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Article

Some Results on the Symmetric Representation of the Generalized Drazin Inverse in a Banach Algebra

1
College of Mathematics and Computing Science, Guilin University of Electronic Technology, Guilin 541004, China
2
College of Mathematics and Computer Science, Guangxi University for Nationalities, Nanning 530006, China
3
Department of Applied Mathematics, Universitat Politècnica de València, 46022 Valencia, Spain
*
Authors to whom correspondence should be addressed.
Symmetry 2019, 11(1), 105; https://doi.org/10.3390/sym11010105
Submission received: 1 January 2019 / Revised: 11 January 2019 / Accepted: 13 January 2019 / Published: 17 January 2019
(This article belongs to the Special Issue Matrices and Symmetry)

Abstract

:
Based on the conditions a b 2 = 0 and b π ( a b ) A d , we derive that ( a b ) n , ( b a ) n , and a b + b a are all generalized Drazin invertible in a Banach algebra A , where n N and a and b are elements of A . By using these results, some results on the symmetry representations for the generalized Drazin inverse of a b + b a are given. We also consider that additive properties for the generalized Drazin inverse of the sum a + b .
MSC:
46H05; 47A05; 15A09

1. Introduction

Let A be a complex unital Banach algebra with unit 1. The sets of all invertible elements and quasinilpotent elements of A are denoted by A 1 and A qnil , respectively, where A 1 : = { a A : x A : a x = x a = 1 } and A qnil : = { a A : lim n + a n 1 / n = 0 } . Let a A and, if there is a element b A such that
b a b = b , a b = b a , and a ( 1 a b ) is quasinilpotent ,
then b is the generalized Drazin inverse of a, denoted by a d , and it is unique. The set of generalized Drazin-invertible elements is denoted by A d = { a A : a d } . In particular, if a ( 1 a b ) = 0 (or a b a = a ), then b is called the group inverse of a. Note that a a d is an idempotent element and let a π = 1 a a d . It was given, in [1] (Lemma 2.4), that a d exists if and only if there is an idempotent q A , such that a q = q a , a q is quasinilpotent, and a + q is invertible.
The generalized inverse in a matrix or operator theory is very useful in scientific calculation and in various engineering technologies [2,3,4]. It is well known that the Drazin inverse has been applied in a few fields, such as statistics and probability [5], ordinary differential equations [6], Markov chains [7], operator matrices [8], neural network models [9,10], and the references therein. In [11], a study of the Drazin inverse for bounded linear operators in a Banach space X is given, when 0 is an isolated spectral point of the operator. In [12], some additive results on the Drazin inverse, under the condition a b = 0 , are obtained. However, as in [12,13], this condition was not enough to derive a formula for the generalized Drazin inverse for a + b . In [14], authors investigated how to express the Drazin inverse of sums, differences, and products of two matrices P and Q, under the conditions P 3 Q = Q P and Q 3 P = P Q . The representations of the Drazin inverse for ( P + Q ) , such that P Q P = 0 and P Q 2 = 0 , is given in [15]. The generalized inverses in C * -algebras has been investigated in [16] and a symmetry of the generalized Drazin inverse in a C * -algebra has been considered in [17].
Some additive properties of the generalized Drazin inverse in a Banach algebra were investigated in [18]. Recently, the expression for the generalized Drazin inverse of the sum a + b on Banach algebra has been studied, such as in the representations of the generalized Drazin inverse for a + b in a Banach algebra, obtained in [19]; some new additive results for the generalized Drazin inverse in a Banach algebra, given in [20]; and additive results on the generalized Drazin inverse of a sum of two elements in a Banach algebra are derived in [21] and the references therein. In this paper, we consider the representations of the generalized Drazin inverse of the sum of two elements in a Banach algebra. By using the assumed conditions a b 2 = 0 and b π ( a b ) A d , it is implied that ( a b ) n , ( b a ) n , and a b + b a A d , and a symmetry representation for the generalized Drazin inverse of a b + b a is obtained, where n N and a , b A d . We also consider the additive properties for the generalized Drazin inverse of the sum a + b .
In Section 2, some notation is introduced and lemmas are given. In Section 3, a symmetric representation of the generalized Drazin inverse for a b + b a in a Banach algebra is derived. The additive properties of the generalized Drazin inverse of a + b are investigated in Section 4.

2. Preliminaries

Let B be a subalgebra of the unital algebra A . For an element b B 1 , the inverse of b in B is denoted by [ b 1 ] B . As in [19], it is given that B 1 A 1 . Let P = { p 1 , p 2 , , p n } be a total system of idempotents in A if p i 2 = p i , for all i, p i p j = 0 if i j , and p 1 + + p n = 1 , as in [22]. If a A d , then
a = a 1 0 0 a 2 P , a d = [ a 1 1 ] p A p 0 0 0 P , a π = 0 0 0 1 p P ,
where p = a a d , P = { p , 1 p } , a 1 [ p A p ] 1 , and a 2 [ ( 1 p ) A ( 1 p ) ] qnil . If a has the representation given as in (2), then a d = [ a 1 1 ] p A p = a 1 d .
The following lemmas are required in what follows.
Lemma 1
([19]). Let P = { p , 1 p } be a total system of idempotents in A , and let a , b A have the following representation
a = x 0 z y P , b = x t 0 y P .
Then there exist ( z n ) n = 0 ( 1 p ) A p and ( t n ) n = 0 p A ( 1 p ) , such that
a n = x n 0 z n y n P , b n = x n t n 0 y n P , n N .
Lemma 2
([22]). Let a , b A be generalized Drazin invertible and a b = 0 . Then, a + b is generalized Drazin invertible and
( a + b ) d = b π n = 0 b n ( a d ) n + 1 + n = 0 ( b d ) n + 1 a n a π .
Lemma 3
([22]). Let x , y A , p be an idempotent of A , and let x and y have the representation
x = a 0 c b { p , 1 p } , y = b c 0 a { 1 p , p } .
(i)
If a [ p A p ] d and b [ ( 1 p ) A ( 1 p ) ] d , then x , y A d and
x d = a d 0 u b d { p , 1 p } , y d = b d u 0 a d { 1 p , p } ,
where
u = n = 0 ( b d ) n + 2 c a n a π + n = 0 b π b n c ( a d ) n + 2 b d c a d .
(ii)
If x A d and a [ p A p ] d , then b [ ( 1 p ) A ( 1 p ) ] d , and x d and y d are given by (4) and (5).
Lemma 4
([11]). Let a A d . Then [ ( a ) n ] d = [ a d ] n , for all n = 1 , 2 , .
Lemma 5
([11]). If a , b A d and a b = b a = 0 . Then, ( a + b ) d also exists and ( a + b ) d = a d + b d .
Lemma 6
([23]). Let a , b A d . Then ( a b ) n + 1 is generalized Drazin invertible, for some n N , if and only if a b is generalized Drazin invertible.
Lemma 7
([23]). Let a , b A d and ( a b ) n + 1 be generalized Drazin invertible for some n N . Then, ( b a ) n is generalized Drazin invertible and [ ( b a ) n ] d = b [ ( a b ) n + 1 ] d a .

3. The Symmetric Representation for the Generalized Drazin Inverse of ab + ba

Let a , b A d . A symmetric expression of ( a b + b a ) d is given, by using a b , b a , ( a b ) d , and ( b a ) d , with the following assumed conditions
a b 2 = 0 , b π ( a b ) A d .
Theorem 1.
Let a , b A d satisfy (6). Then, ( a b ) n , ( b a ) n , a b + b a A d ( n = 1 , 2 , ) , and a representation of ( a b + b a ) d is given as
( a b + b a ) d = ( b a ) π n = 1 ( b a ) n 1 [ ( a b ) n ] d + n = 1 [ ( b a ) n ] d ( a b ) n 1 ( a b ) π .
Proof. 
Let b = b 1 0 0 b 2 P , where P = { b b d , b π } , b 1 is invertible in the subalgebra b b d A b b d , and b 2 is quasinilpotent. Let us write a = a 11 a 12 a 21 a 22 P . From a b 2 = 0 , we have
a 11 = 0 , a 21 = 0 , a 12 b 2 2 = 0 , and a 22 b 2 2 = 0 .
Thus, we have a b = 0 a 12 b 2 0 a 22 b 2 . By Lemma 3, we obtain that a b A d if and only if a 22 b 2 is generalized Drazin invertible. Thus, ( b π a b ) d exists. By using Cline’s formula, it proves that ( a b ) d also is. Therefore, we obtain ( a b ) n , ( b a ) n A d by using Lemma 6 and 7. Since a b 2 = 0 , by Lemma 2 we can prove that a b + b a is generalized Drazin invertible and that (7) holds. If n = 1 , then ( a b + b a ) d = ( b a ) π ( a b ) d + ( b a ) d ( a b ) π . By using mathematical induction, we derive that the representation can be given, as in (7). □
Remark 1.
Note that the expression given in Theorem 1 is symmetric.
Theorem 2.
Let a , b A d satisfy (6) and a 2 = 0 . Then a b + b a A d and [ ( a b + b a ) d ] n = [ ( a b ) d ] n + [ ( b a ) d ] n , for all n = 1 , 2 , .
Proof. 
Let a , b be written as in the proof of Theorem 1, and, by a b 2 = 0 , we derive a b = 0 a 12 b 2 0 a 22 b 2 and a b , b a , ( a b ) n , ( b a ) n A d . Since a b 2 = 0 and a 2 = 0 , we have
( a b ) n ( b a ) n = ( b a ) n ( a b ) n = 0 , ( a b + b a ) n = ( a b ) n + ( b a ) n ,
for all n = 1 , 2 , . By Lemma 4, Lemma 5, and the first equality of (9), we derive
[ ( a b + b a ) d ] n = [ ( a b + b a ) n ] d = [ ( a b ) n + ( b a ) n ] d = [ ( a b ) n ] d + [ ( b a ) n ] d = [ ( a b ) d ] n + [ ( b a ) d ] n .
 □
At the end of Section 3, let A be a C * -algebra, as in [17]. Then, a simple application of the generalized Drazin inverse in a C * -algebra can be given, as follows.
Theorem 3.
Let a , b A be group invertible. If (6) is satisfied, then ( a b + b a ) exists.
Proof. 
By using Theorem 1, we derive that a b + b a is group invertible. As pointed out in [16], a b + b a is generalized invertible. Thus, ( a b + b a ) exists. □
Theorem 4.
Let a , b A d . If (6) is satisfied, then ( a b + b a ) d is self-adjoint in a C * -algebra.
Proof. 
Note that a b + b a is self-adjoint in a C * -algebra. By Theorem 1 and using [17] (Theorem 3.2), we obtain that ( a b + b a ) d is self-adjoint in a C * -algebra. □

4. The Representation for the Generalized Drazin Inverse of a + b

In this section, we consider some results on the expression of ( a + b ) d , by using a, b, a d , and b d , where a , b A d .
Lemma 8.
Let a , b A d satisfy a b 2 = 0 . Then, ( a + b ) d exists if and only if b π ( a + b ) A d .
Proof. 
Similarly, we rewrite a , b as in the proof of Theorem 1. Since a b 2 = 0 , we derive
a + b = b 1 a 12 0 b 2 + a 22 P .
By Lemma 3, note that ( a + b ) d exists if and only if ( a 22 + b 2 ) d exists; that is, ( a + b ) d exists if and only if b π ( a + b ) is generalized Drazin invertible. □
Theorem 5.
Let a , b A d satisfy the conditions of Theorem 2. Then
( a + b ) d = n = 0 ( b d ) 2 n + 1 b d ( a b ) π ( a b ) n a + ( a b ) π ( a b ) n n = 0 b π b 2 n [ ( a b ) d ] n + 1 a + b [ ( a b ) d ] n + 1 .
Proof. 
By Lemma 8, it also leads to (10). By Lemma 3, we can prove that ( a + b ) d exists if and only if ( a 22 + b 2 ) d exists; that is, ( a + b ) d exists if and only if b π ( a + b ) is generalized Drazin invertible. If b π a b A d , then ( a 22 b 2 ) d exists. By Cline’s formula, we have that ( b 2 a 22 ) d exists. As in the proof of Theorem 1, by Lemma 6 and 7, we also obtain that ( a b ) n , ( b a ) n A d , for all n = 1 , 2 , .
By a 2 = 0 , we get
a 12 a 22 = 0 and a 22 2 = 0 .
By (8) and (11), we have ( b 2 a 22 ) ( a 22 b 2 ) = 0 , ( a 22 b 2 ) ( b 2 a 22 ) = 0 . Using Lemma 5, and by Cline’s formula, we derive
( a 22 b 2 + b 2 a 22 ) d = ( a 22 b 2 ) d + ( b 2 a 22 ) d .
By induction, let [ ( a 22 b 2 ) d + ( b 2 a 22 ) d ] n = [ ( a 22 b 2 ) d ] n + [ ( b 2 a 22 ) d ] n for all n 1 . Therefore, we can prove that
[ ( a 22 b 2 + b 2 a 22 ) d ] [ ( a 22 b 2 ) d + ( b 2 a 22 ) d ] n = [ ( a 22 b 2 ) d ] n + 1 + [ ( b 2 a 22 ) d ] n + 1 .
Since ( a 22 b 2 + b 2 a 22 ) b 2 2 = 0 and b 2 are quasinilpotent, by Lemma 5 and (12), we obtain
[ ( a 22 + b 2 ) 2 ] d = ( a 22 b 2 + b 2 a 22 + b 2 2 ) d = n = 0 b 2 2 n [ ( a 22 b 2 + b 2 a 22 ) d ] n + 1 = n = 0 b 2 2 n ( a 22 b 2 ) d + ( b 2 a 22 ) d n + 1 .
Then, b π ( a + b ) A d implies that ( a 22 + b 2 ) d exists and ( a 22 + b 2 ) d = [ ( a 22 + b 2 ) 2 ] d ( a 22 + b 2 ) . Finally, by (13), and ( b 2 a 22 ) d = b 2 ( a 22 b 2 ) d 2 a 22 , we obtain
( a 22 + b 2 ) d = ( a 22 + b 2 ) d 2 ( a 22 + b 2 ) = n = 0 b 2 2 n ( a 22 b 2 ) d n + 1 + b 2 ( a 22 b 2 ) d 2 a 22 n + 1 ( a 22 + b 2 ) = n = 0 b 2 2 n ( a 22 b 2 ) d n + 1 a 22 + n = 0 b 2 2 n b 2 ( a 22 b 2 ) d 2 a 22 n + 1 b 2 = n = 0 b 2 2 n ( a 22 b 2 ) d n + 1 a 22 + b 2 ( a 22 b 2 ) d n + 1
and
( a 22 + b 2 ) π = ( a 22 b 2 ) π n = 0 b 2 2 n + 1 ( a 22 b 2 ) d n + 1 a 22 + b 2 ( a 22 b 2 ) d n + 1 .
By Lemma 3, we get that a + b A d and
( a + b ) d = b 1 1 u 0 ( a 22 + b 2 ) d P ,
and
u = n = 0 ( b 1 1 ) n + 2 a 12 ( b 2 + a 22 ) n ( a 22 + b 2 ) π ( a 22 + b 2 ) d a 12 b 1 1 .
Evidently, we have b 1 1 P = b d and
b d b a = b 1 1 b 1 0 0 0 P 0 a 12 0 a 22 P = 0 a 12 0 0 P = a 12 .
One easily has (by induction and by using (8) and (11)) that, if n 1 , then
a 12 ( a 22 + b 2 ) n = a 12 ( b 2 a 22 ) n / 2 if n is even , a 12 ( b 2 a 22 ) ( n 1 ) / 2 b 2 if n is odd .
By Lemma 1, we obtain that, for any n 1 ,
b π ( b a ) n = 0 0 0 b π P 0 x n 0 ( b 2 a 22 ) n P = 0 0 0 ( b 2 a 22 ) n P = ( b 2 a 22 ) n ,
where ( x n ) n = 0 is a sequence in A . Furthermore, one has b 2 = b π b = b b π and a b π = a ( 1 b b d ) = a ( 1 b 2 ( b d ) 2 ) = a . Hence, if n 1 is even, then
a 12 ( a 22 + b 2 ) n = a 12 ( b 2 a 22 ) n / 2 = b d b a b π ( b a ) n / 2 = b d b a ( b a ) n / 2 = b d ( b a ) ( n + 2 ) / 2 ,
and if n 1 is odd, then
a 12 ( a 22 + b 2 ) n = a 12 ( b 2 a 22 ) ( n 1 ) / 2 b 2 = b d b a b π ( b a ) ( n 1 ) / 2 b π b = b d ( b a ) ( n + 1 ) / 2 b .
From (15), we have
a 12 ( a 22 + b 2 ) π = a 12 ( 1 b 2 ( a 22 b 2 ) d a 22 ) , a 22 ( a 22 + b 2 ) π = ( a 22 b 2 ) π a 22 , a 12 b 2 ( a 22 + b 2 ) π = a 12 b 2 ( a 22 b 2 ) π , a 22 b 2 ( a 22 + b 2 ) π = a 22 b 2 ( a 22 b 2 ) π .
Thus, by using the obvious equality ( b a ) k b = b ( a b ) k , and by (14)–(16) and (18), we have
( a + b ) d = b 1 d + u = b 1 P 1 + n = 0 ( b 1 1 P ) n + 2 a 12 ( b 2 + a 22 ) n ( a 22 + b 2 ) π ( a 22 + b 2 ) d a 12 b 1 1 + ( a 22 + b 2 ) d = n = 0 ( b d ) 2 n + 2 b π ( a b ) n a + n = 0 ( b d ) 2 n + 1 b π ( a b ) n n = 0 b π b 2 n [ ( a b ) d ] n + 1 a + b [ ( a b ) d ] n + 1 = n = 0 ( b d ) 2 n + 1 b d ( a b ) π ( a b ) n a + ( a b ) π ( a b ) n n = 0 b π b 2 n [ ( a b ) d ] n + 1 a + b [ ( a b ) d ] n + 1 .
The proof is completed. □
Theorem 6.
Let a , b A d satisfy (6) and b π a 2 = 0 . Then,
( a + b ) d = b d + u + v ,
where
v = b d a ( b a ) d + n = 0 b d b 2 n + 1 ( ( a b ) d ) n + 1 + ( ( b a ) d ) n + 1 , u = n = 0 ( b d ) n + 2 a ( a + b ) n + n = 0 ( 1 b π ) b n a v n + 2 b d a v .
Proof. 
Let p = b b d and P = { p , 1 p } . Let a and b have the following representation
b = b 1 0 0 b 2 P , a = a 3 a 1 a 4 a 2 P ,
where b 1 is invertible in p A p and b 2 is quasinilpotent in ( 1 p ) A ( 1 p ) . Let us find the expression of b π a 2 in the system of idempotents P :
b π a 2 = 0 0 0 1 p P 0 a 1 0 a 2 P 0 a 1 0 a 2 P = 0 0 0 a 2 2 P = a 2 2 .
Thus, a 2 2 = 0 . On the other hand,
a b 2 = 0 a 1 0 a 2 P b 1 2 0 0 b 2 2 P = 0 a 1 b 2 2 0 a 2 b 2 2 P .
Therefore, a 2 b 2 2 = 0 . By b π a b , b π b a A d , we obtain ( a 2 b 2 ) , ( b 2 a 2 ) A d . We can appeal to Theorem 5, obtaining (recall that b 2 is quasinilpotent and b 2 d = 0 ) that
( a 2 + b 2 ) d = a 2 ( b 2 a 2 ) d n = 0 b 2 2 n + 1 ( ( a 2 b 2 ) d ) n + 1 + ( ( b 2 a 2 ) d ) n + 1 .
From Lemma 3 and the representation of a + b in (16), we have
( a + b ) d = b 1 1 P + ( a 2 + b 2 ) d + u = b 1 1 P + u a 2 ( b 2 a 2 ) d + n = 0 b 2 2 n + 1 ( ( a 2 b 2 ) d ) n + 1 + ( ( b 2 a 2 ) d ) n + 1 ,
where
u = n = 0 ( b 1 1 P ) n + 2 a 1 ( a 2 + b 2 ) n ( a 2 + b 2 ) π + n = 0 b 1 π b 1 n a 1 ( ( a 2 + b 2 ) d ) n + 2 b 1 1 P a 1 ( a 2 + b 2 ) d = n = 0 ( b 1 d ) n + 2 a 1 ( a 2 + b 2 ) n .
Observe that b 1 1 P = b d , and
( b d ) n + 2 a ( a + b ) n = ( b 1 d ) n + 2 0 0 0 P 0 a 1 0 a 2 P b 1 n x n 0 ( a 2 + b 2 ) n P = 0 0 0 ( b 1 d ) n + 2 a 1 ( a 2 + b 2 ) n P = ( b 1 d ) n + 2 a 1 ( a 2 + b 2 ) n , v = b π ( a + b ) d = ( a 2 + b 2 ) d = b d a ( b a ) d + n = 0 b d b 2 n + 1 ( ( a b ) d ) n + 1 + ( ( b a ) d ) n + 1 .
Thus, the above expression of u reduces to
u = n = 0 ( b d ) n + 2 a ( a + b ) n + n = 0 ( 1 b π ) b n a ( v ) n + 2 b d a v .
Expressions (20) and (21) finish the proof. □

5. Conclusions

In this paper, we have proved that the multiplications ( a b ) n and ( b a ) n of elements a , b A d in a Banach algebra are both generalized Drazin invertible with the conditions (6). A symmetry representation of the generalized Drazin inverse for a b + b a has been derived. The expression given in Theorem 1 is symmetric, as in Remark 1. In the other words, if the result is applied in the computation of ( a b + b a ) d , maybe it will improve the corresponding computational effectiveness and reduce its complexity. The additive properties of ( a + b ) d have been investigated under the conditions a b 2 = 0 , b π a b A d , and a 2 = 0 . With similar conditions, but a 2 = 0 being replaced by b π a 2 = 0 , we have also given a resulting expression of ( a + b ) d .
In fact, as pointed out as in [19], it is still an interesting and open problem to express the generalized Drazin inverse of a + b as a function of a, b, and their respective generalized Drazin inverses. In the future, we plan to consider the representations of the generalized Drazin inverse for a ± b by using a, b, and their generalized Drazin inverses, without side conditions.

Author Contributions

Funding acquisition, Y.Q. and X.L.; Methodology, X.L.; Supervision, J.B.; Writing-review and editing, Y.Q.

Funding

This work was supported by the National Natural Science Foundation of China (grant number: 11361009, 61772006,11561015), the Special Fund for Science and Technological Bases and Talents of Guangxi (grant number: 2016AD05050, 2018AD19051), the Special Fund for Bagui Scholars of Guangxi (grant number: 2016A17), the High level innovation teams and distinguished scholars in Guangxi Universities (grant number: GUIJIAOREN201642HAO), the Natural Science Foundation of Guangxi(grant number: 2017GXNSFBA198053, 2018JJD110003), and the open fund of Guangxi Key laboratory of hybrid computation and IC design analysis (grant number: HCIC201607).

Conflicts of Interest

The authors declare that they have no conflict of interest.

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Qin, Y.; Liu, X.; Benítez, J. Some Results on the Symmetric Representation of the Generalized Drazin Inverse in a Banach Algebra. Symmetry 2019, 11, 105. https://doi.org/10.3390/sym11010105

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Qin Y, Liu X, Benítez J. Some Results on the Symmetric Representation of the Generalized Drazin Inverse in a Banach Algebra. Symmetry. 2019; 11(1):105. https://doi.org/10.3390/sym11010105

Chicago/Turabian Style

Qin, Yonghui, Xiaoji Liu, and Julio Benítez. 2019. "Some Results on the Symmetric Representation of the Generalized Drazin Inverse in a Banach Algebra" Symmetry 11, no. 1: 105. https://doi.org/10.3390/sym11010105

APA Style

Qin, Y., Liu, X., & Benítez, J. (2019). Some Results on the Symmetric Representation of the Generalized Drazin Inverse in a Banach Algebra. Symmetry, 11(1), 105. https://doi.org/10.3390/sym11010105

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