Combining fast inertial dynamics for convex optimization with Tikhonov regularization (1602.01973v1)

Abstract: In a Hilbert space setting $\mathcal H$, we study the convergence properties as $t \to + \infty$ of the trajectories of the second-order differential equation \begin{equation*} \mbox{(AVD)}{\alpha, \epsilon} \quad \quad \ddot{x}(t) + \frac{\alpha}{t} \dot{x}(t) + \nabla \Phi (x(t)) + \epsilon (t) x(t) =0, \end{equation*} where $\nabla\Phi$ is the gradient of a convex continuously differentiable function $\Phi: \mathcal H \to \mathbb R$, $\alpha$ is a positive parameter, and $\epsilon (t) x(t)$ is a Tikhonov regularization term, with $\lim{t \to \infty}\epsilon (t) =0$. In this damped inertial system, the damping coefficient $\frac{\alpha}{t}$ vanishes asymptotically, but not too quickly, a key property to obtain rapid convergence of the values. In the case $\epsilon (\cdot) \equiv 0$, this dynamic has been highlighted recently by Su, Boyd, and Cand`es as a continuous version of the Nesterov accelerated method. Depending on the speed of convergence of $\epsilon (t)$ to zero, we analyze the convergence properties of the trajectories of $\mbox{(AVD)}_{\alpha, \epsilon}$. We obtain results ranging from the rapid convergence of $\Phi (x(t))$ to $\min \Phi$ when $\epsilon (t)$ decreases rapidly to zero, up to the strong ergodic convergence of the trajectories to the element of minimal norm of the set of minimizers of $\Phi$, when $\epsilon (t)$ tends slowly to zero.