Un-regularizing: approximate proximal point and faster stochastic algorithms for empirical risk minimization

Roy Frostig, Rong Ge, Sham Kakade, Aaron Sidford

Proceedings of the 32nd International Conference on Machine Learning, PMLR 37:2540-2548, 2015.

Abstract

We develop a family of accelerated stochastic algorithms that optimize sums of convex functions. Our algorithms improve upon the fastest running time for empirical risk minimization (ERM), and in particular linear least-squares regression, across a wide range of problem settings. To achieve this, we establish a framework, based on the classical proximal point algorithm, useful for accelerating recent fast stochastic algorithms in a black-box fashion. Empirically, we demonstrate that the resulting algorithms exhibit notions of stability that are advantageous in practice. Both in theory and in practice, the provided algorithms reap the computational benefits of adding a large strongly convex regularization term, without incurring a corresponding bias to the original ERM problem.

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BibTeX


@InProceedings{pmlr-v37-frostig15,
  title = 	 {Un-regularizing: approximate proximal point and faster stochastic algorithms for empirical risk minimization},
  author = 	 {Frostig, Roy and Ge, Rong and Kakade, Sham and Sidford, Aaron},
  booktitle = 	 {Proceedings of the 32nd International Conference on Machine Learning},
  pages = 	 {2540--2548},
  year = 	 {2015},
  editor = 	 {Bach, Francis and Blei, David},
  volume = 	 {37},
  series = 	 {Proceedings of Machine Learning Research},
  address = 	 {Lille, France},
  month = 	 {07--09 Jul},
  publisher =    {PMLR},
  pdf = 	 {http://proceedings.mlr.press/v37/frostig15.pdf},
  url = 	 {https://proceedings.mlr.press/v37/frostig15.html},
  abstract = 	 {We develop a family of accelerated stochastic algorithms that optimize sums of convex functions. Our algorithms improve upon the fastest running time for empirical risk minimization (ERM), and in particular linear least-squares regression, across a wide range of problem settings. To achieve this, we establish a framework, based on the classical proximal point algorithm, useful for accelerating recent fast stochastic algorithms in a black-box fashion. Empirically, we demonstrate that the resulting algorithms exhibit notions of stability that are advantageous in practice. Both in theory and in practice, the provided algorithms reap the computational benefits of adding a large strongly convex regularization term, without incurring a corresponding bias to the original ERM problem.}
}

Endnote

%0 Conference Paper
%T Un-regularizing: approximate proximal point and faster stochastic algorithms for empirical risk minimization
%A Roy Frostig
%A Rong Ge
%A Sham Kakade
%A Aaron Sidford
%B Proceedings of the 32nd International Conference on Machine Learning
%C Proceedings of Machine Learning Research
%D 2015
%E Francis Bach
%E David Blei	
%F pmlr-v37-frostig15
%I PMLR
%P 2540--2548
%U https://proceedings.mlr.press/v37/frostig15.html
%V 37
%X We develop a family of accelerated stochastic algorithms that optimize sums of convex functions. Our algorithms improve upon the fastest running time for empirical risk minimization (ERM), and in particular linear least-squares regression, across a wide range of problem settings. To achieve this, we establish a framework, based on the classical proximal point algorithm, useful for accelerating recent fast stochastic algorithms in a black-box fashion. Empirically, we demonstrate that the resulting algorithms exhibit notions of stability that are advantageous in practice. Both in theory and in practice, the provided algorithms reap the computational benefits of adding a large strongly convex regularization term, without incurring a corresponding bias to the original ERM problem.

RIS


TY  - CPAPER
TI  - Un-regularizing: approximate proximal point and faster stochastic algorithms for empirical risk minimization
AU  - Roy Frostig
AU  - Rong Ge
AU  - Sham Kakade
AU  - Aaron Sidford
BT  - Proceedings of the 32nd International Conference on Machine Learning
DA  - 2015/06/01
ED  - Francis Bach
ED  - David Blei	
ID  - pmlr-v37-frostig15
PB  - PMLR
DP  - Proceedings of Machine Learning Research
VL  - 37
SP  - 2540
EP  - 2548
L1  - http://proceedings.mlr.press/v37/frostig15.pdf
UR  - https://proceedings.mlr.press/v37/frostig15.html
AB  - We develop a family of accelerated stochastic algorithms that optimize sums of convex functions. Our algorithms improve upon the fastest running time for empirical risk minimization (ERM), and in particular linear least-squares regression, across a wide range of problem settings. To achieve this, we establish a framework, based on the classical proximal point algorithm, useful for accelerating recent fast stochastic algorithms in a black-box fashion. Empirically, we demonstrate that the resulting algorithms exhibit notions of stability that are advantageous in practice. Both in theory and in practice, the provided algorithms reap the computational benefits of adding a large strongly convex regularization term, without incurring a corresponding bias to the original ERM problem.
ER  -

APA


Frostig, R., Ge, R., Kakade, S. & Sidford, A.. (2015). Un-regularizing: approximate proximal point and faster stochastic algorithms for empirical risk minimization. Proceedings of the 32nd International Conference on Machine Learning, in Proceedings of Machine Learning Research 37:2540-2548 Available from https://proceedings.mlr.press/v37/frostig15.html.

Un-regularizing: approximate proximal point and faster stochastic algorithms for empirical risk minimization

Abstract

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