Derivations of univariate polynomials #
In this file we prove that an R
-derivation of Polynomial R
is determined by its value on X
.
We also provide a constructor Polynomial.mkDerivation
that
builds a derivation from its value on X
, and a linear equivalence
Polynomial.mkDerivationEquiv
between A
and Derivation (Polynomial R) A
.
Polynomial.derivative
as a derivation.
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Instances For
The derivation on R[X]
that takes the value a
on X
.
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Polynomial.mkDerivation
as a linear equivalence.
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For a derivation d : A → M
and an element a : A
, d.compAEval a
is the
derivation of R[X]
which takes a polynomial f
to d(aeval a f)
.
This derivation takes values in Module.AEval R M a
, which is M
, regarded as an
R[X]
-module, with the action of a polynomial f
defined by f • m = (aeval a f) • m
.
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A form of the chain rule: if f
is a polynomial over R
and d : A → M
is an R
-derivation then for all a : A
we have
$$ d(f(a)) = f' (a) d a. $$
The equation is in the R[X]
-module Module.AEval R M a
.
For the same equation in M
, see Derivation.compAEval_eq
.
A form of the chain rule: if f
is a polynomial over R
and d : A → M
is an R
-derivation then for all a : A
we have
$$ d(f(a)) = f' (a) d a. $$
The equation is in M
. For the same equation in Module.AEval R M a
,
see Derivation.compAEval_eq
.