Abstract

A new algorithm is developed for computing arbitrary real powers of a matrix . The algorithm starts with a Schur decomposition, takes square roots of the triangular factor , evaluates an [] Padé approximant of at , and squares the result times. The parameters and are chosen to minimize the cost subject to achieving double precision accuracy in the evaluation of the Padé approximant, making use of a result that bounds the error in the matrix Padé approximant by the error in the scalar Padé approximant with argument the norm of the matrix. The Padé approximant is evaluated from the continued fraction representation in bottom-up fashion, which is shown to be numerically stable. In the squaring phase the diagonal and first superdiagonal are computed from explicit formulae for , yielding increased accuracy. Since the basic algorithm is designed for , a criterion for reducing an arbitrary real to this range is developed, making use of bounds for the condition number of the problem. How best to compute for a negative integer is also investigated. In numerical experiments the new algorithm is found to be superior in accuracy and stability to several alternatives, including the use of an eigendecomposition and approaches based on the formula .