I have a question about a statement from P. Wagreich's paper "Elliptic Singularities of Surfaces" (page 425):

[![enter image description here][1]][1]

We consider an elliptic curve $X$ and a line bundle (=invertible sheaf) $L$ on $X$.



Then, following EGA one finds that $V=Spec(\oplus_n \Gamma(X,L^{\otimes -n}))$ (it's a question of convention; often author's assign  instead the scheme $Spec(\oplus_n \Gamma(X,L^{\otimes n}))$).

My first question is what does the author mean by the bundle $L \to X$?

I thought that using GAGA-principles in order to "identify" invertible sheaves with line bundles the corresponding line bundle $B_L$ to $L$ over $X$ is nothing but $Spec(\oplus_n \Gamma(X,L^{\otimes -n}))$ so $V$. See for example [here][2]

But on the other hand $V$ is introduced by the author as already the resolution of the "bundle" $B_L \to X$. This confuses me. So if $V$ is already the resolution what is the associated bundle $B_L \to X$ to $L$?



Second question: I don't understand how to verify that the graded algebra $\oplus_n \Gamma(X,L^{\otimes -n})$ is generated by $1 \in \Gamma(X,L^{-1}, \wp  \in \Gamma(X,L^{-2}), \wp '  \in \Gamma(X,L^{-3})$


Honestly, I have no idea. Does it arise from a general principle for line bundles over ***elliptic curves***?


Remark: I have already asked the same question here: https://math.stackexchange.com/questions/3303909/generators-of-a-graded-algebra


  [1]: https://i.sstatic.net/c6TN1.png
  [2]: https://mathoverflow.net/questions/92588/what-is-the-geometric-point-of-view-of-an-algebraic-line-bundle-compared-to-a-an