Finiteness conditions in commutative algebra #
In this file we define a notion of finiteness that is common in commutative algebra.
Main declarations #
Algebra.FiniteType
,RingHom.FiniteType
,AlgHom.FiniteType
all of these express that some object is finitely generated as algebra over some base ring.
An algebra over a commutative semiring is of FiniteType
if it is finitely generated
over the base ring as algebra.
- out : ⊤.FG
Instances
Equations
- ⋯ = ⋯
An algebra is finitely generated if and only if it is a quotient of a free algebra whose variables are indexed by a finset.
A commutative algebra is finitely generated if and only if it is a quotient of a polynomial ring whose variables are indexed by a finset.
An algebra is finitely generated if and only if it is a quotient of a polynomial ring whose variables are indexed by a fintype.
A commutative algebra is finitely generated if and only if it is a quotient of a polynomial ring whose variables are indexed by a fintype.
A commutative algebra is finitely generated if and only if it is a quotient of a polynomial ring
in n
variables.
Equations
- ⋯ = ⋯
A ring morphism A →+* B
is of FiniteType
if B
is finitely generated as A
-algebra.
Equations
- f.FiniteType = Algebra.FiniteType A B
Instances For
Alias of RingHom.FiniteType.of_finite
.
An algebra morphism A →ₐ[R] B
is of FiniteType
if it is of finite type as ring morphism.
In other words, if B
is finitely generated as A
-algebra.
Equations
- f.FiniteType = f.FiniteType
Instances For
An element of R[M]
is in the subalgebra generated by its support.
If a set S
generates, as algebra, R[M]
, then the set of supports of
elements of S
generates R[M]
.
If a set S
generates, as algebra, R[M]
, then the image of the union of
the supports of elements of S
generates R[M]
.
If R[M]
is of finite type, then there is a G : Finset M
such that its
image generates, as algebra, R[M]
.
The image of an element m : M
in R[M]
belongs the submodule generated by
S : Set M
if and only if m ∈ S
.
If the image of an element m : M
in R[M]
belongs the submodule generated by
the closure of some S : Set M
then m ∈ closure S
.
If a set S
generates an additive monoid M
, then the image of M
generates, as algebra,
R[M]
.
If a set S
generates an additive monoid M
, then the image of M
generates, as algebra,
R[M]
.
If an additive monoid M
is finitely generated then R[M]
is of finite
type.
Equations
- ⋯ = ⋯
An additive monoid M
is finitely generated if and only if R[M]
is of
finite type.
If R[M]
is of finite type then M
is finitely generated.
An additive group G
is finitely generated if and only if R[G]
is of
finite type.
An element of MonoidAlgebra R M
is in the subalgebra generated by its support.
If a set S
generates, as algebra, MonoidAlgebra R M
, then the set of supports of elements
of S
generates MonoidAlgebra R M
.
If a set S
generates, as algebra, MonoidAlgebra R M
, then the image of the union of the
supports of elements of S
generates MonoidAlgebra R M
.
If MonoidAlgebra R M
is of finite type, then there is a G : Finset M
such that its image
generates, as algebra, MonoidAlgebra R M
.
The image of an element m : M
in MonoidAlgebra R M
belongs the submodule generated by
S : Set M
if and only if m ∈ S
.
If the image of an element m : M
in MonoidAlgebra R M
belongs the submodule generated by the
closure of some S : Set M
then m ∈ closure S
.
If a set S
generates a monoid M
, then the image of M
generates, as algebra,
MonoidAlgebra R M
.
If a set S
generates an additive monoid M
, then the image of M
generates, as algebra,
R[M]
.
If a monoid M
is finitely generated then MonoidAlgebra R M
is of finite type.
Equations
- ⋯ = ⋯
A monoid M
is finitely generated if and only if MonoidAlgebra R M
is of finite type.
If MonoidAlgebra R M
is of finite type then M
is finitely generated.
A group G
is finitely generated if and only if R[G]
is of finite type.
Any commutative ring R
satisfies the OrzechProperty
, that is, for any finitely generated
R
-module M
, any surjective homomorphism f : N →ₗ[R] M
from a submodule N
of M
to M
is injective.
This is a consequence of Noetherian case
(IsNoetherian.injective_of_surjective_of_injective
), which requires that M
is a
Noetherian module, but allows R
to be non-commutative. The reduction of this result to
Noetherian case is adapted from https://math.stackexchange.com/a/1066110:
suppose { m_j }
is a finite set of generator of M
, for any n : N
one can write
i n = ∑ j, b_j * m_j
for { b_j }
in R
, here i : N →ₗ[R] M
is the standard inclusion.
We can choose { n_j }
which are preimages of { m_j }
under f
, and can choose
{ c_jl }
in R
such that i n_j = ∑ l, c_jl * m_l
for each j
.
Now let A
be the subring of R
generated by { b_j }
and { c_jl }
, then it is
Noetherian. Let N'
be the A
-submodule of N
generated by n
and { n_j }
,
M'
be the A
-submodule of M
generated by { m_j }
,
then it's easy to see that i
and f
restrict to N' →ₗ[A] M'
,
and the restricted version of f
is surjective, hence by Noetherian case,
it is also injective, in particular, if f n = 0
, then n = 0
.
See also Orzech's original paper: Onto endomorphisms are isomorphisms [orzech1971].
Equations
- ⋯ = ⋯
A theorem by Vasconcelos, given a finite module M
over a commutative ring, any
surjective endomorphism of M
is also injective.
It is a consequence of the fact CommRing.orzechProperty
that any commutative ring R
satisfies the OrzechProperty
;
please use OrzechProperty.injective_of_surjective_endomorphism
instead.
This is similar to IsNoetherian.injective_of_surjective_endomorphism
but only applies in the
commutative case, but does not use a Noetherian hypothesis.