Conservative quantum offline model-based optimization
This work addresses offline design problems where cautious predictions are needed to avoid poor solutions, but it is incremental as it combines existing quantum and classical regularization techniques.
The paper tackles the problem of offline model-based optimization by integrating quantum extremal learning with conservative objective models to prevent overly optimistic predictions, resulting in COM-QEL achieving higher true objective values than QEL on benchmark tasks.
Offline model-based optimization (MBO) refers to the task of optimizing a black-box objective function using only a fixed set of prior input-output data, without any active experimentation. Recent work has introduced quantum extremal learning (QEL), which leverages the expressive power of variational quantum circuits to learn accurate surrogate functions by training on a few data points. However, as widely studied in the classical machine learning literature, predictive models may incorrectly extrapolate objective values in unexplored regions, leading to the selection of overly optimistic solutions. In this paper, we propose integrating QEL with conservative objective models (COM) - a regularization technique aimed at ensuring cautious predictions on out-of-distribution inputs. The resulting hybrid algorithm, COM-QEL, builds on the expressive power of quantum neural networks while safeguarding generalization via conservative modeling. Empirical results on benchmark optimization tasks demonstrate that COM-QEL reliably finds solutions with higher true objective values compared to the original QEL, validating its superiority for offline design problems.