Book contents
- Frontmatter
- Contents
- Preface
- Introduction
- Chapter 1 The Weyl algebra
- Chapter 2 Ideal structure of the Weyl algebra
- Chapter 3 Rings of differential operators
- Chapter 4 Jacobian Conjecture
- Chapter 5 Modules over the Weyl algebra
- Chapter 6 Differential equations
- Chapter 7 Graded and filtered modules
- Chapter 8 Noetherian rings and modules
- Chapter 9 Dimension and multiplicity
- Chapter 10 Holonomic modules
- Chapter 11 Characteristic varieties
- Chapter 12 Tensor products
- Chapter 13 External products
- Chapter 14 Inverse Image
- Chapter 15 Embeddings
- Chapter 16 Direct images
- Chapter 17 Kashiwara's theorem
- Chapter 18 Preservation of holonomy
- Chapter 19 Stability of differential equations
- Chapter 20 Automatic proof of identities
- Coda
- Appendix 1 Defining the action of a module using generators
- Appendix 2 Local inversion theorem
- References
- Index
Chapter 5 - Modules over the Weyl algebra
Published online by Cambridge University Press: 29 December 2009
- Frontmatter
- Contents
- Preface
- Introduction
- Chapter 1 The Weyl algebra
- Chapter 2 Ideal structure of the Weyl algebra
- Chapter 3 Rings of differential operators
- Chapter 4 Jacobian Conjecture
- Chapter 5 Modules over the Weyl algebra
- Chapter 6 Differential equations
- Chapter 7 Graded and filtered modules
- Chapter 8 Noetherian rings and modules
- Chapter 9 Dimension and multiplicity
- Chapter 10 Holonomic modules
- Chapter 11 Characteristic varieties
- Chapter 12 Tensor products
- Chapter 13 External products
- Chapter 14 Inverse Image
- Chapter 15 Embeddings
- Chapter 16 Direct images
- Chapter 17 Kashiwara's theorem
- Chapter 18 Preservation of holonomy
- Chapter 19 Stability of differential equations
- Chapter 20 Automatic proof of identities
- Coda
- Appendix 1 Defining the action of a module using generators
- Appendix 2 Local inversion theorem
- References
- Index
Summary
This chapter collects a number of important examples of modules over the Weyl algebra. The prototype of all the examples we discuss here is the polynomial ring in n variables; and with it we shall begin. The reader is expected to be familiar with the basic notions of module theory, as explained in [Cohn, Ch.10].
THE POLYNOMIAL RING.
In Ch. 1, the Weyl algebra was constructed as a subring of an endomorphism ring. Writing K[X] for the polynomial ring K[x1, …, xn] we have that An(K) is a subring of EndKK[X]. One deduces from this that the polynomial ring is a left An-module. Thus the action of xi on K[X] is by straightforward multiplication; whilst ∂i acts by differentiation with respect to xn. This is a very important example, and we shall study it in some detail. Let us first recall some basic definitions.
Let us first recall some basic definitions. Let R be a ring. An R-module is irreducible, or simple, if it has no proper submodules. Let M be a left R-module. An element u ∈ M is a torsion element if annR(u) is a non-zero left ideal. If every element of M is torsion, then M is called a torsion module.
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- A Primer of Algebraic D-Modules , pp. 36 - 43Publisher: Cambridge University PressPrint publication year: 1995