1. Polynomial -- 1.1 Continuous Polynomials -- 1.2 Topologies on Spaces of Polynomials -- 1.3 Geometry of Spaces of Polynomials -- 1.4 Exercises -- 1.5 Notes -- 2. Duality Theory for Polynomial -- 2.1 Special Spaces of Polynomials and the Approximation Property -- 2.2 Nuclear Spaces -- 2.3 Integral Polynomials and the Radon-Nikodým Property -- 2.4 Reflexivity and Related Concepts -- 2.5 Exercises -- 2.6 Notes -- 3. Holomorphic Mappings between Locally Convex Space -- 3.1 Holomorphic Functions -- 3.2 Topologies on Spaces of Holomorphic Mappings -- 3.3 The Quasi-Local Theory of Holomorphic Functions -- 3.4 Polynomials in the Quasi-Local Theory -- 3.5 Exercises -- 3.6 Notes -- 4. Decompositions of Holomorphic Function -- 4.1 Decompositions of Spaces of Holomorphic Functions -- 4.2 ?? - ?? for Fréchet Spaces -- 4.3 ?b -?? for Fréchet Spaces -- 4.4 Examples and Counterexamples -- 4.5 Exercises -- 4.6 Notes -- 5. Riemann Domain -- 5.1 Holomorphic Germs on a Fréchet Space -- 5.2 Riemann Domains over Locally Convex Spaces -- 5.3 Exercises -- 5.4 Notes -- 6. Holomorphic Extension -- 6.1 Extensions from Dense Subspaces -- 6.2 Extensions from Closed Subspaces -- 6.3 Holomorphic Functions of Bounded Type -- 6.4 Exercises -- 6.5 Notes -- Appendix. Remarks on Selected Exercises -- References.
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SUMMARY OR ABSTRACT
Text of Note
Infinite dimensional holomorphy is the study of holomorphic or analytic func tions over complex topological vector spaces. The terms in this description are easily stated and explained and allow the subject to project itself ini tially, and innocently, as a compact theory with well defined boundaries. However, a comprehensive study would include delving into, and interacting with, not only the obvious topics of topology, several complex variables theory and functional analysis but also, differential geometry, Jordan algebras, Lie groups, operator theory, logic, differential equations and fixed point theory. This diversity leads to a dynamic synthesis of ideas and to an appreciation of a remarkable feature of mathematics - its unity. Unity requires synthesis while synthesis leads to unity. It is necessary to stand back every so often, to take an overall look at one's subject and ask "How has it developed over the last ten, twenty, fifty years? Where is it going? What am I doing?" I was asking these questions during the spring of 1993 as I prepared a short course to be given at Universidade Federal do Rio de Janeiro during the following July. The abundance of suit able material made the selection of topics difficult. For some time I hesitated between two very different aspects of infinite dimensional holomorphy, the geometric-algebraic theory associated with bounded symmetric domains and Jordan triple systems and the topological theory which forms the subject of the present book.