I know the levy triplet of a Poisson process
$N_t$- $(0,0,\lambda\delta_{1}(y))$ and its characteristic function is
$\phi_N=exp[-t\Bigl(\intop_{0}^{\infty}(1-e^{iuy}+iuy1_{\{\mathbf{|}\mathbf{y}|<1\}})\delta_{1}(y)\Big)]$
and also that of the standard $\alpha$ stable subordinator
$D_t$ - $(\frac{iu\alpha}{\Gamma(1-\alpha)},0,\frac{\alpha}{\Gamma(1-\alpha)}y^{-\alpha-1}dy)$ and its characteristic function is
$\phi_{D}(u)=exp[-t\bigl(-\frac{iu\alpha}{\Gamma(1-\alpha)}+\intop_{0}^{\infty}(1-e^{iuy}+iuy1_{\{\mathbf{|}\mathbf{y}|<1\}})\frac{\alpha}{\Gamma(1-\alpha)}y^{-\alpha-1}dy\bigr)]$
My question is how do I find the triplet of $(N_t,D_t)$ where $N_t$ and $D_t$ are independent?
Since in my case the two processes are independent the Levy measure of $(N_t,D_t)$ should be $v_{x}(dy_{1},dy_{2})=\delta_{1}(y_{1})\frac{\alpha}{\Gamma(1-\alpha)}y_{2}^{-\alpha-1}dy_{2}$ (or am I wrong?), in that case the characteristic function should look like this
$exp[-t\Bigl(-iu_{1}-\frac{iu_{2}\alpha}{\Gamma(1-\alpha)}+\intop_{\mathbb{R}^{2}/\{0\}}\bigl(1-e^{iu_{1}y_{1}+iu_{2}y_{2}}+iu_{1}y_{1}1_{\{\mathbf{|}\mathbf{y}|<1\}}+iu_{2}y_{2}1_{\{\mathbf{|}\mathbf{y}|<1\}}\bigr)\delta_{1}(y_{1})\frac{\alpha}{\Gamma(1-\alpha)}y_{2}^{-\alpha-1}dy_{2}\Bigr)]$
so the Levy triplet should be of the form $\bigl((b_1,b_2),0,\delta_{1}(y_{1})\frac{\alpha}{\Gamma(1-\alpha)}y_{2}^{-\alpha-1}dy_{2}\bigr) $
so my problem boils down to what is the vector $(b_1,b_2)$?
I'm not sure I can take the cut-off to be $1_{\{\mathbf{|}\mathbf{y}|<1\}}$ since in that case the integral $\intop_{0}^{\infty}\bigl(1-e^{iu_{1}y_{1}+iu_{2}y_{2}}+iu_{1}y_{1}1_{\{\mathbf{|}\mathbf{y}|<1\}}+iu_{2}y_{2}1_{\{\mathbf{|}\mathbf{y}|<1\}}\bigr)\delta_{1}(y_{1})\frac{\alpha}{\Gamma(1-\alpha)}y_{2}^{-\alpha-1}dy_{2}\Bigr)]$ diverges, or can I?
