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 7 - Graded and filtered modules
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
Simple rings are very hard to study because most techniques in ring theory depend on the existence of two-sided ideals. In the case of the Weyl algebra, however, we have a way out. As we saw in Ch. 2, one may define a degree for the elements of the Weyl algebra. Using this degree, we construct a commutative ring, k[x] works as a shadow of An. We may then draw an outline of what An really looks like. This is the best method we have for understanding the structure of An and of its modules.
GRADED RINGS
An important feature of a polynomial ring is that it admits a degree function. We want to generalize and formalize what it means for an algebra to have a degree. This leads to the definition of graded rings. These rings find their justification in algebraic geometry, more precisely in projective algebraic geometry; for details see [Hartshorne, Ch. 1, §2], For the sake of completeness, we define graded rings without assuming commutativity.
Let R be a K-algebra. We say that R is graded if there are K-vector subspaces Ri, i ∈ ℕ, such that
(1) R = ⊕i∈ℕRi,
(2) Ri · Ri ⊆ Ri+.
The Ri are called the homogeneous components of R. The elements of Ri are the homogeneous elements of degree i. If Ri = 0 when i < 0 then we say that the grading is positive. From now on all graded algebras will have a positive grading unless explicitly stated otherwise.
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- A Primer of Algebraic D-Modules , pp. 53 - 64Publisher: Cambridge University PressPrint publication year: 1995