The Weighted Core-EP Inverse and Its Associated Preorder

Huanyin Chen; Marjan Sheibani

doi:10.20944/preprints202508.0740.v1

Submitted:

10 August 2025

Posted:

12 August 2025

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Abstract

In this paper, we introduce a new preorder derived from the w-core-EP inverse in a *-ring. We characterize this generalized inverse by combining the w-core inverse with nilpotent elements. This characterization allows us to define a new binary relation on w-core-EP invertible elements, based on the w-core preorder. Using the Pierce matrix decomposition for two idempotents as a novel tool, we establish equivalent conditions for the forward and reverse order laws governing w-core-EP invertibility. Furthermore, we extend the *-DMP property to a broader class of elements within the framework of the w-core-EP preorder.

Keywords:

weighted core preorder

;

weighted core-EP inverse

;

weighted core-EP preorder

;

core-EP inverse

;

weighted Drazin inverse

;

*-ring

Subject:

Computer Science and Mathematics - Algebra and Number Theory

MSC: 15A09; 16U90; 06A06

1. Introduction

A ring R is called a *-ring if there exists an involution

* : x \to x^{*}

satisfying

{(x + y)}^{*} = x^{*} + y^{*}, {(x y)}^{*} = y^{*} x^{*}, {(x^{*})}^{*} = x

. An element a in a *-ring R has core inverse if and only if there exist

x \in R

such that

a x^{2} = x, {(a x)}^{*} = a x, x a^{2} = a .

If such x exists, it is unique, and denote it by

a^{#}

(see [34]). An element

a \in A

has core-EP inverse (i.e., pseudo core inverse) if there exist

x \in A

and

k \in N

such that

a x^{2} = x, {(a x)}^{*} = a x, x a^{k + 1} = a^{k} .

If such x exists, it is unique, and denote it by

a^{D}

(see [10]). The core and core-EP inverses have been extensively studied by many authors from various perspectives, including, for example, [1,6,22,24,27,32].

Let

a, w \in R

. Following Zhu et al., an element

a \in A

has w-core inverse if there exist

x \in A

such that

a w x^{2} = x, {(a w x)}^{*} = a w x, x a w a = a .

Many properties of w-core inverse have been investigated in [36,39]. Recently, Mosić extended the w-core inverse to a new class of weighted generalized inverse. An element

a \in A

has w-core-EP inverse if there exist

x \in A

such that

a w x^{2} = x, {(a w x)}^{*} = a w x, x {(a w)}^{k + 1} a = {(a w)}^{k} a .

Such x is unique if it exits, and we denote it by

a_{w}^{D}

(see [25]).

In [28], Rakić and Djordjević, introduced the core preorder on a ring with involution. That is, if

a \in R^{#}, b \in R

, then a is below b under core preorder (written as

a \leq^{#} b

), if

a a^{#} = b a^{#}

and

a^{#} a = a^{#} b

. In [9], Dolinar et al. introduced and studied the core-EP preorder. Recently, the w-core preorder, induced by the w-core inverse, has been defined and studied (see [40]). For more papers on various binary relations induced by specific generalized inverses, we refer the reader to [8,9,12,17,19,20,21,23,37].

The motivation of this paper is to introduce and study a new preorder induced by the w-core-EP inverse. Let

a, b, w \in R

.

Definition 1.1.

Let

a \in R_{w}^{D}

. We define a binary relation "

\leq_{w}^{D}

" on R in the following way:

a \leq_{w}^{D} b

if and only if

a w a_{w}^{D} = b w a_{w}^{D}, a_{w}^{D} a = a_{w}^{D} b .

In Section 2, we characterize the w-core-EP inverse by combining the w-core inverse with nilpotent elements. This characterization establishes a foundation for examining a new binary relation among w-core-EP invertible elements, utilizing the w-core preorder.

In Section 3, we investigate the preorder of w-core-EP inverses, which includes certain self-adjoint elements, thereby extending many established results on Hilbert operators to a more comprehensive class of ring elements.

In Section 4, we apply the method used for the Pierce matrix relative to two idempotents to establish equivalent conditions for the forward and reverse order laws of w-core-EP invertibility in a ring setting.

An element a is w-weighted *-DMP if and only if

a \in R_{w}^{D}

and

w a w a_{w}^{D} = w a_{w}^{D} a w

. Finally, in Section 5, we consider w-weighted *-DMP elements, broadening the applicability of the w-core-EP preorder framework. This extends related results on *-DMP elements to a wider class that includes weighted considerations.

Throughout the paper, all *-rings are associative with an identity.

R^{D, w}, R_{w}^{#}

and

R_{w}^{D}

denote the sets of all w-Drazin, w-core invertible and w-core-EP invertible elements in R, respectively.

2. Weighted Core-EP Decomposition

The objective of this section is to characterize the w-core-EP inverse by combing the w-core inverse and nilpotent within the framework of a *-ring. We begin with

Theorem 2.1.

Let

a, w \in R

. Then the following are equivalent:

(1): $a \in R_{w}^{D}$ .
(2): There exists $x \in R$ such that

$x = a w x^{2}, {(a w x)}^{*} = a w x, x {(a w)}^{k + 1} = {(a w)}^{k}$

for some $k \in N$ .
(3): $a \in R$ has the w-core-EP decomposition, i.e., there exist $x, y \in R$ such that

$a = x + y, x^{*} y = y w x = 0, x \in R_{w}^{#}, y \in R_{w}^{n i l} .$

In this case,

a_{w}^{D} = x_{w}^{#}

.

Proof.

(1) \Rightarrow (2)

By hypothesis, there exists

x \in R

such that

a w x^{2} = x, x {(a w)}^{k + 1} a = {(a w)}^{k} a a n d {(a w x)}^{*} = a w x .

Then

x {(a w)}^{k + 2} = [x {(a w)}^{k + 1} a] w = [{(a w)}^{k} a] w = {(a w)}^{k + 1},

as required.

(2) \Rightarrow (3)

By hypotheses, there exists

x \in R

such that

x = a w x^{2}, {(a w x)}^{*} = a w x, x {(a w)}^{k + 1} = {(a w)}^{k}

for some

k \in N

. Then

x a w x = [x {(a w)}^{k + 1}] x^{k + 1} = {(a w)}^{k} x^{k + 1} = a w x^{2} = x .

Set

z = a w x a

and

y = a - a w x a

. We check that

\begin{matrix} y w z & = & (a - a w x a) w a w x a = a w a w x a - a w x {(a w)}^{2} x a \\ = & a w a w x a - a w (a w x) a = 0, \\ z^{*} y & = & {(a w x a)}^{*} y = a^{*} (a w x) y = a^{*} (a w x) (a - a w x a) \\ = & a^{*} a w (x a - x a w x a) = 0 . \end{matrix}

We claim that

z \in R_{w}^{#}

and

z_{w}^{#} = x

.

Claim 1.

x = z w x^{2}

. We verify that

z w x^{2} = a w x (a w x^{2}) = a w x^{2} = x .

Claim 2.

{(z w x)}^{*} = z w x

. Clearly, we have

z w x = a w (x a w x) = a w x

, and then

{(z w x)}^{*} = {(a w x)}^{*} = a w x = z w x

.

Claim 3.

x z w z = z

. One checks that

x z w z = (x a w x) a w a w x a = x {(a w)}^{2} x a = a w x a = z .

Therefore

z \in R_{w}^{#}

. Moreover, we see that

\begin{matrix} {(a w)}^{n} - a w x {(a w)}^{n} & = & (a - a w x a) w {(a w)}^{n - 1} \\ = & y w {(a w)}^{n - 1} = y w a w {(a w)}^{n - 2} \\ = & y w (z + y) w {(a w)}^{n - 2} = {(y w)}^{2} {(a w)}^{n - 2} \\ = & \dots = {(y w)}^{n} . \end{matrix}

Therefore

lim_{n \to \infty} {(y w)}^{n} = 0,

and then

y \in R_{w}^{n i l}

.

(3) \Rightarrow (1)

By hypothesis, there exist

z, y \in R

such that

a = z + y, z^{*} y = y w z = 0, z \in R_{w}^{#}, y \in R_{w}^{n i l} .

Set

x = z_{w}^{#}

. Then

\begin{matrix} a w x & = & (z + y) w z_{w}^{#} = z w z_{w}^{#}, \\ {(a w x)}^{*} & = & a w x, \\ a w x^{2} & = & (a w x) x = z w z_{w}^{#} (z + y) = z w z_{w}^{#} z = x . \end{matrix}

It is easy to verify that

\begin{matrix} x a w x & = & z_{w}^{#} (z w z_{w}^{#}) = z_{w}^{#} = x, \\ x {(a w)}^{2} x & = & (x a w) (a w x) = z_{w}^{#} (z + y) w z w z_{w}^{#} = z_{w}^{#} z w z w z_{w}^{#} \\ = & z_{w}^{#} z w z w z_{w}^{#} = z w z_{w}^{#} = a w x . \end{matrix}

Moreover, we have

a w x a = (a w x) a = z w z_{w}^{#} (z + y) = z w z_{w}^{#} z = z,

and so

a - a w x a = a - z = y \in R_{w}^{n i l} .

Write

{(y w)}^{n} = 0

for some

n \in N

. Then we verify that

\begin{matrix} {(a w)}^{n} - a w x {(a w)}^{n} & = & (a - a w x a) w {(a w)}^{n - 1} \\ = & y w {(a w)}^{n - 1} = y w a w {(a w)}^{n - 2} \\ = & y w (z + y) w {(a w)}^{n - 2} = {(y w)}^{2} {(a w)}^{n - 2} \\ = & \dots = {(y w)}^{n} = 0 . \end{matrix}

Accordingly,

{(a w)}^{n} = a w x {(a w)}^{n} .

As

z \in R_{w}^{#}

, there exist

s \in R

such that

z w s^{2} = s, s z w z = z a n d {(z w s)}^{*} = z w s .

Then

(z w) s^{2} = s, s {(z w)}^{2} = z w a n d {(z w s)}^{*} = z w s .

Hence,

z w \in R^{D}

. Therefore

z w \in R^{D}

. Since

y w z = 0

, it follows by [[26], Theorem 3.2] that

a w = z w + y w \in A^{D}

.

According, we have

a w x^{2} = x, {(a w x)}^{*} = a w x, {(a w)}^{n} = a w x {(a w)}^{n} = {(a w)}^{n} x^{n} {(a w)}^{n} .

Let

t = (a w) {(a w)}^{D} x

. We claim that

a_{w}^{D} = t

. One directly verifies that

\begin{matrix} a w x - a w t & = & [1 - (a w) {(a w)}^{D}] (a w) x = {[1 - (a w) {(a w)}^{D}]}^{n} {(a w)}^{n} x^{n} \\ = & [{(a w)}^{n} - {(a w)}^{n + 1} {(a w)}^{D}] x^{n} = 0, \end{matrix}

Then

a w t = a w x

, and so

{(a w t)}^{*} = {(a w x)}^{*} = a w x = a w t

.

\begin{matrix} t - a w t^{2} & = & (1 - a w t) t = (1 - a w x) (a w) {(a w)}^{d} x \\ = & (1 - a w x) {(a w)}^{n} {[{(a w)}^{D}]}^{n} x \\ = & [{(a w)}^{n} - {(a w)}^{n} x^{n} {(a w)}^{n}] {[{(a w)}^{D}]}^{n} x = 0 . \end{matrix}

Hence,

t = a w t^{2}

.

Furthermore, we see that

\begin{matrix} {(a w)}^{n} - t {(a w)}^{n + 1} \\ = & [{(a w)}^{n} - {(a w)}^{n + 1} {(a w)}^{D}] + [{(a w)}^{n + 1} {(a w)}^{D} - (a w) {(a w)}^{D} x {(a w)}^{n + 1}] \\ = & [{(a w)}^{n + 1} {(a w)}^{D} - (a w) {(a w)}^{D} x {(a w)}^{n + 1}] \\ = & {(a w)}^{n + 1} {(a w)}^{D} - {(a w)}^{D} [(a w) x {(a w)}^{n}] (a w) \\ = & {(a w)}^{n + 1} {(a w)}^{D} - {(a w)}^{D} {(a w)}^{n} (a w) = 0 . \end{matrix}

Then

{(a w)}^{n} = t {(a w)}^{n + 1},

thus yielding the result. □

Corollary 2.2.

Let

a, b \in R_{w}^{D}

. If

a^{*} b = 0

and

a w b = b w a = 0

, then

a + b \in R_{w}^{D}

. In this case,

{(a + b)}_{w}^{D} = a_{w}^{D} + b_{w}^{D} .

Proof.

Case 1.

a, b \in R_{w}^{#}

. Set

x = a_{w}^{#} + b_{w}^{#}

. Then we verify that

\begin{matrix} (a + b) w (x + y) & = & a w x + b w y, \\ {((a + b) w (x + y))}^{*} & = & (a + b) w (x + y), \\ (a + b) w {(x + y)}^{2} & = & (a w x + b w y) (x + y) \\ = & a w x^{2} + b w y^{2} = x + y, \\ (x + y) (a + b) w (a + b) & = & x a w a + y b w b = x + y . \end{matrix}

Hence

a + b \in R_{w}^{#}

and

{(a + b)}_{w}^{#} = a_{w}^{#} + b_{w}^{#}

.

Case 2. Since

a, b \in R_{w}^{D}

, by virtue of Theorem 2.1, there exist

x, s \in R_{w}^{#}

and

y, t \in R_{w}^{n i l}

such that

\begin{matrix} a & = & x + y, x^{*} y = 0, y w x = 0, x \in R_{w}^{#}, y \in R_{w}^{n i l}; \\ b & = & s + t, s^{*} t = 0, t w s = 0, s \in R_{w}^{#}, t \in R_{w}^{n i l} . \end{matrix}

As in the proof of Theorem 2.1,

x = a w a_{w}^{D} a, y = a - a w a_{w}^{D} a

and

s = b w b_{w}^{D} b, t = b - b w b_{w}^{D} b

. Then

a = (x + s) + (y + t)

. Clearly,

(y + t) w = [(a - a w a_{w}^{D} a) + (b - b w b_{w}^{D} b)] w \in R^{n i l}

. This implies that

y + b \in R_{w}^{n i l}

. We directly check that

\begin{matrix} {(x + s)}^{*} (y + t) & = & x^{*} y + s^{*} t = 0, \\ (y + t) w (x + s) & = & y w x + t w s = 0 . \end{matrix}

By using Theorem 2.1,

a + b \in R_{w}^{D}

. In this case,

{(a + b)}_{w}^{D} = x_{w}^{#} + y_{w}^{#} = a_{w}^{D} + b_{w}^{D} .

□

Lemma 2.3.

Let

a, w \in R

. Then the following are equivalent:

(1): $a \in R_{w}^{D}$ .
(2): $a w \in R^{D}$ .
(3): $a \in R^{D, w}$ and there exists $x \in R$ such that

$x = a w x^{2}, {(a w x)}^{*} = a w x, {(a w)}^{n} = a w x {(a w)}^{n} .$

In this case,

a_{w}^{D} = x = {(a w)}^{D} .

Proof.

(1) \Leftrightarrow (2)

This is proved in [25].

(2) \Rightarrow (3)

In view of [25],

a \in R^{D, w}

and there exists

x \in R

such that

x = a w x^{2}, {(a w x)}^{*} = a w x, {(a w)}^{n} = a w x {(a w)}^{n} .

Moreover, we have

(a w) {(a w)}^{D} x = a_{w}^{D}

. Since

x = a w x^{2}

, by induction, we have

x = {(a w)}^{n} x^{n + 1}

for any

n \in N

. Then

\begin{matrix} x - (a w) {(a w)}^{d} x & = & x - (a w) {(a w)}^{d} x \\ = & [1 - (a w) {(a w)}^{D}] {(a w)}^{n} x^{n + 1} \\ = & {(a w)}^{n} - {(a w)}^{D} {(a w)}^{n + 1} x . \end{matrix}

As

{(a w)}^{n} = {(a w)}^{D} {(a w)}^{n + 1}

, we see that

x = (a w) {(a w)}^{D} x = 0,

and therefore

x = (a w) {(a w)}^{D} x = a_{w}^{D}

, as required.

(3) \Rightarrow (2)

Since

a \in R^{D, w}

, we have

a w \in R^{D}

. Let m be the Drazin index of

a w

. Set

k = m + n

. Then

{(a w)}^{k} x^{k} = a w x

and

{(a w)}^{k} = {(a w)}^{k} x^{k} {(a w)}^{k}

. Hence,

{(a w)}^{k} \in R^{(1, 3)}

. Therefore

a w \in R^{D}

by [10]. □

If a and x satisfy the equations

a = a x a

and

{(a x)}^{*} = a x

, then x is called

(1, 3)

-inverse of a and is denoted by

a^{(1, 3)}

. We use

R^{(1, 3)}

to stand for sets of all

(1, 3)

-invertible elements in R. We now derive

Theorem 2.4.

Let

a, w \in R

. Then the following are equivalent:

(1): $a \in R_{w}^{D}$ .
(2): $a \in R^{D, w}$ and $a^{D, w} \in R_{w}^{#}$ .
(3): $a \in R^{D, w}$ and $a^{D, w} \in R^{(1, 3)}$ .

In this case,

a_{w}^{D} = {[{(a w)}^{D}]}^{2} {[a^{D, w}]}_{w}^{#} = a^{D, w} w a^{D, w} {(a^{D, w})}^{(1, 3)} .

Proof.

(1) \Rightarrow (2)

In view of Lemma 2.3,

a w \in R^{D}

and

x = {(a w)}^{D}

. By virtue of [[10], Theorem 2.3],

a w \in R^{D}

. Evidently,

{[{(a w)}^{D}]}^{#} = {(a w)}^{2} {(a w)}^{D}

. Let

x = {({(a w)}^{D})}^{#}

. Since

{(a w)}^{D} = {[{(a w)}^{D}]}^{2} a w = a^{D, w} w

, we have

a^{D, w} w \in R^{#}

. We direly check that

\begin{matrix} a^{D, w} w x^{2} & = & x, \\ {(a^{D, w} w x)}^{*} & = & a^{D, w} w x, \\ x a^{D, w} w a^{D, w} w & = & a^{D, w} w . \end{matrix}

Hence,

\begin{matrix} x a^{D, w} w a^{D, w} & = & x a^{D, w} w [a^{D, w} w a w a^{D, w}] \\ = & [x a^{D, w} w a^{D, w} w] a w a^{D, w} = a^{D, w} w a w a^{D, w} = a^{D, w} . \end{matrix}

Therefore

a^{D, w} \in R_{w}^{#}

and

{(a^{D, w})}_{w}^{#} = x .

Additionally, we have

\begin{matrix} a_{w}^{D} & = & {(a w)}^{D} \\ = & {[{(a w)}^{D}]}^{2} {[{(a w)}^{D}]}^{#} \\ = & {[{(a w)}^{D}]}^{2} {[a^{D, w}]}_{w}^{#} . \end{matrix}

(2) \Rightarrow (3)

Since

a^{D, w} \in R_{w}^{#}

, by virtue of [[39], Theorem 2.6],

a^{D, w} \in R^{(1, 3)}

, as required.

(3) \Rightarrow (1)

Let

x = a^{D, w} w a^{D, w} {(a^{D, w})}^{(1, 3)}

. Then

x = {[{(a w)}^{D}]}^{3} a {({({(a w)}^{D})}^{2} a)}^{(1, 3)}

. Let

k = i (a w)

. Then

{(a w)}^{D} {(a w)}^{k + 1} = {(a w)}^{k}

.

Claim 1.

a w x {(a w)}^{k} a = {(a w)}^{k} a

.

We verify that

\begin{matrix} a w x {(a w)}^{k} a & = & a w {[{(a w)}^{D}]}^{3} a {({({(a w)}^{D})}^{2} a)}^{(1, 3)} {(a w)}^{k} a \\ = & {[{(a w)}^{D}]}^{2} a {({({(a w)}^{D})}^{2} a)}^{(1, 3)} {[{(a w)}^{D}]}^{2} a [w {(a w)}^{k + 1} a] \\ = & {[{(a w)}^{D}]}^{2} a [w {(a w)}^{k + 1} a] \\ = & {[{(a w)}^{D}]}^{2} {(a w)}^{2} {(a w)}^{k} {a] = (a w)}^{k} a . \end{matrix}

Step 2.

{(a w)}^{k} a R = x R

.

Clearly,

x R \subseteq {(a w)}^{D} R \subseteq {(a w)}^{k} a R

. Also we see that

\begin{matrix} {(a w)}^{k} a & = & {(a w)}^{D} {(a w)}^{k + 1} a = [{({(a w)}^{D})}^{3} a] [w {(a w)}^{k + 2} a] \\ = & {[{(a w)}^{D}]}^{3} a {({({(a w)}^{D})}^{2} a)}^{(1, 3)} {({(a w)}^{D})}^{2} a] [w {(a w)}^{k + 2} a] \\ = & x {({(a w)}^{D})}^{2} a] [w {(a w)}^{k + 2} a]; \end{matrix}

hence,

{(a w)}^{k} a \subseteq x R

. Therefore

{(a w)}^{k} a R = x R

.

Step 3.

R x = R {({(a w)}^{k} a)}^{*}

.

We easily verify that

\begin{matrix} x & = & {[{(a w)}^{D}]}^{3} a {({({(a w)}^{D})}^{2} a)}^{(1, 3)} \\ = & {({[{(a w)}^{D}]}^{3} a {({({(a w)}^{D})}^{2} a)}^{(1, 3)})}^{*} \\ = & {([{(a w)}^{k} a w {({(a w)}^{D})}^{k + 1}] {[{(a w)}^{D}]}^{3} a {({({(a w)}^{D})}^{2} a)}^{(1, 3)})}^{*} \\ = & {([w {({(a w)}^{D})}^{k + 1}] {[{(a w)}^{D}]}^{3} a {({({(a w)}^{D})}^{2} a)}^{(1, 3)})}^{*} {({(a w)}^{k} a)}^{*}, \end{matrix}

and then,

R x \subseteq R {({(a w)}^{k} a)}^{*}

. Moreover, we have

\begin{matrix} {(a w)}^{k} a & = & {(a w)}^{D} {(a w)}^{k + 1} a = {[{(a w)}^{D}]}^{2} a w {(a w)}^{k + 1} a \\ = & ({[{(a w)}^{D}]}^{2} a {({[{(a w)}^{D}]}^{2} a)}^{(1, 3)} {[{(a w)}^{D}]}^{2} a) w {(a w)}^{k + 1} a, \end{matrix}

and then

\begin{matrix} {({(a w)}^{k} a)}^{*} & = & {({[{(a w)}^{D}]}^{2} a w {(a w)}^{k + 1} a)}^{*} {[{(a w)}^{D}]}^{2} a {({[{(a w)}^{D}]}^{2} a)}^{(1, 3)} \\ = & {({[{(a w)}^{D}]}^{2} a w {(a w)}^{k + 1} a)}^{*} (a w) {[{(a w)}^{D}]}^{3} a {({[{(a w)}^{D}]}^{2} a)}^{(1, 3)} \\ = & {({[{(a w)}^{D}]}^{2} a w {(a w)}^{k + 1} a)}^{*} (a w) x . \end{matrix}

Hence

R {({(a w)}^{k} a)}^{*} \subseteq R x

. Therefore

R x = R {({(a w)}^{k} a)}^{*}

.

Accordingly,

a \in R_{w}^{D}

by [[25], Theorem 2.4]. □

Corollary 2.5.

Let

a, w \in R

. Then the following are equivalent:

(1): $a \in R_{w}^{D}$ .
(2): $a \in R^{D, w}$ and $a w a^{D, w} w \in R^{(1, 3)}$ .
(3): $a \in R^{D, w}$ and there exists a projection $q \in R$ such that $a^{D, w} R = q R$ .

In this case,

a_{w}^{D} = a^{D, w} w a^{D, w} {(a^{D, w})}^{(1, 3)} = a^{D, w} w q .

Proof.

(1) \Rightarrow (3)

By virtue of Theorem 2.4,

a^{D, w} \in R^{(1, 3)}

and then

a^{D, w} = a^{D, w} {(a^{D, w})}^{(1, 3)} a^{D, w} a n d {[a^{D, w} {(a^{D, w})}^{(1, 3)}]}^{*} = a^{D, w} {(a^{D, w})}^{(1, 3)} .

Let

q = a^{D, w} {(a^{D, w})}^{(1, 3)}

. Then

a^{D, w} R = q R, q^{2} = q = q^{*}

, as required.

(3) \Rightarrow (2)

Let

x = a^{D, w} w q

. Then

a w x = a w a^{D, w} w q = a w {[{(a w)}^{D}]}^{2} a w q = a w {(a w)}^{D} q = q

, and so

{(a w x)}^{*} = q^{*} = q = a w x

. Moreover, we have

a w x^{2} = (a w x) x = q a^{D, w} w q = a^{D, w} w q = x .

Let n be the Drazin index of

a w

. Then

{(a w)}^{n} = {(a w)}^{D} {(a w)}^{n + 1}

. Obviously,

a^{D, w} w (a w) = (a w) a^{D, w} w

, and so

\begin{matrix} {(a w)}^{n} - x {(a w)}^{n + 1} \\ = & {(a w)}^{n} - a^{D, w} w q {(a w)}^{n + 1} \\ = & {(a w)}^{n} - {(a w)}^{D} q {(a w)}^{n + 1} = {(a w)}^{n} - {(a w)}^{D} q {(a w)}^{D} {(a w)}^{n + 2} \\ = & {(a w)}^{n} - {(a w)}^{D} {(a w)}^{D} {(a w)}^{n + 2} = {(a w)}^{n} - {(a w)}^{D} {(a w)}^{n + 1} = 0 . \end{matrix}

Hence

{(a w)}^{n} = x {(a w)}^{n + 1} .

Thus

x = a_{w}^{D}

. In this case,

a_{w}^{D} = x = a^{D, w} w q = a^{D, w} w a^{D, w} {(a^{D, w})}^{(1, 3)} .

(2) \Rightarrow (1)

Let

x = a^{D, w} w {(a w a^{D, w} w)}^{(1, 3)}

. Then we verify that

\begin{matrix} a w x & = & a w a^{D, w} w {(a w a^{D, w} w)}^{(1, 3)} = a w {(a w)}^{D} {(a w {(a w)}^{D})}^{(1, 3)}, \\ {(a w x)}^{*} & = & a w x, \\ a w x^{2} & = & a w {(a w)}^{D} {(a w {(a w)}^{D})}^{(1, 3)} a^{D, w} w {(a w a^{D, w} w)}^{(1, 3)} \\ = & a w {(a w)}^{D} {(a w {(a w)}^{D})}^{(1, 3)} a w {[{(a w)}^{D}]}^{2} {(a w a^{D, w} w)}^{(1, 3)} \\ = & {(a w)}^{D} {(a w a^{D, w} w)}^{(1, 3)} = x, \end{matrix}

Let n be the Drazin index of

a w

. Then

\begin{matrix} a w x {(a w)}^{n} & = & a w {(a w)}^{D} {(a w {(a w)}^{D})}^{(1, 3)} {(a w)}^{n} \\ = & a w {(a w)}^{D} {(a w {(a w)}^{D})}^{(1, 3)} (a w) {(a w)}^{D} {(a w)}^{n} \\ = & a w {(a w)}^{D} {(a w)}^{n} = {(a w)}^{n} . \end{matrix}

Hence,

{(a w)}^{n} = a w x {(a w)}^{n} .

Therefore

a \in R_{w}^{D}

by Lemma 2.3. In this case,

a_{w}^{D} = a^{D, w} w {(a w a^{D, w} w)}^{(1, 3)} .

□

Corollary 2.6.

Let

a \in R

. Then the following are equivalent:

(1): $a \in R^{D}$ .
(2): $a \in R^{D}$ and $a^{D} \in R^{#}$ .
(3): $a \in R^{D}$ and $a^{D} \in R^{(1, 3)}$ .
(4): $a \in R^{D}$ and $a a^{D} \in R^{(1, 3)}$ .
(5): $a \in R^{D}$ and there exists a projection $q \in R$ such that $a^{D} R = q R$ .

In this case,

a^{D} = {(a^{D})}^{2} (a^{D #} = {(a^{D})}^{2} {(a^{D})}^{(1, 3)} = a^{D} q .

Proof.

This is obvious by choosing

w = 1

in Theorem 2.4 and Corollary 2.5. □

3. Weighted Core-EP Orders

Let

a \in R_{w}^{#}, b \in R

. Recall that

a \leq_{w}^{#} b

if

a w a_{w}^{#} = b w a_{w}^{#}

and

a_{w}^{#} a = a_{w}^{#} b

(see [40]). By employing the w-core-decomposition as a tool, we now characterize the weighted core-EP inverse through the weight core order.

Theorem3.1.

Let

a, b \in R_{w}^{D}

. If

a = a_{1} + a_{2}, b = b_{1} + b_{2}

are w-core-EP decompositions of a and b. Then the following are equivalent:

(1): $a \leq_{w}^{D} b$ .
(2): $a_{1} \leq_{w}^{#} b_{1}$ .
(3): ${(a w)}^{n + 1} = b w {(a w)}^{n}$ and $a^{*} {(a w)}^{n} = b^{*} {(a w)}^{n}$ for some $n \in N$ .

Proof.

(1) \Rightarrow (2)

Since

a \leq_{w}^{D} b

, we have

a w a_{w}^{D} = b w a_{w}^{D}

and

a_{w}^{D} a = a_{w}^{D} b

. For any

m \in N

, we derive

\begin{matrix} a_{1} w {(a_{1})}_{w}^{#} & = & (a_{1} + a_{2}) w {(a_{1})}_{w}^{#} = a w a_{w}^{D} = b w a_{w}^{D} \\ = & b w a w {(a_{w}^{D})}^{2} = b w [a w a_{w}^{D}] a_{w}^{D} = b w [b w a_{w}^{D}] a_{w}^{D} \\ = & {(b w)}^{2} {(a_{w}^{D})}^{2} = \dots = {(b w)}^{m} {(a_{w}^{D})}^{m}, \\ b_{1} w {(a_{1})}_{w}^{#} & = & b w b_{w}^{D} b w a_{w}^{D} = b w b_{w}^{D} b w a w {(a_{w}^{D})}^{2} = b w b_{w}^{D} {(b w)}^{2} {(a_{w}^{D})}^{2} \\ = & \dots = b w b_{w}^{D} {(b w)}^{m} {(a_{w}^{D})}^{m} . \end{matrix}

Thus, we have

\begin{matrix} a_{1} w {(a_{1})}_{w}^{#} - b_{1} w {(a_{1})}_{w}^{#} \\ = & {(b w)}^{m} {(a_{w}^{D})}^{m} - b w b_{w}^{D} {(b w)}^{m} {(a_{w}^{D})}^{m} \\ = & [{(b w)}^{m} - b w b_{w}^{D} {(b w)}^{m}] {(a_{w}^{D})}^{m} . \end{matrix}

In view of Lemma 2.3,

{(b w)}^{m} = b w b_{w}^{D} {(b w)}^{m} .

Hence,

a_{1} w {(a_{1})}_{w}^{#} = b_{1} w {(a_{1})}_{w}^{#} .

Since

b_{1} = b w b_{w}^{D} b

, we verify that

a w a_{w}^{D} = a_{1} w {(a_{1})}_{w}^{#} = b_{1} w {(a_{1})}_{w}^{#} = b w b_{w}^{D} b w a_{w}^{D} = b w b_{w}^{D} a w a_{w}^{D} .

Thus,

{[a w a_{w}^{D}]}^{*} = {[b w b_{w}^{D} a w a_{w}^{D}]}^{*},

and so

a w a_{w}^{D} = a w a_{w}^{D} b w b_{w}^{D} .

Then we see that

\begin{matrix} {(a_{1})}_{w}^{#} a_{1} & = & a_{w}^{D} (a w a_{w}^{D} a) = a_{w}^{D} (a w a_{w}^{D}) a \\ = & a_{w}^{D} (a w a_{w}^{D}) b \\ = & a_{w}^{D} (a w a_{w}^{D} b w b_{w}^{D}) b \\ = & (a_{w}^{D} a w a_{w}^{D}) b w b_{w}^{D}) b \\ = & a_{w}^{D} (b w b_{w}^{D} b) = {(a_{1})}_{w}^{#} b_{1} . \end{matrix}

Therefore

a_{1} \leq_{w}^{#} b_{1}

.

(2) \Rightarrow (1)

Obviously, we have

a w a_{w}^{D} = (a_{1} + a_{2}) w a_{1}^{#} = a_{1} w a_{1}^{#} = b_{1} w a_{1}^{#} = b w b_{w}^{D} b w a_{w}^{D} .

Then

a_{w}^{D} = a w {(a_{w}^{D})}^{2} = b w b_{w}^{D} b w {(a_{w}^{D})}^{2} .

Since

{(b w)}^{n} = b w b_{w}^{D} {(b w)}^{n}

for some

n \in N

, we derive that

b w b_{w}^{D} b w a_{w}^{D} = b w a_{w}^{D} .

Then

a w a_{w}^{D} = b w a_{w}^{D} .

Clearly,

a_{w}^{D} a_{2} = {(a_{1})}_{w}^{#} a_{2} = {(a_{1})}_{w}^{#} a_{1} w {(a_{1})}_{w}^{#} a_{2} = {(a_{1})}_{w}^{#} {(a_{1} w {(a_{1})}_{w}^{#})}^{*} a_{2} = {(a_{1})}_{w}^{#} {[w {(a_{1})}_{w}^{#}]}^{*} {(a_{1})}^{*} a_{2} = 0

.

Moreover, we have

a w a_{w}^{D} = b w b_{w}^{D} b w a_{w}^{D} = (b w b_{w}^{D}) (a w a_{w}^{D}) .

Then

\begin{matrix} a w a_{w}^{D} & = & {(a w a_{w}^{D})}^{*} \\ = & {(a w a_{w}^{D})}^{*} {(b w b_{w}^{D})}^{*} \\ = & a w a_{w}^{D} b w b_{w}^{D} . \end{matrix}

Hence,

a_{w}^{D} = a_{w}^{D} a w a_{w}^{D} = a_{w}^{D} a w a_{w}^{D} b w b_{w}^{D} = a_{w}^{D} b w b_{w}^{D}

. Accordingly,

a_{w}^{D} b = a_{w}^{D} b w b_{w}^{D} b = {(a_{1})}_{w}^{D} b_{1} = {(a_{1})}_{w}^{D} a_{1} = a_{w}^{D} (a_{1} + a_{2}) = a_{w}^{D} a

, as required.

(1) \Rightarrow (3)

Since

a w a_{w}^{D} = b w a_{w}^{D}

and

{(a w)}^{k + 1} = {(a w)}^{k}

, we see that

{(a w)}^{k + 1} = (a w) {(a w)}^{k} = (b w) {(a w)}^{k}

. Also we have

a_{w}^{D} a = a_{w}^{D} b

. Then

a^{*} {(a_{w}^{D})}^{*} = b^{*} {(a_{w}^{D})}^{*}

; hence,

a^{*} {(a_{w}^{D})}^{*} {(a w)}^{*} {(a w)}^{k} = b^{*} {(a_{w}^{D})}^{*} {(a w)}^{*} {(a w)}^{k} .

As

{(a w a_{w}^{D})}^{*} = a w a_{w}

and

a w a_{w}^{D} {(a w)}^{k + 1} = {(a w)}^{k + 2}

, we deduce that

a^{*} {(a w)}^{k + 1} = b^{*} {(a w)}^{k + 1}

. Choose

n = k + 1

. Then

{(a w)}^{n + 1} = b w {(a w)}^{n}

and

a^{*} {(a w)}^{n} = b^{*} {(a w)}^{n}

, as required.

(3) \Rightarrow (1)

By hypothesis,

{(a w)}^{n + 1} = b w {(a w)}^{n}

and

a^{*} {(a w)}^{n} = b^{*} {(a w)}^{n}

for some

n \in N

. Since

{(a w)}^{n + 1} = b w {(a w)}^{n}

, we have

(a w) {(a w)}^{n} {(a_{w}^{D})}^{n + 1} = (b w) {(a w)}^{n} {(a_{w}^{D})}^{n + 1}

. As

a w {(a_{w}^{D})}^{2} = a_{w}^{D}

, we have

(a w) a_{w}^{D} = (b w) a_{w}^{D}

.

Since

a^{*} {(a w)}^{n} = b^{*} {(a w)}^{n}

, we have

{({(a w)}^{n})}^{*} a = {({(a w)}^{n})}^{*} b

. Hence,

{[{(a_{w}^{D})}^{n}]}^{n} {({(a w)}^{n})}^{*} a = {[{(a_{w}^{D})}^{n}]}^{n} {({(a w)}^{n})}^{*} b .

This implies that

a w a_{w}^{D} a = a w a_{w}^{D} b .

Therefore

\begin{matrix} a_{w}^{D} a & = & a_{w}^{D} a = a_{w}^{D} [a w a_{w}^{D} a] \\ = & a_{w}^{D} [a w a_{w}^{D} b] = {[a w)}^{D} a w a_{w}^{D}] b = a_{w}^{D} b, \end{matrix}

as required. □

Corollary 3.2.

The relation

\leq_{w}^{D}

for w-core-EP invertible elements is a preorder on R.

Proof.

Step 1.

a \leq_{w}^{D} a

. Let

a = a_{1} + a_{2}

be the w-core-EP decomposition. In view of [40],

a_{1} \leq_{w}^{#} a_{1}

. By using Theorem 3.1,

a \leq_{w}^{D} a

.

Step 2. Assume that

a \leq_{w}^{D} b

and

b \leq_{w}^{D} c

. We claim that

a \leq_{w}^{D} c

. Let

a = a_{1} + a_{2}, b = b_{1} + b_{2}

and

c = c_{1} + c_{2}

be the w-core-EP decompositions of

a, b

and c, respectively. By virtue of Theorem 3.1,

a_{1} \leq_{w}^{#} b_{1}

and

b_{1} \leq_{w}^{#} c_{1}

. According to [[40], Theorem 2.3], we have

a_{1} \leq_{w}^{#} c_{1}

. By using Theorem 3.1 again,

a \leq_{w}^{D} c

.

Therefore the relation

\leq_{w}^{D}

for w-core-EP invertible elements is a preorder. □

Lemma 3.3.

Let

a, b \in R_{w}^{D}

and

a \leq_{w}^{D} b

. Then the following hold:

(1): $a w a_{w}^{D} = (a w a_{w}^{D}) (b w b_{w}^{D}) = (b w b_{w}^{D}) (a w a_{w}^{D})$ .
(2): $a_{w}^{D} = a_{w}^{D} (b w b_{w}^{D}) = (b w b_{w}^{D}) a_{w}^{D}$ .
(3): $b w a_{w}^{D} = a w a_{w}^{D} a w b_{w}^{D} .$
(4): $b_{w}^{D} a_{w}^{D} = {(a_{w}^{D})}^{2}$ .

Proof.

In view of Lemma 2.3,

a w, b w \in R^{D}, {(a w)}^{D} = a_{w}^{D}

and

{(b w)}^{D} = b_{w}^{D}

. Since

a \leq_{w}^{D} b

, we have

a w a_{w}^{D} = b w a_{w}^{D}, a_{w}^{D} a = a_{w}^{D} b .

Hence,

a_{w}^{D} a w = a_{w}^{D} b w .

This implies that

a w \leq^{D} b w

. In view of [[7], Lemma 6.2.6], we derive

(a w) {(a w)}^{D} = [(a w) {(a w)}^{D}] [(b w) {(b w)}^{D}] = [(b w) {(b w)}^{D}] [(a w) {(a w)}^{D}] .

Therefore

a w a_{w}^{D} = (a w a_{w}^{D}) (b w b_{w}^{D}) = (b w b_{w}^{D}) (a w a_{w}^{D}) .

We directly check that

\begin{matrix} a_{w}^{D} & = & a_{w}^{D} [a w a_{w}^{D}] = [a_{w}^{D} a w a_{w}^{D}] (b w b_{w}^{D}) \\ = & a_{w}^{D} (b w b_{w}^{D}) = [a w a_{w}^{D}] a_{w}^{D} \\ = & (b w) {(b w)}^{D} a w {[{(a w)}^{D}]}^{2} = (b w b_{w}^{D}) a_{w}^{D} . \end{matrix}

Analogously,

(3)

and

(4)

are proved by using [[7], Theorem 6.2.7]. □

Theorem 3.4.

Let

a, b \in R_{w}^{D}

. Then the following are equivalent:

(1): $a \leq_{w}^{D} b$ .
(2): $a_{w}^{D} b = b_{w}^{D} a w a_{w}^{D} a, a_{w}^{D} = a_{w}^{D} b w a_{w}^{D}, b w a_{w}^{D} = a w a_{w}^{D} a w b_{w}^{D} .$

Proof.

(1) \Rightarrow (2)

We claim that

\begin{matrix} a_{w}^{D} b & = & [a_{w}^{D} (b w b_{w}^{D})] b = a_{w}^{D} [b w b_{w}^{D} b] \\ = & {(a_{1})}_{w}^{#} b_{1} = {(a_{1})}_{w}^{#} a_{1} = {(b_{1})}_{w}^{#} a_{1} \\ = & b_{w}^{D} a w a_{w}^{D} a . \end{matrix}

By virtue of Lemma 3.3,

a_{w}^{D} = a_{w}^{D} b w a_{w}^{D}, b w a_{w}^{D} = a w a_{w}^{D} a w b_{w}^{D} .

(2) \Rightarrow (1)

Step 1. By hypothesis, we have

{(a w)}^{D} = {(a w)}^{D} (b w) {(a w)}^{D}, (b w) {(a w)}^{D} = (a w) {(a w)}^{D} (a w) (b w 0^{D} .

Since

a_{w}^{D} b = b_{w}^{D} a w a_{w}^{D} a

, we get

{(a w)}^{D} (b w) = {(b w)}^{D} (a w) {(a w)}^{D} (a w) .

According to [[7], roposition 6.2.8],

a w \leq^{D} b w

. Thus,

(a w) {(a w)}^{D} = (b w) {(a w)}^{D}

; hence,

a w a_{w}^{D} = b w a_{w}^{D}

.

Step 2. We verify that

\begin{matrix} a_{w}^{D} a & = & [a_{w}^{D} (b w a_{w}^{D})] a = [a_{w}^{D} b] [w a_{w}^{D} a] \\ = & [b_{w}^{D} a w a_{w}^{D} a] [w a_{w}^{D} a] = b_{w}^{D} a w [a_{w}^{D} a w a_{w}^{D}] a \\ = & b_{w}^{D} a w a_{w}^{D} a = a_{w}^{D} b . \end{matrix}

This completes the proof. □

Employing the technique of Hilbert operator decomposition, many properties of the core-EP preorder between two Hilbert space operators, grounded in their corresponding self-adjoint operators, were explored in [25]. Through an elementary-wise analysis, we will characterize the preorder of weighted core-EP inverses, which includes certain self-adjoint elements, thereby extending many established results to a more comprehensive class of ring elements.

Theorem 3.5.

Let

a, b \in R_{w}^{D}

. Then the following are equivalent:

(1): $a \leq_{w}^{D} b$ .
(2): $b w a_{w}^{D}$ is self-adjoint and $a_{w}^{D} a = a_{w}^{D} b$ .
(3): $b w a_{w}^{D}$ is self-adjoint and $a w a_{w}^{D} a = a w a_{w}^{D} b$ .
(4): $b w a_{w}^{D}$ is self-adjoint and $a^{*} a_{w}^{D} = b^{*} a_{w}^{D}$ .
(5): $b w a_{w}^{D}$ is self-adjoint and $a^{*} {(a w)}^{n} = b^{*} {(a w)}^{n}$ for some $n \in N$ .
(6): $b w a_{w}^{D}$ is self-adjoint and $a^{*} a^{D, w} = b^{*} a^{D, w}$ .

Proof.

(1)

Since

a \leq_{w}^{D} b

, we have

a w a_{w}^{D} = b w a_{w}^{D} b

and

a_{w}^{D} a = a_{w}^{D} b

. Since

{(a w a_{w}^{D})}^{*} = a w a_{w}^{D}

, we see that

{(b w a_{w}^{D})}^{*} = b w a_{w}^{D}

. That is,

b w a_{w}^{D}

is self-adjoint, as required.

(2) \Rightarrow (3)

This is obvious.

(3) \Rightarrow (1)

By hypothesis,

{(b w a_{w}^{D})}^{*} = b w a_{w}^{D}

. In view of |

cite[Theorem 2.4]MZ,

a_{w}^{D} = a_{w}^{D} a w a_{w}^{D}

and

{(a w a_{w}^{D})}^{*} = a w a_{w}^{D}

. Then

\begin{matrix} b w a_{w}^{D} & = & {[b w (a_{w}^{D} a w a_{w}^{D})]}^{*} \\ = & {(a w a_{w}^{D})}^{*} {(b w a_{w}^{D})}^{*} \\ = & (a w a_{w}^{D}) (b w a_{w}^{D}) \\ = & [a w a_{w}^{D} b] w a_{w}^{D} \\ = & [a w a_{w}^{D} a] w a_{w}^{D} \\ = & a w [a_{w}^{D} a w a_{w}^{D}] \\ = & a w a_{w}^{D}, \end{matrix}

as desired.

(1) \Rightarrow (4)

Obviously,

b w a_{w}^{D}

is self-adjoint and

a_{w}^{D} a = a_{w}^{D} b

. Hence,

a w a_{w}^{D} a = a w a_{w}^{D} b

. This implies that

{(a w a_{w}^{D})}^{*} a = {(a w a_{w}^{D})}^{*} b

. Hence,

a^{*} (a w a_{w}^{D}) = b^{*} (a w a_{w}^{D})

. Therefore

a^{*} a_{w}^{D} = [a^{*} a w a_{w}^{D}] a_{w}^{D} = [b^{*} a w a_{w}^{D}] a_{w}^{D} = b^{*} a_{w}^{D}

, as required.

(4) \Rightarrow (5)

Since

a_{w}^{D} a^{n + 1} = a^{n}

for some

n \in N

, we have

a^{*} {(a w)}^{n} = [a^{*} a_{w}^{D}] a^{n + 1} [b^{*} a_{w}^{D}] a^{n + 1} = b^{*} {(a w)}^{n},

as desired.

(5) \Rightarrow (6)

As

a^{*} {(a w)}^{n} = b^{*} {(a w)}^{n}

, we have

a^{*} {(a w)}^{D} = a^{*} {(a w)}^{n} {[{(a w)}^{D}]}^{n + 1} = b^{*} {(a w)}^{n} {[{(a w)}^{D}]}^{n + 1} = b^{*} {(a w)}^{D}

. Therefore

a^{*} a^{D, w} = [a^{*} {(a w)}^{D}] [{(a w)}^{D} a] = [b^{*} {(a w)}^{D}] [{(a w)}^{D} a] = b^{*} a^{D, w}

.

(6) \Rightarrow (3)

Since

a w {(a w)}^{D} = a^{D, w} w a w

, we have

a^{*} a w {(a w)}^{D} = b^{*} a w {(a w)}^{D}

. In view of [10],

{(a w)}^{D} \in {(a w)}^{D} R

, and then

a^{*} a w {(a w)}^{D} = b^{*} a w {(a w)}^{D}

. Hence

a^{*} a w a_{w}^{D} = b^{*} a w a_{w}^{D}

. As

{(a w a_{w}^{D})}^{*} = a w a_{w}^{D}

, we deduce that

a w a_{w}^{D} a = a w a_{w}^{D} b

. Therefore

a_{w}^{D} a = a_{w}^{D} [a w a_{w}^{D} a] = a_{w}^{D} [a w a_{w}^{D} b] = a_{w}^{D} a,

as asserted. □

Theorem 3.6.

Let

a, b \in R_{w}^{D}

. Then the following are equivalent:

(1): $a \leq_{w}^{D} b$ .
(2): ${(a w a_{w}^{D} a)}^{*} b$ is self-adjoint and $a w a_{w}^{D} = b w a_{w}^{D}$ .
(3): ${(a w a_{w}^{D} a)}^{*} b$ is self-adjoint and $a w a_{w}^{D} a = b w a_{w}^{D} a$ .
(4): ${(a w a_{w}^{D} a)}^{*} b$ is self-adjoint and $a_{w}^{D} {(a w)}^{*} = a_{w}^{D} {(b w)}^{*}$ .

Proof.

(1) \Rightarrow (2)

By hypothesis, we have

a w a_{w}^{D} = b w a_{w}^{D}, a_{w}^{D} a = a_{w}^{D} b .

Hence,

{(a w a_{w}^{D} a)}^{*} b = a^{*} {(a w a_{w}^{D})}^{*} b = a^{*} a w [a_{w}^{D} b] = a^{*} a w [a_{w}^{D} a] = a^{*} [a w a_{w}^{D}] a .

This implies that

{(a w a_{w}^{D} a)}^{*} b

is self-adjoint.

(2) \Rightarrow (3)

This is obvious.

(3) \Rightarrow (1)

Since

a w a_{w}^{D} a = b w a_{w}^{D} a

, we see that

\begin{matrix} a w a_{w}^{D} & = & a w [a_{w}^{D} a w a_{w}^{D}] \\ = & [a w a_{w}^{D} a] w a_{w}^{D} \\ = & [b w a_{w}^{D} a] w a_{w}^{D} \\ = & b w a_{w}^{D} . \end{matrix}

Since

{(a w a_{w}^{D} a)}^{*} b

is self-adjoint, we verify that

\begin{matrix} a_{w}^{D} b & = & a_{w}^{D} {(a w a_{w}^{D})}^{*} a w a_{w}^{D} b \\ = & a_{w}^{D} {(w a_{w}^{D})}^{*} a^{*} {(a w a_{w}^{D})}^{*} b \\ = & a_{w}^{D} {(w a_{w}^{D})}^{*} {(a w a_{w}^{D} a)}^{*} b \\ = & a_{w}^{D} {(w a_{w}^{D})}^{*} {({(a w a_{w}^{D} a)}^{*} b)}^{*} \\ = & a_{w}^{D} {(a w a_{w}^{D})}^{*} {(w a_{w}^{D})}^{*} {({(a w a_{w}^{D} a)}^{*} b)}^{*} \\ = & a_{w}^{D} {(w a_{w}^{D})}^{*} a^{*} {(w a_{w}^{D})}^{*} {({(a w a_{w}^{D} a)}^{*} b)}^{*} \\ = & a_{w}^{D} {(w a_{w}^{D})}^{*} {(w a_{w}^{D} a)}^{*} {({(a w a_{w}^{D} a)}^{*} b)}^{*} \\ = & a_{w}^{D} {(w a_{w}^{D})}^{*} {({(a w a_{w}^{D} a)}^{*} [b w a_{w}^{D} a])}^{*} \\ = & a_{w}^{D} {(w a_{w}^{D})}^{*} {({(a w a_{w}^{D} a)}^{*} [a w a_{w}^{D} a])}^{*} \\ = & a_{w}^{D} {(w a_{w}^{D})}^{*} {(a w a_{w}^{D} a)}^{*} [a w a_{w}^{D} a] \\ = & a_{w}^{D} {(w a_{w}^{D})}^{*} a^{*} {(a w a_{w}^{D})}^{*} [a w a_{w}^{D} a] \\ = & a_{w}^{D} {(a w a_{w}^{D})}^{*} {(a w a_{w}^{D})}^{*} [a w a_{w}^{D} a] \\ = & a_{w}^{D} (a w a_{w}^{D}) (a w a_{w}^{D}) (a w a_{w}^{D}) a \\ = & a_{w}^{D} a . \end{matrix}

Therefore

a \leq_{w}^{D} b

.

(1) \Rightarrow (4)

Obviously,

{(a w a_{w}^{D} a)}^{*} b

is self-adjoint. Clearly,

a w a_{w}^{D} {(a w)}^{2} a_{w}^{D} = b w a_{w}^{D} {(a w)}^{2} a_{w}^{D}

. Since

a_{w}^{D} {(a w)}^{2} a_{w}^{D} = (a w) a_{w}^{D}

, we deduce that

a w (a w a_{w}^{D}) = b w (a w a_{w}^{D})

. As

{(a w a_{w}^{D})}^{*} = a w a_{w}^{D}

, we have

(a w a_{w}^{D}) {(a w)}^{*} = (a w a_{w}^{D}) {(b w)}^{*}

. Since

a_{w}^{D} (a w a_{w}^{D}) = a_{w}^{D}

, we get

a_{w}^{D} {(a w)}^{*} = a_{w}^{D} {(b w)}^{*}

, as required.

(4) \Rightarrow (2)

Since

a_{w}^{D} {(a w)}^{*} = a_{w}^{D} {(b w)}^{*}

, we have

[a w a_{w}^{D}] {(a w)}^{*} = [a w a_{w}^{D}] {(b w)}^{*}

. As

{[a w a_{w}^{D}]}^{*} = a w a_{w}^{D}

, we deduce that

a w [a w a_{w}^{D}] = b w [a w a_{w}^{D}]

; and then

a w a_{w}^{D} = a w [a w {(a_{w}^{D})}^{2}] = [{(a w)}^{2} a_{w}^{D}] a_{w}^{D} = [b w a w a_{w}^{D}] a_{w}^{D} = b w [a w {(a_{w}^{D})}^{2}] = b w a_{w}^{D}

, as desired. □

Theorem 3.7.

Let

a, b \in R_{w}^{D}

. Then the following are equivalent:

(1): $a \leq_{w}^{D} b$ .
(2): $a w a_{w}^{D} a = b w a_{w}^{D} b$ and $a w a_{w}^{D} = b w a_{w}^{D}$ .
(3): $a w a_{w}^{D} (a - b w a_{w}^{D} b) = 0$ and $a w a_{w}^{D} = b w a_{w}^{D}$ .
(4): $a_{w}^{D} (a - b w a_{w}^{D} b) = 0$ and $a w a_{w}^{D} = b w a_{w}^{D}$ .

Proof.

(1) \Rightarrow (2)

Since

a \leq_{w}^{D} b

, we have

a_{w}^{D} a = a_{w}^{D} b

and

a w a_{w}^{D} = b w a_{w}^{D}

. Then

a w a_{w}^{D} a = b w a_{w}^{D} a = b w a_{w}^{D} b

, as required.

(2) \Rightarrow (3)

We directly check that

a w a_{w}^{D} (a - b w a_{w}^{D} b) = a w a_{w}^{D} (a - a w a_{w}^{D} a) = a w a_{w}^{D} a - a w [a_{w}^{D} a w a_{w}^{D}] a = 0,

as desired.

(3) \Rightarrow (4)

Since

a_{w}^{D} = a_{w}^{D} a w a_{w}^{D}

, we conclude that

a_{w}^{D} (a - b w a_{w}^{D} b) = a_{w}^{D} [a w a_{w}^{D} (a - b w a_{w}^{D} b)] = 0

.

(4) \Rightarrow (1)

By hypothesis, we have

a_{w}^{D} a = a_{w}^{D} (b w a_{w}^{D}) b = a_{w}^{D} (a w a_{w}^{D}) b = [a_{w}^{D} a w a_{w}^{D}] b = a_{w}^{D} b .

This completes the proof. □

We are ready to prove:

Theorem 3.8.

Let

a, b \in R_{w}^{D}

. Then the following are equivalent:

(1): $a \leq_{w}^{D} b$ .
(2): $(1 - a w a_{w}^{D}) b w a_{w}^{D} = 0$ and $a_{w}^{D} a = a_{w}^{D} b$ .
(3): $(1 - a w a_{w}^{D}) b w a_{w}^{D} a = 0$ and $a w a_{w}^{D} a = a w a_{w}^{D} b$ .
(4): $(1 - a w a_{w}^{D}) b w a_{w}^{D} = 0$ and $a^{*} {(a w)}^{n} = b^{*} {(a w)}^{n}$ for some $n \in N$ .
(5): $(1 - a w a_{w}^{D}) b w a_{w}^{D} = 0, a_{w}^{D} a = a_{w}^{D} b w a_{w}^{D} a$ and $a_{w}^{D} a (1 - w a w a_{w}^{D}) = a_{w}^{D} b (1 - w a w a_{w}^{D})$ .
(6): $(1 - a w a_{w}^{D}) b w a_{w}^{D} a = 0, a_{w}^{D} = a_{w}^{D} b w a_{w}^{D}$ and $a w a_{w}^{D} a (1 - w a w a_{w}^{D}) = a w a_{w}^{D} b (1 - w a w a_{w}^{D})$ .

Proof.

(1) \Rightarrow (2)

By hypothesis, we have

a w a_{w}^{D} = b w a_{w}^{D}

and

a_{w}^{D} a = a_{w}^{D} b

. Then

(1 - a w a_{w}^{D}) b w a_{w}^{D} a = (1 - a w a_{w}^{D}) a w a_{w}^{D} a = 0

, as required.

(2) \Rightarrow (3)

This is trivial.

(3) \Rightarrow (1)

By hypothesis, we have

b w a_{w}^{D} a = a w a_{w}^{D} b w a_{w}^{D} a

and

a w a_{w}^{D} a = a w a_{w}^{D} b

. Then

b w a_{w}^{D} a = [a w a_{w}^{D} b] w a_{w}^{D} a = [a w a_{w}^{D} a] w a_{w}^{D} a = a w [a_{w}^{D} a w a_{w}^{D}] a = a w a_{w}^{D} a

. Hence,

b w a_{w}^{D} = [b w a_{w}^{D} a] w a_{w}^{D} = [a w a_{w}^{D} a] w a_{w}^{D} = a w a_{w}^{D}

. Since

a w a_{w}^{D} a = a w a_{w}^{D} b

, we deduce that

a_{w}^{D} a = a_{w}^{D} [a w a_{w}^{D} a] = a_{w}^{D} [a w a_{w}^{D} b] = a_{w}^{D} b,

as desired.

(1) \Rightarrow (4)

By the argument above, we have

(1 - a w a_{w}^{D}) b w a_{w}^{D} = 0

. In view of Theorem 3.1,

a^{*} {(a w)}^{n} = b^{*} {(a w)}^{n}

for some

n \in N

.

(4) \Rightarrow (1)

By hypothesis, we verify that

\begin{matrix} {(b w a_{w}^{D})}^{*} & = & {(a w a_{w}^{D} b w a_{w}^{D})}^{*} \\ = & {(w a_{w}^{D})}^{*} b^{*} {(a w a_{w}^{D})}^{*} \\ = & {(w a_{w}^{D})}^{*} b^{*} a w a_{w}^{D} \\ = & {(w a_{w}^{D})}^{*} b^{*} {(a w)}^{n} {(a_{w}^{D})}^{n} \\ = & {(w a_{w}^{D})}^{*} a^{*} {(a w)}^{n} {(a_{w}^{D})}^{n} \\ = & {(a w a_{w}^{D})}^{*} a w a_{w}^{D} \\ = & a w [a_{w}^{D} a w a_{w}^{D}] \\ = & a w a_{w}^{D} . \end{matrix}

Therefore

b w a_{w}^{D} = {(a w a_{w}^{D})}^{*} = a w a_{w}^{D}

. Obviously, we can find some

n \in N

such that

a^{*} {(a w)}^{n} = b^{*} {(a w)}^{n}

and

a_{w}^{D} {(a w)}^{n + 1} = {(a w)}^{n}

; hence,

b w a_{w}^{D} {(a w)}^{n + 1} = {(a w a_{w}^{D})}^{*} = a w a_{w}^{D} {(a w)}^{n + 1}

. This implies that

b w {(a w)}^{n} = a w a_{w}^{D} {(a w)}^{n}

. Accordingly,

a \leq_{w}^{D} b

by Theorem 3.1.

(1) \Rightarrow (5)

Since

a w a_{w}^{D} = b w a_{w}^{D}

and

a_{w}^{D} a = a_{w}^{D} b

. We verify that

a_{w}^{D} a = [a_{w}^{D} a w a_{w}^{D}] a = a_{w}^{D} b w a_{w}^{D} a,

as required.

(5) \Rightarrow (6)

Obviously,

a_{w}^{D} = [a_{w}^{D} a] w a_{w}^{D} = [a_{w}^{D} b w a_{w}^{D} a] w a_{w}^{D} = a_{w}^{D} b w [a_{w}^{D} a w a_{w}^{D}]

= a_{w}^{D} b w a_{w}^{D}

, as desired.

(6) \Rightarrow (3)

By hypothesis, we have

\begin{matrix} a w a_{w}^{D} b w a w a_{w}^{D} & = & a w a_{w}^{D} b w [a_{w}^{D} {(a w)}^{2}] a_{w}^{D} \\ = & a w [a_{w}^{D} b w a_{w}^{D}] {(a w)}^{2} a_{w}^{D} \\ = & a w a_{w}^{D} {(a w)}^{2} a_{w}^{D} . \end{matrix}

Therefore

a w a_{w}^{D} a = a w a_{w}^{D} b

, as asserted. □

4. Weighted Core-EP Inverse of Product and Difference

Let

p, q \in A

be idempotents. Then for any

x \in A

, we have

x = p x q + p x (1 - p) + (1 - p) x q + (1 - p) x (1 - q)

. Thus x can be represented in the matrix form

x = {(\begin{matrix} p x p & p x (1 - p) \\ (1 - p) x p & (1 - p) x (1 - q) \end{matrix})}_{(p, q)}

. With respect to the orthogonal sum of a Hilbert space, Stanimirović and Mosić provided conditions for the equivalence between the forward order law and the reverse order law for the core-EP inverse of Hilbert space operators. We will utilize the preceding matrix, in relation to idempotents, to extend the main results in [25] to a broader class of ring elements. The following theorem is crucial.

Theorem 4.1.

Let

a \in A_{w}^{D}

. Then the following are equivalent:

(1): $a \leq_{w}^{D} b$ .
(2): $a, w$ and b are represented as

$a = {(\begin{matrix} a_{1} & a_{12} \\ 0 & a_{2} \end{matrix})}_{p \times q}, w = {(\begin{matrix} w_{1} & w_{12} \\ 0 & w_{2} \end{matrix})}_{q \times p}, b = {(\begin{matrix} a_{1} & a_{12} \\ 0 & b_{2} \end{matrix})}_{p \times q},$

where

$\begin{matrix} p = a w a_{w}^{D}, q = w a_{w}^{D} a, \\ a_{1} w_{1} \in {(p A p)}^{- 1}, w_{1} a_{1} \in {(q A q)}^{- 1}, \\ a_{2} w_{2} \in {((1 - p) A (1 - p))}^{q n i l}, \\ w_{2} a_{2} \in {((1 - q) A (1 - q))}^{q n i l}, \\ w_{1} a_{12} + w_{12} a_{2} = w_{1} b_{12} + w_{12} b_{2} . \end{matrix}$

Proof.

(1) \Rightarrow (2)

Let

p = a w a_{w}^{D}, q = w a_{w}^{D} a

. Then we verify that

\begin{matrix} (1 - p) a q & = & [1 - a w a_{w}^{D}] a w a_{w}^{D} a \\ = & a w a_{w}^{D} a - a w [a_{w}^{D} a w a_{w}^{D}] a \\ = & 0; \\ (1 - q) w p & = & [1 - w a_{w}^{D} a] w a w a_{w}^{D} \\ = & w a w a_{w}^{D} - w a_{w}^{D} {(a w)}^{2} a_{w}^{D} \\ = & 0 . \end{matrix}

Moreover, we verify that

\begin{matrix} a_{1} w_{1} & = & a w [a_{w}^{D} a w a_{w}^{D}] {(a w)}^{2} a_{w}^{D} \\ = & a w a_{w}^{D} {(a w)}^{2} a_{w}^{D} \\ = & {(a w)}^{2} a_{w}^{D} \\ \in & {(p A p)}^{- 1}; \\ w_{1} a_{1} & = & w a w a_{w}^{D} a \\ \in & {(q A q)}^{- 1}; \\ a_{2} w_{2} & = & [1 - a w a_{w}^{D}] a [1 - w a_{w}^{D} a] w [1 - a w a_{w}^{D}] \\ = & a w - a w a_{w}^{D} a w \\ \in & {[(1 - p) A (1 - p)]}^{q n i l}; \\ w_{2} a_{2} & = & [1 - w a_{w}^{D} a] w [1 - a w a_{w}^{D}] a [1 - w a_{w}^{D} a] \\ = & w a - w a w a_{w}^{D} a \\ \in & {[(1 - q) A (1 - q)]}^{q n i l} . \end{matrix}

Write

b = {(\begin{matrix} b_{1} & b_{12} \\ b_{21} & b_{2} \end{matrix})}_{p \times q} .

Clearly, we have

\begin{matrix} a_{w}^{D} (1 - p) & = & a_{w}^{D} (1 - a w a_{w}^{D}) = 0, \\ (1 - p) a_{w}^{D} & = & (1 - a w a_{w}^{D}) a_{w}^{D} = 0 . \end{matrix}

Then

a_{w}^{D} = {(\begin{matrix} a_{w}^{D} & 0 \\ 0 & 0 \end{matrix})}_{p \times p} .

Since

a \leq_{w}^{D} b

, we have

\begin{matrix} {(\begin{matrix} a_{1} w_{1} a_{w}^{D} & 0 \\ 0 & 0 \end{matrix})}_{p \times q} \\ = & {(\begin{matrix} a_{1} & a_{12} \\ 0 & a_{2} \end{matrix})}_{p \times q} {(\begin{matrix} w_{1} & w_{12} \\ 0 & w_{2} \end{matrix})}_{q \times p} {(\begin{matrix} a_{w}^{D} & 0 \\ 0 & 0 \end{matrix})}_{p \times q} \\ = & (a w) a^{d, w} = (b w) a^{d, w} \\ = & {(\begin{matrix} b_{1} & b_{12} \\ b_{21} & b_{2} \end{matrix})}_{p \times q} {(\begin{matrix} w_{1} & w_{12} \\ 0 & w_{2} \end{matrix})}_{q \times p} {(\begin{matrix} a_{w}^{D} & 0 \\ 0 & 0 \end{matrix})}_{p \times p} \\ = & {(\begin{matrix} b_{1} w_{1} a_{w}^{D} & 0 \\ b_{21} w_{1} a_{w}^{D} & 0 \end{matrix})}_{p \times q} . \end{matrix}

Then

a_{1} w_{1} a_{w}^{D} = b_{1} w_{1} a_{w}^{D}, b_{21} w_{1} a_{w}^{D} = 0

. Hence,

a_{1} w_{1} = b_{1} w_{1}

, and then

a_{1} = (a_{1} w_{1}) (a_{1} w_{1}) a_{w}^{D} = (b_{1} w_{1}) (a_{1} w_{1}) a_{w}^{D} = b_{1}

. Also we have

b_{21} w_{1} = 0

, and so

b_{21} = (b_{21} w_{1}) a_{1} w_{1} a_{w}^{D} = 0

. Moreover, we have

\begin{matrix} {(\begin{matrix} a_{w}^{D} w_{1} a_{1} & a_{w}^{D} w_{1} a_{12} + a_{w}^{D} w_{12} a_{2} \\ 0 & 0 \end{matrix})}_{p \times q} \\ = & {(\begin{matrix} a_{w}^{D} & 0 \\ 0 & 0 \end{matrix})}_{p \times q} {(\begin{matrix} w_{1} & w_{12} \\ 0 & w_{2} \end{matrix})}_{q \times p} {(\begin{matrix} a_{1} & a_{12} \\ 0 & a_{2} \end{matrix})}_{p \times q} \\ = & a_{w}^{D} (w a) = a_{w}^{D} (w b) \\ = & {(\begin{matrix} a_{w}^{D} & 0 \\ 0 & 0 \end{matrix})}_{p \times q} {(\begin{matrix} w_{1} & w_{12} \\ 0 & w_{2} \end{matrix})}_{q \times p} {(\begin{matrix} a_{1} & b_{12} \\ 0 & b_{2} \end{matrix})}_{p \times q} \\ = & {(\begin{matrix} a_{w}^{D} w_{1} a_{1} & a_{w}^{D} w_{1} b_{12} + a_{w}^{D} w_{12} b_{2} \\ 0 & 0 \end{matrix})}_{p \times q} . \end{matrix}

Thus, we have

a_{w}^{D} w_{1} a_{12} + a_{w}^{D} w_{12} a_{2} = a_{w}^{D} w_{1} b_{12} + a_{w}^{D} w_{12} b_{2} .

Thus

w_{1} a_{12} + w_{12} a_{2} = w_{1} b_{12} + w_{12} b_{2} .

Further, we see that

\begin{matrix} {(\begin{matrix} a_{w}^{D} a_{1} & a_{w}^{D} a_{12} \\ 0 & 0 \end{matrix})}_{p \times q} \\ = & {(\begin{matrix} a_{w}^{D} & 0 \\ 0 & 0 \end{matrix})}_{p \times p} {(\begin{matrix} a_{1} & a_{12} \\ 0 & a_{2} \end{matrix})}_{p \times q} \\ = & a_{w}^{D} a = a_{w}^{D} b \\ = & {(\begin{matrix} a_{w}^{D} & 0 \\ 0 & 0 \end{matrix})}_{p \times p} {(\begin{matrix} a_{1} & b_{12} \\ 0 & b_{2} \end{matrix})}_{p \times q} \\ = & {(\begin{matrix} a_{w}^{D} a_{1} & a_{w}^{D} b_{12} \\ 0 & 0 \end{matrix})}_{p \times q} . \end{matrix}

Hence

a_{w}^{D} a_{12} = a_{w}^{D} b_{12} .

Therefore

a_{12} = b_{12}

, as required.

(2) \Rightarrow (1)

By hypothesis, we have

a_{w}^{D} = {(\begin{matrix} a_{w}^{D} & 0 \\ 0 & 0 \end{matrix})}_{p \times q} .

Moreover, we derive

\begin{matrix} a w = {(\begin{matrix} a_{1} w_{1} & a_{1} w_{12} + a_{12} w_{2} \\ 0 & a_{2} w_{2} \end{matrix})}_{p \times p}, b w = {(\begin{matrix} a_{1} w_{1} & a_{1} w_{12} + b_{12} w_{2} \\ 0 & b_{2} w_{2} \end{matrix})}_{p \times p} . \end{matrix}

Then

a w a^{d, w} = {(\begin{matrix} a_{1} w_{1} a_{w}^{D} & 0 \\ 0 & 0 \end{matrix})}_{p \times p} = b w a_{w}^{D} .

Moreover, we have

\begin{matrix} a_{w}^{D} a & = & {(\begin{matrix} a_{w}^{D} & 0 \\ 0 & 0 \end{matrix})}_{p \times q} {(\begin{matrix} a_{1} & a_{12} \\ 0 & a_{2} \end{matrix})}_{p \times q} \\ = & {(\begin{matrix} a_{w}^{D} & 0 \\ 0 & 0 \end{matrix})}_{p \times q} {(\begin{matrix} a_{1} & a_{12} \\ 0 & b_{2} \end{matrix})}_{p \times q} \\ = & a_{w}^{D} b . \end{matrix}

Therefore

a \leq_{w}^{D} b

, as asserted. □

Corollary 4.2.

Let

a, b \in A^{D}

. Then the following are equivalent:

(1): $a \leq_{w}^{D} b$ .
(2): a and b are represented as

$a = {(\begin{matrix} a_{1} & a_{12} \\ 0 & a_{2} \end{matrix})}_{p \times p}, b = {(\begin{matrix} a_{1} & a_{12} \\ 0 & b_{2} \end{matrix})}_{p \times p},$

where $p = a a^{D}, a_{1} \in {(p A p)}^{- 1}, b_{1} \in {(p A p)}^{q n i l}, a_{2} \in {((1 - p) A (1 - p))}^{- 1}$ and $b_{2} \in {((1 - p) A (1 - p))}^{q n i l}$ .

Proof.

This is evident by setting

w = 1

in Theorem 4.1. □

We now derive the equivalent conditions for the forward order law of the weighted core-EP inverse.

Theorem 4.3.

Let

a, b, a w b \in R_{w}^{D}

and

a \leq_{w}^{D} b

. Then the following are equivalent:

(1): ${(a w b)}_{w}^{D} = a_{w}^{D} b_{w}^{D}$ .
(2): ${(a w b)}_{w}^{D} (1 - a w a_{w}^{D}) = a_{w}^{D} b_{w}^{D} (1 - a w a_{w}^{D}) = 0$ .
(3): ${(a w b)}_{w}^{D} (1 - a w a_{w}^{D}) = a w a_{w}^{D} b_{w}^{D} (1 - a w a_{w}^{D}) = 0$ .
(4): ${(a w b)}_{w}^{D} = b_{w}^{D} a_{w}^{D}$ and $a w a_{w}^{D} b_{w}^{D} (1 - a w a_{w}^{D}) = 0$ .
(5): ${(a w b)}_{w}^{D} = b_{w}^{D} a_{w}^{D}$ and $a_{w}^{D} b_{w}^{D} (1 - a w a_{w}^{D}) = 0$ .

Proof.

In view of Theorem 4.1,

a, w

and b are represented as

a = {(\begin{matrix} a_{1} & a_{12} \\ 0 & a_{2} \end{matrix})}_{p \times q}, w = {(\begin{matrix} w_{1} & w_{12} \\ 0 & w_{2} \end{matrix})}_{q \times p}, b = {(\begin{matrix} a_{1} & a_{12} \\ 0 & b_{2} \end{matrix})}_{p \times q},

where

\begin{matrix} p = a w a_{w}^{D}, q = w a_{w}^{D} a, \\ a_{1} w_{1} \in {(p A p)}^{- 1}, w_{1} a_{1} \in {(q A q)}^{- 1}, \\ a_{2} w_{2} \in {((1 - p) A (1 - p))}^{q n i l}, \\ w_{2} a_{2} \in {((1 - q) A (1 - q))}^{q n i l}, \\ w_{1} a_{12} + w_{12} a_{2} = w_{1} b_{12} + w_{12} b_{2} . \end{matrix}

Then

a w b = {(\begin{matrix} a_{1} w_{1} a_{1} & (a_{1} w_{1}) a_{12} + (a_{1} w_{12} + a_{12} w_{2}) b_{2} \\ 0 & a_{2} w_{2} b_{2} \end{matrix})}_{p \times q} .

\begin{matrix} a_{w}^{D} = {(\begin{matrix} a_{w}^{D} & 0 \\ 0 & 0 \end{matrix})}_{p \times p}, b_{w}^{D} = {(\begin{matrix} a_{w}^{D} & - a_{w}^{D} a_{12} b_{w}^{D} (1 - p) \\ 0 & (1 - p) b_{w}^{D} (1 - p) \end{matrix})}_{(p, p)}, \\ {(a w b)}_{w}^{D} = {(\begin{matrix} {(a_{w}^{D})}^{2} & - {(a_{w}^{D})}^{2} [(a_{1} w_{1}) a_{12} + (a_{1} w_{12} + a_{12} w_{2}) b_{2}] {(a w b)}_{w}^{D} (1 - p) \\ 0 & (1 - p) {(a w b)}_{w}^{D} (1 - p) \end{matrix})}_{(p, p)} . \end{matrix}

\begin{matrix} a_{w}^{D} b_{w}^{D} = {(\begin{matrix} {(a_{w}^{D})}^{2} & - {(a_{w}^{D})}^{2} a_{12} b_{w}^{D} (1 - p) \\ 0 & 0 \end{matrix})}_{(p, p)} . \end{matrix}

(1) \Rightarrow (2)

Since

{(a w b)}_{w}^{D} = a_{w}^{D} b_{w}^{D}

, we see that

a_{w}^{D} b_{w}^{D} (1 - a w a_{w}^{D}) = 0

. Moreover, we have

p {(a w b)}_{w}^{D} p = (1 - p) {(a w b)}_{w}^{D} (1 - p),

and then

{(a w b)}_{w}^{D} (1 - a w a_{w}^{D}) = 0

.

(2) \Rightarrow (3)

This is trivial.

(3) \Rightarrow (1)

Since

a w a_{w}^{D} b_{w}^{D} (1 - a w a_{w}^{D}) = 0

, we see that

b_{w}^{D} = {(\begin{matrix} a_{w}^{D} & 0 \\ 0 & (1 - p) b_{w}^{D} (1 - p) \end{matrix})}_{(p, p)} .

Hence,

\begin{matrix} a_{w}^{D} b_{w}^{D} = {(\begin{matrix} {(a_{w}^{D})}^{2} & 0 \\ 0 & 0 \end{matrix})}_{(p, p)} . \end{matrix}

Therefore

a_{w}^{D} b_{w}^{D} = {(a w b)}_{w}^{D}

, as required.

(3) \Leftrightarrow (4) \Leftrightarrow (5)

By the preceding argument, we have

\begin{matrix} a_{w}^{D} = {(\begin{matrix} a_{w}^{D} & 0 \\ 0 & 0 \end{matrix})}_{p \times p}, b_{w}^{D} = {(\begin{matrix} a_{w}^{D} & - a_{w}^{D} a_{12} b_{w}^{D} (1 - p) \\ 0 & (1 - p) b_{w}^{D} (1 - p) \end{matrix})}_{(p, p)}, \\ {(a w b)}_{w}^{D} = {(\begin{matrix} {(a_{w}^{D})}^{2} & - {(a_{w}^{D})}^{2} [(a_{1} w_{1}) a_{12} + (a_{1} w_{12} + a_{12} w_{2}) b_{2}] {(a w b)}_{w}^{D} (1 - p) \\ 0 & (1 - p) {(a w b)}_{w}^{D} (1 - p) \end{matrix})}_{(p, p)} . \end{matrix}

Then

b_{w}^{D} a_{w}^{D} = {(\begin{matrix} a_{w}^{D} & - a_{w}^{D} a_{12} b_{w}^{D} (1 - p) \\ 0 & (1 - p) b_{w}^{D} (1 - p) \end{matrix})}_{(p, p)} {(\begin{matrix} a_{w}^{D} & 0 \\ 0 & 0 \end{matrix})}_{p \times p} = {(\begin{matrix} {(a_{w}^{D})}^{2} & 0 \\ 0 & 0 \end{matrix})}_{p \times p} .

Then

{(a w b)}_{w}^{D} = b_{w}^{D} a_{w}^{D}

if and only if

{(a w b)}_{w}^{D} (1 - a w a_{w}^{D}) = 0

, as required. □

As an immediate consequence of Theorem 4.3, we extend [29] from the core-EP preorder for Hilbert space operators to that for elements of a ring with involution.

Corollary 4.4.

Let

a, b, a b \in R^{D}

and

a \leq^{D} b

. Then the following are equivalent:

(1): ${(a b)}^{D} = a^{D} b^{D}$ .
(2): ${(a b)}^{D} (1 - a a^{D}) = a^{D} b^{D} (1 - a a^{D}) = 0$ .
(3): ${(a b)}^{D} (1 - a a^{D}) = a a^{D} b^{D} (1 - a a^{D}) = 0$ .
(4): ${(a b)}^{D} = b^{D} a^{D}$ and $a a^{D} b^{D} (1 - a a^{D}) = 0$ .
(5): ${(a b)}^{D} = b^{D} a^{D}$ and $a^{D} b^{D} (1 - a a^{D}) = 0$ .

Lemma 4.5.

Let

a, b \in R_{w}^{D}

and

a \leq_{w}^{D} b

. Then the following are equivalent:

(1): $a_{w}^{D} \leq^{D} b_{w}^{D}$ .
(2): $a_{w}^{D} b_{w}^{D} = b_{w}^{D} a_{w}^{D}$ .
(3): $a_{w}^{D} b_{w}^{D} = {(a_{w}^{D})}^{2} .$

Proof.

By virtue of Theorem 4.1,

a, w

and b are represented as

a = {(\begin{matrix} a_{1} & a_{12} \\ 0 & a_{2} \end{matrix})}_{p \times q}, w = {(\begin{matrix} w_{1} & w_{12} \\ 0 & w_{2} \end{matrix})}_{q \times p}, b = {(\begin{matrix} a_{1} & a_{12} \\ 0 & b_{2} \end{matrix})}_{p \times q},

where

p = a w a_{w}^{D}, q = w a_{w}^{D} a .

As in the proof of Theorem 4.3, we have

\begin{matrix} a_{w}^{D} = {(\begin{matrix} a_{w}^{D} & 0 \\ 0 & 0 \end{matrix})}_{p \times p}, b_{w}^{D} = {(\begin{matrix} a_{w}^{D} & - a_{w}^{D} a_{12} b_{w}^{D} (1 - p) \\ 0 & (1 - p) b_{w}^{D} (1 - p) \end{matrix})}_{(p, p)} . \end{matrix}

Then

\begin{matrix} a_{w}^{D} b_{w}^{D} & = & {(\begin{matrix} a_{w}^{D} & 0 \\ 0 & 0 \end{matrix})}_{p \times p} {(\begin{matrix} a_{w}^{D} & - a_{w}^{D} a_{12} b_{w}^{D} (1 - p) \\ 0 & (1 - p) b_{w}^{D} (1 - p) \end{matrix})}_{(p, p)} \\ = & {(\begin{matrix} {(a_{w}^{D})}^{2} & - {(a_{w}^{D})}^{2} a_{12} b_{w}^{D} (1 - p) \\ 0 & 0 \end{matrix})}_{p \times p}, \\ b_{w}^{D} a_{w}^{D} & = & {(\begin{matrix} a_{w}^{D} & - a_{w}^{D} a_{12} b_{w}^{D} (1 - p) \\ 0 & (1 - p) b_{w}^{D} (1 - p) \end{matrix})}_{(p, p)} {(\begin{matrix} a_{w}^{D} & 0 \\ 0 & 0 \end{matrix})}_{p \times p} \\ = & {(\begin{matrix} {(a_{w}^{D})}^{2} & 0 \\ 0 & 0 \end{matrix})}_{p \times p} . \end{matrix}

(1) \Leftrightarrow (2)

Obviously,

{[a_{w}^{D}]}^{D} = {(a w)}^{2} a_{w}^{D} = {(\begin{matrix} {(a w)}^{2} a_{w}^{D} & 0 \\ 0 & 0 \end{matrix})}_{p \times p} .

Then

a_{w}^{D} \leq^{D} b_{w}^{D}

if and only if the following hold:

\begin{matrix} a_{w}^{D} {[a_{w}^{D}]}^{D} & = & {(\begin{matrix} {(a w)}^{2} a_{w}^{D} & 0 \\ 0 & 0 \end{matrix})}_{p \times p} = b_{w}^{D} {[a_{w}^{D}]}^{D}, \\ {[a_{w}^{D}]}^{D} a_{w}^{D} & = & {(\begin{matrix} a w a_{w}^{D} & 0 \\ 0 & 0 \end{matrix})}_{p \times p} \\ = & {(\begin{matrix} a w a_{w}^{D} & - p a_{12} b_{w}^{D} (1 - p) \\ 0 & 0 \end{matrix})}_{p \times p} \\ = & {[a_{w}^{D}]}^{D} b_{w}^{D} . \end{matrix},

i.e.,

p a_{12} b_{w}^{D} (1 - p) = 0

.

On the other hand,

a_{w}^{D} b_{w}^{D} = b_{w}^{D} a_{w}^{D}

if and only if

- a_{w}^{D} a_{12} b_{w}^{D} (1 - p) = 0

. Clearly,

a_{w}^{D} = a_{w}^{D} p

. Then

p a_{12} b_{w}^{D} (1 - p) = 0

if and only if

- a_{w}^{D} a_{12} b_{w}^{D} (1 - p) = 0

, as required.

(1) \Leftrightarrow (3)

Since

{(a_{w}^{D})}^{2} = {(\begin{matrix} {(a_{w}^{D})}^{2} & 0 \\ 0 & 0 \end{matrix})}_{p \times p}

, we see that

a_{w}^{D} b_{w}^{D} = {(a_{w}^{D})}^{2}

if and only if

- {(a_{w}^{D})}^{2} a_{12} b_{w}^{D} (1 - p) = 0

.

Since

p = a w {(a_{w}^{D})}^{2}

and

{(a_{w}^{D})}^{2} = a_{w}^{D} p

, we have

- {(a_{w}^{D})}^{2} a_{12} b_{w}^{D} (1 - p) = 0

if and only if

p a_{12} b_{w}^{D} (1 - p) = 0 .

By the argument above, we complete the proof. □

Theorem 4.6.

Let

a, b, a w b \in R_{w}^{D}

and

a \leq_{w}^{D} b

. Then

{(a w b)}_{w}^{D} = a_{w}^{D} b_{w}^{D}

if and only if

(1): $a_{w}^{D} \leq^{D} b_{w}^{D}$ ;
(2): ${(a w b)}_{w}^{D} (1 - a w a_{w}^{D}) = 0 .$

Proof.

⟹ Since

a \leq_{w}^{D} b

, by using Theorem 4.3 and Lemma 4.5,

a_{w}^{D} \leq^{D} b_{w}^{D}

. According to Theorem 4.3,

{(a w b)}_{w}^{D} (1 - a w a_{w}^{D}) = 0,

as required.

⟸ By virtue of Lemma 4.5,

a_{w}^{D} b_{w}^{D} = b_{w}^{D} a_{w}^{D}

. This completes the proof by Theorem 4.3. □

Corollary 4.7.

Let

a, b, a b \in R^{D}

and

a \leq^{D} b

. Then

{(a b)}^{D} = a^{D} b^{D}

if and only if

(1): $a^{D} \leq^{D} b^{D}$ ;
(2): ${(a b)}^{D} (1 - a a^{D}) = 0 .$

Proof.

This is obvious by choosing

w = 1

in Theorem 4.6. □

Dually, we derive the equivalent conditions for the reverse order law of the weighted core-EP inverse.

Theorem 4.8.

Let

a, b, b w a \in R_{w}^{D}

and

a \leq_{w}^{D} b

. Then the following are equivalent:

(1): ${(b w a)}_{w}^{D} = b_{w}^{D} a_{w}^{D}$ .
(2): ${(b w a)}_{w}^{D} (1 - a w a_{w}^{D}) = a w a_{w}^{D} b_{w}^{D} (1 - a w a_{w}^{D}) = 0$ .
(3): ${(b w a)}_{w}^{D} (1 - a w a_{w}^{D}) = a_{w}^{D} b_{w}^{D} (1 - a w a_{w}^{D}) = 0$ .
(4): ${(b w a)}_{w}^{D} = a_{w}^{D} b_{w}^{D}$ and $a w a_{w}^{D} b_{w}^{D} (1 - a w a_{w}^{D}) = 0$ .
(5): ${(b w a)}_{w}^{D} = a_{w}^{D} b_{w}^{D}$ and $a_{w}^{D} b_{w}^{D} (1 - a w a_{w}^{D}) = 0$ .

Proof.

By virtue of Theorem 4.1,

a, w

and b are represented as

a = {(\begin{matrix} a_{1} & a_{12} \\ 0 & a_{2} \end{matrix})}_{p \times q}, w = {(\begin{matrix} w_{1} & w_{12} \\ 0 & w_{2} \end{matrix})}_{q \times p}, b = {(\begin{matrix} a_{1} & a_{12} \\ 0 & b_{2} \end{matrix})}_{p \times q},

where

p = a w a_{w}^{D}, q = w a_{w}^{D} a .

Then

a_{w}^{D}

and

b_{w}^{D}

can be written in the matrix forms as in the proof of Theorem 4.3. Moreover, we check that

\begin{matrix} b_{w}^{D} a_{w}^{D} = {(\begin{matrix} {(a_{w}^{D})}^{2} & 0 \\ 0 & 0 \end{matrix})}_{(p, p)} . \end{matrix}

(1) \Rightarrow (2)

Since

{(b w a)}_{w}^{D} = b_{w}^{D} a_{w}^{D}

, we have

{(b w a)}_{w}^{D} (1 - a w a_{w}^{D}) = b_{w}^{D} a_{w}^{D} (1 - a w a_{w}^{D}) = 0

. Moreover, we have

p {(a w b)}_{w}^{D} p = (1 - p) {(a w b)}_{w}^{D} (1 - p),

and then

{(a w b)}_{w}^{D} (1 - a w a_{w}^{D}) = 0

.

(2) \Rightarrow (3)

This is trivial.

(3) \Rightarrow (1)

Since

a w a_{w}^{D} b_{w}^{D} (1 - a w a_{w}^{D}) = 0

, we see that

b_{w}^{D} = {(\begin{matrix} a_{w}^{D} & 0 \\ 0 & (1 - p) b_{w}^{D} (1 - p) \end{matrix})}_{(p, p)} .

Hence,

\begin{matrix} a_{w}^{D} b_{w}^{D} = {(\begin{matrix} {(a_{w}^{D})}^{2} & 0 \\ 0 & 0 \end{matrix})}_{(p, p)} . \end{matrix}

Therefore

a_{w}^{D} b_{w}^{D} = {(a w b)}_{w}^{D}

, as required.

(3) \Leftrightarrow (4) \Leftrightarrow (5)

By the preceding argument, we have

a_{w}^{D} = {(\begin{matrix} a_{w}^{D} & 0 \\ 0 & 0 \end{matrix})}_{p \times p}, b_{w}^{D} = {(\begin{matrix} a_{w}^{D} & - a_{w}^{D} a_{12} b_{w}^{D} (1 - p) \\ 0 & (1 - p) b_{w}^{D} (1 - p) \end{matrix})}_{(p, p)},

\begin{matrix} {(a w b)}_{w}^{D} \\ = & {(\begin{matrix} {(a_{w}^{D})}^{2} & - {(a_{w}^{D})}^{2} [(a_{1} w_{1}) a_{12} + (a_{1} w_{12} + a_{12} w_{2}) b_{2}] {(a w b)}_{w}^{D} (1 - p) \\ 0 & (1 - p) {(a w b)}_{w}^{D} (1 - p) \end{matrix})}_{(p, p)} . \end{matrix}

Then

b_{w}^{D} a_{w}^{D} = {(\begin{matrix} a_{w}^{D} & - a_{w}^{D} a_{12} b_{w}^{D} (1 - p) \\ 0 & (1 - p) b_{w}^{D} (1 - p) \end{matrix})}_{(p, p)} {(\begin{matrix} a_{w}^{D} & 0 \\ 0 & 0 \end{matrix})}_{p \times p} = {(\begin{matrix} {(a_{w}^{D})}^{2} & 0 \\ 0 & 0 \end{matrix})}_{p \times p} .

Then

{(a w b)}_{w}^{D} = b_{w}^{D} a_{w}^{D}

if and only if

{(a w b)}_{w}^{D} (1 - a w a_{w}^{D}) = 0

, as required. □

We now explore the equivalent conditions for

{(b - a)}_{w}^{D} = b_{w}^{D} - a_{w}^{D}

.

Theorem 4.9.

Let

a, b, b - a \in R_{w}^{D}

and

a \leq_{w}^{D} b

. Then the following are equivalent:

(1): ${(b - a)}_{w}^{D} = b_{w}^{D} - a_{w}^{D}$ .
(2): ${(b - a)}_{w}^{D} = b_{w}^{D} (1 - a w a_{w}^{D})$ .
(3): ${(b - a)}_{w}^{D} = (1 - a w a_{w}^{D}) b_{w}^{D}$ and $a_{w}^{D} b_{w}^{D} = {(a_{w}^{D})}^{2} .$
(4): ${(b - a)}_{w}^{D} = (1 - a w a_{w}^{D}) b_{w}^{D}$ and $a_{w}^{D} b_{w}^{D} (1 - a w a_{w}^{D}) = 0 .$

Proof.

By virtue of Theorem 4.1, we have

a = {(\begin{matrix} a_{1} & a_{12} \\ 0 & a_{2} \end{matrix})}_{p \times q}, w = {(\begin{matrix} w_{1} & w_{12} \\ 0 & w_{2} \end{matrix})}_{q \times p}, b = {(\begin{matrix} a_{1} & a_{12} \\ 0 & b_{2} \end{matrix})}_{p \times q},

where

p = a w a_{w}^{D}, q = w a_{w}^{D} a .

. Moreover, we compute that

\begin{matrix} a_{w}^{D} = {(\begin{matrix} a_{w}^{D} & 0 \\ 0 & 0 \end{matrix})}_{p \times p}, b_{w}^{D} = {(\begin{matrix} a_{w}^{D} & - a_{w}^{D} a_{12} b_{w}^{D} (1 - p) \\ 0 & (1 - p) b_{w}^{D} (1 - p) \end{matrix})}_{(p, p)}, \\ {(b - a)}_{w}^{D} = {(\begin{matrix} 0 & 0 \\ 0 & (1 - p) {(b - a)}_{w}^{D} (1 - p) \end{matrix})}_{(p, p)} . \end{matrix}

(1) \Leftrightarrow (2)

Obviously,

- a_{w}^{D} a_{12} b_{w}^{D} (1 - p) = p b_{w}^{D} (1 - p)

. Then

{(b - a)}_{w}^{D} = b_{w}^{D} - a_{w}^{D}

if and only if

(1 - p) {(b - a)}_{w}^{D} (1 - p) = (1 - p) b_{w}^{D} (1 - p), p b_{w}^{D} (1 - p) = 0,

i.e.,

{(b - a)}_{w}^{D} = (1 - p) {(b - a)}_{w}^{D} (1 - p) = b_{w}^{D} (1 - a w a_{w}^{D})

.

(2) \Rightarrow (3)

By the argument above, we have

\begin{matrix} a_{w}^{D} = {(\begin{matrix} a_{w}^{D} & 0 \\ 0 & 0 \end{matrix})}_{p \times p}, b_{w}^{D} = {(\begin{matrix} a_{w}^{D} & 0 \\ 0 & (1 - p) b_{w}^{D} (1 - p) \end{matrix})}_{(p, p)} . \end{matrix}

Then

a_{w}^{D} b_{w}^{D} = {(\begin{matrix} {(a_{w}^{D})}^{2} & 0 \\ 0 & 0 \end{matrix})}_{(p, p)} = {(a_{w}^{D})}^{2} .

Accordingly,

{(b - a)}_{w}^{D} = b_{w}^{D} - a_{w}^{D} = b_{w}^{D} - a w {(a_{w}^{D})}^{2} = b_{w}^{D} - a w a_{w}^{D} b_{w}^{D} = (1 - a w a_{w}^{D}) b_{w}^{D}

.

(3) \Rightarrow (4)

This is obvious as

a_{w}^{D} b_{w}^{D} (1 - a w a_{w}^{D}) = {(a_{w}^{D})}^{2} (1 - a w a_{w}^{D}) = 0 .

(4) \Rightarrow (1)

Since

a \leq_{w}^{D} b

, we have

b_{w}^{D} a = a_{w}^{D} a

. By hypothesis,

a_{w}^{D} b_{w}^{D} = a_{w}^{D} b_{w}^{D} a w a_{w}^{D}

, and then

\begin{matrix} {(b - a)}_{w}^{D} & = & b_{w}^{D} - a w (a_{w}^{D} b_{w}^{D}) \\ = & b_{w}^{D} - a w (a_{w}^{D} b_{w}^{D} a w a_{w}^{D}) \\ = & b_{w}^{D} - a w a_{w}^{D} (b_{w}^{D} a) w a_{w}^{D} \\ = & b_{w}^{D} - a w a_{w}^{D} (a_{w}^{D} a) w a_{w}^{D} \\ = & b_{w}^{D} - [a w {(a_{w}^{D})}^{2}] a w a_{w}^{D} \\ = & b_{w}^{D} - a_{w}^{D} a w a_{w}^{D} \\ = & b_{w}^{D} - a_{w}^{D}, \end{matrix}

as asserted. □

5. Weighted *-DMP Elements

The aim of this section is to characterize the weighted *-DMP element using a specific weighted core-EP decomposition. Subsequently, we will investigate the weighted core-EP order involving the weighted *-DMP element in a ring. An element a is w-weighted EP if and only if

a \in R_{w}^{#}

and

w a w a_{w}^{#} = w a_{w}^{#} a w

. We now express the weighted core-EP element by combining the weighted EP element with a nilpotent element in a ring.

Theorem 5.1.

Let

a \in R

. Then the following are equivalent:

(1): a is w-weighted *-DMP.
(2): There exist $x, y \in R$ such that

$a = x + y, x^{*} y = y w x = 0, x \in R i s w - w e i g h t e d E P, y \in R_{w}^{n i l} .$

Proof.

(1) \Rightarrow (2)

Since a is a w-weighted *-DMP element,

a \in R_{w}^{D}

. By virtue of Theorem 2.1, There exist

x, y \in R

such that

a = x + y, x^{*} y = y w x = 0, x \in R_{w}^{#}, y \in R_{w}^{n i l} .

Evidently,

a_{w}^{D} = x_{w}^{#}

. Since

w a w a_{w}^{D} = w a_{w}^{D} a w

, we check that

\begin{matrix} w x_{w}^{#} x w & = & w x_{w}^{#} x w + w x_{w}^{#} {[w x_{w}^{#}]}^{*} (x^{*} y) w \\ = & w x_{w}^{#} x w + w x_{w}^{#} [x w x_{w}^{#}] y w = w x_{w}^{#} x w + w [x_{w}^{#} x w x_{w}^{#}] y w \\ = & w x_{w}^{#} x w + w x_{w}^{#} y w = w x_{w}^{#} (x + y) w = w a_{w}^{D} a w \\ = & a w a_{w}^{D} = w (x + y) w x_{w}^{#} = w x w x_{w}^{#} . \end{matrix}

Therefore x is a w-EP element, as required.

(2) \Rightarrow (1)

By virtue of Theorem 2.1,

a \in R_{w}^{D}

. Since x is a w-EP element, we see that

w x_{w}^{#} x w = w x w x_{w}^{#}

. Hence, we have

\begin{matrix} w a_{w}^{D} a w & = & w x_{w}^{#} x w + w x_{w}^{#} y w \\ = & w x_{w}^{#} x w + w [x_{w}^{#} x w x_{w}^{#}] y w \\ = & w x_{w}^{#} x w + w [x_{w}^{#} {(w x_{w}^{#})}^{*}] (x^{*} y) w \\ = & w x_{w}^{#} x w = w (x + y) w x_{w}^{#} = w a w a_{w}^{#} . \end{matrix}

Therefore a is w-weighted *-DMP, as asserted. □

Corollary 5.2.

Let

a \in R

. Then the following are equivalent:

(1): a is *-DMP.
(2): There exist $x, y \in R$ such that

$a = x + y, x^{*} y = y w x = 0, x \in R i s E P, y \in R_{w}^{n i l} .$

Proof.

This is obtained by choosing

w = 1

in Theorem 5.1. □

Theorem 5.3.

Let

a \in R

.Then the following are equivalent:

(1): $a \in R$ is w-weighted *-DMP.
(2): ${(a w)}^{D} \in R^{#}$ and ${(a w)}^{D} {[{(a w)}^{D}]}^{#} a$ is w-weighted EP.

Proof.

(1) \Rightarrow (2)

Obviously,

a \in R_{w}^{D}

; and so

a w \in R^{D}

. In light of [4],

{(a w)}^{D} \in R^{#}

. By virtue of Theorem 5.1, there exist

x, y \in R

such that

a = x + y, x^{*} y = y w x = 0, x \in R i s w - w e i g h t e d E P, y \in R_{w}^{n i l} .

Evidently,

x = a w a_{w}^{D} a

. By using Theorem 2.4, we have

x = a w a_{w}^{D} a = a w {[{(a w)}^{D}]}^{2} {[{(a w)}^{D}]}^{#} a = {(a w)}^{D} {[{(a w)}^{D}]}^{#} a

. This implies that

{(a w)}^{D} {[{(a w)}^{D}]}^{#} a

is w-weighted EP.

(2) \Rightarrow (1)

Let

x = {(a w)}^{D} {[{(a w)}^{D}]}^{#} a

and

y = a - {(a w)}^{D} {[{(a w)}^{D}]}^{#} a

. Then

a = x + y

. Let n be the Deazin index of

a w

. Then

{(a w)}^{D} {(a w)}^{n + 1} = {(a w)}^{n}

. Obviously, we have

\begin{matrix} a w - {[{(a w)}^{D}]}^{n} {[{(a w)}^{D}]}^{#} {(a w)}^{n} \\ = & a w - {[{(a w)}^{D}]}^{n} {[{(a w)}^{D}]}^{#} {(a w)}^{D} {(a w)}^{n + 1} \\ = & a w - {[{(a w)}^{D}]}^{n - 1} ({(a w)}^{D} {[{(a w)}^{D}]}^{#} {(a w)}^{D}) {(a w)}^{n + 1} \\ = & a w - {[{(a w)}^{D}]}^{n - 1} {(a w)}^{D} {(a w)}^{n + 1} \\ = & a w - {[{(a w)}^{D}]}^{n - 1} {(a w)}^{n} = a w - {(a w)}^{D} {(a w)}^{2} . \end{matrix}

Hence,

a w - {[{(a w)}^{D}]}^{n} {[{(a w)}^{D}]}^{#} (a w) {(a w)}^{n - 1}

is nilpotent. Since

y w = a w - {(a w)}^{D} {[{(a w)}^{D}]}^{#} a w = a w - {(a w)}^{n - 1} {[{(a w)}^{D}]}^{n} {[{(a w)}^{D}]}^{#} a w

, we show that

y w \in R

is nilpotent. One easily checks that

\begin{matrix} x^{*} y & = & {({(a w)}^{D} {[{(a w)}^{D}]}^{#} a)}^{*} [a - {(a w)}^{D} {[{(a w)}^{D}]}^{#} a] \\ = & a^{*} {({(a w)}^{D} {[{(a w)}^{D}]}^{#})}^{*} [1 - {(a w)}^{D} {[{(a w)}^{D}]}^{#}] a \\ = & a^{*} {(a w)}^{D} {[{(a w)}^{D}]}^{#} [1 - {(a w)}^{D} {[{(a w)}^{D}]}^{#}] a = 0, \\ y w x & = & [a - {(a w)}^{D} {[{(a w)}^{D}]}^{#} a] w {(a w)}^{D} {[{(a w)}^{D}]}^{#} a \\ = & [1 - {(a w)}^{D} {[{(a w)}^{D}]}^{#}] a w {(a w)}^{D} {[{(a w)}^{D}]}^{#} a \\ = & [1 - {(a w)}^{D} {[{(a w)}^{D}]}^{#}] {[{(a w)}^{D}]}^{#} a \\ = & 0 . \end{matrix}

Therefore

a \in R

is w-weighted *-DMP by Theorem 2.1. □

As an immediate consequence of Theorem 5.3, we derive

Corollary 5.4.

Let

a \in R

. Then the following are equivalent:

(1): $a \in R$ is *-DMP.
(2): $a^{D} \in R^{#}$ and $a^{D} {(a^{D})}^{#} a$ is EP.

Lemma 5.5.

Let

a \in R

be w-weighted *-DMP. If

a \leq_{w}^{D} b

, then

(a w a_{w}^{D}) b w = b w (a w a_{w}^{D})

and

a_{w}^{D} b_{w}^{D} = b_{w}^{D} a_{w}^{D}

.

Proof.

Since a is w-weighted *-DMP, we have

w (a w a_{w}^{D}) = w (a_{w}^{D} a w)

. Assume that

a \leq_{w}^{D} b

. Then

a w a_{w}^{D} = b w a_{w}^{D}

and

a_{w}^{D} a = a_{w}^{D} b

. We check that

\begin{matrix} (a w a_{w}^{D}) b w & = & a w (a_{w}^{D} b) w = a w (a_{w}^{D} a) w \\ = & (a w a_{w}^{D}) a w = (b w a_{w}^{D}) a w \\ = & b w (a_{w}^{D} a w) = b w (a w a_{w}^{D}) . \end{matrix}

Since

{(a w a_{w}^{D})}^{*} = (a w a_{w}^{D})

, we deduce that

(a w a_{w}^{D}) {(b w)}^{*} = {(b w)}^{*} (a w a_{w}^{D})

. In view of [3],

(a w a_{w}^{D}) {(b w)}^{D} = {(b w)}^{D} (a w a_{w}^{D})

. Thus we have

\begin{matrix} (a w a_{w}^{D}) b_{w}^{D} & = & b_{w}^{D} (a w a_{w}^{D}) = b_{w}^{D} (b w a_{w}^{D}) \\ = & b_{w}^{D} (b w) (a w a_{w}^{D}) a_{w}^{D} = b_{w}^{D} {(b w)}^{2} {(a_{w}^{D})}^{2} \\ ⋮ \\ = & b_{w}^{D} {(b w)}^{k + 1} {(a_{w}^{D})}^{k + 1} = {(b w)}^{k} {(a_{w}^{D})}^{k + 1} = a_{w}^{D} . \end{matrix}

Therefore

\begin{matrix} a_{w}^{D} b_{w}^{D} & = & [a_{w}^{D} a w a_{w}^{D}] b_{w}^{D} = a_{w}^{D} [(a w a_{w}^{D}) b_{w}^{D}] \\ = & {(a_{w}^{D})}^{2} = [b_{w}^{D} (a w a_{w}^{D})] a_{w}^{D} = b_{w}^{D} [a w {(a_{w}^{D})}^{2}] = b_{w}^{D} a_{w}^{D}, \end{matrix}

as desired. □

We are ready to prove:

Theorem 5.6.

Let

a \in R

be w-weighted *-DMP. If

a \leq_{w}^{D} b

, then

b w (1 - a w a_{w}^{D}) \in R^{D}

.

Proof.

Since

a \leq_{w}^{D} b

, we have

a w a_{w}^{D} = b w a_{w}^{D}, a_{w}^{D} a = a_{w}^{D} b .

Since a is w-weighted *-DMP, by virtue of Lemma 5.5, we have

(a w a_{w}^{D}) b w = b w (a w a_{w}^{D}) .

We claim that

{[b w (1 - a w a_{w}^{D})]}^{D} = b_{w}^{D} - a_{w}^{D} .

Since b is w-weighted *-DMP, we have

w b w b_{w}^{D} = w b_{w}^{D} b w

. In light of Lemma 4.5 and Lemma 5.5, we have

a_{w}^{D} b_{w}^{D} = {(a_{w}^{D})}^{2}

. Then

\begin{matrix} [b w (1 - a w a_{w}^{D})] [b_{w}^{D} - a_{w}^{D}] \\ = & [b (w - w a w a_{w}^{D})] b_{w}^{D} - [b (w - w a w a_{w}^{D})] a_{w}^{D} \\ = & b w b_{w}^{D} - b w a w [a_{w}^{D} b_{w}^{D}] - b w a_{w}^{D} + b w [a w {(a_{w}^{D})}^{2}] \\ = & b w b_{w}^{D} - b w [a w {(a_{w}^{D})}^{2}] - b w a_{w}^{D} + b w [a w {(a_{w}^{D})}^{2}] \\ = & b w b_{w}^{D} - a w a_{w}^{D}; \end{matrix}

Since

{(b w b_{w}^{D})}^{*} = b w b_{w}^{D}

and

{(a w a_{w}^{D})}^{*} = a w a_{w}^{D}

, we have

{([b w (1 - a w a_{w}^{D})] [b_{w}^{D} - a_{w}^{D}])}^{*} = [b w (1 - a w a_{w}^{D})] [b_{w}^{D} - a_{w}^{D}] .

Moreover, we check that

\begin{matrix} [b w (1 - a w a_{w}^{D})] {[b_{w}^{D} - a_{w}^{D}]}^{2} \\ = & [b w b_{w}^{D} - a w a_{w}^{D}] [b_{w}^{D} - a_{w}^{D}] \\ = & b w {(b_{w}^{D})}^{2} - b w b_{w}^{D} a_{w}^{D} - a w a_{w}^{D} b_{w}^{D} + a w {(a_{w}^{D})}^{2} \\ = & b_{w}^{D} - [b w a_{w}^{D}] b_{w}^{D} = b_{w}^{D} - [a w a_{w}^{D}] b_{w}^{D} \\ = & b_{w}^{D} - a w {(a_{w}^{D})}^{2} = b_{w}^{D} - a_{w}^{D}; \\ [b_{w}^{D} - a_{w}^{D}] {[b w (1 - a w a_{w}^{D})]}^{k + 1} \\ = & [b_{w}^{D} - a_{w}^{D}] {(b w)}^{k + 1} (1 - a w a_{w}^{D}) = b_{w}^{D} ({(b w)}^{k + 1} (1 - a w a_{w}^{D}) \\ = & {(b w)}^{k} (1 - a w a_{w}^{D}) = {[b w (1 - a w a_{w}^{D})]}^{k} . \end{matrix}

This completes the proof. □

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The Weighted Core-EP Inverse and Its Associated Preorder

Abstract

Keywords:

Subject:

1. Introduction

2. Weighted Core-EP Decomposition

3. Weighted Core-EP Orders

4. Weighted Core-EP Inverse of Product and Difference

5. Weighted *-DMP Elements

References

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