Wait-Less Offline Tuning and Re-solving for Online Decision Making
December 12, 2024 ยท Declared Dead ยท ๐ International Conference on Machine Learning
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Authors
Jingruo Sun, Wenzhi Gao, Ellen Vitercik, Yinyu Ye
arXiv ID
2412.09594
Category
stat.ML: Machine Learning (Stat)
Cross-listed
cs.LG,
math.OC
Citations
1
Venue
International Conference on Machine Learning
Last Checked
4 months ago
Abstract
Online linear programming (OLP) has found broad applications in revenue management and resource allocation. State-of-the-art OLP algorithms achieve low regret by repeatedly solving linear programming (LP) subproblems that incorporate updated resource information. However, LP-based methods are computationally expensive and often inefficient for large-scale applications. In contrast, recent first-order OLP algorithms are more computationally efficient but typically suffer from worse regret guarantees. To address these shortcomings, we propose a new algorithm that combines the strengths of LP-based and first-order OLP methods. The algorithm re-solves the LP subproblems periodically at a predefined frequency $f$ and uses the latest dual prices to guide online decision-making. In addition, a first-order method runs in parallel during each interval between LP re-solves, smoothing resource consumption. Our algorithm achieves $\mathscr{O}(\log (T/f) + \sqrt{f})$ regret, delivering a "wait-less" online decision-making process that balances the computational efficiency of first-order methods and the superior regret guarantee of LP-based methods.
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