论文信息 - BREGMAN DYNAMICS FOR OPTIMIZATION We begin with a brief review of the dynamical framework introduced in

BREGMAN DYNAMICS FOR OPTIMIZATION We begin with a brief review of the dynamical framework introduced in

Accelerated gradient methods have had significant impact in machine learning—in particular the theoretical side of machine learning— due to their ability to achieve oracle lower bounds. But their heuristic construction has hindered their full integration into the practical machine-learning algorithmic toolbox, and has limited their scope. In this paper we build on recent work which casts acceleration as a phenomenon best explained in continuous time, and we augment that picture by providing a systematic methodology for converting continuous-time dynamics into discrete-time algorithms while retaining oracle rates. Our framework is based on ideas from Hamiltonian dynamical systems and symplectic integration. These ideas have had major impact in many areas in applied mathematics, but have not yet been seen to have a relationship with optimization.

Michael I. Jordan | Ashia C. Wilson | M. Betancourt

[1] Michael I. Jordan,et al. Accelerated Gradient Descent Escapes Saddle Points Faster than Gradient Descent , 2017, COLT.

[2] Andre Wibisono,et al. A variational perspective on accelerated methods in optimization , 2016, Proceedings of the National Academy of Sciences.

[3] Stephen P. Boyd,et al. A Differential Equation for Modeling Nesterov's Accelerated Gradient Method: Theory and Insights , 2014, J. Mach. Learn. Res..

[4] Alexandre M. Bayen,et al. Accelerated Mirror Descent in Continuous and Discrete Time , 2015, NIPS.

[5] Michael Betancourt,et al. The Fundamental Incompatibility of Scalable Hamiltonian Monte Carlo and Naive Data Subsampling , 2015, ICML.

[6] E. Hairer,et al. Geometric Numerical Integration: Structure Preserving Algorithms for Ordinary Differential Equations , 2004 .

[7] G. R. W. Quispel,et al. On the Nonlinear Stability of Symplectic Integrators , 2004 .

[8] John M. Lee. Introduction to Smooth Manifolds , 2002 .

[9] J. V. José,et al. Classical Dynamics: A Contemporary Approach , 1998 .

[10] R. Bains,et al. Methods of differential geometry in analytical mechanics , 1992 .

[11] Y. Nesterov. A method for solving the convex programming problem with convergence rate O(1/k^2) , 1983 .