AbstractWe extend the theory of nonnegative matrices to the matrices that have some negative entries. We present and prove some properties which give us information, when a matrix possesses a Perron–Frobenius eigenpair. We apply also this theory by proposing the Perron–Frobenius splitting for the solution of the linear system Ax=b by classical iterative methods. Perron–Frobenius splittings constitute an extension of the well known regular splittings, weak regular splittings and nonnegative splittings. Convergence and comparison properties are given and proved
AbstractFor nonnegative matrices A, the well known Perron–Frobenius theory studies the spectral radi...
AbstractIt is well known that the Perron root r(A) of a nonnegative matrix A lies between the smalle...
We study the combinatorial and algebraic properties of Nonnegative Matrices. Our results are divided...
AbstractWe extend the theory of nonnegative matrices to the matrices that have some negative entries...
AbstractWe extend here the Perron–Frobenius theory of nonnegative matrices to certain complex matric...
AbstractThe Stein–Rosenberg theorem is extended and generalized to the class of nonnegative splittin...
AbstractLet An,n∈N, be a sequence of k×k matrices which converge to a matrix A as n→∞. It is shown t...
AbstractWe present an extension of Perron–Frobenius theory to the spectra and numerical ranges of Pe...
AbstractWe extend the classical Perron–Frobenius theorem to matrices with some negative entries. We ...
AbstractWe present a new extension of the well-known Perron–Frobenius theorem to regular matrix pair...
AbstractTwo different generalizations of the Perron—Frobenius theory to the matrix pencil Ax = λBx a...
AbstractGeneralizations of M-matrices are studied, including the new class of GM-matrices. The matri...
Power nonnegative matrices are defined as complex matrices having at least one nonnegative integer p...
The saddle point matrices arising from many scientific computing fields have block structure $ W= \l...
AbstractThe purpose of this work is to extend some of the results of Perron and Frobenius to the fol...
AbstractFor nonnegative matrices A, the well known Perron–Frobenius theory studies the spectral radi...
AbstractIt is well known that the Perron root r(A) of a nonnegative matrix A lies between the smalle...
We study the combinatorial and algebraic properties of Nonnegative Matrices. Our results are divided...
AbstractWe extend the theory of nonnegative matrices to the matrices that have some negative entries...
AbstractWe extend here the Perron–Frobenius theory of nonnegative matrices to certain complex matric...
AbstractThe Stein–Rosenberg theorem is extended and generalized to the class of nonnegative splittin...
AbstractLet An,n∈N, be a sequence of k×k matrices which converge to a matrix A as n→∞. It is shown t...
AbstractWe present an extension of Perron–Frobenius theory to the spectra and numerical ranges of Pe...
AbstractWe extend the classical Perron–Frobenius theorem to matrices with some negative entries. We ...
AbstractWe present a new extension of the well-known Perron–Frobenius theorem to regular matrix pair...
AbstractTwo different generalizations of the Perron—Frobenius theory to the matrix pencil Ax = λBx a...
AbstractGeneralizations of M-matrices are studied, including the new class of GM-matrices. The matri...
Power nonnegative matrices are defined as complex matrices having at least one nonnegative integer p...
The saddle point matrices arising from many scientific computing fields have block structure $ W= \l...
AbstractThe purpose of this work is to extend some of the results of Perron and Frobenius to the fol...
AbstractFor nonnegative matrices A, the well known Perron–Frobenius theory studies the spectral radi...
AbstractIt is well known that the Perron root r(A) of a nonnegative matrix A lies between the smalle...
We study the combinatorial and algebraic properties of Nonnegative Matrices. Our results are divided...