Complementary composite minimization, small gradients in general norms, and applications

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS
Jelena Diakonikolas, Cristóbal Guzmán
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Abstract

Composite minimization is a powerful framework in large-scale convex optimization, based on decoupling of the objective function into terms with structurally different properties and allowing for more flexible algorithmic design. We introduce a new algorithmic framework for complementary composite minimization, where the objective function decouples into a (weakly) smooth and a uniformly convex term. This particular form of decoupling is pervasive in statistics and machine learning, due to its link to regularization. The main contributions of our work are summarized as follows. First, we introduce the problem of complementary composite minimization in general normed spaces; second, we provide a unified accelerated algorithmic framework to address broad classes of complementary composite minimization problems; and third, we prove that the algorithms resulting from our framework are near-optimal in most of the standard optimization settings. Additionally, we show that our algorithmic framework can be used to address the problem of making the gradients small in general normed spaces. As a concrete example, we obtain a nearly-optimal method for the standard \(\ell _1\) setup (small gradients in the \(\ell _\infty \) norm), essentially matching the bound of Nesterov (Optima Math Optim Soc Newsl 88:10–11, 2012) that was previously known only for the Euclidean setup. Finally, we show that our composite methods are broadly applicable to a number of regression and other classes of optimization problems, where regularization plays a key role. Our methods lead to complexity bounds that are either new or match the best existing ones.

互补复合最小化、一般规范中的小梯度及其应用
复合最小化是大规模凸优化的一个强大框架,其基础是将目标函数解耦为具有不同结构性质的项,从而实现更灵活的算法设计。我们为互补复合最小化引入了一个新的算法框架,其中目标函数解耦为一个(弱)平滑项和一个均匀凸项。由于与正则化的联系,这种特殊形式的解耦在统计学和机器学习中非常普遍。我们工作的主要贡献总结如下。首先,我们介绍了一般规范空间中的互补复合最小化问题;其次,我们提供了一个统一的加速算法框架,以解决各类互补复合最小化问题;第三,我们证明了我们的框架所产生的算法在大多数标准优化设置中接近最优。此外,我们还证明了我们的算法框架可用于解决在一般规范空间中使梯度变小的问题。举个具体的例子,我们得到了标准 \(\ell _1\)设置(在 \(\ell _infty \)规范中的小梯度)的近乎最优方法,基本上与内斯特洛夫(Optima Math Optim Soc Newsl 88:10-11,2012)的约束相匹配,而这一约束以前只在欧几里得设置中已知。最后,我们展示了我们的复合方法广泛适用于许多回归和其他优化问题,其中正则化起着关键作用。我们的方法所得出的复杂度边界要么是全新的,要么与现有的最佳边界相匹配。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
ACS Applied Bio Materials
ACS Applied Bio Materials Chemistry-Chemistry (all)
CiteScore
9.40
自引率
2.10%
发文量
464
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