A Generalized Index Theorem For Monotone Matrix-Valued Functions With Applications To Discrete Oscillation Theory

An index theorem is a tool for computing the change of the index (i.e., the number of negative eigenvalues) of a symmetric monotone matrix-valued function when its variable passes through a singularity. In 1995, the first author proved an index theorem in which a certain critical matrix coefficient is constant. In this paper, we generalize the above index theorem to the case when this critical matrix may be varying, but its rank, as well as the rank of some additional matrix, are constant. This includes as a special case the situation when this matrix has a constant image. We also show that the index theorem does not hold when the main assumption on constant ranks is violated. Our investigation is motivated by the oscillation theory of discrete symplectic systems and Sturm-Liouville difference equations with nonlinear dependence on the spectral parameter, which was recently developed by the second author and for which we obtain new oscillation theorems.