You are working in the compact group of unitary symplectic $4\times4$ matrices, in which every matrix is diagonalizable (because of the unitary condition); moreover there are only two independent eigenvalues, since for each eigenvalue the inverse is also an eigenvalue (because of the symplectic condition). Therefore each group element is conjugate to a diagonal matrix with diagonal entries $x,y,x^{-1},y^{-1}$ for some complex values $x,y$ of modulus $1$; it suffices to know the trace (which is invariant on conjugacy classes) on these matrices. The trace will be given by a Laurent polynomial in $x,y$ which in addition is symmetric in $x$ and $y$ and invariant under interchange of $x$ and $x^{-1}$.
The Weyl character formula gives you this Laurent polynomial as a quotient of two alternating polynomials (in the sense that they change sign under the symmetries indicated above). The result for the weight you indicated is not easy to express as a closed formula in $v$, but for instance for $v=3$ you get a Laurent polynomial with terms $x^3y^3+x^3y+x^2y^2+x^2+2xy+2$, to be completed with other terms like $x^{-3}y^3$ , $xy^3$ and $2x^{-1}y^{-1}$ to establish the required symmetry (there are $4+8+4+4+4+1=25$ terms in all; I'm too lazy to write them all down). That this is indeed the right formula can be checked by multiplying the $25$-term polynomial by the Weyl denominator $x^2y-xy^2+x^{-1}y^2-x^{-2}y+x^{-2}y^{-1}-x^{-1}y^{-2}+xy^{-2}-x^2y^{-1}$, which should give $ x^5y^4-x^4y^5+x^{-4}y^5-x^{-5}y^4+x^{-5}y^{-4}-x^{-4}y^{-5}+x^4y^{-5}-x^5y^{-4}. $ Thus that $25$-term polynomial gives you the trace of the action of any matrix in the group as function of its eigenvalues.