The Jordan decomposition and Kaplansky's second test problem for Hermitian holomorphic vector bundles
Abstract
In 1954, I. Kaplansky proposed three test problems for deciding the strength of structural understanding of a class of mathematical objects in his treatise "Infinite abelian groups", which can be formulated for very general mathematical systems. In this paper, we focus on Kaplansky's second test problem in a context of complex geometry. Let H2β be a weighted Hardy space. The Cowen-Douglas operator theory tells us that each h∈Hol(D) induces a Hermitian holomorphic vector bundle on H2β, denoted by Eh(Sβ)(), where is a domain. We show that the vector bundle Eh(Sβ) is a push-forwards Hermitian holomorphic vector bundle and study the similarity deformation problems. Our main theorem is that if H2β is a weighted Hardy space of polynomial growth, then for any f∈ Hol(D), there exists a unique positive integer m and an function h∈Hol(D) inducing an indecomposable vector bundle Eh(Sβ), such that Ef(Sβ) is similar to 1m Eh(Sβ), where h is unique in the sense of analytic automorphism group action. That could be seemed as a Jordan decomposition theorem for the push-forwards Hermitian holomorphic vector bundles. Furthermore, we give the similarity classification of those push-forwards Hermitian holomorphic vector bundles induced by analytic functions, and give an affirmative answer to Kaplansky's second test problem for those objects. We also give an affirmative answer to the geometric version and generalized version of a problem proposed by R. Douglas in 2007, and obtain the K0-group of the commutant algebra of a multiplication operator on a weighted Hardy space of polynomial growth. In addition, we give an example to show the setting of polynomial growth condition is necessary.
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