Derivation (mathematics): Difference between revisions
imported>Richard Pinch (→References: added Goldschmidt) |
imported>Richard Pinch (added section and anchors on Kähler differentials) |
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:<math>\Omega_{A/R} = J/J^2 \,</math> | :<math>\Omega_{A/R} = J/J^2 \,</math> | ||
as an ideal in <math>(A \otimes A)/J^2</math>, where the ''A''-module structure is given by ''A'' acting on the first factor, that is, as <math>A \otimes 1</math>. We define the map ''d'' | as an ideal in <math>(A \otimes A)/J^2</math>, where the ''A''-module structure is given by ''A'' acting on the first factor, that is, as <math>A \otimes 1</math>. We define the map ''d'' from ''A'' to Ω by | ||
:<math>d : a \mapsto 1 \otimes a - a \otimes 1 \pmod{J^2} .\,</math>. | :<math>d : a \mapsto 1 \otimes a - a \otimes 1 \pmod{J^2} .\,</math>. | ||
This is the universal derivation. | This is the universal derivation. | ||
==Kähler differentials== | |||
A '''[[Kähler differential]]''', or '''formal differential form''', is an element of the universal derivation space Ω, hence of the form <math>\sum_i x_i dy_i</math>. An ''exact'' differential is of the form <math>dy</math> for some ''y'' in ''A''. The exact differentials form a submodule of Ω. | |||
==References== | ==References== | ||
* {{cite book | author=David M. Goldschmidt | title=Algebraic Functions and Projective Curves | series=[[Graduate Texts in Mathematics]] | volume=215 | publisher=[[Springer-Verlag]] | year=2003 | isbn=0-387-95432-5 | pages=24-30 }} | * {{cite book | author=David M. Goldschmidt | title=Algebraic Functions and Projective Curves | series=[[Graduate Texts in Mathematics]] | volume=215 | publisher=[[Springer-Verlag]] | year=2003 | isbn=0-387-95432-5 | pages=24-30 }} | ||
* {{cite book | author=Serge Lang | authorlink=Serge Lang | title=Algebra | edition=3rd ed | publisher=[[Addison-Wesley]] | year=1993 | isbn=0-201-55540-9 | pages=746-749 }} | * {{cite book | author=Serge Lang | authorlink=Serge Lang | title=Algebra | edition=3rd ed | publisher=[[Addison-Wesley]] | year=1993 | isbn=0-201-55540-9 | pages=746-749 }} | ||
Revision as of 16:30, 21 December 2008
In mathematics, a derivation is a map which has formal algebraic properties generalising those of the derivative.
Let R be a ring (mathematics) and A an R-algebra (A is a ring containing a copy of R in the centre). A derivation is an R-linear map D from A to some A-module M with the property that
The constants of D are the elements mapped to zero. The constants include the copy of R inside A.
A derivation "on" A is a derivation from A to A.
Linear combinations of derivations are again derivations, so the derivations from A to M form an R-module, denoted DerR(A,M).
Examples
- The zero map is a derivation.
- The formal derivative is a derivation on the polynomial ring R[X] with constants R.
Universal derivation
There is a universal derivation (Ω,d) with a universal property. Given a derivation D:A → M, there is a unique A-linear f:Ω → M such that D = d.f. Hence
as a functorial isomorphism.
Consider the multiplication map μ on the tensor product (over R)
defined by . Let J be the kernel of μ. We define the module of differentials
as an ideal in , where the A-module structure is given by A acting on the first factor, that is, as . We define the map d from A to Ω by
- .
This is the universal derivation.
Kähler differentials
A Kähler differential, or formal differential form, is an element of the universal derivation space Ω, hence of the form . An exact differential is of the form for some y in A. The exact differentials form a submodule of Ω.
References
- David M. Goldschmidt (2003). Algebraic Functions and Projective Curves. Springer-Verlag, 24-30. ISBN 0-387-95432-5.
- Serge Lang (1993). Algebra, 3rd ed. Addison-Wesley, 746-749. ISBN 0-201-55540-9.