Coverings and sieves; from sheaves on sites and sheaves on spaces #
In this file, we connect coverings in a topological space to sieves in the associated Grothendieck topology, in preparation of connecting the sheaf condition on sites to the various sheaf conditions on spaces.
We also specialize results about sheaves on sites to sheaves on spaces; we show that the inclusion
functor from a topological basis to TopologicalSpace.Opens
is cover dense, that open maps
induce cover preserving functors, and that open embeddings induce continuous functors.
Given a presieve R
on U
, we obtain a covering family of open sets in X
, by taking as index
type the type of dependent pairs (V, f)
, where f : V ⟶ U
is in R
.
Equations
- TopCat.Presheaf.coveringOfPresieve U R f = f.fst
Instances For
If R
is a presieve in the grothendieck topology on Opens X
, the covering family associated
to R
really is covering, i.e. the union of all open sets equals U
.
Given a family of opens U : ι → Opens X
and any open Y : Opens X
, we obtain a presieve
on Y
by declaring that a morphism f : V ⟶ Y
is a member of the presieve if and only if
there exists an index i : ι
such that V = U i
.
Equations
- TopCat.Presheaf.presieveOfCoveringAux U Y x = ∃ (i : ι), V = U i
Instances For
Take Y
to be iSup U
and obtain a presieve over iSup U
.
Equations
Instances For
Given a presieve R
on Y
, if we take its associated family of opens via
coveringOfPresieve
(which may not cover Y
if R
is not covering), and take
the presieve on Y
associated to the family of opens via presieveOfCoveringAux
,
then we get back the original presieve R
.
The sieve generated by presieveOfCovering U
is a member of the grothendieck topology.
An index i : ι
can be turned into a dependent pair (V, f)
, where V
is an open set and
f : V ⟶ iSup U
is a member of presieveOfCovering U f
.
Equations
- TopCat.Presheaf.presieveOfCovering.homOfIndex U i = { fst := U i, snd := { val := TopologicalSpace.Opens.leSupr U i, property := (_ : ∃ (i_1 : ι), U i = U i_1) } }
Instances For
By using the axiom of choice, a dependent pair (V, f)
where f : V ⟶ iSup U
is a member of
presieveOfCovering U f
can be turned into an index i : ι
, such that V = U i
.
Equations
Instances For
Equations
Equations
- One or more equations did not get rendered due to their size.
The empty component of a sheaf is terminal.
Equations
- TopCat.Sheaf.isTerminalOfEmpty F = CategoryTheory.Sheaf.isTerminalOfBotCover F ⊥ (_ : ∀ x ∈ ⊥, ∃ (U : TopologicalSpace.Opens ↑X) (f : U ⟶ ⊥), ⊥.arrows f ∧ x ∈ U)
Instances For
A variant of isTerminalOfEmpty
that is easier to apply
.
Equations
- One or more equations did not get rendered due to their size.
Instances For
If a family B
of open sets forms a basis of the topology on X
, and if F'
is a sheaf on X
, then a homomorphism between a presheaf F
on X
and F'
is equivalent to a homomorphism between their restrictions to the indexing type
ι
of B
, with the induced category structure on ι
.
Equations
- TopCat.Sheaf.restrictHomEquivHom F F' h = CategoryTheory.Functor.IsCoverDense.restrictHomEquivHom