I have an expression to evaluate as follow:
$\mathbb{E}\left[\sum_{k=1}^K s_k f(x_k)\Big|s_k=s_k^{\ast} \right]$
where $\{s_k^\ast\}$ can be treated as a ${policy}$ which is defined as follows:
\begin{align} {s}_k^\ast=\left\{ \begin{aligned} &1, \quad \text{if } X_k=\max_j \{X_j\}>0 \\ &0, \quad otherwise \end{aligned}\right. \end{align} with \begin{align} X_k=a_k\left[\log (a_k x_k) \right]^+ -\Big(a_k-\frac{1}{x_k}\Big)^+ \end{align} where $a_k>0$ for all $k$ are constants, and $x_k>0$ is a random variable following $\exp(1)$ distribution. Let me define another simple policy: \begin{align} \widetilde{s}_k^\ast=\left\{ \begin{aligned} &1, \quad \text{if } x_k=\max_j \{x_j\} \\ &0, \quad otherwise \end{aligned}\right. \end{align}
According to the extreme value theory, we know the growth rate result: $x_{k^\ast}=\mathcal{O}(\log K)$, where $k^\ast=\arg\max_k \{x_k\}$, and $K$ is the number of random variables. Based on this result and the definitions of ${s}_k^\ast$ and $\widetilde{s}_k^\ast$, we know that \begin{align} {s}_k^\ast \rightarrow \widetilde{s}_k^\ast, \quad as \ K \rightarrow \infty \end{align} Therefore, we must have \begin{align} \mathbb{E}\left[\sum_{k=1}^K s_k f(x_k)\Big|s_k=s_k^{\ast} \right] \rightarrow \mathbb{E}\left[\sum_{k=1}^K s_k f(x_k)\Big|s_k=\widetilde{s}_k^{\ast} \right], \quad as \ K \rightarrow \infty \end{align} My question is whether we can quantify the gap w.r.t. $K$, i.e., \begin{align} \left|\mathbb{E}\left[\sum_{k=1}^K s_k f(x_k)\Big|s_k=s_k^{\ast} \right] -\mathbb{E}\left[\sum_{k=1}^K s_k f(x_k)\Big|s_k=\widetilde{s}_k^{\ast} \right]\right| \end{align} decrease at what order w.r.t. $K$ as $K$ increases?