Random products of $SL(2,R)$ matrices and Furstenberg's theorem

Because its Lyapunov exponent is zero, but that is not what you are computing.

Instead of looking at random walks on $SL(2, mathbb{R})$, let me focus on random walks on $mathbb{R}_+^*$, as there is the same issue. Let $(X_n)$ be i.i.d. in $mathbb{R}_+^*$, and to make things simple, assume that there are only finitely many values. Let $P_n := X_n ldots X_1$.

The Lyapunov exponent of this random walk is the real $Lambda$ such that

$$lim_{n to + infty} frac{ln (P_n)}{n} = Lambda.$$

By the law of large numbers, $Lambda = mathbb{E} (ln(X_1))$. For instance, if $X_1$ takes values $2$ and $1/2$ each with probability $1/2$, the Lyapunov exponent is $0$: the Markov chain $(P_n)$ will oscillate between very large and very low values.

However, if you compute the expectation of the norm, a short computation gets you $mathbb{E} (P_n) = (5/4)^n$, which grows exponentially fast. But that does not mean that the Lyapunov exponent is $ln (5/4)$. The issue is merely that the exponential does not commute with the expectation:

$$1 = e^{mathbb{E}(ln(P_n))} leq mathbb{E} (e^{ln(P_n)}) = (5/4)^n.$$

To get back to a general random walk, and very roughyl, we have $ln(P_n) simeq mathcal{N} (nmu, nsigma^2)$. The Lyapunov exponent is the constant $mu$. However,

$$mathbb{E} (P_n) simeq mathbb{E} (e^{mathcal{N} (nmu, nsigma^2)}) = mathbb{E} (e^{n(mu+frac{sigma^2}{2})}),$$

so taking the norm as you get gives you an error coming from the diffusion of the random walk (well, in practice, the exact value of $sigma^2/2$ for this error is wrong, but I don't think the heuristics is too bad at this level).