Locally finite cycles of linear mappings in countable dimension

Abstract

Let n be a positive integer. An n-cycle of linear mappings is an n-tuple (u1,…,un) of linear maps u1 ∈ Hom(U1,U2),u2 ∈ Hom(U2,U3),…,un ∈ Hom(Un,U1), where U1,…,Un are vector spaces over a field. We classify such cycles, up to equivalence, when the spaces U1,…,Un have countable dimension and the composite un un-1 ·s u1 is locally finite. When n=1, this problem amounts to classifying the reduced locally nilpotent endomorphisms of a countable-dimensional vector space up to similarity, and the known solution involves the so-called Kaplansky invariants of u. Here, we extend Kaplansky's results to cycles of arbitrary length. As an application, we prove that if un ·s u1 is locally nilpotent and the Ui spaces have countable dimension, then there are bases B1,…,Bn of U1,…,Un, respectively, such that, for every i ∈ \1,…,n\, ui maps every vector of Bi either to a vector of Bi+1 or to the zero vector of Ui+1 (where we convene that Un+1=U1 and Bn+1=B1).