holds for all , then we have
holds for any pair , then we have a section such that
holds for all .
We may similarly define sheaf of sets, sheaf of modules, etc.
Restriction map of is defined in an obvious manner.
Then it is easy to see that satisfies the sheaf axiom and that
holds for any in a natural way.
From the previous Lemma, we only need to prove locality and gluing lemma for open sets of the form . That means, in proving the properties (1) and (2) of Definition 1.19, we may assume that for some elements .
Furthermore, in doing so we may use the identification . By replacing by , this means that we may assume that .
To sum up, we may assume
To simplify the notation, in the rest of the proof, we shall denote by
the canonical map which we have formerly written . Furthermore, for any pair of the index set, we shall denote by the canonical map
Locality: Compactness of (Theorem 1.12) implies that there exist finitely many open sets among such that . In particular there exit elements of such that
(PU) |
Let be elements such that
With the help of the ``module version'' of Lemma 1.8, we see that for each , there exist positive integers such that
holds for all . Let us take the maximum of . It is easy to see that
holds for any . On the other hand, taking -th power of the equation (PU) above, we may find elements such that
holds. Then we compute
to conclude that .
Gluing lemma:
Let be given such that they satisfy
for any . We fist choose a finite subcovering of . Then we may choose a positive integer such that
holds for all .
Then by the same argument which appears in the ``locality" part, there exists a positive integer such that
holds for all . We rewrite the above equation as follows.
On the other hand, by taking -th power of the equation (PU), we may see that there exist elements such that
holds.
Now we put
Then since for any
holds on , we have .
Now, take any other open set from the covering . is again a finite open covering of . We thus know from the argument above that there exists an element of such that
From the locality, coincides with . In particular, holds. This means satisfies the requirement for the ``glued object''.