Abstract
We give out a general method to prove the complete convergence for arrays of rowwise 
-mixing random variables and to present some results on complete convergence under some suitable conditions. Some results generalize previous known results for rowwise independent random variables.
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1. Introduction
Let 
be a probability space, and let 
be a sequence of random variables defined on this space.
Definition 1.1.
The sequence 
is said to be 
-mixing if
as 
, where 
denotes the 
-field generated by 
.
The 
-mixing random variables were first introduced by Kolmogorov and Rozanov [1]. The limiting behavior of 
-mixing random variables is very rich, for example, these in the study by Ibragimov [2], Peligrad [3], and Bradley [4] for central limit theorem; Peligrad [5] and Shao [6, 7] for weak invariance principle; Shao [8] for complete convergence; Shao [9] for almost sure invariance principle; Peligrad [10], Shao [11] and Liang and Yang [12] for convergence rate; Shao [11], for the maximal inequality, and so forth.
For arrays of rowwise independent random variables, complete convergence has been extensively investigated (see, e.g., Hu et al. [13], Sung et al. [14], and Kruglov et al. [15]). Recently, complete convergence for arrays of rowwise dependent random variables has been considered. We refer to Kuczmaszewska [16] for 
-mixing and 
-mixing sequences, Kuczmaszewska [17] for negatively associated sequence, and Baek and Park [18] for negatively dependent sequence. In the paper, we study the complete convergence for arrays of rowwise 
-mixing sequence under some suitable conditions using the techniques of Kuczmaszewska [16, 17]. We consider the case of complete convergence of maximum weighted sums, which is different from Kuczmaszewska [16]. Some results also generalize some previous known results for rowwise independent random variables.
Now, we present a few definitions needed in the coming part of this paper.
Definition 1.2.
An array 
of random variables is said to be stochastically dominated by a random variable 
if there exists a constant 
, such that
for all 
, 
, and 
.
Definition 1.3.
A real-valued function 
, positive and measurable on 
for some 
, is said to be slowly varying if
Throughout the sequel, 
will represent a positive constant although its value may change from one appearance to the next; 
indicates the maximum integer not larger than 
; 
denotes the indicator function of the set 
.
The following lemmas will be useful in our study.
Lemma 1.4 (Shao [11]).
Let 
be a sequence of 
-mixing random variables with 
and 
for some 
. Then there exists a positive constant 
depending only on 
and 
such that for any 
Lemma 1.5 (Sung [19]).
Let 
be a sequence of random variables which is stochastically dominated by a random variable 
. For any 
and 
, the following statement holds:
Lemma 1.6 (Zhou [20]).
If 
is a slowly varying function as 
, then
(i)
for 
,
(ii)
for 
.
This paper is organized as follows. In Section 2, we give the main result and its proof. A few applications of the main result are provided in Section 3.
2. Main Result and Its Proof
This paper studies arrays of rowwise 
-mixing sequence. Let 
be the mixing coefficient defined in Definition 1.1 for the 
th row of an array 
, that is, for the sequence 
.
Now, we state our main result.
Theorem 2.1.
Let 
be an array of rowwise 
-mixing random variables satisfying 
for some 
, and let 
be an array of real numbers. Let 
be an increasing sequence of positive integers, and let 
be a sequence of positive real numbers. If for some 
and any 
the following conditions are fulfilled:
(a)
,
(b)
,
(c)
,
then
Remark 2.2.
Theorem 2.1 extends some results of Kuczmaszewska [17] to the case of arrays of rowwise 
-mixing sequence and generalizes the results of Kuczmaszewska [16] to the case of maximum weighted sums.
Remark 2.3.
Theorem 2.1 firstly gives the condition of the mixing coefficient, so the conditions (a)–(c) do not contain the mixing coefficient. Thus, the conditions (a)–(c) are obviously simpler than the conditions (i)–(iii) in Theorem 2.1 of Kuczmaszewska [16]. Our conditions are also different from those of Theorem 2.1 in the study by Kuczmaszewska [17]: 
is only required in Theorem 2.1, not 
in Theorem 2.1 of Kuczmaszewska [17]; the powers of 
in (b) and (c) of Theorem 2.1 are 
and 
, respectively, not 
in Theorem 2.1 of Kuczmaszewska [17].
Now, we give the proof of Theorem 2.1.
Proof.
The conclusion of the theorem is obvious if 
is convergent. Therefore, we will consider that only 
is divergent. Let
Note that
By (a) it is enough to prove that for all 
By Markov inequality and Lemma 1.4, and note that the assumption 
for some 
, we get
From (b), (c), and (2.5), we see that (2.4) holds.
3. Applications
Theorem 3.1.
Let 
be an array of rowwise 
-mixing random variables satisfying 
for some 
, 
, and 
for all 
, 
, and 
. Let 
be an array of real numbers satisfying the condition
for some 
. Then for any 
and 
Proof.
Put 
, 
, and 
in Theorem 2.1. By (3.1), we get
following from 
. By the assumption 
for 
, 
and by (3.1), we have
because 
and 
. Thus, we complete the proof of the theorem.
Theorem 3.2.
Let 
be an array of rowwise 
-mixing random variables satisfying 
for some 
, 
, and 
for all 
, 
, and 
. Let the random variables in each row be stochastically dominated by a random variable 
, such that 
, and let 
be an array of real numbers satisfying the condition
for some 
. Then for any 
and 
(3.2) holds.
Theorem 3.3.
Let 
be an array of rowwise 
-mixing random variables satisfying 
for some 
and 
for all 
, 
. Let the random variables in each row be stochastically dominated by a random variable 
, and let 
be an array of real numbers. If for some 
, 
then for any 
Proof.
Take 
and 
for 
. Then we see that (a) and (b) are satisfied. Indeed, taking 
, by Lemma 1.5 and (3.6), we get
In order to prove that (c) holds, we consider the following two cases.
If 
, by Lemma 1.5, 
inequality, and (3.6), we have
If 
, take 
. We have that 
. Note that in this case 
. We have
The proof will be completed if we show that
Indeed, by Lemma 1.5, we have
Theorem 3.4.
Let 
be an array of rowwise 
-mixing random variables satisfying 
for some 
, and let 
be an array of real numbers. Let 
be a slowly varying function as 
. If for some 
and real number 
, and any 
the following conditions are fulfilled:
,
,
,
then
Proof.
Let 
and 
. Using Theorem 2.1, we obtain (3.13) easily.
Theorem 3.5.
Let 
be an array of rowwise 
-mixing identically distributed random variables satisfying 
for some 
and 
. Let 
be a slowly varying function as 
. If for 
, 
, and 
then
Proof.
Put 
and 
for 
, 
in Theorem 3.4. To prove (3.15), it is enough to note that under the assumptions of Theorem 3.4, the conditions (A)–(C) of Theorem 3.4 hold.
By Lemma 1.6, we obtain
which proves that condition (A) is satisfied.
Taking 
, we have 
. By Lemma 1.6, we have
which proves that (B) holds.
In order to prove that (C) holds, we consider the following two cases.
If 
, take 
. We have
If 
, take 
. We have 
. Note that in this case 
. We obtain
The proof will be completed if we show that
If 
, then
If 
, note that 
, then
We complete the proof of the theorem.
Noting that for typical slowly varying functions, 
and 
, we can get the simpler formulas in the above theorems.
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Acknowledgments
The authors thank the academic editor and the reviewers for comments that greatly improved the paper. This work is partially supported by the Anhui Province College Excellent Young Talents Fund Project of China (no. 2009SQRZ176ZD) and National Natural Science Foundation of China (nos. 11001052, 10871001, 10971097).
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Zhou, Xc., Lin, Jg. On Complete Convergence for Arrays of Rowwise 
-Mixing Random Variables and Its Applications.
J Inequal Appl 2010, 769201 (2010). https://doi.org/10.1155/2010/769201
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DOI: https://doi.org/10.1155/2010/769201