Cost-Efficient Online Hyperparameter Optimization
This work addresses the computational bottleneck in hyperparameter tuning for deep learning practitioners, offering a more efficient alternative to existing methods.
The paper tackles the high computational cost of online hyperparameter optimization by proposing a cost-efficient algorithm that queries validation loss only when model confidence is low, achieving human expert-level performance on VGG and ResNet with modest overhead.
Recent work on hyperparameters optimization (HPO) has shown the possibility of training certain hyperparameters together with regular parameters. However, these online HPO algorithms still require running evaluation on a set of validation examples at each training step, steeply increasing the training cost. To decide when to query the validation loss, we model online HPO as a time-varying Bayesian optimization problem, on top of which we propose a novel \textit{costly feedback} setting to capture the concept of the query cost. Under this setting, standard algorithms are cost-inefficient as they evaluate on the validation set at every round. In contrast, the cost-efficient GP-UCB algorithm proposed in this paper queries the unknown function only when the model is less confident about current decisions. We evaluate our proposed algorithm by tuning hyperparameters online for VGG and ResNet on CIFAR-10 and ImageNet100. Our proposed online HPO algorithm reaches human expert-level performance within a single run of the experiment, while incurring only modest computational overhead compared to regular training.