Mathematical foundations of stable RKHSs

Reproducing kernel Hilbert spaces (RKHSs) are key spaces for machine learning that are becoming popular also for linear system identification. In particular, the so-called stable RKHSs can be used to model absolutely summable impulse responses. In combination e.g. with regularized least squares they can then be used to reconstruct dynamic systems from input-output data. In this paper we provide new structural properties of stable RKHSs. The relation between stable kernels and other fundamental classes, like those containing absolutely summable or finite-trace kernels, is elucidated. These insights are then brought into the feature space context. First, it is proved that any stable kernel admits feature maps induced by a basis of orthogonal eigenvectors in l2. The exact connection with classical system identification approaches that exploit such kind of functions to model impulse responses is also provided. Then, the necessary and sufficient stability condition for RKHSs designed by formulating kernel eigenvectors and eigenvalues is obtained. Overall, our new results provide novel mathematical foundations of stable RKHSs with impact on stability tests, impulse responses modeling and computational efficiency of regularized schemes for linear system identification.