A W-weighted generalization of \1,2,3,1k\-inverse for rectangular matrices
Abstract
This paper presents a novel extension of the \1,2,3,1k\-inverse concept to complex rectangular matrices, denoted as a W-weighted \1,2,3,1k\-inverse (or \1',2',3',1k'\-inverse), where the weight W ∈ Cn × m. The study begins by introducing a weighted \1,2,3\-inverse (or \1',2',3'\-inverse) along with its representations and characterizations. The paper establishes criteria for the existence of \1',2',3'\-inverses and extends the criteria to \1'\-inverses. It is further demonstrated that A∈ Cm × n admits a \1',2',3',1k'\-inverse if and only if r(WAW)=r(A), where r(·) is the rank of a matrix. The work additionally establishes various representations for the set A\ 1',2',3',1k'\, including canonical representations derived through singular value and core-nilpotent decompositions. This, in turn, yields distinctive canonical representations for the set A\ 1,2,3,1k\. \ 1',2',3',1k'\-inverse is shown to be unique if and only if it has index 0 or 1, reducing it to the weighted core inverse. Moreover, the paper investigates properties and characterizations of \1',2',3',1k'\-inverses, which then results in new insights into the characterizations of the set A\ 1,2,3,1k\.
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