of Theorem 9 (ii). Let
. Then it follows that
and
. Otherwise, if
, then we have from () that
. This is a contradiction since
and
is arbitrary. Similarly, if
, then we have from (
27) that
. This is a contradiction since
and
. Besides, in view of Theorem 7 (i), we can obtain that
if
. Thus, the necessity of Theorem 9 (ii) is proved.
Therefore, we complete the proof of Theorem 9. □
4. Applications
In this section, we will establish some results to reveal the relationship between the logarithm order
, the logarithm type
, the lower logarithm type
, the form exponent
and the form coefficients
of Laplace–Stieltjes transformation of small growth, by applying the inequalities given in
Section 1 and
Section 2. Denote
Theorem 10. If Laplace–Stieltjes transform , and is of logarithmic order , logarithmic type and lower logarithmic type . If andthen we have The following example shows that the inequalities in (
35) are best possible to some extent.
Example 1. Let and satisfy Then (1) can be expressed as the form In view of Theorems 2-4, by simple calculation, we have , and . Thus, this shows that the equal sign situation in (35) can be attained. Proof. Assume that
. From the definitions of
w and
W, for a fixed positive integer
, then we obtain that for any
, the following inequalities
hold for all
. Thus, for any positive integer
, we have
Let
in (
37), adding them, then it follows that
In view of (
34) and (
38), for all
, then we obtain that
Thus, it follows from (
39) that
By combining with Remark 3 and Theorem 4, we have from (
40) that
If
or
, the conclusions (
41) are obvious. If
, then
. We can obtain (
40) by replacing
by an arbitrarily large number. If
, then
. We also obtain (
38) by replacing
by an arbitrarily large number. Thus, we can obtain (
41) in either case.
Therefore, this completes the proof of Theorem 10. □
Theorem 11. If Laplace–Stieltjes transform , and is of logarithmic order and logarithmic type . If the sequence satisfy (34) and form a non-decreasing function of , then we have Proof. From the assumptions of Theorem 11, and the definitions of logarithmic type
, for any given
, there exists a positive integer
such that for all
, we have
Thus, it follows that
and
By combining with the non-decreasing function
, we obtain
that is,
In view of
, and let
, then we obtain from (
46) that
By combining with the fact that
for
, it follows from (
47) that
Thus, we can obtain (
42) from (
35) and (
48) immediately.
Therefore, we complete the proof of Theorem 11. □
Theorem 12. If Laplace–Stieltjes transform , and is of logarithmic order . If satisfy and form a non-decreasing function of , then we have Proof. From the assumptions of Theorem 12, and the definitions of
v and
V, for any positive number
, there exists
such that for all
,
Since
is an increasing function of
n, taking
then we have that
is the maximum term for
, that is,
. In view of (
50) and (
51), we have
for all
. Thus, let
, it follows from (
52) that
and in view of
, the second inequality in (
53) becomes
Obviously, (
53) and (
40) hold for
and
. Besides, if
, we can obtain (
54) by replacing
by an arbitrary large number in (
50). Similarly, we can obtain (
53) for
.
On the other hand, from the definition of
V, we have
for a sequence of values of
, tending to
∞. Thus, in view of (
51), corresponding to the sequence
, we obtain
In view of
, for a sequence of values of
, we have
Similar to the above argument, we have
Thus, in view of (
54)–(
56), we can obtain
and
.
Therefore, this completes the proof of Theorem 12. □
Theorem 13. If Laplace–Stieltjes transform , and is of logarithmic order . If satisfy and form a non-decreasing function of . We have
(i) is of perfectly logarithmic linear growth if, and only if, (ii) if , then .
Proof. (i) From Theorem 9 (i) and Theorem 12, we can obtain Theorem 13 (i) easily.
(ii) Similar to the argument as in the proof of Theorem 9 (ii), and combining with the conclusions of Theorem 12, we can prove Theorem 13 (ii).
Therefore, this completes the proof of Theorem 13. □
5. Conclusions
In view of Theorems 7–13, we can see that these results reveal the relationships between the logarithmic growth and some indexes of entire functions represented by Laplace–Stieltjes transforms of finite logarithmic order . In fact, Theorems 7–11 and Remark 5 exhibit the relationships concerning some indexes including . These theorems show that the (lower) logarithmic type of Laplace–Stieltjes transform can be bounded not only by the center indexes of the maximum terms (see Theorems 7 and 8), but also by the logarithmic order , and (see Theorems 10 and 11). Finally, Theorems 12 and 13 depict the equivalence conditions between the (lower) logarithmic type and of Laplace–Stieltjes transforms with certain restricts. These are very obvious differences since the growth indexes are usual estimated by (can be founded in Theorems 1–3).