This question is something of a follow-up to Transformation formulae for classical theta functions .
How does one recognise whether a subgroup of the modular group $\Gamma=\mathrm{SL}_2(\mathbb{Z})$ is a congruence subgroup?
Now that's too broad a question for me to expect a simple answer so here's a more specific question. The subgroup $\Gamma_1(4)$ of the modular group is free of rank $2$ and freely generated by $A=\left( \begin{array}{cc} 1&1\\\ 0&1 \end{array}\right)$ and $B=\left( \begin{array}{cc} 1&0\\\ 4&1 \end{array}\right)$. If $\zeta$ and $\eta$ are roots of unity there is a homomorphism $\phi$ from $\Gamma_1(4)$ to the unit circle group sending $A$ and $B$ to $\zeta$ and $\eta$ resepectively. Then the kernel $K$ of $\phi$ has finite index in $\Gamma_1(4)$. How do we determine whether $K$ is a congruence subgroup, and if so what its level is?
In this example, the answer is yes when $\zeta^4=\eta^4=1$. There are also examples involving cube roots of unity, and involving eighth roots of unity where the answer is yes. I am interested in this example since one can construct a "modular function" $f$, homolomorphic on the upper half-plane and meromorphic at cusps such that $f(Az)=\phi(A)f(z)$ for all $A\in\Gamma_1(4)$. One can take $f=\theta_2^a\theta_3^b\theta_4^c$ for appropriate rationals $a$, $b$ and $c$.
Finally, a vaguer general question. Given a subgroup $H$ of $\Gamma$ specified as the kernel of a homomorphism from $\Gamma$ or $\Gamma_1(4)$ (or something similar) to a reasonably tractable target group, how does one determine whether $H$ is a congruence subgroup?
