主动轮廓情况下的 PDE 框架公式加速优化。

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS
ACS Applied Bio Materials Pub Date : 2020-01-01 Epub Date: 2020-11-19 DOI:10.1137/19m1304210
Anthony Yezzi, Ganesh Sundaramoorthi, Minas Benyamin
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引用次数: 0

摘要

在涅斯捷罗夫的开创性工作之后,加速优化方法已被用于在二阶优化策略不适用或不切实际的情况下,有力地提高基于梯度的一阶参数估计的性能。与传统梯度下降法相比,加速梯度下降法不仅收敛速度快得多,而且对参数空间进行的局部搜索更加稳健,最初会出现超调,然后在最终配置中振荡回调,从而只选择局部最小值,其吸引力基础大到足以包含最初的超调。这种行为使得加速和随机梯度搜索方法在机器学习界特别流行。在最近发表的 2016 年美国国家科学院院刊论文《优化加速方法的变分视角》(A Variational Perspective on Accelerated Methods in Optimization)中,Wibisono、Wilson 和 Jordan 展示了如何在围绕布雷格曼发散(Bregman divergence)制定的变分框架中采用一大类加速方案,从而引出连续极限 ODE。我们展示了如何通过用切线空间上的内积代替布雷格曼发散,并明确引入分布式质量模型,在优化过程中与感兴趣的对象共同演化,从而将他们的公式进一步扩展到无限维流形(这里从曲线和曲面的几何空间开始)。引入共同演化的质量模型纯粹是为了赋予优化以有益的动态性,同时也将由此产生的基于 PDE 的加速优化方案与最优质量传输的流体动力学公式联系起来。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Accelerated Optimization in the PDE Framework Formulations for the Active Contour Case.

Following the seminal work of Nesterov, accelerated optimization methods have been used to powerfully boost the performance of first-order, gradient based parameter estimation in scenarios where second-order optimization strategies are either inapplicable or impractical. Not only does accelerated gradient descent converge considerably faster than traditional gradient descent, but it also performs a more robust local search of the parameter space by initially overshooting and then oscillating back as it settles into a final configuration, thereby selecting only local minimizers with a basis of attraction large enough to contain the initial overshoot. This behavior has made accelerated and stochastic gradient search methods particularly popular within the machine learning community. In their recent PNAS 2016 paper, A Variational Perspective on Accelerated Methods in Optimization, Wibisono, Wilson, and Jordan demonstrate how a broad class of accelerated schemes can be cast in a variational framework formulated around the Bregman divergence, leading to continuum limit ODEs. We show how their formulation may be further extended to infinite dimensional manifolds (starting here with the geometric space of curves and surfaces) by substituting the Bregman divergence with inner products on the tangent space and explicitly introducing a distributed mass model which evolves in conjunction with the object of interest during the optimization process. The coevolving mass model, which is introduced purely for the sake of endowing the optimization with helpful dynamics, also links the resulting class of accelerated PDE based optimization schemes to fluid dynamical formulations of optimal mass transport.

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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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