Pre-training helps Bayesian optimization too
This addresses the problem of inefficient hyperparameter tuning for machine learning practitioners, offering a significant improvement but being incremental as it builds on existing Bayesian optimization methods.
The paper tackles the challenge of selecting Gaussian process priors in Bayesian optimization for hyperparameter tuning by proposing a pre-training approach using data from similar functions, resulting in at least 3 times more efficient location of good hyperparameters compared to competing methods.
Bayesian optimization (BO) has become a popular strategy for global optimization of many expensive real-world functions. Contrary to a common belief that BO is suited to optimizing black-box functions, it actually requires domain knowledge on characteristics of those functions to deploy BO successfully. Such domain knowledge often manifests in Gaussian process priors that specify initial beliefs on functions. However, even with expert knowledge, it is not an easy task to select a prior. This is especially true for hyperparameter tuning problems on complex machine learning models, where landscapes of tuning objectives are often difficult to comprehend. We seek an alternative practice for setting these functional priors. In particular, we consider the scenario where we have data from similar functions that allow us to pre-train a tighter distribution a priori. To verify our approach in realistic model training setups, we collected a large multi-task hyperparameter tuning dataset by training tens of thousands of configurations of near-state-of-the-art models on popular image and text datasets, as well as a protein sequence dataset. Our results show that on average, our method is able to locate good hyperparameters at least 3 times more efficiently than the best competing methods.