In a Hilbert space setting, we consider a new first order optimization algorithm which is obtained by temporal discretization of a damped inertial dynamic involving dry friction. The function f to be minimized is assumed to be differentiable (not necessarily convex). The dry friction potential function φ, which has a sharp minimum at the origin, enters the algorithm via its proximal mapping, which acts as a soft thresholding operator on the sum of the velocity and the gradient terms. After a finite number of steps, the structure of the algorithm changes, losing its inertial character to become the steepest descent method. The geometric damping driven by the Hessian of f makes it possible to control and attenuate the oscillations. The algori...
International audienceWe introduce a new class of forward-backward algorithms for structured convex ...
First-order optimization algorithms can be considered as a discretization of ordinary differential e...
Optimization is an important discipline of applied mathematics with far-reaching applications. Optim...
In a Hilbert space setting, we consider a new first order optimization algorithm which is obtained b...
In a Hilbert space $H$, based on inertial dynamics with dry friction damping, we introduce a new cla...
In a Hilbert space H, we introduce a new class of proximal-gradient algorithms with finite convergen...
In a Hilbert space setting, for convex optimization, we analyze the convergence rate of a class of f...
International audienceIn a Hilbert space setting, for convex optimization, we analyze the convergenc...
In a Hilbert space setting, for convex optimization, we show the convergence of the iterates to opti...
In a Hilbert space setting, in order to develop fast first-order methods for convex optimization, we...
In a Hilbert space H, we study the stabilization in finite time of the trajectories generated by a c...
In a Hilbertian framework, for the minimization of a general convex differentiable function f , we i...
International audienceIn a Hilbert framework, for general convex differentiable optimization, we con...
In a Hilbert space setting, we study a class of first-order algorithms which aim to solve structured...
In a Hilbert space H, we study a dynamic inertial Newton method which aims to solve additively struc...
International audienceWe introduce a new class of forward-backward algorithms for structured convex ...
First-order optimization algorithms can be considered as a discretization of ordinary differential e...
Optimization is an important discipline of applied mathematics with far-reaching applications. Optim...
In a Hilbert space setting, we consider a new first order optimization algorithm which is obtained b...
In a Hilbert space $H$, based on inertial dynamics with dry friction damping, we introduce a new cla...
In a Hilbert space H, we introduce a new class of proximal-gradient algorithms with finite convergen...
In a Hilbert space setting, for convex optimization, we analyze the convergence rate of a class of f...
International audienceIn a Hilbert space setting, for convex optimization, we analyze the convergenc...
In a Hilbert space setting, for convex optimization, we show the convergence of the iterates to opti...
In a Hilbert space setting, in order to develop fast first-order methods for convex optimization, we...
In a Hilbert space H, we study the stabilization in finite time of the trajectories generated by a c...
In a Hilbertian framework, for the minimization of a general convex differentiable function f , we i...
International audienceIn a Hilbert framework, for general convex differentiable optimization, we con...
In a Hilbert space setting, we study a class of first-order algorithms which aim to solve structured...
In a Hilbert space H, we study a dynamic inertial Newton method which aims to solve additively struc...
International audienceWe introduce a new class of forward-backward algorithms for structured convex ...
First-order optimization algorithms can be considered as a discretization of ordinary differential e...
Optimization is an important discipline of applied mathematics with far-reaching applications. Optim...