Weak convergence of sum of log normal random variables

Question

Let $S_t$ be the Geometric Brownian Motion, we know that $$dS_t=rS_tdt+\sigma S_tdW_t, t\in [0,T], S_0>0, r>0,\sigma>0$$ and the distribution of $S_t$ is known explicitly. Please see the link above for the density function of $S_t$. Let $h(.)$ be a bounded continuous function (as nice as you want), and consider the discretely monitored $S_{t_1},S_{t_2},\ldots, S_{t_n}$ with log-normal distribution of $S_t$. Assume that we have $$S^{k}_{t_i}\Longrightarrow S_{t_i},\quad\text{weakly as}\quad k\to\infty,$$ where $S_{t_i}$ is log-normally distributed.

My question here : Do we have the following weak convergence $$ \displaystyle\sum_{i=1}^{n}h(S^{k}_{t_i}) \Longrightarrow \displaystyle\sum_{i=1}^{n}h(S_{t_i}),\quad\text{as}\quad k\to\infty? $$ In other words, do we have $$(S_{t_1}^k,\ldots,S_{t_n}^k)\Longrightarrow (S_{t_1},\ldots,S_{t_n}) \quad\text{as}\quad k\to\infty?$$ We note the above is not true in general but I am not sure for the log-normal random variable case. It would be nice if some one could give me some ideas or hints. Thank you so much for your time. I truly appreciate it.

Answer 1

For each i, $S_{t_i}$ is distributed as $exp( (r - \sigma^2/2)t_i + Z \sqrt{t_i})$, where $Z$ is a standard normal. If we take $S^k_{t_i} = exp( (r - \sigma^2/2)t_i + Z \sqrt{t_i})$ for all k and i, then, trivially, $S^{k}_{t_i}\Longrightarrow S_{t_i},\quad\text{weakly as}\quad k\to\infty$. Take $h = ln$, then $\sum_{i=1}^{n}h(S^{k}_{t_i}) = (\sum_{i=1}^{n}(r - \sigma^2/2)t_i) + \sigma (\sum_{i=1}^{n} \sqrt{t_i}) Z$, but $\sum_{i=1}^{n}h(S_{t_i}) = (\sum_{i=1}^{n}(r - \sigma^2/2)t_i) + \sigma (\sum_{i=1}^{n} W_{t_i}) $, both normal, with same mean, but different variances, so, in general, $\sum_{i=1}^{n}h(S^{k}_{t_i})$ does not converge weakly to $\sum_{i=1}^{n}h(S_{t_i})$.