English

Risk Bounds and Calibration for a Smart Predict-then-Optimize Method

Machine Learning 2021-10-27 v2 Optimization and Control Machine Learning

Abstract

The predict-then-optimize framework is fundamental in practical stochastic decision-making problems: first predict unknown parameters of an optimization model, then solve the problem using the predicted values. A natural loss function in this setting is defined by measuring the decision error induced by the predicted parameters, which was named the Smart Predict-then-Optimize (SPO) loss by Elmachtoub and Grigas [arXiv:1710.08005]. Since the SPO loss is typically nonconvex and possibly discontinuous, Elmachtoub and Grigas [arXiv:1710.08005] introduced a convex surrogate, called the SPO+ loss, that importantly accounts for the underlying structure of the optimization model. In this paper, we greatly expand upon the consistency results for the SPO+ loss provided by Elmachtoub and Grigas [arXiv:1710.08005]. We develop risk bounds and uniform calibration results for the SPO+ loss relative to the SPO loss, which provide a quantitative way to transfer the excess surrogate risk to excess true risk. By combining our risk bounds with generalization bounds, we show that the empirical minimizer of the SPO+ loss achieves low excess true risk with high probability. We first demonstrate these results in the case when the feasible region of the underlying optimization problem is a polyhedron, and then we show that the results can be strengthened substantially when the feasible region is a level set of a strongly convex function. We perform experiments to empirically demonstrate the strength of the SPO+ surrogate, as compared to standard 1\ell_1 and squared 2\ell_2 prediction error losses, on portfolio allocation and cost-sensitive multi-class classification problems.

Keywords

Cite

@article{arxiv.2108.08887,
  title  = {Risk Bounds and Calibration for a Smart Predict-then-Optimize Method},
  author = {Heyuan Liu and Paul Grigas},
  journal= {arXiv preprint arXiv:2108.08887},
  year   = {2021}
}

Comments

To appear in NeurIPS 2021

R2 v1 2026-06-24T05:15:59.330Z