Fredholm backstepping for critical operators and application to rapid stabilization for the linearized water waves

TL;DR

This paper introduces a new compactness/duality method based on Fredholm's alternative to extend Fredholm backstepping techniques for critical operators, demonstrated on rapid stabilization of linearized water waves.

Contribution

It develops a novel method to handle operators of order $ extstyle rac{3}{2}$, enabling the construction of backstepping transformations for critical operators.

Findings

Successfully proved the existence of a Riesz basis for the backstepping transformation.

Extended the applicability of Fredholm backstepping to operators with $ extstyle rac{3}{2}$ order.

Applied the method to stabilize linearized water wave equations.

Abstract

Fredholm-type backstepping transformation, introduced by Coron and L\"u, has become a powerful tool for rapid stabilization with fast development over the last decade. Its strength lies in its systematic approach, allowing to deduce rapid stabilization from approximate controllability. But limitations with the current approach exist for operators of the form $|D_x|^\alpha$ for $\alpha \in (1,3/2]$. We present here a new compactness/duality method which hinges on Fredholm's alternative to overcome the $\alpha=3/2$ threshold. More precisely, the compactness/duality method allows to prove the existence of a Riesz basis for the backstepping transformation for skew-adjoint operator verifying $\alpha>1$, a key step in the construction of the Fredholm backstepping transformation, where the usual methods only work for $\alpha>3/2$. The illustration of this new method is shown on the rapid stabilization of the linearized capillary-gravity water wave equation exhibiting an operator of critical order $\alpha=3/2$.