Unified Classical and Robust Optimization for Least Squares

Econometrics: Mathematical Methods & Programming eJournal Pub Date : 2018-05-21 DOI:10.2139/ssrn.3182422

Long Zhao, Deepayan Chakrabarti, K. Muthuraman

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Abstract

The solutions to robust optimization problems are sometimes too conservative because of the focus on worst-case performance. For the least-squares (LS) problem, we describe a way to overcome this by combining the classical formulation with its robust version. We do this by constructing a sequence of problems that are parameterized in terms of the well-estimated aspects of the data. One end of this sequence is the Classical LS, and the other end is a variant of Robust LS that we construct for this purpose. By choosing the right point in the sequence, we are selectively robust only to the poorly estimated aspects of the data. However, we show that better estimation does not imply better prediction. We then transform the problem to align the estimation and prediction objectives, calling it objective matching. This transformation improves prediction while provably retaining the problem structure. Objective matching allows our method (called Unified Least Squares or ULS) to consistently match or outperform other state-of-the-art techniques, including both ridge and LASSO regression, on simulations and real-world data sets.

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最小二乘的统一经典鲁棒优化

由于关注最坏情况的性能，鲁棒优化问题的解决方案有时过于保守。对于最小二乘(LS)问题，我们描述了一种通过将经典公式与其鲁棒版本相结合来克服这一问题的方法。我们通过构造一系列问题来实现这一点，这些问题是根据数据的良好估计方面参数化的。该序列的一端是经典LS，另一端是我们为此目的构建的鲁棒LS的变体。通过在序列中选择正确的点，我们只对数据估计不佳的方面具有选择性的鲁棒性。然而，我们表明更好的估计并不意味着更好的预测。然后我们将问题转换为对齐估计和预测目标，称之为目标匹配。这种转换改进了预测，同时可证明地保留了问题结构。客观匹配允许我们的方法(称为统一最小二乘法或ULS)在模拟和现实世界数据集上始终匹配或优于其他最先进的技术，包括脊回归和LASSO回归。

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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Econometrics: Mathematical Methods & Programming eJournal

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