Memoirs of the American Mathematical Society 2004; 81 pp; softcover Volume: 167 ISBN10: 0821834320 ISBN13: 9780821834329 List Price: US$57 Individual Members: US$34.20 Institutional Members: US$45.60 Order Code: MEMO/167/791
 A bounded operator \(T\) acting on a Hilbert space \(\mathcal H\) is called cyclic if there is a vector \(x\) such that the linear span of the orbit \(\{T^n x : n \geq 0 \}\) is dense in \(\mathcal H\). If the scalar multiples of the orbit are dense, then \(T\) is called supercyclic. Finally, if the orbit itself is dense, then \(T\) is called hypercyclic. We completely characterize the cyclicity, the supercyclicity and the hypercyclicity of scalar multiples of composition operators, whose symbols are linear fractional maps, acting on weighted Dirichlet spaces. Particular instances of these spaces are the Bergman space, the Hardy space, and the Dirichlet space. Thus, we complete earlier work on cyclicity of linear fractional composition operators on these spaces. In this way, we find exactly the spaces in which these composition operators fail to be cyclic, supercyclic or hypercyclic. Consequently, we answer some open questions posed by Zorboska. In almost all the cases, the cutoff of cyclicity, supercyclicity or hypercyclicity of scalar multiples is determined by the spectrum. We will find that the Dirichlet space plays a critical role in the cutoff. Readership Graduate students and research mathematicians interested in operator theory. Table of Contents  Introduction and preliminaries
 Linear fractional maps with an interior fixed point
 Non elliptic automorphisms
 The parabolic non automorphism
 Supercyclic linear fractional composition operators
 Endnotes
 Bibliography
