通过持久性敏感优化实现拓扑正则化

IF 0.4 4区 计算机科学 Q4 MATHEMATICS
Arnur Nigmetov , Aditi Krishnapriyan , Nicole Sanderson , Dmitriy Morozov
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引用次数: 0

摘要

优化是机器学习和统计学的重要工具,它依赖于正则化来减少过拟合。传统的正则化方法控制解的规范,以确保其平滑性。最近,拓扑方法应运而生,它能对解法进行更精确、更有表现力的控制,依靠持久同源性来量化和降低解法的粗糙度。所有这些现有技术都是通过持久图反向传播梯度,持久图是函数拓扑特征的总结。它们的缺点是只能提供函数临界点的信息。我们提出的方法则建立在对持久性敏感的简化基础上,将持久性图所需的变化转化为包括临界点和规则点在内的大域子集上的变化。这种方法可以实现更快、更精确的拓扑正则化,我们将通过实验来说明这种方法的优势。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Topological regularization via persistence-sensitive optimization

Optimization, a key tool in machine learning and statistics, relies on regularization to reduce overfitting. Traditional regularization methods control a norm of the solution to ensure its smoothness. Recently, topological methods have emerged as a way to provide a more precise and expressive control over the solution, relying on persistent homology to quantify and reduce its roughness. All such existing techniques back-propagate gradients through the persistence diagram, which is a summary of the topological features of a function. Their downside is that they provide information only at the critical points of the function. We propose a method that instead builds on persistence-sensitive simplification and translates the required changes to the persistence diagram into changes on large subsets of the domain, including both critical and regular points. This approach enables a faster and more precise topological regularization, the benefits of which we illustrate with experimental evidence.

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来源期刊
CiteScore
1.60
自引率
16.70%
发文量
43
审稿时长
>12 weeks
期刊介绍: Computational Geometry is a forum for research in theoretical and applied aspects of computational geometry. The journal publishes fundamental research in all areas of the subject, as well as disseminating information on the applications, techniques, and use of computational geometry. Computational Geometry publishes articles on the design and analysis of geometric algorithms. All aspects of computational geometry are covered, including the numerical, graph theoretical and combinatorial aspects. Also welcomed are computational geometry solutions to fundamental problems arising in computer graphics, pattern recognition, robotics, image processing, CAD-CAM, VLSI design and geographical information systems. Computational Geometry features a special section containing open problems and concise reports on implementations of computational geometry tools.
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