$$\textrm{Problem}\qquad\qquad
\begin{cases}\max\{\pi_0 F_{L_0}(W)-\frac{\pi_1}{W}\int_0^W F_{L_1}( \alpha )d \alpha \},  \\\
\textrm{s.t.}\quad \int_0^W F_{L_0} (\alpha)d\alpha <\xi''
\end{cases}
$$

$W$ is the variable, and $F( \cdot )$ is probability distribution function, $L_0$ and $L_1$ are random variables. Also, $\pi_0, \pi_1>0$ and $\pi_0 + \pi_1 =1$. Further, for example, $F_{L_0}$ and $F_{L_1}$ can be such as below:

\begin{eqnarray}
  F_{L_0}(\alpha) &=& 1-e^{-\mu \alpha} \quad \alpha \geq 0. \label{PDF0}\\
  F_{L_1}(\alpha) &=& 1-e^{-\lambda \alpha} \quad \alpha \geq 0.  \label{PDF1}
\end{eqnarray}