On the stability of gradient descent with second order dynamics for time-varying cost functions.

Transactions on machine learning research Pub Date : 2025-02-01

Travis E Gibson, Sawal Acharya, Anjali Parashar, Joseph E Gaudio, Anuradha M Annaswamy

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Abstract

Gradient based optimization algorithms deployed in Machine Learning (ML) applications are often analyzed and compared by their convergence rates or regret bounds. While these rates and bounds convey valuable information they don't always directly translate to stability guarantees. Stability and similar concepts, like robustness, will become ever more important as we move towards deploying models in real-time and safety critical systems. In this work we build upon the results in Gaudio et al. 2021 and Moreu & Annaswamy 2022 for gradient descent with second order dynamics when applied to explicitly time varying cost functions and provide more general stability guarantees. These more general results can aid in the design and certification of these optimization schemes so as to help ensure safe and reliable deployment for real-time learning applications. We also hope that the techniques provided here will stimulate and cross-fertilize the analysis that occurs on the same algorithms from the online learning and stochastic optimization communities.

本刊更多论文

时变代价函数二阶动力学梯度下降的稳定性。

在机器学习（ML）应用中部署的基于梯度的优化算法通常通过其收敛速度或遗憾界限进行分析和比较。虽然这些利率和上限传达了有价值的信息，但它们并不总是直接转化为稳定的保证。随着我们在实时和安全关键系统中部署模型，稳定性和类似的概念（如鲁棒性）将变得越来越重要。在这项工作中，我们以Gaudio等人2021年和Moreu & Annaswamy 2022年的结果为基础，研究了当应用于显式时变成本函数时，二阶动力学梯度下降的结果，并提供更一般的稳定性保证。这些更通用的结果可以帮助这些优化方案的设计和认证，从而帮助确保实时学习应用程序的安全可靠部署。我们也希望这里提供的技术能够刺激和促进来自在线学习和随机优化社区的相同算法的分析。

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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Transactions on machine learning research

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