Let \K denote a field and let V denote a vector space over \K with finite positive dimension. We consider an ordered pair of linear transformations A:V\to V and A*:V \to V that satisfy the following four conditions: (i) Each of A,A* is diagonalizable; (ii) there exists an ordering {V_i}_{i=0}^d of the eigenspaces of A such that A*V_i\subseteq V_{i-1}+V_i+V_{i+1} for 0\leq i\leq d, where V_{-1}=0 and V_{d+1}=0; (iii) there exists an ordering {V*_i}_{i=0}^δ of the eigenspaces of A* such that AV*_i\subseteq V*_{i-1}+V*_i+V*_{i+1} for 0\leq i\leqδ, where V*_{-1}=0 and V*_{δ+1}=0; (iv) there does not exist a subspace W of V such that AW\subseteq W, A*W\subseteq W, W\neq0, W\neq V. We call such a pair a TD pair on V. It is known that d=δ; to avoid trivialities assume d\geq 1. We show that there exists a unique linear transformation Δ:V\to V such that (Δ-I)V*_i\subseteq V*_0+V*_1+...+V*_{i-1} and Δ(V_i+V_{i+1}+...+V_d)=V_0 +V_{1}+...+V_{d-i} for 0\leq i \leq d. We show that there exists a unique linear transformation Ψ:V\to V such that ΨV_i\subseteq V_{i-1}+V_i+V_{i+1} and (Ψ-Λ)V*_i\subseteq V*_0+V*_1+...+V*_{i-2} for 0\leq i\leq d, where Λ=(Δ-I)(θ_0-θ_d)^{-1} and θ_0 (resp θ_d) denotes the eigenvalue of A associated with V_0 (resp V_d). We characterize Δ,Ψin several ways. There are two well-known decompositions of V called the first and second split decomposition. We discuss how Δ,Ψact on these decompositions. We also show how Δ,Ψrelate to each other. Along this line we have two main results. Our first main result is that Δ,Ψcommute. In the literature on TD pairs there is a scalar βused to describe the eigenvalues. Our second main result is that each of Δ^{\pm 1} is a polynomial of degree d in Ψ, under a minor assumption on β.

36 pages