Perturbation formulae for quenched random dynamics with applications to open systems and extreme value theory (2206.02471v1)

Abstract: We consider quasi-compact linear operator cocycles $\mathcal{L}^{n}\omega:=\mathcal{L}{\sigma^{n-1}\omega}\circ\cdots\circ\mathcal{L}_{\sigma\omega}\circ \mathcal{L}{\omega}$ driven by an invertible ergodic process $\sigma:\Omega\to\Omega$, and their small perturbations $\mathcal{L}{\omega,\epsilon}^{n}$. We prove an abstract $\omega$-wise first-order formula for the leading Lyapunov multipliers. We then consider the situation where $\mathcal{L}{\omega}^{n}$ is a transfer operator cocycle for a random map cocycle $T\omega^{n}:=T_{\sigma^{n-1}\omega}\circ\cdots\circ T_{\sigma\omega}\circ T_{\omega}$ and the perturbed transfer operators $\mathcal{L}{\omega,\epsilon}$ are defined by the introduction of small random holes $H{\omega,\epsilon}$ in $[0,1]$, creating a random open dynamical system. We obtain a first-order perturbation formula in this setting, which reads $\lambda_{\omega,\epsilon}=\lambda_\omega-\theta_{\omega}\mu_{\omega}(H_{\omega,\epsilon})+o(\mu_\omega(H_{\omega,\epsilon})),$ where $\mu_\omega$ is the unique equivariant random measure (and equilibrium state) for the original closed random dynamics. Our new machinery is then deployed to create a spectral approach for a quenched extreme value theory that considers random dynamics with general ergodic invertible driving, and random observations. An extreme value law is derived using the first-order terms $\theta_\omega$. Further, in the setting of random piecewise expanding interval maps, we establish the existence of random equilibrium states and conditionally invariant measures for random open systems via a random perturbative approach. Finally we prove quenched statistical limit theorems for random equilibrium states arising from contracting potentials. We illustrate the theory with a variety of explicit examples.