I consider the N-step transfer matrix T for a general block Hamiltonian, with
eigenvalue equation
L_n \psi_{n+1} + H_n \psi_n + L_{n-1}^\dagger \psi_{n-1} = E \psi_n
where H_n and L_n are matrices, and provide its explicit representation in
terms of blocks of the resolvent of the Hamiltonian matrix for the system of
length N with boundary conditions \psi_0 =\psi_{N+1} =0. I then introduce the
related Hamiltonian for the case \psi_0 = z^{-1} \psi_N and \psi_{N+1} = z
\psi_1, and provide an exact relation between the trace of its resolvent and
Tr(T-z)^{-1}, together with an identity of Thouless type connecting Tr(\log
|T|) with the Hamiltonian eigenvalues for z=e^{i\phi}. The results are then
extended to T^\dagger T by showing that it is itself a transfer matrix. Besides
their own mathematical interest, the identities should be useful for an
analytical approach in the study of spectral properties of a physically
relevant class of transfer matrices.
P.A.C.S.: 02.10.Sp (theory of matrices), 05.60 (theory of quantum transport),
71.23 (Anderson model), 72.17.Rn (Quantum localization)