The inverse spectral problem for first order systems on the half line
Abstract
On the half line [0,∞) we study first order differential operators of the form B 1/i d/(dx) + Q(x), where B:=B100-B2, B1,B2∈ M(n,) are self--adjoint positive definite matrices and Q:+ M(2n,), +:=[0,∞), is a continuous self-adjoint off-diagonal matrix function. We determine the self-adjoint boundary conditions for these operators. We prove that for each such boundary value problem there exists a unique matrix spectral function σ and a generalized Fourier transform which diagonalizes the corresponding operator in L2σ(R, C). We give necessary and sufficient conditions for a matrix function σ to be the spectral measure of a matrix potential Q. Moreover we present a procedure based on a Gelfand-Levitan type equation for the determination of Q from σ . Our results generalize earlier results of M. Gasymov and B. Levitan. We apply our results to show the existence of 2n× 2n Dirac systems with purely absolute continuous, purely singular continuous and purely discrete spectrum of multiplicity p, where 1 p n is arbitrary.
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