Taniyama's problems

Let ${\displaystyle k}$ be a totally real number field, and ${\displaystyle F(\tau )}$ be a Hilbert modular form to the field ${\displaystyle k}$. Then, choosing ${\displaystyle F(\tau )}$ in a suitable manner, we can obtain a system of Erich Hecke's L-series with Größencharakter ${\displaystyle \lambda }$, which corresponds one-to-one to this ${\displaystyle F(\tau )}$ by the process of Mellin transformation. This can be proved by a generalization of the theory of operator ${\displaystyle T}$ of Hecke to Hilbert modular functions (cf. Hermann Weyl).^[3]

Let ${\displaystyle C}$ be an elliptic curve defined over an algebraic number field ${\displaystyle k}$, and ${\displaystyle L_{C}(s)}$ the L-function of ${\displaystyle C}$ over ${\displaystyle k}$ in the sense that ${\displaystyle \zeta _{C}(s)=\zeta _{k}(s)\zeta _{k}(s-1)/L_{C}(s)}$ is the zeta function of ${\displaystyle C}$ over ${\displaystyle k}$. If the Hasse–Weil conjecture is true for ${\displaystyle \zeta _{C}(s)}$, then the Fourier series obtained from ${\displaystyle L_{C}(s)}$ by the inverse Mellin transformation must be an automorphic form of dimension -2 of a special type (see Hecke^[a]). If so, it is very plausible that this form is an ellipic differential of the field of associated automorphic functions. Now, going through these observations backward, is it possible to prove the Hasse-Weil conjecture by finding a suitable automorphic form from which ${\displaystyle L_{C}(s)}$ can be obtained?^[6][3]

To characterize the field of elliptic modular functions of level ${\displaystyle N}$, and especially to decompose the Jacobian variety ${\displaystyle J}$ of this function field into simple factors up to isogeny. Also it is well known that if ${\displaystyle N=q}$, a prime, and ${\displaystyle q\equiv 3{\pmod {4}}}$, then ${\displaystyle J}$ contains elliptic curves with complex multiplication. What can one say for general ${\displaystyle N}$?^[1]