**The problem**

Let us suppose $P$ and $P+\Delta$ are two stochastic matrices (non-negative coefficients with $P \mathbf{1} = \mathbf{1}$ and $(P+\Delta) \mathbf{1} = \mathbf{1}$).

Let $n \geq 1$, I am seeking for a bound on $\|(P+\Delta)^n - P^n\|_F$, if possible depending on $\|\Delta\|_F$

**Discussion**

When $P$ and $P+\Delta$ are irreductible aperiodic stochastic matrices, I was thinking of studying separately :

- $\|(P+\Delta)^n - \underset{n \to \infty}{\lim} (P+\Delta)^n\|_F$
- $\|P^n - \underset{n \to \infty}{\lim}P^n\|_F$
- $\|\underset{n \to \infty}{\lim} (P+\Delta)^n - \underset{n \to \infty}{\lim}P^n\|_F$

Do you know if there is a straightforward way to bound these quantities ?

In general, can we use the convergence in average of the ergodic theorem to find a similar decomposition ?