I am reading this paper, which gives the following coupling result:
Throughout this, I'll assume the dimension $k$ is clear. Let $e_i$ be the $i$-th basis in the $k$ dimensional standard basis.
A $k$ dimensional random variable $X$ is a multinomial bernoulli random variable if it is parameterized by $p \in [0,1]^k$ such that $X \in \{{\bf 0}, e_1, ..., e_k\}$ with $\Pr[X=e_i]=p_i$ and $\Pr[X={\bf 0}]=1-\sum_i p_i$.
Let $X_1, \ldots, X_n $ be independent multinomial bernoulli random variables parameterized by $p_1, ..., p_n$. Let $Y_1, ..., Y_n$ be $k$ dimensional poisson random variables where dimension $j$ of $Y_i$ is an independent Poisson $\text{Poisson}(p_{i,j})$.
Let $S_n = \sum_{i=1}^n X_i$ and $T_n = \sum_{j=1}^n Y_j$. Then the total variational distance $d(S_n, T_n)$ has the bound
$$d(S_n, T_n) = \sup_A |\Pr(S_n \in A)-\Pr(T_n \in A)| \leq \sum_{i=1}^n \left( \sum_{j=1}^k p_{i,j} \right)^2$$
Question:
The proof is fairly short. First, they use the fact that $d(X, Y)\leq \Pr[X\neq Y]$. So we have
$$d(S_n, T_n) \leq \Pr[S_n \neq T_n] \leq \sum_{i=1}^n \Pr[X_i \neq Y_i]$$ (where the last inequality uses union bound, or Boole's inequality). By using maximum coupling on $(X_i, Y_i)$, we get $\Pr[X_i \neq Y_i] \leq \Pr[X_i^\ast \neq Y_i^\ast]=d(X_i, Y_i)$. Finally, they bound $d(X_i, Y_i) \leq \left( \sum_{j=1}^k p_{i,j} \right)^2$.
My question is, where in this proof does it use independence of $X_1, ..., X_n$? Specifically, union bound does not require independence?
