Let $E$ be an elliptic curve over the raional field with conductor $N$, which corresponds to the eigenform $f(z)=\sum a_nq^n$. Let $L(Sym^2E,s)$ be the L function of the symmetric power of $E$.I am trying to understand a formula in Zagier's paper "Classical and elliptic polylogarithms and special values of L series" on Page 36 which can be used to compute $L(Sym^2E,3)$.
Let $L_2(f,s):=\zeta(s-1)L(Sym^2E,s)=\sum_{n}b_n/n^s$. By Rankin's method we have the functional equation $L^{*}_2(f,s)=L^{*}_2(f,3-s)$, where $L^{*}(f,s)=(2\pi)^{-2s}N^s\Gamma(s)\Gamma(s-1)L_2(f,s)$.
The Gamma factor $\Gamma(s)\Gamma(s-1)$ has a relation with the Bessel function:
$\int_{0}^{\infty}K_v(y)y^s\frac{dy}{y}=2^{s-2}\Gamma(\frac{s+v}{2})\Gamma(\frac{s-v}{2})$ See page 106 of Bump's book Automorphic forms and representations.
Then Zagier gives the following formula
$$L_2(f,3)=C(A-\frac{A^2}{2})+\frac{1}{16}\sum_{n=1}^{\infty}\frac{b_n}{n^3}G_1(4\pi\sqrt{\frac{nA}{N}})+\frac{2^8\pi^6}{N^3}\sum_{n=1}^{\infty}b_nG_2(4\pi\sqrt{\frac{n}{NA}}),$$
Where $$C=2\pi^2N^{-1}L(Sym^2E,2)$$ and
$$G_1(x):=\int_x^{\infty}t^4K_1(t)dt$$ and $$G_2(x):=\int_x^{\infty}t^{-2}K_1(t)dt$$
Zagier mentioned that the formula $L_2(f,3)$ is obtained by splitting up the integral of the Mellin transform of the K-Bessel function into two pieces in the usual way. I would like to know how this can be done by choosing some $A$ in the formula of $L_2(f,s)$
