Eigenvector in Non-Commutative Algebra

Abstract

[1]#1 [1]#1 **- Let e be a basis of vector space V over non-commutative D-algebra A. Endomorhism eb of vector space V whose matrix with respect to given basis e has form Eb where E is identity matrix is called similarity transformation with respect to the basis e. Let V be a left A-vector space and e be basis of left A-vector space V. The vector v∈ V is called eigenvector of the endomorphism \[ f:V→ V\] with respect to the basis e, if there exists b∈ A such that \[ fv= eb v \] A-number b is called eigenvalue of the endomorphism f with respect to the basis e. There are two products of matrices: ** (row column: (ab)ij=aikbkj) and ** (column row: (ab)ij=akjbik). A-number b is called eigenvalue of the matrix f if the matrix f-bE is singular matrix. The A-number b is called right eigenvalue if there exists the column vector u which satisfies to the equality \[a** u=ub\] The column vector u is called eigencolumn for right eigenvalue b. The A-number b is called left eigenvalue if there exists the row vector u which satisfies to the equality \[u** a=bu\] The row vector u is called eigenrow for right eigenvalue b. The set spec(a) of all left and right eigenvalues is called spectrum of the matrix a.